control-spec.txt 19 KB

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  1. $Id$
  2. TC: A Tor control protocol
  3. 0. Scope
  4. This document describes an implementation-specific protocol that is used
  5. for other programs (such as frontend user-interfaces) to communicate
  6. with a locally running Tor process. It is not part of the Tor onion
  7. routing protocol.
  8. We're trying to be pretty extensible here, but not infinitely
  9. forward-compatible.
  10. 1. Protocol outline
  11. TC is a bidirectional message-based protocol. It assumes an underlying
  12. stream for communication between a controlling process (the "client") and
  13. a Tor process (the "server"). The stream may be implemented via TCP,
  14. TLS-over-TCP, a Unix-domain socket, or so on, but it must provide
  15. reliable in-order delivery. For security, the stream should not be
  16. accessible by untrusted parties.
  17. In TC, the client and server send typed variable-length messages to each
  18. other over the underlying stream. By default, all messages from the server
  19. are in response to messages from the client. Some client requests, however,
  20. will cause the server to send messages to the client indefinitely far into
  21. the future.
  22. Servers respond to messages in the order they're received.
  23. 2. Message format
  24. The messages take the following format:
  25. Length [2 octets; big-endian]
  26. Type [2 octets; big-endian]
  27. Body [Length octets]
  28. Upon encountering a recognized Type, implementations behave as described in
  29. section 3 below. If the type is not recognized, servers respond with an
  30. "ERROR" message (code UNRECOGNIZED; see 3.1 below), and clients simply ignore
  31. the message.
  32. 2.1. Types and encodings
  33. All numbers are given in big-endian (network) order.
  34. OR identities are given in hexadecimal, in the same format as identity key
  35. fingerprints, but without spaces; see tor-spec.txt for more information.
  36. 3. Message types
  37. Message types are drawn from the following ranges:
  38. 0x0000-0xEFFF : Reserved for use by official versions of this spec.
  39. 0xF000-0xFFFF : Unallocated; usable by unofficial extensions.
  40. 3.1. ERROR (Type 0x0000)
  41. Sent in response to a message that could not be processed as requested.
  42. The body of the message begins with a 2-byte error code. The following
  43. values are defined:
  44. 0x0000 Unspecified error
  45. []
  46. 0x0001 Internal error
  47. [Something went wrong inside Tor, so that the client's
  48. request couldn't be fulfilled.]
  49. 0x0002 Unrecognized message type
  50. [The client sent a message type we don't understand.]
  51. 0x0003 Syntax error
  52. [The client sent a message body in a format we can't parse.]
  53. 0x0004 Unrecognized configuration key
  54. [The client tried to get or set a configuration option we don't
  55. recognize.]
  56. 0x0005 Invalid configuration value
  57. [The client tried to set a configuration option to an
  58. incorrect, ill-formed, or impossible value.]
  59. 0x0006 Unrecognized byte code
  60. [The client tried to set a byte code (in the body) that
  61. we don't recognize.]
  62. 0x0007 Unauthorized.
  63. [The client tried to send a command that requires
  64. authorization, but it hasn't sent a valid AUTHENTICATE
  65. message.]
  66. 0x0008 Failed authentication attempt
  67. [The client sent a well-formed authorization message.]
  68. 0x0009 Resource exhausted
  69. [The server didn't have enough of a given resource to
  70. fulfill a given request.]
  71. 0x000A No such stream
  72. 0x000B No such circuit
  73. 0x000C No such OR
  74. The rest of the body should be a human-readable description of the error.
  75. In general, new error codes should only be added when they don't fall under
  76. one of the existing error codes.
  77. 3.2. DONE (Type 0x0001)
  78. Sent from server to client in response to a request that was successfully
  79. completed, with no more information needed. The body is usually empty but
  80. may contain a message.
  81. 3.3. SETCONF (Type 0x0002)
  82. Change the value of a configuration variable. The body contains a list of
  83. newline-terminated key-value configuration lines. An individual key-value
  84. configuration line consists of the key, followed by a space, followed by
  85. the value. The server behaves as though it had just read the key-value pair
  86. in its configuration file.
  87. The server responds with a DONE message on success, or an ERROR message on
  88. failure.
  89. When a configuration options takes multiple values, or when multiple
  90. configuration keys form a context-sensitive group (see below), then
  91. setting _any_ of the options in a SETCONF command is taken to reset all of
  92. the others. For example, if two ORBindAddress values are configured,
  93. and a SETCONF command arrives containing a single ORBindAddress value, the
  94. new command's value replaces the two old values.
  95. To _remove_ all settings for a given option entirely (and go back to its
  96. default value), send a single line containing the key and no value.
