Developer
<?php
/**
* PKCS#8 Formatted Key Handler
*
* PHP version 5
*
* Used by PHP's openssl_public_encrypt() and openssl's rsautl (when -pubin is set)
*
* Processes keys with the following headers:
*
* -----BEGIN ENCRYPTED PRIVATE KEY-----
* -----BEGIN PRIVATE KEY-----
* -----BEGIN PUBLIC KEY-----
*
* Analogous to ssh-keygen's pkcs8 format (as specified by -m). Although PKCS8
* is specific to private keys it's basically creating a DER-encoded wrapper
* for keys. This just extends that same concept to public keys (much like ssh-keygen)
*
* @author Jim Wigginton <terrafrost@php.net>
* @copyright 2015 Jim Wigginton
* @license http://www.opensource.org/licenses/mit-license.html MIT License
* @link http://phpseclib.sourceforge.net
*/
namespace phpseclib3\Crypt\Common\Formats\Keys;
use phpseclib3\Common\Functions\Strings;
use phpseclib3\Crypt\AES;
use phpseclib3\Crypt\DES;
use phpseclib3\Crypt\Random;
use phpseclib3\Crypt\RC2;
use phpseclib3\Crypt\RC4;
use phpseclib3\Crypt\TripleDES;
use phpseclib3\Exception\InsufficientSetupException;
use phpseclib3\Exception\UnsupportedAlgorithmException;
use phpseclib3\File\ASN1;
use phpseclib3\File\ASN1\Maps;
/**
* PKCS#8 Formatted Key Handler
*
* @author Jim Wigginton <terrafrost@php.net>
*/
abstract class PKCS8 extends PKCS
{
/**
* Default encryption algorithm
*
* @var string
*/
private static $defaultEncryptionAlgorithm = 'id-PBES2';
/**
* Default encryption scheme
*
* Only used when defaultEncryptionAlgorithm is id-PBES2
*
* @var string
*/
private static $defaultEncryptionScheme = 'aes128-CBC-PAD';
/**
* Default PRF
*
* Only used when defaultEncryptionAlgorithm is id-PBES2
*
* @var string
*/
private static $defaultPRF = 'id-hmacWithSHA256';
/**
* Default Iteration Count
*
* @var int
*/
private static $defaultIterationCount = 2048;
/**
* OIDs loaded
*
* @var bool
*/
private static $oidsLoaded = false;
/**
* Sets the default encryption algorithm
*
* @param string $algo
*/
public static function setEncryptionAlgorithm($algo)
{
self::$defaultEncryptionAlgorithm = $algo;
}
/**
* Sets the default encryption algorithm for PBES2
*
* @param string $algo
*/
public static function setEncryptionScheme($algo)
{
self::$defaultEncryptionScheme = $algo;
}
/**
* Sets the iteration count
*
* @param int $count
*/
public static function setIterationCount($count)
{
self::$defaultIterationCount = $count;
}
/**
* Sets the PRF for PBES2
*
* @param string $algo
*/
public static function setPRF($algo)
{
self::$defaultPRF = $algo;
}
/**
* Returns a SymmetricKey object based on a PBES1 $algo
*
* @return \phpseclib3\Crypt\Common\SymmetricKey
* @param string $algo
*/
private static function getPBES1EncryptionObject($algo)
{
$algo = preg_match('#^pbeWith(?:MD2|MD5|SHA1|SHA)And(.*?)-CBC$#', $algo, $matches) ?
