121-hidden-service-authentication.txt 40 KB

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  1. Filename: 121-hidden-service-authentication.txt
  2. Title: Hidden Service Authentication
  3. Author: Tobias Kamm, Thomas Lauterbach, Karsten Loesing, Ferdinand Rieger,
  4. Christoph Weingarten
  5. Created: 10-Sep-2007
  6. Status: Finished
  7. Implemented-In: 0.2.1.x
  8. Change history:
  9. 26-Sep-2007 Initial proposal for or-dev
  10. 08-Dec-2007 Incorporated comments by Nick posted to or-dev on 10-Oct-2007
  11. 15-Dec-2007 Rewrote complete proposal for better readability, modified
  12. authentication protocol, merged in personal notes
  13. 24-Dec-2007 Replaced misleading term "authentication" by "authorization"
  14. and added some clarifications (comments by Sven Kaffille)
  15. 28-Apr-2008 Updated most parts of the concrete authorization protocol
  16. 04-Jul-2008 Add a simple algorithm to delay descriptor publication for
  17. different clients of a hidden service
  18. 19-Jul-2008 Added INTRODUCE1V cell type (1.2), improved replay
  19. protection for INTRODUCE2 cells (1.3), described limitations
  20. for auth protocols (1.6), improved hidden service protocol
  21. without client authorization (2.1), added second, more
  22. scalable authorization protocol (2.2), rewrote existing
  23. authorization protocol (2.3); changes based on discussion
  24. with Nick
  25. 31-Jul-2008 Limit maximum descriptor size to 20 kilobytes to prevent
  26. abuse.
  27. 01-Aug-2008 Use first part of Diffie-Hellman handshake for replay
  28. protection instead of rendezvous cookie.
  29. 01-Aug-2008 Remove improved hidden service protocol without client
  30. authorization (2.1). It might get implemented in proposal
  31. 142.
  32. Overview:
  33. This proposal deals with a general infrastructure for performing
  34. authorization (not necessarily implying authentication) of requests to
  35. hidden services at three points: (1) when downloading and decrypting
  36. parts of the hidden service descriptor, (2) at the introduction point,
  37. and (3) at Bob's Tor client before contacting the rendezvous point. A
  38. service provider will be able to restrict access to his service at these
  39. three points to authorized clients only. Further, the proposal contains
  40. specific authorization protocols as instances that implement the
  41. presented authorization infrastructure.
  42. This proposal is based on v2 hidden service descriptors as described in
  43. proposal 114 and introduced in version 0.2.0.10-alpha.
  44. The proposal is structured as follows: The next section motivates the
  45. integration of authorization mechanisms in the hidden service protocol.
  46. Then we describe a general infrastructure for authorization in hidden
  47. services, followed by specific authorization protocols for this
  48. infrastructure. At the end we discuss a number of attacks and non-attacks
  49. as well as compatibility issues.
  50. Motivation:
  51. The major part of hidden services does not require client authorization
  52. now and won't do so in the future. To the contrary, many clients would
  53. not want to be (pseudonymously) identifiable by the service (though this
  54. is unavoidable to some extent), but rather use the service
  55. anonymously. These services are not addressed by this proposal.
  56. However, there may be certain services which are intended to be accessed
  57. by a limited set of clients only. A possible application might be a
  58. wiki or forum that should only be accessible for a closed user group.
  59. Another, less intuitive example might be a real-time communication
  60. service, where someone provides a presence and messaging service only to
  61. his buddies. Finally, a possible application would be a personal home
  62. server that should be remotely accessed by its owner.
  63. Performing authorization for a hidden service within the Tor network, as
  64. proposed here, offers a range of advantages compared to allowing all
  65. client connections in the first instance and deferring authorization to
  66. the transported protocol:
  67. (1) Reduced traffic: Unauthorized requests would be rejected as early as
  68. possible, thereby reducing the overall traffic in the network generated
  69. by establishing circuits and sending cells.
  70. (2) Better protection of service location: Unauthorized clients could not
  71. force Bob to create circuits to their rendezvous points, thus preventing
  72. the attack described by Øverlier and Syverson in their paper "Locating
  73. Hidden Servers" even without the need for guards.
  74. (3) Hiding activity: Apart from performing the actual authorization, a
  75. service provider could also hide the mere presence of his service from
  76. unauthorized clients when not providing hidden service descriptors to
  77. them, rejecting unauthorized requests already at the introduction
  78. point (ideally without leaking presence information at any of these
  79. points), or not answering unauthorized introduction requests.
