/* * Public Key Interface * (C) 1999-2010 Jack Lloyd * * Distributed under the terms of the Botan license */ #ifndef BOTAN_PUBKEY_H__ #define BOTAN_PUBKEY_H__ #include #include #include #include #include #include #include namespace Botan { /** * The two types of signature format supported by Botan. */ enum Signature_Format { IEEE_1363, DER_SEQUENCE }; /** * Public Key Encryptor */ class BOTAN_DLL PK_Encryptor { public: /** * Encrypt a message. * @param in the message as a byte array * @param length the length of the above byte array * @param rng the random number source to use * @return the encrypted message */ SecureVector encrypt(const byte in[], u32bit length, RandomNumberGenerator& rng) const { return enc(in, length, rng); } /** * Encrypt a message. * @param in the message * @param rng the random number source to use * @return the encrypted message */ SecureVector encrypt(const MemoryRegion& in, RandomNumberGenerator& rng) const { return enc(&in[0], in.size(), rng); } /** * Return the maximum allowed message size in bytes. * @return the maximum message size in bytes */ virtual u32bit maximum_input_size() const = 0; PK_Encryptor() {} virtual ~PK_Encryptor() {} private: PK_Encryptor(const PK_Encryptor&) {} PK_Encryptor& operator=(const PK_Encryptor&) { return *this; } virtual SecureVector enc(const byte[], u32bit, RandomNumberGenerator&) const = 0; }; /** * Public Key Decryptor */ class BOTAN_DLL PK_Decryptor { public: /** * Decrypt a ciphertext. * @param in the ciphertext as a byte array * @param length the length of the above byte array * @return the decrypted message */ SecureVector decrypt(const byte in[], u32bit length) const { return dec(in, length); } /** * Decrypt a ciphertext. * @param in the ciphertext * @return the decrypted message */ SecureVector decrypt(const MemoryRegion& in) const { return dec(&in[0], in.size()); } PK_Decryptor() {} virtual ~PK_Decryptor() {} private: PK_Decryptor(const PK_Decryptor&) {} PK_Decryptor& operator=(const PK_Decryptor&) { return *this; } virtual SecureVector dec(const byte[], u32bit) const = 0; }; /** * Public Key Signer. Use the sign_message() functions for small * messages. Use multiple calls update() to process large messages and * generate the signature by finally calling signature(). */ class BOTAN_DLL PK_Signer { public: /** * Sign a message. * @param in the message to sign as a byte array * @param length the length of the above byte array * @param rng the rng to use * @return the signature */ SecureVector sign_message(const byte in[], u32bit length, RandomNumberGenerator& rng); /** * Sign a message. * @param in the message to sign * @param rng the rng to use * @return the signature */ SecureVector sign_message(const MemoryRegion& in, RandomNumberGenerator& rng) { return sign_message(&in[0], in.size(), rng); } /** * Add a message part (single byte). * @param the byte to add */ void update(byte in) { update(&in, 1); } /** * Add a message part. * @param in the message part to add as a byte array * @param length the length of the above byte array */ void update(const byte in[], u32bit length); /** * Add a message part. * @param in the message part to add */ void update(const MemoryRegion& in) { update(&in[0], in.size()); } /** * Get the signature of the so far processed message (provided by the * calls to update()). * @param rng the rng to use * @return the signature of the total message */ SecureVector signature(RandomNumberGenerator& rng); /** * Set the output format of the signature. * @param format the signature format to use */ void set_output_format(Signature_Format format) { sig_format = format; } /** * Construct a PK Signer. * @param key the key to use inside this signer * @param emsa the EMSA to use * An example would be "EMSA1(SHA-224)". * @param format the signature format to use */ PK_Signer(const Private_Key& key, const std::string& emsa, Signature_Format format = IEEE_1363); ~PK_Signer() { delete op; delete verify_op; delete emsa; } private: bool self_test_signature(const MemoryRegion& msg, const MemoryRegion& sig) const; PK_Signer(const PK_Signer&) {} PK_Signer& operator=(const PK_Signer&) { return *this; } PK_Ops::Signature* op; PK_Ops::Verification* verify_op; EMSA* emsa; Signature_Format sig_format; }; /** * Public Key Verifier. Use the verify_message() functions for small * messages. Use multiple calls update() to process large messages and * verify the signature by finally calling check_signature(). */ class BOTAN_DLL PK_Verifier { public: /** * Verify a signature. * @param msg the message that the signature belongs to, as a byte array * @param msg_length the length of the above byte array msg * @param sig the signature as a byte array * @param sig_length the length of the above byte array sig * @return true if the signature is valid */ bool verify_message(const byte msg[], u32bit msg_length, const byte sig[], u32bit sig_length); /** * Verify a signature. * @param msg the message that the signature belongs to * @param sig the signature * @return true if the signature is valid */ bool verify_message(const