Summary

In 2016, attackers broke into John Podesta’s e-mail account and published his mailbox via WikiLeaks; many messages could be authenticated by their DKIM signatures. After this, secure messaging apps saw a flood of new users: Signal, for example saw a 400% increase in downloads. One reason for this is that secure messaging applications, like Signal, promise cryptographic deniability: that when you send a message to someone, they can verify that it came from you but the protocol will not leave any trace that can be used to convince skeptical third parties who sent that message.

Enter remote attestation: most new processors include a hardware-assisted trusted execution environment (TEE) that provides remote attestation; such TEEs can prove something about their state to a remote party. An attacker, even a manifestly untrustworthy one like a criminal or propaganda organization, can piggyback on the trust placed in the TEE, allowing them to prove to a skeptical audience that their purloined messages are authenticated by the messaging protocol, and that the attacker did not have the keys needed to forge the messages.

We have demonstrated this attack using the Signal protocol and Intel SGX, but it applies to any purely-software protocol that provides sender authentication of messages.

We have also shown how to design protocols that resist attackers with remote attestation, including both completely cryptographic methods such as on-line deniable key establishment (that work against some adversaries and as adopted by the upcoming OTRv4) and methods that use TEEs (which can stop it completely).

More generally, we want to raise awareness among users of secure messaging protocols about the limits of the level of deniability they can expect and among designers of such protocols that widespread availability of hardware-assisted remote attestation has changed the implicit assumptions they make.

More information

Talks

Paper

Lachlan J. Gunn, Ricardo Vieitez Parra, N. Asokan: Circumventing Cryptographic Deniability with Remote Attestation, Proceedings on Privacy-Enhancing Technologies, 2019(3), pp. 350–369. 2019.