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359 lines
19 KiB
Plaintext
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Filename: 121-hidden-service-authentication.txt
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Title: Hidden Service Authentication
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Version: $LastChangedRevision$
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Last-Modified: $LastChangedDate$
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Author: Tobias Kamm, Thomas Lauterbach, Karsten Loesing, Ferdinand Rieger,
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Christoph Weingarten
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Created: 10-Sep-2007
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Status: Open
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Change history:
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26-Sep-2007 Initial proposal for or-dev
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Overview:
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This proposal deals with some possibilities to implement authentication
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for restricted access to hidden services. This way we try to increase the
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security level for the service provider (Bob) by giving him the ability
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to exclude non-authorized users from using his service. It is based on
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proposal 114-distributed-storage but is better suited for a fine grained
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way of authentication, because it is less resource-consuming. Whenever we
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refer to service descriptors and cell formats, we are talking about the
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definitions found in 114-distributed-storage unless otherwise stated.
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We discuss password and public-key authentication for the Onion Proxy
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(OP) of Bob's hidden service (HS). Furthermore a challenge-response
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authentication mechanism is introduced at the introduction point.
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These modifications aim at:
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- increasing the security of hidden services by limiting access only to
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authorized users (specification see details) and
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- reducing the traffic in the network by rejecting unauthorized access
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requests earlier.
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Motivation:
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The currently used implementation of hidden services does not provide any
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kind of authentication. The v2 implementation adds an authentication
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mechanism at the directory server. Security can be further improved by
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adding two more authentication authorities at the introduction point
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(IPo) and the OP.
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Although the service descriptors are already designed to carry
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authentication information the existing fields are not used so far.
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Moreover one can find a couple of notes at the specification of cell
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formats (rend-spec) which point at adding authentication information but
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no fields are specified yet. It would be preferable to extend the Tor
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network with authentication features to offer a solution for all
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services. This would also provide means to authorize access to services
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that currently do not support authentication mechanisms. Moreover, Bob's
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authentication administration for all services could be performed
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centralized in the Tor application, and the implementation overhead for
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developers would be significantly reduced. Another benefit would be the
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reduced traffic by checking authentication data and dropping unauthorized
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requests as soon as possible. For example unauthorized requests could
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already be discarded at the introduction points.
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In addition to that, our implementation is able to hide the service from
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users, who still have access to the secret cookie (see
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114-distributed-storage) but should no longer be authorized. Bob can now
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not only hide his location, but also to a certain degree his presence
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towards unauthorized clients given that none of his IPo's are corrupted.
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Details:
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/1/ Client authentication at the hidden service
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In proposal 114 a client (Alice) who has a valid secret cookie, which may
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be considered as a form of authentication, and a service ID is able to
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connect to Bob if he is online. He can not distinguish between Alice
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being intentionally authorized by himself or being an attacker.
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Integrating authentication in Tor HS will ensure Bob that Alice is only
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able to use the service if she is authorized by him.
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Authentication data will be transmitted via the RELAY_INTRODUCE1 cell
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from Alice to Bob that is forwarded by the IPo. For this message several
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format versions are specified in the rend-spec in section 1.8. We will
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use the format version 3. This specification already contains the fields
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"AUTHT" (to specify the authentication method), "AUTHL" (length of the
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authentication data), and "AUTHD" (the authentication data) that will be
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used to store authentication data. Since these fields are encrypted with
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the service's public key, sniffing attacks will fail. Bob will only build
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the circuit to the rendezvous point if the provided authentication data
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is valid, otherwise he will drop the cell. This will improve security due
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to preventing communication between Bob and Alice if she is an attacker.
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As a positive side effect it reduces network traffic because it avoids
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Bob from building unnecessary circuits to the rendezvous points.
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Authentication at the HS should be the last gatekeeper and the number of
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cases in which a client successfully passes the introduction point, but
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fails at the HS should be almost zero. Therefore it is very important to
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perform fine-grained access control already at the IPo (but without
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relying on it).