  97. 3.4. GETCONF (Type 0x0003)
  98. Request the value of a configuration variable. The body contains one or
  99. more NL-terminated strings for configuration keys. The server replies
  100. with a CONFVALUE message.
  101. If an option appears multiple times in the configuration, all of its
  102. key-value pairs are returned in order.
  103. Some options are context-sensitive, and depend on other options with
  104. different keywords. These cannot be fetched directly. Currently there
  105. is only one such option: clients should use the "HiddenServiceOptions"
  106. virtual keyword to get all HiddenServiceDir, HiddenServicePort,
  107. HiddenServiceNodes, and HiddenServiceExcludeNodes option settings.
  108. 3.5. CONFVALUE (Type 0x0004)
  109. Sent in response to a GETCONF message; contains a list of "Key Value\n"
  110. (A non-whitespace keyword, a single space, a non-NL value, a NL)
  111. strings.
  112. 3.6. SETEVENTS (Type 0x0005)
  113. Request the server to inform the client about interesting events.
  114. The body contains a list of 2-byte event codes (see "event" below).
  115. Any events *not* listed in the SETEVENTS body are turned off; thus, sending
  116. SETEVENTS with an empty body turns off all event reporting.
  117. The server responds with a DONE message on success, and an ERROR message
  118. if one of the event codes isn't recognized. (On error, the list of active
  119. event codes isn't changed.)
  120. 3.7. EVENT (Type 0x0006)
  121. Sent from the server to the client when an event has occurred and the
  122. client has requested that kind of event. The body contains a 2-byte
  123. event code followed by additional event-dependent information. Event
  124. codes are:
  125. 0x0001 -- Circuit status changed
  126. Status [1 octet]
  127. 0x00 Launched - circuit ID assigned to new circuit
  128. 0x01 Built - all hops finished, can now accept streams
  129. 0x02 Extended - one more hop has been completed
  130. 0x03 Failed - circuit closed (was not built)
  131. 0x04 Closed - circuit closed (was built)
  132. Circuit ID [4 octets]
  133. (Must be unique to Tor process/time)
  134. Path [NUL-terminated comma-separated string]
  135. (For extended/failed, is the portion of the path that is
  136. built)
  137. 0x0002 -- Stream status changed
  138. Status [1 octet]
  139. (Sent connect=0,sent resolve=1,succeeded=2,failed=3,
  140. closed=4, new connection=5, new resolve request=6,
  141. stream detached from circuit and still retriable=7)
  142. Stream ID [4 octets]
  143. (Must be unique to Tor process/time)
  144. Target (NUL-terminated address-port string]
  145. 0x0003 -- OR Connection status changed
  146. Status [1 octet]
  147. (Launched=0,connected=1,failed=2,closed=3)
  148. OR nickname/identity [NUL-terminated]
  149. 0x0004 -- Bandwidth used in the last second
  150. Bytes read [4 octets]
  151. Bytes written [4 octets]
  152. 0x0005 -- Notice/warning/error occurred
  153. Message [NUL-terminated]
  154. <obsolete: use 0x0007-0x000B instead.>
  155. 0x0006 -- New descriptors available
  156. OR List [NUL-terminated, comma-delimited list of
  157. OR identity]
  158. 0x0007 -- Debug message occurred
  159. 0x0008 -- Info message occurred
  160. 0x0009 -- Notice message occurred
  161. 0x000A -- Warning message occurred
  162. 0x000B -- Error message occurred
  163. Message [NUL-terminated]
  164. 3.8. AUTHENTICATE (Type 0x0007)
  165. Sent from the client to the server. Contains a 'magic cookie' to prove
  166. that client is really allowed to control this Tor process. The server
  167. responds with DONE or ERROR.
  168. The format of the 'cookie' is implementation-dependent; see 4.1 below for
  169. information on how the standard Tor implementation handles it.
  170. 3.9. SAVECONF (Type 0x0008)
  171. Sent from the client to the server. Instructs the server to write out
  172. its config options into its torrc. Server returns DONE if successful, or
  173. ERROR if it can't write the file or some other error occurs.
  174. 3.10. SIGNAL (Type 0x0009)
  175. Sent from the client to the server. The body contains one byte that
  176. indicates the action the client wishes the server to take.
  177. 1 (0x01) -- Reload: reload config items, refetch directory.
  178. 2 (0x02) -- Controlled shutdown: if server is an OP, exit immediately.
  179. If it's an OR, close listeners and exit after 30 seconds.
  180. 10 (0x0A) -- Dump stats: log information about open connections and
  181. circuits.
  182. 12 (0x0C) -- Debug: switch all open logs to loglevel debug.
  183. 15 (0x0F) -- Immediate shutdown: clean up and exit now.
