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Update to the Yubikey PBA
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
This commit is contained in:
parent
8e74e1fded
commit
09f9af17b4
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@ -43,22 +43,33 @@ let
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}
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hextorb() {
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( tr '[:lower:]' '[:upper:]' | sed -e 's/\([0-9A-F]\{2\}\)/\\\\\\x\1/gI'| xargs printf )
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( tr '[:lower:]' '[:upper:]' | sed -e 's/\([0-9A-F]\{2\}\)/\\\\\\x\1/gI' | xargs printf )
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}
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open_yubikey() {
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# Make all of these local to this function
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# to prevent their values being leaked
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local salt
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local iterations
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local k_user
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local challenge
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local response
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local k_luks
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local opened
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local new_salt
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local new_iterations
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local new_challenge
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local new_response
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local new_k_luks
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mkdir -p ${yubikey.storage.mountPoint}
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mount -t ${yubikey.storage.fsType} ${toString yubikey.storage.device} ${yubikey.storage.mountPoint}
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local uuid_r
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local k_user
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local challenge
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local opened
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sleep 1
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uuid_r="$(cat ${yubikey.storage.mountPoint}${yubikey.storage.path})"
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salt="$(cat ${yubikey.storage.mountPoint}${yubikey.storage.path} | sed -n 1p | tr -d '\n')"
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iterations="$(cat ${yubikey.storage.mountPoint}${yubikey.storage.path} | sed -n 2p | tr -d '\n')"
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challenge="$(echo -n $salt | openssl-wrap dgst -binary -sha512 | rbtohex)"
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response="$(ykchalresp -${toString yubikey.slot} -x $challenge 2>/dev/null)"
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for try in $(seq 3); do
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@ -68,9 +79,11 @@ let
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echo
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''}
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challenge="$(echo -n $k_user$uuid_r | openssl-wrap dgst -binary -sha512 | rbtohex)"
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k_luks="$(ykchalresp -${toString yubikey.slot} -x $challenge 2>/dev/null)"
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if [ ! -z "$k_user" ]; then
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k_luks="$(echo -n $k_user | pbkdf2-sha512 ${toString yubikey.keyLength} $iterations $response | rbtohex)"
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else
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k_luks="$(echo | pbkdf2-sha512 ${toString yubikey.keyLength} $iterations $response | rbtohex)"
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fi
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echo -n "$k_luks" | hextorb | cryptsetup luksOpen ${device} ${name} ${optionalString allowDiscards "--allow-discards"} --key-file=-
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@ -89,53 +102,60 @@ let
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exit 1
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fi
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update_failed=false
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echo -n "Gathering entropy for new salt (please enter random keys to generate entropy if this blocks for long)..."
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for i in $(seq ${toString yubikey.saltLength}); do
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byte="$(dd if=/dev/random bs=1 count=1 2>/dev/null | rbtohex)";
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new_salt="$new_salt$byte";
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echo -n .
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done;
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echo "ok"
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local new_uuid_r
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new_uuid_r="$(uuidgen)"
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if [ $? != "0" ]; then
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for try in $(seq 10); do
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sleep 1
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new_uuid_r="$(uuidgen)"
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if [ $? == "0" ]; then break; fi
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if [ $try -eq 10 ]; then update_failed=true; fi
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done
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fi
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new_iterations="$iterations"
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${optionalString (yubikey.iterationStep > 0) ''
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new_iterations="$(($new_iterations + ${toString yubikey.iterationStep}))"
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''}
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if [ "$update_failed" == false ]; then
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new_uuid_r="$(echo -n $new_uuid_r | head -c 36 | tr -d '-')"
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new_challenge="$(echo -n $new_salt | openssl-wrap dgst -binary -sha512 | rbtohex)"
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local new_challenge
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new_challenge="$(echo -n $k_user$new_uuid_r | openssl-wrap dgst -binary -sha512 | rbtohex)"
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new_response="$(ykchalresp -${toString yubikey.slot} -x $new_challenge 2>/dev/null)"
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local new_k_luks
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new_k_luks="$(ykchalresp -${toString yubikey.slot} -x $new_challenge 2>/dev/null)"
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mkdir -p ${yubikey.ramfsMountPoint}
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# A ramfs is used here to ensure that the file used to update
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# the key slot with cryptsetup will never get swapped out.
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# Warning: Do NOT replace with tmpfs!
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mount -t ramfs none ${yubikey.ramfsMountPoint}
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echo -n "$new_k_luks" | hextorb > ${yubikey.ramfsMountPoint}/new_key
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echo -n "$k_luks" | cryptsetup luksChangeKey ${device} --key-file=- ${yubikey.ramfsMountPoint}/new_key
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if [ $? == "0" ]; then
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echo -n "$new_uuid_r" > ${yubikey.storage.mountPoint}${yubikey.storage.path}
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else
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echo "Warning: Could not update LUKS key, current challenge persists!"
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fi
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rm -f ${yubikey.ramfsMountPoint}/new_key
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umount ${yubikey.ramfsMountPoint}
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rm -rf ${yubikey.ramfsMountPoint}
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if [ ! -z "$k_user" ]; then
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new_k_luks="$(echo -n $k_user | pbkdf2-sha512 ${toString yubikey.keyLength} $new_iterations $new_response | rbtohex)"
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else
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echo "Warning: Could not obtain new UUID, current challenge persists!"
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new_k_luks="$(echo | pbkdf2-sha512 ${toString yubikey.keyLength} $new_iterations $new_response | rbtohex)"
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fi
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mkdir -p ${yubikey.ramfsMountPoint}
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# A ramfs is used here to ensure that the file used to update
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# the key slot with cryptsetup will never get swapped out.