  80. (4) Better protection of introduction points: When providing hidden
  81. service descriptors to authorized clients only and encrypting the
  82. introduction points as described in proposal 114, the introduction points
  83. would be unknown to unauthorized clients and thereby protected from DoS
  84. attacks.
  85. (5) Protocol independence: Authorization could be performed for all
  86. transported protocols, regardless of their own capabilities to do so.
  87. (6) Ease of administration: A service provider running multiple hidden
  88. services would be able to configure access at a single place uniformly
  89. instead of doing so for all services separately.
  90. (7) Optional QoS support: Bob could adapt his node selection algorithm
  91. for building the circuit to Alice's rendezvous point depending on a
  92. previously guaranteed QoS level, thus providing better latency or
  93. bandwidth for selected clients.
  94. A disadvantage of performing authorization within the Tor network is
  95. that a hidden service cannot make use of authorization data in
  96. the transported protocol. Tor hidden services were designed to be
  97. independent of the transported protocol. Therefore it's only possible to
  98. either grant or deny access to the whole service, but not to specific
  99. resources of the service.
  100. Authorization often implies authentication, i.e. proving one's identity.
  101. However, when performing authorization within the Tor network, untrusted
  102. points should not gain any useful information about the identities of
  103. communicating parties, neither server nor client. A crucial challenge is
  104. to remain anonymous towards directory servers and introduction points.
  105. However, trying to hide identity from the hidden service is a futile
  106. task, because a client would never know if he is the only authorized
  107. client and therefore perfectly identifiable. Therefore, hiding client
  108. identity from the hidden service is not an aim of this proposal.
  109. The current implementation of hidden services does not provide any kind
  110. of authorization. The hidden service descriptor version 2, introduced by
  111. proposal 114, was designed to use a descriptor cookie for downloading and
  112. decrypting parts of the descriptor content, but this feature is not yet
  113. in use. Further, most relevant cell formats specified in rend-spec
  114. contain fields for authorization data, but those fields are neither
  115. implemented nor do they suffice entirely.
  116. Details:
  117. 1. General infrastructure for authorization to hidden services
  118. We spotted three possible authorization points in the hidden service
  119. protocol:
  120. (1) when downloading and decrypting parts of the hidden service
  121. descriptor,
  122. (2) at the introduction point, and
  123. (3) at Bob's Tor client before contacting the rendezvous point.
  124. The general idea of this proposal is to allow service providers to
  125. restrict access to some or all of these points to authorized clients
  126. only.
  127. 1.1. Client authorization at directory
  128. Since the implementation of proposal 114 it is possible to combine a
  129. hidden service descriptor with a so-called descriptor cookie. If done so,
  130. the descriptor cookie becomes part of the descriptor ID, thus having an
  131. effect on the storage location of the descriptor. Someone who has learned
  132. about a service, but is not aware of the descriptor cookie, won't be able
  133. to determine the descriptor ID and download the current hidden service
  134. descriptor; he won't even know whether the service has uploaded a
  135. descriptor recently. Descriptor IDs are calculated as follows (see
  136. section 1.2 of rend-spec for the complete specification of v2 hidden
  137. service descriptors):
  138. descriptor-id =
  139. H(service-id | H(time-period | descriptor-cookie | replica))
  140. Currently, service-id is equivalent to permanent-id which is calculated
  141. as in the following formula. But in principle it could be any public
  142. key.
  143. permanent-id = H(permanent-key)[:10]
  144. The second purpose of the descriptor cookie is to encrypt the list of
  145. introduction points, including optional authorization data. Hence, the
  146. hidden service directories won't learn any introduction information from
  147. storing a hidden service descriptor. This feature is implemented but
  148. unused at the moment. So this proposal will harness the advantages
  149. of proposal 114.
  150. The descriptor cookie can be used for authorization by keeping it secret
  151. from everyone but authorized clients. A service could then decide whether
  152. to publish hidden service descriptors using that descriptor cookie later
  153. on. An authorized client being aware of the descriptor cookie would be
  154. able to download and decrypt the hidden service descriptor.
  155. The number of concurrently used descriptor cookies for one hidden service
  156. is not restricted. A service could use a single descriptor cookie for all
  157. users, a distinct cookie per user, or something in between, like one
  158. cookie per group of users. It is up to the specific protocol and how it
  159. is applied by a service provider.
  160. Two or more hidden service descriptors for different groups or users
  161. should not be uploaded at the same time. A directory node could conclude
  162. easily that the descriptors were issued by the same hidden service, thus
  163. being able to link the two groups or users. Therefore, descriptors for
  164. different users or clients that ought to be stored on the same directory
  165. are delayed, so that only one descriptor is uploaded to a directory at a
  166. time. The remaining descriptors are uploaded with a delay of up to
  167. 30 seconds.