$matches[1] :
substr($algo, 13); // strlen('pbeWithSHAAnd') == 13
switch ($algo) {
case 'DES':
$cipher = new DES('cbc');
break;
case 'RC2':
$cipher = new RC2('cbc');
$cipher->setKeyLength(64);
break;
case '3-KeyTripleDES':
$cipher = new TripleDES('cbc');
break;
case '2-KeyTripleDES':
$cipher = new TripleDES('cbc');
$cipher->setKeyLength(128);
break;
case '128BitRC2':
$cipher = new RC2('cbc');
$cipher->setKeyLength(128);
break;
case '40BitRC2':
$cipher = new RC2('cbc');
$cipher->setKeyLength(40);
break;
case '128BitRC4':
$cipher = new RC4();
$cipher->setKeyLength(128);
break;
case '40BitRC4':
$cipher = new RC4();
$cipher->setKeyLength(40);
break;
default:
throw new UnsupportedAlgorithmException("$algo is not a supported algorithm");
}
return $cipher;
}
/**
* Returns a hash based on a PBES1 $algo
*
* @return string
* @param string $algo
*/
private static function getPBES1Hash($algo)
{
if (preg_match('#^pbeWith(MD2|MD5|SHA1|SHA)And.*?-CBC$#', $algo, $matches)) {
return $matches[1] == 'SHA' ? 'sha1' : $matches[1];
}
return 'sha1';
}
/**
* Returns a KDF baesd on a PBES1 $algo
*
* @return string
* @param string $algo
*/
private static function getPBES1KDF($algo)
{
switch ($algo) {
case 'pbeWithMD2AndDES-CBC':
case 'pbeWithMD2AndRC2-CBC':
case 'pbeWithMD5AndDES-CBC':
case 'pbeWithMD5AndRC2-CBC':
case 'pbeWithSHA1AndDES-CBC':
case 'pbeWithSHA1AndRC2-CBC':
return 'pbkdf1';
}
return 'pkcs12';
}
/**
* Returns a SymmetricKey object baesd on a PBES2 $algo
*
* @return SymmetricKey
* @param string $algo
*/
private static function getPBES2EncryptionObject($algo)
{
switch ($algo) {
case 'desCBC':
$cipher = new DES('cbc');
break;
case 'des-EDE3-CBC':
$cipher = new TripleDES('cbc');
break;
case 'rc2CBC':
$cipher = new RC2('cbc');
// in theory this can be changed
$cipher->setKeyLength(128);
break;
case 'rc5-CBC-PAD':
throw new UnsupportedAlgorithmException('rc5-CBC-PAD is not supported for PBES2 PKCS#8 keys');
case 'aes128-CBC-PAD':
case 'aes192-CBC-PAD':
case 'aes256-CBC-PAD':
$cipher = new AES('cbc');
$cipher->setKeyLength(substr($algo, 3, 3));
break;
default:
throw new UnsupportedAlgorithmException("$algo is not supported");
}
return $cipher;
}
/**
* Initialize static variables
*
*/
private static function initialize_static_variables()
{
if (!isset(static::$childOIDsLoaded)) {
throw new InsufficientSetupException('This class should not be called directly');
}
if (!static::$childOIDsLoaded) {
ASN1::loadOIDs(is_array(static::OID_NAME) ?
array_combine(static::OID_NAME, static::OID_VALUE) :
[static::OID_NAME => static::OID_VALUE]);
static::$childOIDsLoaded = true;
}
if (!self::$oidsLoaded) {
// from https://tools.ietf.org/html/rfc2898
ASN1::loadOIDs([
// PBES1 encryption schemes
'pbeWithMD2AndDES-CBC' => '1.2.840.113549.1.5.1',
'pbeWithMD2AndRC2-CBC' => '1.2.840.113549.1.5.4',
'pbeWithMD5AndDES-CBC' => '1.2.840.113549.1.5.3',
'pbeWithMD5AndRC2-CBC' => '1.2.840.113549.1.5.6',
'pbeWithSHA1AndDES-CBC' => '1.2.840.113549.1.5.10',
'pbeWithSHA1AndRC2-CBC' => '1.2.840.113549.1.5.11',
// from PKCS#12:
// https://tools.ietf.org/html/rfc7292
'pbeWithSHAAnd128BitRC4' => '1.2.840.113549.1.12.1.1',
'pbeWithSHAAnd40BitRC4' => '1.2.840.113549.1.12.1.2',
'pbeWithSHAAnd3-KeyTripleDES-CBC' => '1.2.840.113549.1.12.1.3',
'pbeWithSHAAnd2-KeyTripleDES-CBC' => '1.2.840.113549.1.12.1.4',
'pbeWithSHAAnd128BitRC2-CBC' => '1.2.840.113549.1.12.1.5',
'pbeWithSHAAnd40BitRC2-CBC' => '1.2.840.113549.1.12.1.6',
'id-PBKDF2' => '1.2.840.113549.1.5.12',
'id-PBES2' => '1.2.840.113549.1.5.13',
'id-PBMAC1' => '1.2.840.113549.1.5.14',
// from PKCS#5 v2.1:
// http://www.rsa.com/rsalabs/pkcs/files/h11302-wp-pkcs5v2-1-password-based-cryptography-standard.pdf