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The first authentication mechanism that will be supported is password
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(symmetric secret) authentication. "AUTHT" is set to "1" for this
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authentication method while the "AUTHL" field is set to "20", the length
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of the SHA-1 digest of the password.
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(1) Alice creates a password x and sends the password digest h(x) to Bob
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out of band.
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(2) Alice sends h(x) to Bob, encrypted with Bob's fresh service key (not
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subject to this proposal, see proposal 114).
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(3) Bob decrypts Alice's message using his private service key (see
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proposal 114) and compares the contained h(x) with what he knows what
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Alice's password digest h(x) should be.
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This kind of authentication is well-known. It has the known disadvantage
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of weak passwords that are vulnerable to dictionary or brute-force
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attacks. Nevertheless it seems to be an appropriate solution since safe
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passwords can be randomly generated by Tor. Cracking methods that rely on
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guessing passwords should not be effective in the constantly changing
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network infrastructure. A usability advantage is that this method is easy
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to perform even for unexperienced users. The authenticationdata will be
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the SHA-1 secure hash (see tor-spec) of the shared secret (password).
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The premise to use password authentication is that Bob must send the
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password to Alice outside Tor. If at the same time the secret cookie is
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transmitted and the message is intercepted the attacker can gain access
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to the service. Therefore, a secure way to exchange this information must
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be established.
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The second authentication mechanism is public-key authentication. The
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well-known RSA implementation will be used as cipher (see tor-spec).
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Authentication data will be the hash of the rendezvous cookie, signed
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with the private key (SK).
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When Alice wants to use this authentication method she sets "AUTHT" to
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"2" and "AUTHL" to "128" which is the size of the encrypted data. Since
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the rendezvous cookie changes each time Alice connects, replay attacks
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can be easily prevented.
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(1) Alice creates a private key e and sends the corresponding public key
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d to Bob out of band.
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(2) Alice generates a random rendezvous cookie r, computes PKSign(e, r),
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encrypts it with Bob's fresh service key (see proposal 114), and
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sends the result to Bob.
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(3) Bob decrypts Alice's message using his private service key (see
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proposal 114) and verifies PKSign(e, r) with d.
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The premise for public-key authentication is that Alice must send the
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generated public key to Bob outside Tor. If an attacker is able to swap
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that key, the attacker could perform a man-in-the-middle attack, if he
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managed to serve as an IPo for Bob. Therefore a secure exchange channel
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must be established.
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Depending on what authentication data Bob knows from Alice (password
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and/or public key, or other data that is added later) there are several
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choices for Alice to authenticate to the service.
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After validating the provided "AUTHD" Bob builds a circuit to the
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rendezvous point and starts interacting with Alice. If Bob cannot
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identify the client he must refuse the request by not connecting to the
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rendezvous point.
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It will also still be possible to establish v2 hidden services without
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authentication. Therefore the "AUTHT" field must be set to "0". "AUTHL"
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and "AUTHD" are not provided by the client in that case.
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/2/ Client authentication at the introduction point
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In addition to authentication at the HS OP, the IPo should be able to
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detect and abandon all unauthorized requests. This would help to raise
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the level of privacy and therefore also the level of security for Bob by
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better hiding his online activity from unauthorized users. Especially if
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Alice still has access to the secret cookie. This can be the case if she
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had access to the service earlier, but is no longer authorized or the
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directory is outdated. Another advantage of this additional "gate keeper"
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would be reduced traffic in the network, because unauthorized requests
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could already be detected and declined at the IPo.
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It is important to notice that the IPo may not be trustworthy, and
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therefore can not replace authentication at the HS OP itself. Nor should
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the IPo get hold of critical authentication information (because it could
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try to access the service itself).
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A challenge-response authentication protocol is used to address these
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issues. This means that a challenge is needed to be solved by Alice to
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get forwarded to Bob by the IPo.