MemoryRegion& msg, const MemoryRegion& sig) { return verify_message(msg, msg.size(), sig, sig.size()); } /** * Add a message part (single byte) of the message corresponding to the * signature to be verified. * @param in the byte to add */ void update(byte in) { update(&in, 1); } /** * Add a message part of the message corresponding to the * signature to be verified. * @param msg_part the new message part as a byte array * @param length the length of the above byte array */ void update(const byte msg_part[], u32bit length); /** * Add a message part of the message corresponding to the * signature to be verified. * @param in the new message part */ void update(const MemoryRegion& in) { update(&in[0], in.size()); } /** * Check the signature of the buffered message, i.e. the one build * by successive calls to update. * @param sig the signature to be verified as a byte array * @param length the length of the above byte array * @return true if the signature is valid, false otherwise */ bool check_signature(const byte sig[], u32bit length); /** * Check the signature of the buffered message, i.e. the one build * by successive calls to update. * @param sig the signature to be verified * @return true if the signature is valid, false otherwise */ bool check_signature(const MemoryRegion& sig) { return check_signature(&sig[0], sig.size()); } /** * Set the format of the signatures fed to this verifier. * @param format the signature format to use */ void set_input_format(Signature_Format format); /** * Construct a PK Verifier. * @param pub_key the public key to verify against * @param emsa the EMSA to use (eg "EMSA3(SHA-1)") * @param format the signature format to use */ PK_Verifier(const Public_Key& pub_key, const std::string& emsa, Signature_Format format = IEEE_1363); ~PK_Verifier() { delete op; delete emsa; } private: PK_Verifier(const PK_Verifier&) {} PK_Verifier& operator=(const PK_Verifier&) { return *this; } bool validate_signature(const MemoryRegion& msg, const byte sig[], u32bit sig_len); PK_Ops::Verification* op; EMSA* emsa; Signature_Format sig_format; }; /* * Key Agreement */ class BOTAN_DLL PK_Key_Agreement { public: /* * Perform Key Agreement Operation * @param key_len the desired key output size * @param in the other parties key * @param in_len the length of in in bytes * @param params extra derivation params * @param params_len the length of params in bytes */ SymmetricKey derive_key(u32bit key_len, const byte in[], u32bit in_len, const byte params[], u32bit params_len) const; /* * Perform Key Agreement Operation * @param key_len the desired key output size * @param in the other parties key * @param in_len the length of in in bytes * @param params extra derivation params * @param params_len the length of params in bytes */ SymmetricKey derive_key(u32bit key_len, const MemoryRegion& in, const byte params[], u32bit params_len) const { return derive_key(key_len, &in[0], in.size(), params, params_len); } /* * Perform Key Agreement Operation * @param key_len the desired key output size * @param in the other parties key * @param in_len the length of in in bytes * @param params extra derivation params */ SymmetricKey derive_key(u32bit key_len, const byte in[], u32bit in_len, const std::string& params = "") const { return derive_key(key_len, in, in_len, reinterpret_cast(params.data()), params.length()); } /* * Perform Key Agreement Operation * @param key_len the desired key output size * @param in the other parties key * @param params extra derivation params */ SymmetricKey derive_key(u32bit key_len, const MemoryRegion& in, const std::string& params = "") const { return derive_key(key_len, &in[0], in.size(), reinterpret_cast(params.data()), params.length()); } /** * Construct a PK Key Agreement. * @param key the key to use * @param kdf name of the KDF to use (or 'Raw' for no KDF) */ PK_Key_Agreement(const PK_Key_Agreement_Key& key, const std::string& kdf); ~PK_Key_Agreement() { delete op; delete kdf; } private: PK_Key_Agreement(const PK_Key_Agreement_Key&) {} PK_Key_Agreement& operator=(const PK_Key_Agreement&) { return *this; } PK_Ops::Key_Agreement* op; KDF* kdf; }; /** * Encryption with an MR algorithm and an EME. */ class BOTAN_DLL PK_Encryptor_EME : public PK_Encryptor { public: u32bit maximum_input_size() const; /** * Construct an instance. * @param key the key to use inside the decryptor * @param eme the EME to use */ PK_Encryptor_EME(const Public_Key& key, const std::string& eme); ~PK_Encryptor_EME() { delete op; delete eme; } private: SecureVector enc(const byte[], u32bit, RandomNumberGenerator& rng) const; PK_Ops::Encryption* op; const EME* eme; }; /** * Decryption with an MR algorithm and an EME. */ class BOTAN_DLL PK_Decryptor_EME : public PK_Decryptor { public: /** * Construct an instance. * @param key the key to use inside the encryptor * @param eme the EME to use */ PK_Decryptor_EME(const Private_Key& key, const std::string& eme); ~PK_Decryptor_EME() { delete op; delete eme; } private: SecureVector dec(const byte[], u32bit) const; PK_Ops::Decryption* op; const EME* eme; }; } #endif