tor/doc/tor-spec.txt

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$Id$
TOR Spec
Note: This is an attempt to specify TOR as it exists as implemented in
early June, 2003. It is not recommended that others implement this
design as it stands; future versions of TOR will implement improved
protocols.
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TODO: (very soon)
- Specify truncate/truncated
- Sendme w/stream0 is circuit sendme
- Integrate -NM and -RD comments
0. Notation:
PK -- a public key.
SK -- a private key
K -- a key for a symmetric cypher
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a|b -- concatenation of 'a' with 'b'.
All numeric values are encoded in network (big-endian) order.
Unless otherwise specified, all symmetric ciphers are AES in counter
mode, with an IV of all 0 bytes. Asymmetric ciphers are either RSA
with 1024-bit keys and exponents of 65537, or DH with the safe prime
from rfc2409, section 6.2, whose hex representation is:
"FFFFFFFFFFFFFFFFC90FDAA22168C234C4C6628B80DC1CD129024E08"
"8A67CC74020BBEA63B139B22514A08798E3404DDEF9519B3CD3A431B"
"302B0A6DF25F14374FE1356D6D51C245E485B576625E7EC6F44C42E9"
"A637ED6B0BFF5CB6F406B7EDEE386BFB5A899FA5AE9F24117C4B1FE6"
"49286651ECE65381FFFFFFFFFFFFFFFF"
1. System overview
Tor is a connection-oriented anonymizing communication service. Users
build a path known as a "virtual circuit" through the network, in which
each node knows its predecessor and successor, but no others. Traffic
flowing down the circuit is unwrapped by a symmetric key at each node,
which reveals the downstream node.
2. Connections
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There are two ways to connect to an onion router (OR). The first is
as an onion proxy (OP), which allows the OP to authenticate the OR
without authenticating itself. The second is as another OR, which
allows mutual authentication.
Tor uses TLS for link encryption, using the cipher suite
"TLS_DHE_RSA_WITH_AES_128_CBC_SHA". An OR always sends a
self-signed X.509 certificate whose commonName is the server's
nickname, and whose public key is in the server directory.
All parties receiving certificates must confirm that the public
key is as it appears in the server directory, and close the
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connection if it is not.
Once a TLS connection is established, the two sides send cells
(specified below) to one another. Cells are sent serially. All
cells are 256 bytes long. Cells may be sent embedded in TLS
records of any size or divided across TLS records, but the framing
of TLS records should not leak information about the type or
contents of the cells.
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OR-to-OR connections are never deliberately closed. An OP should
close a connection to an OR if there are no circuits running over
the connection, and an amount of time (KeepalivePeriod, defaults to
5 minutes) has passed.
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
fields:
ACI (anonymous circuit identifier) [2 bytes]
Command [1 byte]
Length [1 byte]
Sequence number (unused, set to 0) [4 bytes]
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Payload (padded with 0 bytes) [248 bytes]
[Total size: 256 bytes]
The 'Command' field holds one of the following values:
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0 -- PADDING (Padding) (See Sec 6.2)
1 -- CREATE (Create a circuit) (See Sec 4)
2 -- CREATED (Acknowledge create) (See Sec 4)
3 -- RELAY (End-to-end data) (See Sec 5)
4 -- DESTROY (Stop using a circuit) (See Sec 4)
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The interpretation of 'Length' and 'Payload' depend on the type of
the cell.
PADDING: Neither field is used.
CREATE: Length is 144; the payload contains the first phase of the
DH handshake.
CREATED: Length is 128; the payload contains the second phase of
the DH handshake.
RELAY: Length is a value between 8 and 248; the first 'length'
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bytes of payload contain useful data.
DESTROY: Neither field is used.
Unused fields are filled with 0 bytes. The payload is padded with
0 bytes.
PADDING cells are currently used to implement connection
keepalive. ORs and OPs send one another a PADDING cell every few
minutes.
CREATE and DESTROY cells are used to manage circuits; see section
4 below.
RELAY cells are used to send commands and data along a circuit; see
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section 5 below.
4. Circuit management
4.1. CREATE and CREATED cells
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Users set up circuits incrementally, one hop at a time. To create
a new circuit, users send a CREATE cell to the first node, with the
first half of the DH handshake; that node responds with a CREATED cell
with the second half of the DH handshake. To extend a circuit past
the first hop, the user sends an EXTEND relay cell (see section 5)
which instructs the last node in the circuit to send a CREATE cell
to extend the circuit.
The payload for a CREATE cell is an 'onion skin', consisting of:
RSA-encrypted data [128 bytes]
Symmetrically-encrypted data [16 bytes]
The RSA-encrypted portion contains:
Symmetric key [16 bytes]
First part of DH data (g^x) [112 bytes]
The symmetrically encrypted portion contains:
Second part of DH data (g^x) [16 bytes]
The two parts of the DH data, once decrypted and concatenated, form
g^x as calculated by the client.
