Filename: XXX-mitm-bridge-detection-resistance.txt Title: Bridge Detection Resistance against MITM-capable Adversaries Author: George Kadianakis Created: 07 Nov 2011 Status: Open
1. Overview
Proposals 187, 189 and 190 make the first steps toward scanning resistant bridges. They attempt to block attacks from censoring adversaries who provoke bridges into speaking the Tor protocol.
An attack vector that hasn't been explored in those previous proposals is that of an adversary capable of performing Man In The Middle attacks to Tor clients. At the moment, Tor clients using the v3 link protocol have no way to detect such an MITM attack, and will gladly send an VERSIONS or an AUTHORIZE cell to the MITMed connection, thereby revealing the Tor protocol and thus the bridge.
This proposal introduces a way for clients to detect an MITMed SSL connection, allowing them to protect against the above attack.
2. Motivation
When the v3 link handshake protocol is performed, Tor's SSL handshake is performed with the server sending a self-signed certificate and the client blindly accepting it. This allows the adversary to perform an MITM attack.
A Tor client must detect the MITM attack before he initializes the Tor protocol by sending a VERSIONS or an AUTHORIZE cell. A good moment to detect such an MITM attack is during the SSL handshake.
To achieve that, bridge operators provide their bridge users with a hash digest of the public-key certificate their bridge is using for SSL. Bridge clients store that hash digest locally and associate it with that specific bridge. Bridge clients who have "pinned" a bridge to a certificate "fingerprint" can thereafter validate that their SSL connection peer is the intended bridge.
Of course, the hash digest must be provided to users out-of-band and before the actual SSL handshake. Usually, the bridge operator gives the hash digest to her bridge users along with the rest of the bridge credentials, like the bridge's address and port.
3. Security implications
Bridge clients who have pinned a bridge to a certificate fingerprint will be able to detect an MITMing adversary in timely fashion. If after detection they act as an innocuous Internet client, they can successfully remove suspicion from the SSL connection and subvert bridge detection.
Pinning a certificate fingerprint and detecting an MITMing attacker does not automatically aleviate suspicions from the bridge or the client. Clients must have a behavior to follow after detecting the MITM attack so that they look like innocent Netizens. This proposal does not try to specify such a behavior.
Implementation and use of this scheme does not render bridges and clients immune to scanning or DPI attacks. This scheme should be used along with bridge client authorization schemes like the ones detailed in proposal 190.
4. Tor Implementation
4.1. Certificate fingerprint creation
The certificate fingerprints used on this scheme MUST be computed by applying the SHA256 cryptographic hash function upon the ASN.1 DER encoding of a public-key certificate.
4.2. Bridge side implementation
Tor bridge implementations SHOULD provide a command line option that exports a fully equipped Bridge line containing the bridge address and port, the link certificate fingerprint and any other enabled Bridge options, so that bridge operators can easily send it to their users.
In the case of expiring SSL certificates, Tor bridge implementations SHOULD warn the bridge operator a sensible amount of time before the expiration, so that she can warn her clients and potentially rotate the certificate herself.
4.3. Client side implementation
Tor client implementations MUST extend their Bridge line format to support bridge SSL certificate fingerprints. The new format is: Bridge <method> address:port [["keyid="]<id-fingerprint>] \ ["shared_secret="<shared_secret>] ["link_cert_fpr="<fingerprint>]
where <fingerprint> is the bridge's SSL certificate fingerprint in hexademical encoding.
Tor clients who use bridges and want to pin their SSL certificates must specify the bridge's SSL certificate fingerprint as in: Bridge 12.34.56.78 shared_secret=934caff420aa7852b855 \ link_cert_fpr=38b0712e90bed729df81f2a22811d3dd89e91406d2522f4482ae4079e5245187
4.4. Implementation prerequisites
Tor bridges currently rotate their SSL certificates every 2 hours. This not only acts as a fingerprint for the bridges, but it also acts as a blocker for this proposal.
Tor trac ticket #4390 and proposal YYY were created to resolve this issue.
5. Acknowledgements
Thanks to Robert Ransom for his great help and suggestions on devising this scheme and writing this proposal!