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Security-relevant changes:
* No (salted) passphrase hash send to the yubikey, only hash of the salt (as it was in the original implementation).
* Derive $k_luks with PBKDF2 from the yubikey $response (as the PBKDF2 salt) and the passphrase $k_user
(as the PBKDF2 password), so that if two-factor authentication is enabled
(a) a USB-MITM attack on the yubikey itself is not enough to break the system
(b) the potentially low-entropy $k_user is better protected against brute-force attacks
* Instead of using uuidgen, gather the salt (previously random uuid / uuid_r) directly from /dev/random.
* Length of the new salt in byte added as the parameter "saltLength", defaults to 16 byte.
Note: Length of the challenge is 64 byte, so saltLength > 64 may have no benefit over saltLengh = 64.
* Length of $k_luks derived with PBKDF2 in byte added as the parameter "keyLength", defaults to 64 byte.
Example: For a luks device with a 512-bit key, keyLength should be 64.
* Increase of the PBKDF2 iteration count per successful authentication added as the
parameter "iterationStep", defaults to 0.
Other changes:
* Add optional grace period before trying to find the yubikey, defaults to 2 seconds.
Full overview of the yubikey authentication process:
(1) Read $salt and $iterations from unencrypted device (UD).
(2) Calculate the $challenge from the $salt with a hash function.
Chosen instantiation: SHA-512($salt).
(3) Challenge the yubikey with the $challenge and receive the $response.
(4) Repeat three times:
(a) Prompt for the passphrase $k_user.
(b) Derive the key $k_luks for the luks device with a key derivation function from $k_user and $response.
Chosen instantiation: PBKDF2(HMAC-SHA-512, $k_user, $response, $iterations, keyLength).
(c) Try to open the luks device with $k_luks and escape loop (4) only on success.
(5) Proceed only if luks device was opened successfully, fail otherwise.
(6) Gather $new_salt from a cryptographically secure pseudorandom number generator
Chosen instantiation: /dev/random
(7) Calculate the $new_challenge from the $new_salt with the same hash function as (2).
(8) Challenge the yubikey with the $new_challenge and receive the $new_response.
(9) Derive the new key $new_k_luks for the luks device in the same manner as in (4) (b),
but with more iterations as given by iterationStep.
(10) Try to change the luks device's key $k_luks to $new_k_luks.
(11) If (10) was successful, write the $new_salt and the $new_iterations to the UD.
Note: $new_iterations = $iterations + iterationStep
Known (software) attack vectors:
* A MITM attack on the keyboard can recover $k_user. This, combined with a USB-MITM
attack on the yubikey for the $response (1) or the $new_response (2) will result in
(1) $k_luks being recovered,
(2) $new_k_luks being recovered.
* Any attacker with access to the RAM state of stage-1 at mid- or post-authentication
can recover $k_user, $k_luks, and $new_k_luks
* If an attacker has recovered $response or $new_response, he can perform a brute-force
attack on $k_user with it without the Yubikey needing to be present (using cryptsetup's
"luksOpen --verify-passphrase" oracle. He could even make a copy of the luks device's
luks header and run the brute-force attack without further access to the system.
* A USB-MITM attack on the yubikey will allow an attacker to attempt to brute-force
the yubikey's internal key ("shared secret") without it needing to be present anymore.
Credits:
* Florian Klien,
for the original concept and the reference implementation over at
https://github.com/flowolf/initramfs_ykfde
* Anthony Thysse,
for the reference implementation of accessing OpenSSL's PBKDF2 over at
http://www.ict.griffith.edu.au/anthony/software/pbkdf2.c
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