  168. Further, descriptors for different groups or users that are to be stored
  169. on different directories are delayed for a random time of up to 30
  170. seconds to hide relations from colluding directories. Certainly, this
  171. does not prevent linking entirely, but it makes it somewhat harder.
  172. There is a conflict between hiding links between clients and making a
  173. service available in a timely manner.
  174. Although this part of the proposal is meant to describe a general
  175. infrastructure for authorization, changing the way of using the
  176. descriptor cookie to look up hidden service descriptors, e.g. applying
  177. some sort of asymmetric crypto system, would require in-depth changes
  178. that would be incompatible to v2 hidden service descriptors. On the
  179. contrary, using another key for en-/decrypting the introduction point
  180. part of a hidden service descriptor, e.g. a different symmetric key or
  181. asymmetric encryption, would be easy to implement and compatible to v2
  182. hidden service descriptors as understood by hidden service directories
  183. (clients and services would have to be upgraded anyway for using the new
  184. features).
  185. An adversary could try to abuse the fact that introduction points can be
  186. encrypted by storing arbitrary, unrelated data in the hidden service
  187. directory. This abuse can be limited by setting a hard descriptor size
  188. limit, forcing the adversary to split data into multiple chunks. There
  189. are some limitations that make splitting data across multiple descriptors
  190. unattractive: 1) The adversary would not be able to choose descriptor IDs
  191. freely and would therefore have to implement his own indexing
  192. structure. 2) Validity of descriptors is limited to at most 24 hours
  193. after which descriptors need to be republished.
  194. The regular descriptor size in bytes is 745 + num_ipos * 837 + auth_data.
  195. A large descriptor with 7 introduction points and 5 kilobytes of
  196. authorization data would be 11724 bytes in size. The upper size limit of
  197. descriptors should be set to 20 kilobytes, which limits the effect of
  198. abuse while retaining enough flexibility in designing authorization
  199. protocols.
  200. 1.2. Client authorization at introduction point
  201. The next possible authorization point after downloading and decrypting
  202. a hidden service descriptor is the introduction point. It may be important
  203. for authorization, because it bears the last chance of hiding presence
  204. of a hidden service from unauthorized clients. Further, performing
  205. authorization at the introduction point might reduce traffic in the
  206. network, because unauthorized requests would not be passed to the
  207. hidden service. This applies to those clients who are aware of a
  208. descriptor cookie and thereby of the hidden service descriptor, but do
  209. not have authorization data to pass the introduction point or access the
  210. service (such a situation might occur when authorization data for
  211. authorization at the directory is not issued on a per-user basis, but
  212. authorization data for authorization at the introduction point is).
  213. It is important to note that the introduction point must be considered
  214. untrustworthy, and therefore cannot replace authorization at the hidden
  215. service itself. Nor should the introduction point learn any sensitive
  216. identifiable information from either the service or the client.
  217. In order to perform authorization at the introduction point, three
  218. message formats need to be modified: (1) v2 hidden service descriptors,
  219. (2) ESTABLISH_INTRO cells, and (3) INTRODUCE1 cells.
  220. A v2 hidden service descriptor needs to contain authorization data that
  221. is introduction-point-specific and sometimes also authorization data
  222. that is introduction-point-independent. Therefore, v2 hidden service
  223. descriptors as specified in section 1.2 of rend-spec already contain two
  224. reserved fields "intro-authorization" and "service-authorization"
  225. (originally, the names of these fields were "...-authentication")
  226. containing an authorization type number and arbitrary authorization
  227. data. We propose that authorization data consists of base64 encoded
  228. objects of arbitrary length, surrounded by "-----BEGIN MESSAGE-----" and
  229. "-----END MESSAGE-----". This will increase the size of hidden service
  230. descriptors, but this is allowed since there is no strict upper limit.
  231. The current ESTABLISH_INTRO cells as described in section 1.3 of
  232. rend-spec do not contain either authorization data or version
  233. information. Therefore, we propose a new version 1 of the ESTABLISH_INTRO
  234. cells adding these two issues as follows:
  235. V Format byte: set to 255 [1 octet]
  236. V Version byte: set to 1 [1 octet]
  237. KL Key length [2 octets]
  238. PK Bob's public key [KL octets]
  239. HS Hash of session info [20 octets]
  240. AUTHT The auth type that is supported [1 octet]
  241. AUTHL Length of auth data [2 octets]
  242. AUTHD Auth data [variable]
  243. SIG Signature of above information [variable]
  244. From the format it is possible to determine the maximum allowed size for
  245. authorization data: given the fact that cells are 512 octets long, of
  246. which 498 octets are usable (see section 6.1 of tor-spec), and assuming
  247. 1024 bit = 128 octet long keys, there are 215 octets left for
  248. authorization data. Hence, authorization protocols are bound to use no
  249. more than these 215 octets, regardless of the number of clients that
  250. shall be authenticated at the introduction point. Otherwise, one would
  251. need to send multiple ESTABLISH_INTRO cells or split them up, which we do
  252. not specify here.
