# Are there any serious problems with this technique for generating symmetric keys?

I'm using a technique borrowed out of a book by Bruce Schneier and Niels Ferguson called Practical Cryptography. Basically, it boils down to this:

Bob does this:

pubk_A = Alice's public key

entropy = bytes from cryptographic quality PRNG

encrypted_entropy = RSA_Encryptpubk_A(entropy)

hashed_entropy = SHA2-512(entropy)

encrypt_keyBA = hashed_entropy[0:32]
encrypt_nonceBA = hashed_entropy[32:48]
hmac_keyBA = hashed_entropy[48:64]

Bob then sends encrypted_entropy to Alice.

Then Alice does this:

privk_A = Alice's private key

entropy = RSA_Decryptprivk_A(encrypted_entropy)

hashed_entropy = SHA2-512(entropy)

encrypt_keyBA = hashed_entropy[0:32]
encrypt_nonceBA = hashed_entropy[32:48]
hmac_keyBA = hashed_entropy[48:64]

This works great for generating keys that can be used to communicate from Bob to Alice. But I need keys I can use in both directions. I was thinking of modifying the algorithm in this way:

Bob does this with entropy:

pubk_B = Bob's public key

hashed_entropyBA = SHA2-512(SHA2-256(pubk_A) + entropy

encrypt_keyBA = hashed_entropy[0:32]
encrypt_nonceBA = hashed_entropy[32:48]
hmac_keyBA = hashed_entropy[48:64]

hashed_entropyAB = SHA2-512(SHA2-256(pubk_B) + entropy

encrypt_keyAB = hashed_entropy[0:32]
encrypt_nonceAB = hashed_entropy[32:48]
hmac_keyAB = hashed_entropy[48:64]

Alice can do the same thing on her side after she obtains entropy by decrypting encrypted_entropy.

As you can see, now there are two sets of keys, one used for communicating from Bob to Alice, and another for communicating from Alice to Bob.

Is there anything wrong with this? What security risks am I taking? Is the security of the system less or more than if I simply had one party tweak a bit in the nonce? Is there a better way to handle this problem without adding round-trips?

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I enjoyed reading Practical Cryptography. –  rook Mar 28 '11 at 18:13
Cross-posted on security.stackexchange.com/questions/2772/…. This should probably be answered there. –  Jeff Ferland Mar 28 '11 at 18:30
@Jeff Ferland: I really hate how stack has fragmented the way it has. Makes it much harder to figure out where a question should be asked and where it will be most likely to get an answer. I notice that it's hardly even been looked at on security.stackexchange.com –  Omnifarious Mar 28 '11 at 18:44
@Omnifarious: I understand your concern about topic fragmentation. Unfortunately, in my opinion, the alternative is worse. The signal to noise ratio, or the questions you're interested in versus the questions you have no interest in, would decrease dramatically, to the point where people would leave, because it wouldn't be worth the bother anymore. Stack Overflow is starting to feel that way to me, even with the topic fragmentation. –  Gilbert Le Blanc Mar 28 '11 at 18:51
@Gilbert Le Blance: I aggressively use tag filtering to here to handle the problem. There are a whole host of tags I've asked to never see questions about. The 'Interesting question' tab is also a good attempt. Unfortunately, it completely misses the absolutely most interesting thing to me about a question, which is that it has no answers at all (upvoted or not). –  Omnifarious Mar 28 '11 at 18:54

There shouldn't be a problem with both Alice and Bob having a shared key for bi-directional communication. In fact this is a lot like SSL/TLS's shared master secret. The only consideration is that you cannot use the same `iv+master key` combo with any packet. Also this iv must be random.
One improvement that can be made to this Schneier/Ferguson protocol is using cmac mode, which would remove the need for the `hmac_key`. This would reduce bandwidth used in the handshake and cpu usage for each packet.
In terms of your variant of this protocol. You still have to rely upon transmitting `encrypted_entropy = RSA_Encryptpubk_A(entropy)`. This is an important step because you need to have a shared secret. The use of a known value `pubk_A` in the key generation bothers me. Keep in mind that it should be assumed that any public key is known to the attacker. The use of sha256 doesn't make this value more random or more difficult to brute force. Thus the number of guesses the attacker has to make is equivalent for these three calculations: `sha512(sha256(pubk_A)+entropy)`,`sha512(pubk_A+entropy)`,`sha512(entropy)`. Which means this is a waste of resources because you are not obtaining an advantage over your attacker.