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Two types of authentication are supported and need to be preconfigured by
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Bob when creating the service: password and public-key authentication.
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Again it is up to Alice what kind of authentication mechanism she wants
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to use, given that Bob knows both her password and her public key.
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If Alice uses a password to authenticate herself at the IPo, the
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authentication is based on a symmetric challenge-response authentication
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protocol. In this case the challenge for Alice is to send h(x|y) where x
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is a user-specific password, which should be different from the password
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needed for authentication at the hidden service and y is a randomly
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generated value. Alice gets hold of her password out of band.
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With the initial RELAY_ESTABLISH_INTRO cell, the IPo gets a list of
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h(x|y)'s which it stores locally. Upon a request of Alice it compares her
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provided authentication data with the list entries. If there is a
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matching entry in its list, Alice's request is valid and can be forwarded
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to Bob. To generate the hash, Alice needs to know the password (which she
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will get out of band) and the random value y. This value is contained in
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the cookie-encrypted part of the hidden service descriptor which Alice
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can retrieve from the directory using her secret cookie.
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(1) Alice creates a password x and sends the password digest h(x) to Bob
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out of band.
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(2) Bob creates a random value y, computes h(h(x)|y), and sends the
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result to the introduction point.
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(3) Bob encrypts y with a secret cookie (see proposal 114) and writes it
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to a rendezvous service descriptor.
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(4) Alice fetches Bob's rendezvous service descriptor, decrypts y using
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the secret cookie (see proposal 114), computes h(h(x)|y), encrypts
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it with the public key of the introduction point, and sends it to
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that introduction point.
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(5) The introduction point decrypts h(h(x)|y) from Alice's message and
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compares it to the value it knows from Bob (from step 2).
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If Alice wants to use public-key authentication to authenticate herself
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at Bob's HS, the challenge-response authentication protocol is slightly
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different.
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The IPo's are provided with a list of random value hashes h(r) with an
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entry for each user via the RELAY_ESTABLISH_INTRO cell. For public-key
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authentication Alice uses an RSA public/private-key pair (as specified in
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tor-spec). The public key is made known to Bob out of band. The IPo's
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will now be sent a new ESTABLISH_INTRO cell with an additional random
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value hash for Alice and a new descriptor is uploaded to the responsible
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directories. The public-key authentication part of the service descriptor
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holds a blank separated list of key-value pairs with one pair for every
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authorized user. The hash of the public key of a user serves as a key,
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while the PK-encrypted r represents the value. Authorized users can now
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find their respective key-value pair and decrypt the value of h(r). This
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result serves as an authorization token at the IPo in the same way as
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with password authentication. The IPo does not know which authentication
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method was used since the tokens always have the same format.
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(1) Alice creates a private key e and sends the corresponding public key
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d to Bob out of band.
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(2) Bob creates a random value y and sends it to the introduction point.
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(3) Bob computes PKEncrypt(d, y), encrypts the result with a secret
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cookie (see proposal 114), and writes it to a rendezvous service
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descriptor.
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(4) Alice fetches Bob's rendezvous service descriptor, decrypts
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PKEncrypt(d, y) using the secret cookie (see proposal 114), decrypts
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y from it using her private key e, and sends it to the introduction
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point.
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(5) The introduction point compares y with the value it knows from Bob
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(from step 2).
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To remove a user from a group, Bob needs to update the random value list
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at the IPo's.
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The changes needed in Tor to realize these two challenge-response
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variations affect the RELAY_ESTABLISH_INTRO and RELAY_INTRODUCE1 relay
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cells, the service descriptor and the code parts in Tor where these cells
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and the descriptor are handled.
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The RELAY_ESTABLISH_INTRO cell is now structured as follows:
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V Format byte: set to 255 [1 octet]
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V Version byte: set to 2 [1 octet]
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KL Key length [2 octets]
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PK Bob's public key [KL octets]
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HS Hash of session info [20 octets]
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AUTHT The auth type that is supported [1 octet]
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AUTHL Length of auth data [2 octets]
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AUTHD Auth data [variable]
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SIG Signature of above information [variable]
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"AUTHT" is set to "1" for password/public-key authentication.