  184. The server responds with DONE if the signal is recognized (or simply
  185. closes the socket if it was asked to close immediately), else ERROR.
  186. 3.11. MAPADDRESS (Type 0x000A)
  187. Sent from the client to the server. The body contains a sequence of
  188. address mappings, each consisting of the address to be mapped, a single
  189. space, the replacement address, and a NL character.
  190. Addresses may be IPv4 addresses, IPv6 addresses, or hostnames.
  191. The client sends this message to the server in order to tell it that future
  192. SOCKS requests for connections to the original address should be replaced
  193. with connections to the specified replacement address. If the addresses
  194. are well-formed, and the server is able to fulfill the request, the server
  195. replies with a single DONE message containing the source and destination
  196. addresses. If request is malformed, the server replies with a syntax error
  197. message. The server can't fulfill the request, it replies with an internal
  198. ERROR message.
  199. The client may decline to provide a body for the original address, and
  200. instead send a special null address ("0.0.0.0" for IPv4, "::0" for IPv6, or
  201. "." for hostname), signifying that the server should choose the original
  202. address itself, and return that address in the DONE message. The server
  203. should ensure that it returns an element of address space that is unlikely
  204. to be in actual use. If there is already an address mapped to the
  205. destination address, the server may reuse that mapping.
  206. If the original address is already mapped to a different address, the old
  207. mapping is removed. If the original address and the destination address
  208. are the same, the server removes any mapping in place for the original
  209. address.
  210. {Note: This feature is designed to be used to help Tor-ify applications
  211. that need to use SOCKS4 or hostname-less SOCKS5. There are three
  212. approaches to doing this:
  213. 1. Somehow make them use SOCKS4a or SOCKS5-with-hostnames instead.
  214. 2. Use tor-resolve (or another interface to Tor's resolve-over-SOCKS
  215. feature) to resolve the hostname remotely. This doesn't work
  216. with special addresses like x.onion or x.y.exit.
  217. 3. Use MAPADDRESS to map an IP address to the desired hostname, and then
  218. arrange to fool the application into thinking that the hostname
  219. has resolved to that IP.
  220. This functionality is designed to help implement the 3rd approach.}
  221. [XXXX When, if ever, can mappings expire? Should they expire?]
  222. [XXXX What addresses, if any, are safe to use?]
  223. 3.12 GETINFO (Type 0x000B)
  224. Sent from the client to the server. The message body is as for GETCONF:
  225. one or more NL-terminated strings. The server replies with an INFOVALUE
  226. message.
  227. Unlike GETCONF, this message is used for data that are not stored in the
  228. Tor configuration file, but instead.
  229. Recognized key and their values include:
  230. "version" -- The version of the server's software, including the name
  231. of the software. (example: "Tor 0.0.9.4")
  232. "desc/id/<OR identity>" or "desc/name/<OR nickname>" -- the latest server
  233. descriptor for a given OR, NUL-terminated. If no such OR is known, the
  234. corresponding value is an empty string.
  235. "network-status" -- a space-separated list of all known OR identities.
  236. This is in the same format as the router-status line in directories;
  237. see tor-spec.txt for details.
  238. "addr-mappings/all"
  239. "addr-mappings/config"
  240. "addr-mappings/cache"
  241. "addr-mappings/control" -- a NL-terminated list of address mappings, each
  242. in the form of "from-address" SP "to-address". The 'config' key
  243. returns those address mappings set in the configuration; the 'cache'
  244. key returns the mappings in the client-side DNS cache; the 'control'
  245. key returns the mappings set via the control interface; the 'all'
  246. target returns the mappings set through any mechanism.
  247. 3.13 INFOVALUE (Type 0x000C)
  248. Sent from the server to the client in response to a GETINFO message.
  249. Contains one or more items of the format:
  250. Key [(NUL-terminated string)]
  251. Value [(NUL-terminated string)]
  252. The keys match those given in the GETINFO message.
  253. 3.14 EXTENDCIRCUIT (Type 0x000D)
  254. Sent from the client to the server. The message body contains two fields:
  255. Circuit ID [4 octets]
  256. Path [NUL-terminated, comma-delimited string of OR nickname/identity]
  257. This request takes one of two forms: either the Circuit ID is zero, in
  258. which case it is a request for the server to build a new circuit according
  259. to the specified path, or the Circuit ID is nonzero, in which case it is a
  260. request for the server to extend an existing circuit with that ID according
  261. to the specified path.
  262. If the request is successful, the server sends a DONE message containing
  263. a message body consisting of the four-octet Circuit ID of the newly created
  264. circuit.
  265. 3.15 ATTACHSTREAM (Type 0x000E)
  266. Sent from the client to the server. The message body contains two fields:
  267. Stream ID [4 octets]
  268. Circuit ID [4 octets]
  269. This message informs the server that the specified stream should be
  270. associated with the specified circuit. Each stream may be associated with
  271. at most one circuit, and multiple streams may share the same circuit.