'id-hmacWithSHA1' => '1.2.840.113549.2.7',
'id-hmacWithSHA224' => '1.2.840.113549.2.8',
'id-hmacWithSHA256' => '1.2.840.113549.2.9',
'id-hmacWithSHA384' => '1.2.840.113549.2.10',
'id-hmacWithSHA512' => '1.2.840.113549.2.11',
'id-hmacWithSHA512-224' => '1.2.840.113549.2.12',
'id-hmacWithSHA512-256' => '1.2.840.113549.2.13',
'desCBC' => '1.3.14.3.2.7',
'des-EDE3-CBC' => '1.2.840.113549.3.7',
'rc2CBC' => '1.2.840.113549.3.2',
'rc5-CBC-PAD' => '1.2.840.113549.3.9',
'aes128-CBC-PAD' => '2.16.840.1.101.3.4.1.2',
'aes192-CBC-PAD' => '2.16.840.1.101.3.4.1.22',
'aes256-CBC-PAD' => '2.16.840.1.101.3.4.1.42'
]);
self::$oidsLoaded = true;
}
}
/**
* Break a public or private key down into its constituent components
*
* @param string $key
* @param string $password optional
* @return array
*/
protected static function load($key, $password = '')
{
if (!Strings::is_stringable($key)) {
throw new \UnexpectedValueException('Key should be a string - not a ' . gettype($key));
}
$isPublic = strpos($key, 'PUBLIC') !== false;
$isPrivate = strpos($key, 'PRIVATE') !== false;
$decoded = self::preParse($key);
$meta = [];
$decrypted = ASN1::asn1map($decoded[0], Maps\EncryptedPrivateKeyInfo::MAP);
if (strlen($password) && is_array($decrypted)) {
$algorithm = $decrypted['encryptionAlgorithm']['algorithm'];
switch ($algorithm) {
// PBES1
case 'pbeWithMD2AndDES-CBC':
case 'pbeWithMD2AndRC2-CBC':
case 'pbeWithMD5AndDES-CBC':
case 'pbeWithMD5AndRC2-CBC':
case 'pbeWithSHA1AndDES-CBC':
case 'pbeWithSHA1AndRC2-CBC':
case 'pbeWithSHAAnd3-KeyTripleDES-CBC':
case 'pbeWithSHAAnd2-KeyTripleDES-CBC':
case 'pbeWithSHAAnd128BitRC2-CBC':
case 'pbeWithSHAAnd40BitRC2-CBC':
case 'pbeWithSHAAnd128BitRC4':
case 'pbeWithSHAAnd40BitRC4':
$cipher = self::getPBES1EncryptionObject($algorithm);
$hash = self::getPBES1Hash($algorithm);
$kdf = self::getPBES1KDF($algorithm);
$meta['meta']['algorithm'] = $algorithm;
$temp = ASN1::decodeBER($decrypted['encryptionAlgorithm']['parameters']);
if (!$temp) {
throw new \RuntimeException('Unable to decode BER');
}
extract(ASN1::asn1map($temp[0], Maps\PBEParameter::MAP));
$iterationCount = (int) $iterationCount->toString();
$cipher->setPassword($password, $kdf, $hash, $salt, $iterationCount);
$key = $cipher->decrypt($decrypted['encryptedData']);
$decoded = ASN1::decodeBER($key);
if (!$decoded) {
throw new \RuntimeException('Unable to decode BER 2');
}
break;
case 'id-PBES2':
$meta['meta']['algorithm'] = $algorithm;
$temp = ASN1::decodeBER($decrypted['encryptionAlgorithm']['parameters']);
if (!$temp) {
throw new \RuntimeException('Unable to decode BER');
}
$temp = ASN1::asn1map($temp[0], Maps\PBES2params::MAP);
extract($temp);
$cipher = self::getPBES2EncryptionObject($encryptionScheme['algorithm']);
$meta['meta']['cipher'] = $encryptionScheme['algorithm'];
$temp = ASN1::decodeBER($decrypted['encryptionAlgorithm']['parameters']);
if (!$temp) {
throw new \RuntimeException('Unable to decode BER');
}
$temp = ASN1::asn1map($temp[0], Maps\PBES2params::MAP);
extract($temp);
if (!$cipher instanceof RC2) {
$cipher->setIV($encryptionScheme['parameters']['octetString']);
} else {
$temp = ASN1::decodeBER($encryptionScheme['parameters']);
if (!$temp) {
throw new \RuntimeException('Unable to decode BER');
}
extract(ASN1::asn1map($temp[0], Maps\RC2CBCParameter::MAP));
$effectiveKeyLength = (int) $rc2ParametersVersion->toString();
switch ($effectiveKeyLength) {
case 160:
$effectiveKeyLength = 40;
break;
case 120:
$effectiveKeyLength = 64;
break;
case 58:
$effectiveKeyLength = 128;
break;
//default: // should be >= 256
}
$cipher->setIV($iv);
$cipher->setKeyLength($effectiveKeyLength);
}
$meta['meta']['keyDerivationFunc'] = $keyDerivationFunc['algorithm'];