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"AUTHD" is a list of 20 octet long challenges for clients.
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The service descriptor as specified in 114-distributed-storage is used in
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our implementation.
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For password authentication "authentication" auth-type is set to "1" and
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auth-data contains the 20 octets long string used by clients to construct
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the response to the challenge for authentication at the IPo.
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When using public-key authentication the auth-type is set to "2" and
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auth-data holds a list of 148 octets long blank separated values. The
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first 20 octets of each value is the hash of the public key of a certain
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client and used by Alice to determine her entry in the list. The
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remaining 128 octets contain the PK-encrypted token needed to
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authenticate to the IPo.
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The part of the RELAY_INTRODUCE1 cell that can be read by the IPo has the
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following fields added:
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AUTHT The auth type that is supported [1 octet]
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AUTHL Length of auth data [1 octets]
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AUTHD Auth data [variable]
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The AUTHT and AUTHL fields are provided to allow extensions of the
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protocol. Currently, we set AUTHT to 1 for password/public-key
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authentication and AUTHL to 20 for the length of the authorization token.
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Security implications:
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In addition to the security features proposed in 114-distributed-storage
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a new way of authentication is added at the OP of Bob. Moreover, the
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authentication at the IPo's is improved to support a fine-grained access
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control. Corrupted IPo's may easily bypass this authentication, but given
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the case that the majority of IPo's is acting as expected we still
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consider this feature as being useful.
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Bob can now decide whether he wants to allow Alice to use his services or
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not. This gives him the possibility to offer his services only to known
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and trusted users that need to identify by a password or by signing their
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messages. The anonymity of the client towards the service provider is
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thereby reduced to pseudonymity.
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Changing of access rights now involves all three authorization authorities
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depending on what changes should be made:
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- The user configures his changes at the local OP. Therefore he can
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edit the cookie files that were extended to support multiple users.
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Moreover he can edit the new user files that were added to specify
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authentication information for every user.
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- Whenever local changes occur, this information needs to be either
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passed to the responsible IPo's, the directory servers, or both
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depending on the authorization method and operation used. It is
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important to have consistent authorization results at all authorities
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at the same time, to create a trustworthy system with good user
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acceptance. As these reconfigurations always follow local changes
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they can be done automatically by the new Tor implementation and
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therefore no user interaction is needed.
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- The secret cookies proposed in 114-distributed-storage are used for
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group management in our implementation as their use would be far to
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costly for a user-based authorization. That is because right now one
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descriptor is generated and uploaded for every secret cookie. Changes
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in this configuration should therefore be rare (maybe never) and only
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a few groups should exist. Provided that this is the case the costs
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for changes seem acceptable. As there is currently no possibility to
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make a directory remove the descriptor for a group an updated
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descriptor without any IPo should be uploaded to the directory
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servers.
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Local changes to access rights can now be done faster than by changing
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service descriptors which reduces the directory server load and network
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traffic. Still every configuration change remains costly and users should
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carefully choose how detailed the access right configuration should be.
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Attacking clients now need to bypass two more authentication steps to
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reach the service implementation. Compared to the current state it is
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more likely that attackers can be stopped even before they are able to
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contact Bob's OP. We expect that the possibility of an attack is thereby
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significantly reduced. Another positive side effect is that network
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traffic and router load is reduced by discarding unauthorized cells which
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should lower the effectiveness of denial of service attacks.
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Compatibility:
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When using our authentication for hidden services the implementation of
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IPo's needs to be extended. Therefore we use version information provided
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in router descriptors to be sure that we only send modified
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RELAY_ESTABLISH_INTRO cells to routers that can handle them. Clients of
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v2 hidden services will have to update their Tor installation if they
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want to be able to use the service.
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