  253. In order to understand a v1 ESTABLISH_INTRO cell, the implementation of
  254. a relay must have a certain Tor version. Hidden services need to be able
  255. to distinguish relays being capable of understanding the new v1 cell
  256. formats and perform authorization. We propose to use the version number
  257. that is contained in networkstatus documents to find capable
  258. introduction points.
  259. The current INTRODUCE1 cell as described in section 1.8 of rend-spec is
  260. not designed to carry authorization data and has no version number, too.
  261. Unfortunately, unversioned INTRODUCE1 cells consist only of a fixed-size,
  262. seemingly random PK_ID, followed by the encrypted INTRODUCE2 cell. This
  263. makes it impossible to distinguish unversioned INTRODUCE1 cells from any
  264. later format. In particular, it is not possible to introduce some kind of
  265. format and version byte for newer versions of this cell. That's probably
  266. where the comment "[XXX011 want to put intro-level auth info here, but no
  267. version. crap. -RD]" that was part of rend-spec some time ago comes from.
  268. We propose that new versioned INTRODUCE1 cells use the new cell type 41
  269. RELAY_INTRODUCE1V (where V stands for versioned):
  270. Cleartext
  271. V Version byte: set to 1 [1 octet]
  272. PK_ID Identifier for Bob's PK [20 octets]
  273. AUTHT The auth type that is included [1 octet]
  274. AUTHL Length of auth data [2 octets]
  275. AUTHD Auth data [variable]
  276. Encrypted to Bob's PK:
  277. (RELAY_INTRODUCE2 cell)
  278. The maximum length of contained authorization data depends on the length
  279. of the contained INTRODUCE2 cell. A calculation follows below when
  280. describing the INTRODUCE2 cell format we propose to use.
  281. 1.3. Client authorization at hidden service
  282. The time when a hidden service receives an INTRODUCE2 cell constitutes
  283. the last possible authorization point during the hidden service
  284. protocol. Performing authorization here is easier than at the other two
  285. authorization points, because there are no possibly untrusted entities
  286. involved.
  287. In general, a client that is successfully authorized at the introduction
  288. point should be granted access at the hidden service, too. Otherwise, the
  289. client would receive a positive INTRODUCE_ACK cell from the introduction
  290. point and conclude that it may connect to the service, but the request
  291. will be dropped without notice. This would appear as a failure to
  292. clients. Therefore, the number of cases in which a client successfully
  293. passes the introduction point but fails at the hidden service should be
  294. zero. However, this does not lead to the conclusion that the
  295. authorization data used at the introduction point and the hidden service
  296. must be the same, but only that both authorization data should lead to
  297. the same authorization result.
  298. Authorization data is transmitted from client to server via an
  299. INTRODUCE2 cell that is forwarded by the introduction point. There are
  300. versions 0 to 2 specified in section 1.8 of rend-spec, but none of these
  301. contain fields for carrying authorization data. We propose a slightly
  302. modified version of v3 INTRODUCE2 cells that is specified in section
  303. 1.8.1 and which is not implemented as of December 2007. In contrast to
  304. the specified v3 we avoid specifying (and implementing) IPv6 capabilities,
  305. because Tor relays will be required to support IPv4 addresses for a long
  306. time in the future, so that this seems unnecessary at the moment. The
  307. proposed format of v3 INTRODUCE2 cells is as follows:
  308. VER Version byte: set to 3. [1 octet]
  309. AUTHT The auth type that is used [1 octet]
  310. AUTHL Length of auth data [2 octets]
  311. AUTHD Auth data [variable]
  312. TS Timestamp (seconds since 1-1-1970) [4 octets]
  313. IP Rendezvous point's address [4 octets]
  314. PORT Rendezvous point's OR port [2 octets]
  315. ID Rendezvous point identity ID [20 octets]
  316. KLEN Length of onion key [2 octets]
  317. KEY Rendezvous point onion key [KLEN octets]
  318. RC Rendezvous cookie [20 octets]
  319. g^x Diffie-Hellman data, part 1 [128 octets]
  320. The maximum possible length of authorization data is related to the
  321. enclosing INTRODUCE1V cell. A v3 INTRODUCE2 cell with
  322. 1024 bit = 128 octets long public key without any authorization data
  323. occupies 306 octets (AUTHL is only used when AUTHT has a value != 0),
  324. plus 58 octets for hybrid public key encryption (see
  325. section 5.1 of tor-spec on hybrid encryption of CREATE cells). The
  326. surrounding INTRODUCE1V cell requires 24 octets. This leaves only 110
  327. of the 498 available octets free, which must be shared between
  328. authorization data to the introduction point _and_ to the hidden
  329. service.