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The relay payload for an EXTEND relay cell consists of:
Address [4 bytes]
Port [2 bytes]
Onion skin [144 bytes]
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The port and address field denote the IPV4 address and port of the
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
servers can now calculate g^xy with ordinary DH. From the base key
material g^xy, they compute two 16 byte keys, called Kf and Kb as
follows. First, the server represents g^xy as a big-endian
unsigned integer. Next, the server computes 40 bytes of key data
as K = SHA1(g^xy | [00]) | SHA1(g^xy | [01]) where "00" is a single
octet whose value is zero, and "01" is a single octet whose value
is one. The first 16 bytes of K form Kf, and the next 16 bytes of
K form Kb.
Kf is used to encrypt the stream of data going from the OP to the
OR, whereas Kb is used to encrypt the stream of data going from the
OR to the OP.
4.3. Creating circuits
When creating a circuit through the network, the circuit creator
performs the following steps:
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1. Choose a chain of N onion routers (R_1...R_N) to constitute
the path, such that no router appears in the path twice.
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2. If not already connected to the first router in the chain,
open a new connection to that router.
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3. Choose an ACI not already in use on the connection with the
first router in the chain. If our address/port pair is
numerically higher than the address/port pair of the other
side, then let the high bit of the ACI be 1, else 0.
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4. Send a CREATE cell along the connection, to be received by
the first onion router.
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5. Wait until a CREATED cell is received; finish the handshake
and extract the forward key Kf_1 and the back key Kb_1.
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6. For each subsequent onion router R (R_2 through R_N), extend
the circuit to R.
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To extend the circuit by a single onion router R_M, the circuit
creator performs these steps:
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1. Create an onion skin, encrypting the RSA-encrypted part with
R's public key.
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2. Encrypt and send the onion skin in a relay EXTEND cell along
the circuit (see section 5).
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3. When a relay EXTENDED cell is received, calculate the shared
keys. The circuit is now extended.
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When an onion router receives an EXTEND relay cell, it sends a
CREATE cell to the next onion router, with the enclosed onion skin
as its payload. The initiating onion router chooses some random
ACI not yet used on the connection between the two onion routers.
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As an extension (called router twins), if the desired next onion
router R in the circuit is down, and some other onion router R'
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
circuit on the given connection with the given ACI, it drops the
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cell. Otherwise, sometime after receiving the CREATE cell, it completes
the DH handshake, and replies with a CREATED cell, containing g^y
as its [128 byte] payload. Upon receiving a CREATED cell, an onion
router packs it payload into an EXTENDED relay cell (see section 5),
and sends that cell up the circuit. Upon receiving the EXTENDED
relay cell, the OP can retrieve g^y.
(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
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
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
either completely or hop-by-hop.
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To tear down a circuit completely, an OR or OP sends a DESTROY
cell to the adjacent nodes on that circuit, using the appropriate
direction's ACI.
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Upon receiving an outgoing DESTROY cell, an OR frees resources
associated with the corresponding circuit. If it's not the end of
the circuit, it sends a DESTROY cell for that circuit to the next OR
in the circuit. If the node is the end of the circuit, then 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
destroy cells for the corresponding circuit.
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To tear down part of a circuit, the OP sends a RELAY_TRUNCATE cell
signaling a given OR (Stream ID zero). That OR sends a DESTROY
cell to the next node in the circuit, and replies to the OP with a
RELAY_TRUNCATED cell.
When an unrecoverable error occurs along one connection in a
circuit, the nodes on either side of the connection should, if they
are able, act as follows: the node closer to the OP should send a
RELAY_TRUNCATED cell towards the OP; the node farther from the OP
should send a DESTROY cell down the circuit.
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[We'll have to reevaluate this section once we figure out cleaner
circuit/connection killing conventions. -RD]
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4.5. Routing data cells
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When an OR receives a RELAY cell, it checks the cell's ACI and
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determines whether it has a corresponding circuit along that
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,
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:
'Forward' relay cell (same direction as CREATE):
Use Kf as key; encrypt.
'Back' relay cell (opposite direction from CREATE):
Use Kb as key; decrypt.
If the OR recognizes the stream ID on the cell (it is either the ID
of an open stream or the signaling (zero) ID), the OR processes the
contents of the relay cell. Otherwise, it passes the decrypted
relay cell along the circuit if the circuit continues, or drops the
cell if it's the end of the circuit. [Getting an unrecognized
relay cell at the end of the circuit must be allowed for now;
we can reexamine this once we've designed full tcp-style close
handshakes. -RD]
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
follows:
OP sends data cell to node R_M:
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:
OP receives data cell:
For I=N...1,
Encrypt with Kb_I. If the stream ID is a recognized
stream for R_I, or if the stream ID is the signaling
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
RELAY packets to tunnel end-to-end commands and TCP connections
("Streams") across circuits. End-to-end commands can be initiated
by either edge; streams are initiated by the OP.