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# Warning: Do NOT replace with tmpfs!
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mount -t ramfs none ${yubikey.ramfsMountPoint}
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echo -n "$new_k_luks" | hextorb > ${yubikey.ramfsMountPoint}/new_key
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echo -n "$k_luks" | hextorb | cryptsetup luksChangeKey ${device} --key-file=- ${yubikey.ramfsMountPoint}/new_key
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if [ $? == "0" ]; then
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echo -ne "$new_salt\n$new_iterations" > ${yubikey.storage.mountPoint}${yubikey.storage.path}
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else
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echo "Warning: Could not update LUKS key, current challenge persists!"
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fi
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rm -f ${yubikey.ramfsMountPoint}/new_key
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umount ${yubikey.ramfsMountPoint}
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rm -rf ${yubikey.ramfsMountPoint}
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umount ${yubikey.storage.mountPoint}
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}
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${optionalString (yubikey.gracePeriod > 0) ''
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echo -n "Waiting ${toString yubikey.gracePeriod} seconds as grace..."
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for i in $(seq ${toString yubikey.gracePeriod}); do
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sleep 1
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echo -n .
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done
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echo "ok"
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''}
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yubikey_missing=true
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ykinfo -v 1>/dev/null 2>&1
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if [ $? != "0" ]; then
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@ -292,6 +312,30 @@ in
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description = "Which slot on the Yubikey to challenge";
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};
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saltLength = mkOption {
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default = 16;
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type = types.int;
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description = "Length of the new salt in byte (64 is the effective maximum)";
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};
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keyLength = mkOption {
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default = 64;
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type = types.int;
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description = "Length of the LUKS slot key derived with PBKDF2 in byte";
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};
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iterationStep = mkOption {
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default = 0;
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type = types.int;
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description = "How much the iteration count for PBKDF2 is increased at each successful authentication";
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};
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gracePeriod = mkOption {
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default = 2;
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type = types.int;
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description = "Time in seconds to wait before attempting to find the Yubikey";
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};
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ramfsMountPoint = mkOption {
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default = "/crypt-ramfs";
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type = types.string;
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storage = mkOption {
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type = types.optionSet;
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description = "Options related to the storing the random UUID";
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description = "Options related to the storing the salt";
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options = {
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device = mkOption {
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type = types.path;
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description = ''
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An unencrypted device that will temporarily be mounted in stage-1.
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Must contain the current random UUID to create the challenge for this LUKS device.
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Must contain the current salt to create the challenge for this LUKS device.
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'';
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};
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default = "/crypt-storage/default";
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type = types.string;
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description = ''
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Absolute path of the random UUID on the unencrypted device with
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Absolute path of the salt on the unencrypted device with
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that device's root directory as "/".
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'';
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};
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cp -pdv ${pkgs.popt}/lib/libpopt*.so.* $out/lib
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${optionalString luks.yubikeySupport ''
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cp -pdv ${pkgs.utillinux}/bin/uuidgen $out/bin
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cp -pdv ${pkgs.ykpers}/bin/ykchalresp $out/bin
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cp -pdv ${pkgs.ykpers}/bin/ykinfo $out/bin
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cp -pdv ${pkgs.openssl}/bin/openssl $out/bin
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cc -O3 -I${pkgs.openssl}/include -L${pkgs.openssl}/lib ${./pbkdf2-sha512.c} -o $out/bin/pbkdf2-sha512 -lcrypto
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strip -s $out/bin/pbkdf2-sha512
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cp -pdv ${pkgs.libusb1}/lib/libusb*.so.* $out/lib
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cp -pdv ${pkgs.ykpers}/lib/libykpers*.so.* $out/lib
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cp -pdv ${pkgs.libyubikey}/lib/libyubikey*.so.* $out/lib
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@ -394,7 +440,6 @@ EOF
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boot.initrd.extraUtilsCommandsTest = ''
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$out/bin/cryptsetup --version
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${optionalString luks.yubikeySupport ''
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$out/bin/uuidgen --version
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$out/bin/ykchalresp -V
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$out/bin/ykinfo -V
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cat > $out/bin/openssl-wrap <<EOF
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38
nixos/modules/system/boot/pbkdf2-sha512.c
Normal file
38
nixos/modules/system/boot/pbkdf2-sha512.c
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@ -0,0 +1,38 @@
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#include <stdint.h>
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#include <string.h>
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#include <stdio.h>
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#include <openssl/evp.h>
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void hextorb(uint8_t* hex, uint8_t* rb)
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{
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while(sscanf(hex, "%2x", rb) == 1)
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{
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hex += 2;
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rb += 1;
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}
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*rb = '\0';
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}
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int main(int argc, char** argv)
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{
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uint8_t k_user[2048];
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uint8_t salt[2048];
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uint8_t key[4096];
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uint32_t key_length = atoi(argv[1]);
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uint32_t iteration_count = atoi(argv[2]);
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hextorb(argv[3], salt);
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uint32_t salt_length = strlen(argv[3]) / 2;
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fgets(k_user, 2048, stdin);
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uint32_t k_user_length = strlen(k_user);
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if(k_user[k_user_length - 1] == '\n') {
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k_user[k_user_length - 1] = '\0';
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}
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PKCS5_PBKDF2_HMAC(k_user, k_user_length, salt, salt_length, iteration_count, EVP_sha512(), key_length, key);
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fwrite(key, 1, key_length, stdout);
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return 0;
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}
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