  330. When receiving a v3 INTRODUCE2 cell, Bob checks whether a client has
  331. provided valid authorization data to him. He also requires that the
  332. timestamp is no more than 30 minutes in the past or future and that the
  333. first part of the Diffie-Hellman handshake has not been used in the past
  334. 60 minutes to prevent replay attacks by rogue introduction points. (The
  335. reason for not using the rendezvous cookie to detect replays---even
  336. though it is only sent once in the current design---is that it might be
  337. desirable to re-use rendezvous cookies for multiple introduction requests
  338. in the future.) If all checks pass, Bob builds a circuit to the provided
  339. rendezvous point. Otherwise he drops the cell.
  340. 1.4. Summary of authorization data fields
  341. In summary, the proposed descriptor format and cell formats provide the
  342. following fields for carrying authorization data:
  343. (1) The v2 hidden service descriptor contains:
  344. - a descriptor cookie that is used for the lookup process, and
  345. - an arbitrary encryption schema to ensure authorization to access
  346. introduction information (currently symmetric encryption with the
  347. descriptor cookie).
  348. (2) For performing authorization at the introduction point we can use:
  349. - the fields intro-authorization and service-authorization in
  350. hidden service descriptors,
  351. - a maximum of 215 octets in the ESTABLISH_INTRO cell, and
  352. - one part of 110 octets in the INTRODUCE1V cell.
  353. (3) For performing authorization at the hidden service we can use:
  354. - the fields intro-authorization and service-authorization in
  355. hidden service descriptors,
  356. - the other part of 110 octets in the INTRODUCE2 cell.
  357. It will also still be possible to access a hidden service without any
  358. authorization or only use a part of the authorization infrastructure.
  359. However, this requires to consider all parts of the infrastructure. For
  360. example, authorization at the introduction point relying on confidential
  361. intro-authorization data transported in the hidden service descriptor
  362. cannot be performed without using an encryption schema for introduction
  363. information.
  364. 1.5. Managing authorization data at servers and clients
  365. In order to provide authorization data at the hidden service and the
  366. authenticated clients, we propose to use files---either the Tor
  367. configuration file or separate files. The exact format of these special
  368. files depends on the authorization protocol used.
  369. Currently, rend-spec contains the proposition to encode client-side
  370. authorization data in the URL, like in x.y.z.onion. This was never used
  371. and is also a bad idea, because in case of HTTP the requested URL may be
  372. contained in the Host and Referer fields.
  373. 1.6. Limitations for authorization protocols
  374. There are two limitations of the current hidden service protocol for
  375. authorization protocols that shall be identified here.
  376. 1. The three cell types ESTABLISH_INTRO, INTRODUCE1V, and INTRODUCE2
  377. restricts the amount of data that can be used for authorization.
  378. This forces authorization protocols that require per-user
  379. authorization data at the introduction point to restrict the number
  380. of authorized clients artificially. A possible solution could be to
  381. split contents among multiple cells and reassemble them at the
  382. introduction points.
  383. 2. The current hidden service protocol does not specify cell types to
  384. perform interactive authorization between client and introduction
  385. point or hidden service. If there should be an authorization
  386. protocol that requires interaction, new cell types would have to be
  387. defined and integrated into the hidden service protocol.
  388. 2. Specific authorization protocol instances
  389. In the following we present two specific authorization protocols that
  390. make use of (parts of) the new authorization infrastructure:
  391. 1. The first protocol allows a service provider to restrict access
  392. to clients with a previously received secret key only, but does not
  393. attempt to hide service activity from others.
  394. 2. The second protocol, albeit being feasible for a limited set of about
  395. 16 clients, performs client authorization and hides service activity
  396. from everyone but the authorized clients.
  397. These two protocol instances extend the existing hidden service protocol
  398. version 2. Hidden services that perform client authorization may run in
  399. parallel to other services running versions 0, 2, or both.