The first 8 bytes of each relay cell are reserved as follows:
Relay command [1 byte]
Stream ID [7 bytes]
The recognized relay commands are:
1 -- RELAY_BEGIN
2 -- RELAY_DATA
3 -- RELAY_END
4 -- RELAY_CONNECTED
5 -- RELAY_SENDME
6 -- RELAY_EXTEND
7 -- RELAY_EXTENDED
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8 -- RELAY_TRUNCATE
9 -- RELAY_TRUNCATED
All RELAY cells pertaining to the same tunneled stream have the
same stream ID. Stream ID's are chosen randomly by the OP. A
stream ID is considered "recognized" on a circuit C by an OP or an
OR if it already has an existing stream established on that
circuit, or if the stream ID is equal to the signaling stream ID,
which is all zero: [00 00 00 00 00 00 00]
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To create a new anonymized TCP connection, the OP sends a
RELAY_BEGIN data cell with a payload encoding the address and port
of the destination host. The stream ID is zero. The payload format is:
ADDRESS | ':' | PORT | '\000'
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where ADDRESS may be a DNS hostname, or an IPv4 address in
dotted-quad format; and where PORT is encoded in decimal.
Upon receiving this packet, the exit node resolves the address as
necessary, and opens a new TCP connection to the target port. If
the address cannot be resolved, or a connection can't be
established, the exit node replies with a RELAY_END cell.
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
package stream data in RELAY_DATA cells, and upon receiving such
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cells, echo their contents to the corresponding TCP stream.
5.2. Closing streams
[Note -- TCP streams can only be half-closed for reading. Our
Bickford's conversation was incorrect. -NM]
Because TCP connections can be half-open, we follow an equivalent
to TCP's FIN/FIN-ACK/ACK protocol to close streams.
A exit conneection can have a TCP stream in one of three states:
'OPEN', 'DONE_PACKAGING', and 'DONE_DELIVERING'. For the purposes
of modeling transitions, we treat 'CLOSED' as a fourth state,
although connections in this state are not, in fact, tracked by the
onion router.
A stream begins in the 'OPEN' state. Upon receiving a 'FIN' from
the corresponding TCP connection, the edge node sends a 'RELAY_END'
cell along the circuit and changes its state to 'DONE_PACKAGING'.
Upon receiving a 'RELAY_END' cell, an edge node sends a 'FIN' to
the corresponding TCP connection (e.g., by calling
shutdown(SHUT_WR)) and changing its state to 'DONE_DELIVERING'.
When a stream in already in 'DONE_DELIVERING' receives a 'FIN', it
also sends a 'RELAY_END' along the circuit, and changes its state
to 'CLOSED'. When a stream already in 'DONE_PACKAGING' receives a
'RELAY_END' cell, it sends a 'FIN' and changes its state to
'CLOSED'.
[Note: Please rename 'RELAY_END2'. :) -NM ]
If an edge node encounters an error on any stram, it sends a
'RELAY_END2' cell along the circuit (if possible) and closes the
TCP connection immediately. If an edge node receives a
'RELAY_END2' cell for any stream, it closes the TCP connection
completely, and sends nothing along the circuit.
6. Flow control
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6.1. Link throttling
Each node should do appropriate bandwidth throttling to keep its
user happy.
Communicants rely on TCP's default flow control to push back when they
stop reading.
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6.2. Link padding
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.
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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
two 'windows', consisting of how many RELAY_DATA cells it is
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
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
receives a RELAY_SENDME cell with stream ID zero, it increments its
packaging window.
Either of these cells increment the corresponding window by 100.
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The OP behaves identically, except that it must track a packaging
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
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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6.4. Stream-level flow control
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Edge nodes use RELAY_SENDME cells to implement end-to-end flow
control for individual connections across circuits. Similarly to
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.
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7. Directories and routers
7.1. Router descriptor format.
(Unless otherwise noted, tokens on the same line are space-separated.)
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Router ::= Router-Line Date-Line Onion-Key Link-Key Signing-Key Exit-Policy Router-Signature NL
Router-Line ::= "router" address ORPort APPort DirPort bandwidth NL
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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)
APPort ::= where the router listens for applications (speaking socks)
DirPort ::= where the router listens for directory download requests
bandwidth ::= maximum bandwidth, in bytes/s
Example:
router moria.mit.edu 9001 9021 9031 100000
-----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.
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7.3. Behavior of a directory server
lists nodes that are connected currently
speaks http on a socket, spits out directory on request