switch ($keyDerivationFunc['algorithm']) {
case 'id-PBKDF2':
$temp = ASN1::decodeBER($keyDerivationFunc['parameters']);
if (!$temp) {
throw new \RuntimeException('Unable to decode BER');
}
$prf = ['algorithm' => 'id-hmacWithSHA1'];
$params = ASN1::asn1map($temp[0], Maps\PBKDF2params::MAP);
extract($params);
$meta['meta']['prf'] = $prf['algorithm'];
$hash = str_replace('-', '/', substr($prf['algorithm'], 11));
$params = [
$password,
'pbkdf2',
$hash,
$salt,
(int) $iterationCount->toString()
];
if (isset($keyLength)) {
$params[] = (int) $keyLength->toString();
}
$cipher->setPassword(...$params);
$key = $cipher->decrypt($decrypted['encryptedData']);
$decoded = ASN1::decodeBER($key);
if (!$decoded) {
throw new \RuntimeException('Unable to decode BER 3');
}
break;
default:
throw new UnsupportedAlgorithmException('Only PBKDF2 is supported for PBES2 PKCS#8 keys');
}
break;
case 'id-PBMAC1':
//$temp = ASN1::decodeBER($decrypted['encryptionAlgorithm']['parameters']);
//$value = ASN1::asn1map($temp[0], Maps\PBMAC1params::MAP);
// since i can't find any implementation that does PBMAC1 it is unsupported
throw new UnsupportedAlgorithmException('Only PBES1 and PBES2 PKCS#8 keys are supported.');
// at this point we'll assume that the key conforms to PublicKeyInfo
}
}
$private = ASN1::asn1map($decoded[0], Maps\OneAsymmetricKey::MAP);
if (is_array($private)) {
if ($isPublic) {
throw new \UnexpectedValueException('Human readable string claims public key but DER encoded string claims private key');
}
if (isset($private['privateKeyAlgorithm']['parameters']) && !$private['privateKeyAlgorithm']['parameters'] instanceof ASN1\Element && isset($decoded[0]['content'][1]['content'][1])) {
$temp = $decoded[0]['content'][1]['content'][1];
$private['privateKeyAlgorithm']['parameters'] = new ASN1\Element(substr($key, $temp['start'], $temp['length']));
}
if (is_array(static::OID_NAME)) {
if (!in_array($private['privateKeyAlgorithm']['algorithm'], static::OID_NAME)) {
throw new UnsupportedAlgorithmException($private['privateKeyAlgorithm']['algorithm'] . ' is not a supported key type');
}
} else {
if ($private['privateKeyAlgorithm']['algorithm'] != static::OID_NAME) {
throw new UnsupportedAlgorithmException('Only ' . static::OID_NAME . ' keys are supported; this is a ' . $private['privateKeyAlgorithm']['algorithm'] . ' key');
}
}
if (isset($private['publicKey'])) {
if ($private['publicKey'][0] != "\0") {
throw new \UnexpectedValueException('The first byte of the public key should be null - not ' . bin2hex($private['publicKey'][0]));
}
$private['publicKey'] = substr($private['publicKey'], 1);
}
return $private + $meta;
}
// EncryptedPrivateKeyInfo and PublicKeyInfo have largely identical "signatures". the only difference
// is that the former has an octet string and the later has a bit string. the first byte of a bit
// string represents the number of bits in the last byte that are to be ignored but, currently,
// bit strings wanting a non-zero amount of bits trimmed are not supported
$public = ASN1::asn1map($decoded[0], Maps\PublicKeyInfo::MAP);
if (is_array($public)) {
if ($isPrivate) {
throw new \UnexpectedValueException('Human readable string claims private key but DER encoded string claims public key');
}
if ($public['publicKey'][0] != "\0") {
throw new \UnexpectedValueException('The first byte of the public key should be null - not ' . bin2hex($public['publicKey'][0]));
}
if (is_array(static::OID_NAME)) {
if (!in_array($public['publicKeyAlgorithm']['algorithm'], static::OID_NAME)) {
throw new UnsupportedAlgorithmException($public['publicKeyAlgorithm']['algorithm'] . ' is not a supported key type');
}
} else {
if ($public['publicKeyAlgorithm']['algorithm'] != static::OID_NAME) {