  400. 2.1. Service with large-scale client authorization
  401. The first client authorization protocol aims at performing access control
  402. while consuming as few additional resources as possible. A service
  403. provider should be able to permit access to a large number of clients
  404. while denying access for everyone else. However, the price for
  405. scalability is that the service won't be able to hide its activity from
  406. unauthorized or formerly authorized clients.
  407. The main idea of this protocol is to encrypt the introduction-point part
  408. in hidden service descriptors to authorized clients using symmetric keys.
  409. This ensures that nobody else but authorized clients can learn which
  410. introduction points a service currently uses, nor can someone send a
  411. valid INTRODUCE1 message without knowing the introduction key. Therefore,
  412. a subsequent authorization at the introduction point is not required.
  413. A service provider generates symmetric "descriptor cookies" for his
  414. clients and distributes them outside of Tor. The suggested key size is
  415. 128 bits, so that descriptor cookies can be encoded in 22 base64 chars
  416. (which can hold up to 22 * 5 = 132 bits, leaving 4 bits to encode the
  417. authorization type (here: "0") and allow a client to distinguish this
  418. authorization protocol from others like the one proposed below).
  419. Typically, the contact information for a hidden service using this
  420. authorization protocol looks like this:
  421. v2cbb2l4lsnpio4q.onion Ll3X7Xgz9eHGKCCnlFH0uz
  422. When generating a hidden service descriptor, the service encrypts the
  423. introduction-point part with a single randomly generated symmetric
  424. 128-bit session key using AES-CTR as described for v2 hidden service
  425. descriptors in rend-spec. Afterwards, the service encrypts the session
  426. key to all descriptor cookies using AES. Authorized client should be able
  427. to efficiently find the session key that is encrypted for him/her, so
  428. that 4 octet long client ID are generated consisting of descriptor cookie
  429. and initialization vector. Descriptors always contain a number of
  430. encrypted session keys that is a multiple of 16 by adding fake entries.
  431. Encrypted session keys are ordered by client IDs in order to conceal
  432. addition or removal of authorized clients by the service provider.
  433. ATYPE Authorization type: set to 1. [1 octet]
  434. ALEN Number of clients := 1 + ((clients - 1) div 16) [1 octet]
  435. for each symmetric descriptor cookie:
  436. ID Client ID: H(descriptor cookie | IV)[:4] [4 octets]
  437. SKEY Session key encrypted with descriptor cookie [16 octets]
  438. (end of client-specific part)
  439. RND Random data [(15 - ((clients - 1) mod 16)) * 20 octets]
  440. IV AES initialization vector [16 octets]
  441. IPOS Intro points, encrypted with session key [remaining octets]
  442. An authorized client needs to configure Tor to use the descriptor cookie
  443. when accessing the hidden service. Therefore, a user adds the contact
  444. information that she received from the service provider to her torrc
  445. file. Upon downloading a hidden service descriptor, Tor finds the
  446. encrypted introduction-point part and attempts to decrypt it using the
  447. configured descriptor cookie. (In the rare event of two or more client
  448. IDs being equal a client tries to decrypt all of them.)
  449. Upon sending the introduction, the client includes her descriptor cookie
  450. as auth type "1" in the INTRODUCE2 cell that she sends to the service.
  451. The hidden service checks whether the included descriptor cookie is
  452. authorized to access the service and either responds to the introduction
  453. request, or not.
  454. 2.2. Authorization for limited number of clients
  455. A second, more sophisticated client authorization protocol goes the extra
  456. mile of hiding service activity from unauthorized clients. With all else
  457. being equal to the preceding authorization protocol, the second protocol
  458. publishes hidden service descriptors for each user separately and gets
  459. along with encrypting the introduction-point part of descriptors to a
  460. single client. This allows the service to stop publishing descriptors for
  461. removed clients. As long as a removed client cannot link descriptors
  462. issued for other clients to the service, it cannot derive service
  463. activity any more. The downside of this approach is limited scalability.
  464. Even though the distributed storage of descriptors (cf. proposal 114)
  465. tackles the problem of limited scalability to a certain extent, this
  466. protocol should not be used for services with more than 16 clients. (In
  467. fact, Tor should refuse to advertise services for more than this number
  468. of clients.)
