/* * PKCS #8 * (C) 1999-2007 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #ifndef BOTAN_PKCS8_H__ #define BOTAN_PKCS8_H__ #include #include #include namespace Botan { /** * PKCS #8 General Exception */ struct BOTAN_DLL PKCS8_Exception : public Decoding_Error { explicit PKCS8_Exception(const std::string& error) : Decoding_Error("PKCS #8: " + error) {} }; /** * This namespace contains functions for handling PKCS #8 private keys */ namespace PKCS8 { /** * BER encode a private key * @param key the private key to encode * @return BER encoded key */ BOTAN_DLL secure_vector BER_encode(const Private_Key& key); /** * Get a string containing a PEM encoded private key. * @param key the key to encode * @return encoded key */ BOTAN_DLL std::string PEM_encode(const Private_Key& key); /** * Encrypt a key using PKCS #8 encryption * @param key the key to encode * @param rng the rng to use * @param pass the password to use for encryption * @param msec number of milliseconds to run the password derivation * @param pbe_algo the name of the desired password-based encryption algorithm; if empty ("") a reasonable (portable/secure) default will be chosen. * @return encrypted key in binary BER form */ BOTAN_DLL std::vector BER_encode(const Private_Key& key, RandomNumberGenerator& rng, const std::string& pass, std::chrono::milliseconds msec = std::chrono::milliseconds(300), const std::string& pbe_algo = ""); /** * Get a string containing a PEM encoded private key, encrypting it with a * password. * @param key the key to encode * @param rng the rng to use * @param pass the password to use for encryption * @param msec number of milliseconds to run the password derivation * @param pbe_algo the name of the desired password-based encryption algorithm; if empty ("") a reasonable (portable/secure) default will be chosen. * @return encrypted key in PEM form */ BOTAN_DLL std::string PEM_encode(const Private_Key& key, RandomNumberGenerator& rng, const std::string& pass, std::chrono::milliseconds msec = std::chrono::milliseconds(300), const std::string& pbe_algo = ""); /** * Encrypt a key using PKCS #8 encryption and a fixed iteration count * @param key the key to encode * @param rng the rng to use * @param pass the password to use for encryption * @param pbkdf_iter number of interations to run PBKDF2 * @param cipher if non-empty specifies the cipher to use. CBC and GCM modes * are supported, for example "AES-128/CBC", "AES-256/GCM", "Serpent/CBC". * If empty a suitable default is chosen. * @param pbkdf_hash if non-empty specifies the PBKDF hash function to use. * For example "SHA-256" or "SHA-384". If empty a suitable default is chosen. * @return encrypted key in binary BER form */ BOTAN_DLL std::vector BER_encode_encrypted_pbkdf_iter(const Private_Key& key, RandomNumberGenerator& rng, const std::string& pass, size_t pbkdf_iter, const std::string& cipher = "", const std::string& pbkdf_hash = ""); /** * Get a string containing a PEM encoded private key, encrypting it with a * password. * @param key the key to encode * @param rng the rng to use * @param pass the password to use for encryption * @param pbkdf_iter number of iterations to run PBKDF * @param cipher if non-empty specifies the cipher to use. CBC and GCM modes * are supported, for example "AES-128/CBC", "AES-256/GCM", "Serpent/CBC". * If empty a suitable default is chosen. * @param pbkdf_hash if non-empty specifies the PBKDF hash function to use. * For example "SHA-256" or "SHA-384". If empty a suitable default is chosen. * @return encrypted key in PEM form */ BOTAN_DLL std::string PEM_encode_encrypted_pbkdf_iter(const Private_Key& key, RandomNumberGenerator& rng, const std::string& pass, size_t pbkdf_iter, const std::string& cipher = "", const std::string& pbkdf_hash = ""); /** * Encrypt a key using PKCS #8 encryption and a variable iteration count * @param key the key to encode * @param rng the rng to use * @param pass the password to use for encryption * @param pbkdf_msec how long to run PBKDF2 * @param pbkdf_iterations if non-null, set to the number of iterations used * @param cipher if non-empty specifies the cipher to use. CBC and GCM modes * are supported, for example "AES-128/CBC", "AES-256/GCM", "Serpent/CBC". * If empty a suitable default is chosen. * @param pbkdf_hash if non-empty specifies the PBKDF hash function to use. * For example "SHA-256" or "SHA-384". If empty a suitable default is chosen. * @return encrypted key in binary BER form */ BOTAN_DLL std::vector BER_encode_encrypted_pbkdf_msec(const Private_Key& key, RandomNumberGenerator& rng, const std::string& pass, std::chrono::milliseconds pbkdf_msec, size_t* pbkdf_iterations, const std::string& cipher = "", const std::string& pbkdf_hash = ""); /** * Get a string containing a PEM encoded private key, encrypting it with a * password. * @param key the key to encode * @param rng the rng to use * @param pass the password to use for encryption * @param pbkdf_iter number of iterations to run PBKDF * @param cipher if non-empty specifies the cipher to use. CBC and GCM modes * are supported, for example "AES-128/CBC", "AES-256/GCM", "Serpent/CBC". * If empty a suitable default is chosen. * @param pbkdf_hash if non-empty specifies the PBKDF hash function to use. * For example "SHA-256" or "SHA-384". If empty a suitable default is chosen. * @return encrypted key in PEM form */ BOTAN_DLL std::string PEM_encode_encrypted_pbkdf_msec(const Private_Key& key, RandomNumberGenerator& rng, const std::string& pass, std::chrono::milliseconds pbkdf_msec, size_t* pbkdf_iterations, const std::string& cipher = "", const std::string& pbkdf_hash = ""); /** * Load an encrypted key from a data source. * @param source the data source providing the encoded key * @param rng ignored for compatability * @param get_passphrase a function that returns passphrases * @return loaded private key object */ BOTAN_DLL Private_Key* load_key(DataSource& source, RandomNumberGenerator& rng, std::function get_passphrase); /** Load an encrypted key from a data source. * @param source the data source providing the encoded key * @param rng ignored for compatability * @param pass the passphrase to decrypt the key * @return loaded private key object */ BOTAN_DLL Private_Key* load_key(DataSource& source, RandomNumberGenerator& rng, const std::string& pass); /** Load an unencrypted key from a data source. * @param source the data source providing the encoded key * @param rng ignored for compatability * @return loaded private key object */ BOTAN_DLL Private_Key* load_key(DataSource& source, RandomNumberGenerator& rng); #if defined(BOTAN_TARGET_OS_HAS_FILESYSTEM) /** * Load an encrypted key from a file. * @param filename the path to the file containing the encoded key * @param rng ignored for compatability * @param get_passphrase a function that returns passphrases * @return loaded private key object */ BOTAN_DLL Private_Key* load_key(const std::string& filename, RandomNumberGenerator& rng, std::function get_passphrase); /** Load an encrypted key from a file. * @param filename the path to the file containing the encoded key * @param rng ignored for compatability * @param pass the passphrase to decrypt the key * @return loaded private key object */ BOTAN_DLL Private_Key* load_key(const std::string& filename, RandomNumberGenerator& rng, const std::string& pass); /** Load an unencrypted key from a file. * @param filename the path to the file containing the encoded key * @param rng ignored for compatability * @return loaded private key object */ BOTAN_DLL Private_Key* load_key(const std::string& filename, RandomNumberGenerator& rng); #endif /** * Copy an existing encoded key object. * @param key the key to copy * @param rng ignored for compatability * @return new copy of the key */ BOTAN_DLL Private_Key* copy_key(const Private_Key& key, RandomNumberGenerator& rng); } } #endif