Previously:
Theseus: A Robust System for Preserving and Sharing Research
Resisting Sybil Attacks in Distributed Hash Tables
This won't be a long one -- I just wanted to take a few spare moments to jot down an idea for how friends in a Theseus-like network who know each other only by public key but don't have each other's network contact info could first get in touch.
I believe it's possible to do this without anyone else finding that contact info, deducing the social connection, or even knowing that either involved party is trying to get in touch with anyone. Those guarantees would be tricky to establish through naive use of public-key cryptography, but I believe this Diffie-Hellman based scheme can offer all that and more without breaking a sweat.
I believe it's possible to do this without anyone else finding that contact info, deducing the social connection, or even knowing that either involved party is trying to get in touch with anyone. Those guarantees would be tricky to establish through naive use of public-key cryptography, but I believe this Diffie-Hellman based scheme can offer all that and more without breaking a sweat.
This solution strikes me as being simple and elegant enough that it's almost certainly been discovered before. As always, if anyone can point out prior work, please do.
In addition to basic cryptographic primitives, the scheme requires a couple nontrivial building blocks. I assume the existence of a distributed hash table like the one being designed for Theseus. I also assume that the DHT can be accessed anonymously. This second assumption is of course easier said than done, but we'll address that issue in its own blog post in due time.
This idea allows for two parties who only know each other's public keys to establish communication without any personally-identifying metainfo leaking to third parties. No centralized authority of any kind is required. Communicating public keys to each other is a bit of a pain but, again, we're sweeping that under the rug for now. Everything in due time.
How it starts is: if you're on the Theseus network and you have a public key that you're using with Theseus, you probably have some file signatures associated with the key published to the DHT. You're going to publish something else along with them: a very large integer signed by your key.
If your friend also has a public key associated with Theseus, they'll share a very large integer signed by their key as well.
These integers are each chosen to constitute one half of a Diffie-Hellman key exchange. Behind them lie personal secrets used to derive them. Put any two of them together, and someone knowing at least one of the personal secrets can derive a shared secret. So, if everyone who wants to be contacted by public key publishes such an integer, then any two such people can arrive at a shared secret without ever directly communicating.
(as an aside, if the public keys are for an elliptic-curve cryptosystem then ECDH could be used to do away with the need to publish traditional DH keys at all, since the public keys essentially also become the DH keys. This may or may not be desirable.)
(as an aside, if the public keys are for an elliptic-curve cryptosystem then ECDH could be used to do away with the need to publish traditional DH keys at all, since the public keys essentially also become the DH keys. This may or may not be desirable.)
It's perhaps worth mentioning that using the same public Diffie-Hellman integer in multiple key exchanges does nothing to weaken it. Also, while we're mentioning things, this requires system-wide constants for a DH modulus and base, which is no problem.
Okay, so this allows two arbitrary people who have exchanged public keys to reach a shared secret, but since the value of this secret is essentially random, they still haven't managed to communicate. They don't even have each other's contact info. What next?
The idea here is to set up a dead drop. Specifically:
- Calculate the shared secret
- XOR together cryptographic hashes of the two public keys
- Compute an HMAC of the resulting value, keyed by the shared secret
- The first 160 bits of this are the address for your dead drop
- Take your contact info and encrypt it with the shared secret
- Store the encrypted value at the dead drop address
The encryption key is derived from Diffie-Hellman, rather than from the public keys (which are only used to certify the trustworthiness of the DH integers), meaning that this system achieves forward secrecy even if users' private keys are later compromised.
One might be inclined to just directly hash the concatenation of the pubkey XOR and the shared secret instead of using an HMAC, but such a simple approach can have unexpected consequences, for instance vulnerability to length extension attacks. The use of an HMAC is a conservative measure intended to increase resilience to such arcanae.
The particularly conservative might, prior to storage, doubly encrypt their contact info: first with the shared secret, then with their contact's public key. This would complicate brute-force attacks on the shared secret somewhat, at the cost of increasing overhead and complicating the algorithm. That measure is not taken here because the benefit of it seems small enough to be outweighed by the cost.
The system as described seems to me fairly robust. To an outside observer, the dead drop address and the stored value convey no personal information. However, to someone who knows the shared secret and both public keys, the drop is easy to locate and decrypt. So as long as users can somehow anonymize themselves while accessing the data, this system has all the properties we want.
One might be inclined to just directly hash the concatenation of the pubkey XOR and the shared secret instead of using an HMAC, but such a simple approach can have unexpected consequences, for instance vulnerability to length extension attacks. The use of an HMAC is a conservative measure intended to increase resilience to such arcanae.
The particularly conservative might, prior to storage, doubly encrypt their contact info: first with the shared secret, then with their contact's public key. This would complicate brute-force attacks on the shared secret somewhat, at the cost of increasing overhead and complicating the algorithm. That measure is not taken here because the benefit of it seems small enough to be outweighed by the cost.
The system as described seems to me fairly robust. To an outside observer, the dead drop address and the stored value convey no personal information. However, to someone who knows the shared secret and both public keys, the drop is easy to locate and decrypt. So as long as users can somehow anonymize themselves while accessing the data, this system has all the properties we want.
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