  469. A hidden service generates an asymmetric "client key" and a symmetric
  470. "descriptor cookie" for each client. The client key is used as
  471. replacement for the service's permanent key, so that the service uses a
  472. different identity for each of his clients. The descriptor cookie is used
  473. to store descriptors at changing directory nodes that are unpredictable
  474. for anyone but service and client, to encrypt the introduction-point
  475. part, and to be included in INTRODUCE2 cells. Once the service has
  476. created client key and descriptor cookie, he tells them to the client
  477. outside of Tor. The contact information string looks similar to the one
  478. used by the preceding authorization protocol (with the only difference
  479. that it has "1" encoded as auth-type in the remaining 4 of 132 bits
  480. instead of "0" as before).
  481. When creating a hidden service descriptor for an authorized client, the
  482. hidden service uses the client key and descriptor cookie to compute
  483. secret ID part and descriptor ID:
  484. secret-id-part = H(time-period | descriptor-cookie | replica)
  485. descriptor-id = H(client-key[:10] | secret-id-part)
  486. The hidden service also replaces permanent-key in the descriptor with
  487. client-key and encrypts introduction-points with the descriptor cookie.
  488. ATYPE Authorization type: set to 2. [1 octet]
  489. IV AES initialization vector [16 octets]
  490. IPOS Intro points, encr. with descriptor cookie [remaining octets]
  491. When uploading descriptors, the hidden service needs to make sure that
  492. descriptors for different clients are not uploaded at the same time (cf.
  493. Section 1.1) which is also a limiting factor for the number of clients.
  494. When a client is requested to establish a connection to a hidden service
  495. it looks up whether it has any authorization data configured for that
  496. service. If the user has configured authorization data for authorization
  497. protocol "2", the descriptor ID is determined as described in the last
  498. paragraph. Upon receiving a descriptor, the client decrypts the
  499. introduction-point part using its descriptor cookie. Further, the client
  500. includes its descriptor cookie as auth-type "2" in INTRODUCE2 cells that
  501. it sends to the service.
  502. 2.3. Hidden service configuration
  503. A hidden service that is meant to perform client authorization adds a
  504. new option HiddenServiceAuthorizeClient to its hidden service
  505. configuration. This option contains the authorization type which is
  506. either "1" for the protocol described in 2.1 or "2" for the protocol in
  507. 2.2 and a comma-separated list of human-readable client names, so that
  508. Tor can create authorization data for these clients:
  509. HiddenServiceAuthorizeClient auth-type client-name,client-name,...
  510. If this option is configured, HiddenServiceVersion is automatically
  511. reconfigured to contain only version numbers of 2 or higher.
  512. Tor stores all generated authorization data for the authorization
  513. protocols described in Sections 2.1 and 2.2 in a new file using the
  514. following file format:
  515. "client-name" human-readable client identifier NL
  516. "descriptor-cookie" 128-bit key ^= 22 base64 chars NL
  517. If the authorization protocol of Section 2.2 is used, Tor also generates
  518. and stores the following data:
  519. "client-key" NL a public key in PEM format
  520. 2.4. Client configuration
  521. Clients need to make their authorization data known to Tor using another
  522. configuration option that contains a service name (mainly for the sake of
  523. convenience), the service address, and the descriptor cookie that is
  524. required to access a hidden service (the authorization protocol number is
  525. encoded in the descriptor cookie):
  526. HidServAuth service-name service-address descriptor-cookie
  527. Security implications:
  528. In the following we want to discuss possible attacks by dishonest
  529. entities in the presented infrastructure and specific protocol. These
  530. security implications would have to be verified once more when adding
  531. another protocol. The dishonest entities (theoretically) include the
  532. hidden service itself, the authenticated clients, hidden service directory
  533. nodes, introduction points, and rendezvous points. The relays that are
  534. part of circuits used during protocol execution, but never learn about
  535. the exchanged descriptors or cells by design, are not considered.
  536. Obviously, this list makes no claim to be complete. The discussed attacks
  537. are sorted by the difficulty to perform them, in ascending order,
  538. starting with roles that everyone could attempt to take and ending with
  539. partially trusted entities abusing the trust put in them.
  540. (1) A hidden service directory could attempt to conclude presence of a
  541. service from the existence of a locally stored hidden service descriptor:
  542. This passive attack is possible only for a single client-service
  543. relation, because descriptors need to contain a publicly visible
  544. signature of the service using the client key.
  545. A possible protection would be to increase the number of hidden service
  546. directories in the network.
  547. (2) A hidden service directory could try to break the descriptor cookies
  548. of locally stored descriptors: This attack can be performed offline. The
  549. only useful countermeasure against it might be using safe passwords that
  550. are generated by Tor.