throw new UnsupportedAlgorithmException('Only ' . static::OID_NAME . ' keys are supported; this is a ' . $public['publicKeyAlgorithm']['algorithm'] . ' key');
}
}
if (isset($public['publicKeyAlgorithm']['parameters']) && !$public['publicKeyAlgorithm']['parameters'] instanceof ASN1\Element && isset($decoded[0]['content'][0]['content'][1])) {
$temp = $decoded[0]['content'][0]['content'][1];
$public['publicKeyAlgorithm']['parameters'] = new ASN1\Element(substr($key, $temp['start'], $temp['length']));
}
$public['publicKey'] = substr($public['publicKey'], 1);
return $public;
}
throw new \RuntimeException('Unable to parse using either OneAsymmetricKey or PublicKeyInfo ASN1 maps');
}
/**
* Wrap a private key appropriately
*
* @param string $key
* @param string $attr
* @param mixed $params
* @param string $password
* @param string $oid optional
* @param string $publicKey optional
* @param array $options optional
* @return string
*/
protected static function wrapPrivateKey($key, $attr, $params, $password, $oid = null, $publicKey = '', array $options = [])
{
self::initialize_static_variables();
$key = [
'version' => 'v1',
'privateKeyAlgorithm' => [
'algorithm' => is_string(static::OID_NAME) ? static::OID_NAME : $oid
],
'privateKey' => $key
];
if ($oid != 'id-Ed25519' && $oid != 'id-Ed448') {
$key['privateKeyAlgorithm']['parameters'] = $params;
}
if (!empty($attr)) {
$key['attributes'] = $attr;
}
if (!empty($publicKey)) {
$key['version'] = 'v2';
$key['publicKey'] = $publicKey;
}
$key = ASN1::encodeDER($key, Maps\OneAsymmetricKey::MAP);
if (!empty($password) && is_string($password)) {
$salt = Random::string(8);
$iterationCount = isset($options['iterationCount']) ? $options['iterationCount'] : self::$defaultIterationCount;
$encryptionAlgorithm = isset($options['encryptionAlgorithm']) ? $options['encryptionAlgorithm'] : self::$defaultEncryptionAlgorithm;
$encryptionScheme = isset($options['encryptionScheme']) ? $options['encryptionScheme'] : self::$defaultEncryptionScheme;
$prf = isset($options['PRF']) ? $options['PRF'] : self::$defaultPRF;
if ($encryptionAlgorithm == 'id-PBES2') {
$crypto = self::getPBES2EncryptionObject($encryptionScheme);
$hash = str_replace('-', '/', substr($prf, 11));
$kdf = 'pbkdf2';
$iv = Random::string($crypto->getBlockLength() >> 3);
$PBKDF2params = [
'salt' => $salt,
'iterationCount' => $iterationCount,
'prf' => ['algorithm' => $prf, 'parameters' => null]
];
$PBKDF2params = ASN1::encodeDER($PBKDF2params, Maps\PBKDF2params::MAP);
if (!$crypto instanceof RC2) {
$params = ['octetString' => $iv];
} else {
$params = [
'rc2ParametersVersion' => 58,
'iv' => $iv
];
$params = ASN1::encodeDER($params, Maps\RC2CBCParameter::MAP);
$params = new ASN1\Element($params);
}
$params = [
'keyDerivationFunc' => [
'algorithm' => 'id-PBKDF2',
'parameters' => new ASN1\Element($PBKDF2params)
],
'encryptionScheme' => [
'algorithm' => $encryptionScheme,
'parameters' => $params
]
];
$params = ASN1::encodeDER($params, Maps\PBES2params::MAP);
$crypto->setIV($iv);
} else {
$crypto = self::getPBES1EncryptionObject($encryptionAlgorithm);
$hash = self::getPBES1Hash($encryptionAlgorithm);
$kdf = self::getPBES1KDF($encryptionAlgorithm);
$params = [
'salt' => $salt,
'iterationCount' => $iterationCount
];
$params = ASN1::encodeDER($params, Maps\PBEParameter::MAP);
}
$crypto->setPassword($password, $kdf, $hash, $salt, $iterationCount);
$key = $crypto->encrypt($key);
$key = [
'encryptionAlgorithm' => [
'algorithm' => $encryptionAlgorithm,
'parameters' => new ASN1\Element($params)
],
'encryptedData' => $key
];
$key = ASN1::encodeDER($key, Maps\EncryptedPrivateKeyInfo::MAP);
return "-----BEGIN ENCRYPTED PRIVATE KEY-----\r\n" .
