Cryptosystems have been developed over the years under the typical prevalent setting which assumes that the receiver’s key is kept secure from the adversary, and that the choice of the message to be sent is freely performed by the sender and is kept secure from the adversary as well. Under these fundamental and basic operational assumptions, modern Cryptography has flourished over the last half a century or so, with amazing achievements: New systems (including public-key Cryptography), beautiful and useful models (including security definitions such as semantic security), and new primitives (such as zero-knowledge proofs) have been developed. Furthermore, these fundamental achievements have been translated into actual working systems, and span many of the daily human activities over the Internet.
However, in recent years, there is an overgrowing pressure from many governments to allow the government itself access to keys and messages of encryption systems (under various names: escrow encryption, emergency access, communication decency acts, etc.). Numerous non-direct arguments against such policies have been raised, such as "the bad guys can utilize other encryption system" so all other cryptosystems have to be declared illegal, or that "allowing the government access is an ill-advised policy since it creates a natural weak systems security point, which may attract others (to masquerade as the government)." It has remained a fundamental open issue, though, to show directly that the above mentioned efforts by a government (called here “a dictator” for brevity) which mandate breaking of the basic operational assumption (and disallowing other cryptosystems), is, in fact, a futile exercise. This is a direct technical point which needs to be made and has not been made to date.
In this work, as a technical demonstration of the futility of the dictator’s demands, we invent the notion of “Anamorphic Encryption” which shows that even if the dictator gets the keys and the messages used in the system (before anything is sent) and no other system is allowed, there is a covert way within the context of well established public-key cryptosystems for an entity to immediately (with no latency) send piggybacked secure messages which are, in spite of the stringent dictator conditions, hidden from the dictator itself! We feel that this may be an important direct technical argument against the nature of governments’ attempts to police the use of strong cryptographic systems, and we hope to stimulate further works in this direction.
I want to share an interesting cryptography paper which introduces “anamorphic encryption”, where the ciphertext encrypts two messages. One is a message to reveal to a dictator, who wants the secret key and message to control the narrative. Behind it lies a hidden message, guarded behind a “double key”, which is to communicate messages of intent secretly.
It’s kind of like having a duress key to reveal, but instead you can send real messages with the real key.
For instance, an investigative journalist could encrypt a fake message “Everyone is content in our utopia” as a smokescreen to show to the dictator, while true messages like “Minorities are forced into labor camps” can be hidden in the anamorphically encrypted ciphertexts to notify the outside free press.
The authors argue that cryptosystems already in use supports the anamorphic mode, where you encrypt a normal-looking ciphertext which contains the hidden message.
Given that it has been 3 years since this paper, I think there would have been some applications of this technology. Do you guys know of any?
I posed this in another ‘obfuscation’ thread, but in the case of steganography, wouldn’t AI have the ability to ‘see’ that the a file, say a image’ has odd bits in it that shouldn’t be in an image? Even further, would it be able to ascertain that you have two levels of messages hidden inside the image? It sounds similar to what you can do with VeraCrypt Cryptomater in that you have two ‘levels’ of encrypted data. One to reveal to the authorities and one that’s for the intended target of the data packet.
That’s if you are using a file to store additional data. Also JPEG and other lossy formats can have all sorts of artifacts that may (depending on the size of hidden data) seem typical.
What I thought they were referring to was encryption at the filesystem level which doesn’t require file blocks to be contiguous, allowing blocks to be interlaced with the hidden data.
I posed this in another ‘obfuscation’ thread, but in the case of steganography, wouldn’t AI have the ability to ‘see’ that the a file, say a image’ has odd bits in it that shouldn’t be in an image? Even further, would it be able to ascertain that you have two levels of messages hidden inside the image? It sounds similar to what you can do with
VeraCryptCryptomater in that you have two ‘levels’ of encrypted data. One to reveal to the authorities and one that’s for the intended target of the data packet.That’s if you are using a file to store additional data. Also JPEG and other lossy formats can have all sorts of artifacts that may (depending on the size of hidden data) seem typical.
What I thought they were referring to was encryption at the filesystem level which doesn’t require file blocks to be contiguous, allowing blocks to be interlaced with the hidden data.