  551. [passwords? where did those come in? -RD]
  552. (3) An introduction point could try to identify the pseudonym of the
  553. hidden service on behalf of which it operates: This is impossible by
  554. design, because the service uses a fresh public key for every
  555. establishment of an introduction point (see proposal 114) and the
  556. introduction point receives a fresh introduction cookie, so that there is
  557. no identifiable information about the service that the introduction point
  558. could learn. The introduction point cannot even tell if client accesses
  559. belong to the same client or not, nor can it know the total number of
  560. authorized clients. The only information might be the pattern of
  561. anonymous client accesses, but that is hardly enough to reliably identify
  562. a specific service.
  563. (4) An introduction point could want to learn the identities of accessing
  564. clients: This is also impossible by design, because all clients use the
  565. same introduction cookie for authorization at the introduction point.
  566. (5) An introduction point could try to replay a correct INTRODUCE1 cell
  567. to other introduction points of the same service, e.g. in order to force
  568. the service to create a huge number of useless circuits: This attack is
  569. not possible by design, because INTRODUCE1 cells are encrypted using a
  570. freshly created introduction key that is only known to authorized
  571. clients.
  572. (6) An introduction point could attempt to replay a correct INTRODUCE2
  573. cell to the hidden service, e.g. for the same reason as in the last
  574. attack: This attack is stopped by the fact that a service will drop
  575. INTRODUCE2 cells containing a DH handshake they have seen recently.
  576. (7) An introduction point could block client requests by sending either
  577. positive or negative INTRODUCE_ACK cells back to the client, but without
  578. forwarding INTRODUCE2 cells to the server: This attack is an annoyance
  579. for clients, because they might wait for a timeout to elapse until trying
  580. another introduction point. However, this attack is not introduced by
  581. performing authorization and it cannot be targeted towards a specific
  582. client. A countermeasure might be for the server to periodically perform
  583. introduction requests to his own service to see if introduction points
  584. are working correctly.
  585. (8) The rendezvous point could attempt to identify either server or
  586. client: This remains impossible as it was before, because the
  587. rendezvous cookie does not contain any identifiable information.
  588. (9) An authenticated client could swamp the server with valid INTRODUCE1
  589. and INTRODUCE2 cells, e.g. in order to force the service to create
  590. useless circuits to rendezvous points; as opposed to an introduction
  591. point replaying the same INTRODUCE2 cell, a client could include a new
  592. rendezvous cookie for every request: The countermeasure for this attack
  593. is the restriction to 10 connection establishments per client per hour.
  594. Compatibility:
  595. An implementation of this proposal would require changes to hidden
  596. services and clients to process authorization data and encode and
  597. understand the new formats. However, both services and clients would
  598. remain compatible to regular hidden services without authorization.
  599. Implementation:
  600. The implementation of this proposal can be divided into a number of
  601. changes to hidden service and client side. There are no
  602. changes necessary on directory, introduction, or rendezvous nodes. All
  603. changes are marked with either [service] or [client] do denote on which
  604. side they need to be made.
  605. /1/ Configure client authorization [service]
  606. - Parse configuration option HiddenServiceAuthorizeClient containing
  607. authorized client names.
  608. - Load previously created client keys and descriptor cookies.
  609. - Generate missing client keys and descriptor cookies, add them to
  610. client_keys file.
  611. - Rewrite the hostname file.
  612. - Keep client keys and descriptor cookies of authorized clients in
  613. memory.
  614. [- In case of reconfiguration, mark which client authorizations were
  615. added and whether any were removed. This can be used later when
  616. deciding whether to rebuild introduction points and publish new
  617. hidden service descriptors. Not implemented yet.]
  618. /2/ Publish hidden service descriptors [service]
  619. - Create and upload hidden service descriptors for all authorized
  620. clients.
  621. [- See /1/ for the case of reconfiguration.]
  622. /3/ Configure permission for hidden services [client]
  623. - Parse configuration option HidServAuth containing service
  624. authorization, store authorization data in memory.
  625. /5/ Fetch hidden service descriptors [client]
  626. - Look up client authorization upon receiving a hidden service request.
  627. - Request hidden service descriptor ID including client key and
  628. descriptor cookie. Only request v2 descriptors, no v0.
  629. /6/ Process hidden service descriptor [client]
  630. - Decrypt introduction points with descriptor cookie.
  631. /7/ Create introduction request [client]
  632. - Include descriptor cookie in INTRODUCE2 cell to introduction point.
  633. - Pass descriptor cookie around between involved connections and
  634. circuits.
  635. /8/ Process introduction request [service]
  636. - Read descriptor cookie from INTRODUCE2 cell.
  637. - Check whether descriptor cookie is authorized for access, including
  638. checking access counters.
  639. - Log access for accountability.