chunk_split(Strings::base64_encode($key), 64) .
"-----END ENCRYPTED PRIVATE KEY-----";
}
return "-----BEGIN PRIVATE KEY-----\r\n" .
chunk_split(Strings::base64_encode($key), 64) .
"-----END PRIVATE KEY-----";
}
/**
* Wrap a public key appropriately
*
* @param string $key
* @param mixed $params
* @param string $oid
* @return string
*/
protected static function wrapPublicKey($key, $params, $oid = null)
{
self::initialize_static_variables();
$key = [
'publicKeyAlgorithm' => [
'algorithm' => is_string(static::OID_NAME) ? static::OID_NAME : $oid
],
'publicKey' => "\0" . $key
];
if ($oid != 'id-Ed25519' && $oid != 'id-Ed448') {
$key['publicKeyAlgorithm']['parameters'] = $params;
}
$key = ASN1::encodeDER($key, Maps\PublicKeyInfo::MAP);
return "-----BEGIN PUBLIC KEY-----\r\n" .
chunk_split(Strings::base64_encode($key), 64) .
"-----END PUBLIC KEY-----";
}
/**
* Perform some preliminary parsing of the key
*
* @param string $key
* @return array
*/
private static function preParse(&$key)
{
self::initialize_static_variables();
if (self::$format != self::MODE_DER) {
$decoded = ASN1::extractBER($key);
if ($decoded !== false) {
$key = $decoded;
} elseif (self::$format == self::MODE_PEM) {
throw new \UnexpectedValueException('Expected base64-encoded PEM format but was unable to decode base64 text');
}
}
$decoded = ASN1::decodeBER($key);
if (!$decoded) {
throw new \RuntimeException('Unable to decode BER');
}
return $decoded;
}
/**
* Returns the encryption parameters used by the key
*
* @param string $key
* @return array
*/
public static function extractEncryptionAlgorithm($key)
{
if (!Strings::is_stringable($key)) {
throw new \UnexpectedValueException('Key should be a string - not a ' . gettype($key));
}
$decoded = self::preParse($key);
$r = ASN1::asn1map($decoded[0], ASN1\Maps\EncryptedPrivateKeyInfo::MAP);
if (!is_array($r)) {
throw new \RuntimeException('Unable to parse using EncryptedPrivateKeyInfo map');
}
if ($r['encryptionAlgorithm']['algorithm'] == 'id-PBES2') {
$decoded = ASN1::decodeBER($r['encryptionAlgorithm']['parameters']->element);
if (!$decoded) {
throw new \RuntimeException('Unable to decode BER');
}
$r['encryptionAlgorithm']['parameters'] = ASN1::asn1map($decoded[0], ASN1\Maps\PBES2params::MAP);
$kdf = &$r['encryptionAlgorithm']['parameters']['keyDerivationFunc'];
switch ($kdf['algorithm']) {
case 'id-PBKDF2':
$decoded = ASN1::decodeBER($kdf['parameters']->element);
if (!$decoded) {
throw new \RuntimeException('Unable to decode BER');
}
$kdf['parameters'] = ASN1::asn1map($decoded[0], Maps\PBKDF2params::MAP);
}
}
return $r['encryptionAlgorithm'];
}
}
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