  272. Streams can only be attached to completed circuits (that is, circuits that
  273. have sent a circuit status 'built' event).
  274. If the circuit ID is 0, responsibility for attaching the given stream is
  275. returned to Tor.
  276. {Implementation note: By default, Tor automatically attaches streams to
  277. circuits itself, unless the configuration variable
  278. "__LeaveStreamsUnattached" is set to "1". Attempting to attach streams
  279. via TC when "__LeaveStreamsUnattached" is false may cause a race between
  280. Tor and the controller, as both attempt to attach streams to circuits.}
  281. 3.16 POSTDESCRIPTOR (Type 0x000F)
  282. Sent from the client to the server. The message body contains one field:
  283. Descriptor [NUL-terminated string]
  284. This message informs the server about a new descriptor.
  285. The descriptor, when parsed, must contain a number of well-specified
  286. fields, including fields for its nickname and identity.
  287. If there is an error in parsing the descriptor, the server must send an
  288. appropriate error message. If the descriptor is well-formed but the server
  289. chooses not to add it, it must reply with a DONE message whose body
  290. explains why the server was not added.
  291. 3.17 FRAGMENTHEADER (Type 0x0010)
  292. Sent in either direction. Used to encapsulate messages longer than 65535
  293. bytes in length.
  294. Underlying type [2 bytes]
  295. Total Length [4 bytes]
  296. Data [Rest of message]
  297. A FRAGMENTHEADER message MUST be followed immediately by a number of
  298. FRAGMENT messages, such that lengths of the "Data" fields of the
  299. FRAGMENTHEADER and FRAGMENT messages add to the "Total Length" field of the
  300. FRAGMENTHEADER message.
  301. Implementations MUST NOT fragment messages of length less than 65536 bytes.
  302. Implementations MUST be able to process fragmented messages that not
  303. optimally packed.
  304. 3.18 FRAGMENT (Type 0x0011)
  305. Data [Entire message]
  306. See FRAGMENTHEADER for more information
  307. 3.19 REDIRECTSTREAM (Type 0x0012)
  308. Sent from the client to the server. The message body contains two fields:
  309. Stream ID [4 octets]
  310. Address [variable-length, NUL-terminated.]
  311. Tells the server to change the exit address on the specified stream. No
  312. remapping is performed on the new provided address.
  313. To be sure that the modified address will be used, this event must be sent
  314. after a new stream event is received, and before attaching this stream to
  315. a circuit.
  316. 3.20 CLOSESTREAM (Type 0x0013)
  317. Sent from the client to the server. The message body contains three
  318. fields:
  319. Stream ID [4 octets]
  320. Reason [1 octet]
  321. Flags [1 octet]
  322. Tells the server to close the specified stream. The reason should be
  323. one of the Tor RELAY_END reasons given in tor-spec.txt. Flags is not
  324. used currently. Tor may hold the stream open for a while to flush
  325. any data that is pending.
  326. 3.21 CLOSECIRCUIT (Type 0x0014)
  327. Sent from the client to the server. The message body contains two
  328. fields:
  329. Circuit ID [4 octets]
  330. Flags [1 octet]
  331. Tells the server to close the specified circuit. If the LSB of the flags
  332. field is nonzero, do not close the circuit unless it is unused.
  333. 4. Implementation notes
  334. 4.1. Authentication
  335. By default, the current Tor implementation trusts all local users.
  336. If the 'CookieAuthentication' option is true, Tor writes a "magic cookie"
  337. file named "control_auth_cookie" into its data directory. To authenticate,
  338. the controller must send the contents of this file.
  339. If the 'HashedControlPassword' option is set, it must contain the salted
  340. hash of a secret password. The salted hash is computed according to the
  341. S2K algorithm in RFC 2440 (OpenPGP), and prefixed with the s2k specifier.
  342. This is then encoded in hexadecimal, prefixed by the indicator sequence
  343. "16:". Thus, for example, the password 'foo' could encode to:
  344. 16:660537E3E1CD49996044A3BF558097A981F539FEA2F9DA662B4626C1C2
  345. ++++++++++++++++**^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
  346. salt hashed value
  347. indicator
  348. You can generate the salt of a password by calling
  349. 'tor --hash-password <password>'
  350. or by using the example code in the Python and Java controller libraries.
  351. To authenticate under this scheme, the controller sends Tor the original
  352. secret that was used to generate the password.
  353. 4.2. Don't let the buffer get too big.
  354. If you ask for lots of events, and 16MB of them queue up on the buffer,
  355. the Tor process will close the socket.