/* * Public Key Base * (C) 1999-2010 Jack Lloyd * * Distributed under the terms of the Botan license */ #include #include #include #include #include #include #include #include #include #include #include namespace Botan { /* * PK_Encryptor_EME Constructor */ PK_Encryptor_EME::PK_Encryptor_EME(const Public_Key& key, const std::string& eme_name) { Algorithm_Factory::Engine_Iterator i(global_state().algorithm_factory()); while(const Engine* engine = i.next()) { op = engine->get_encryption_op(key); if(op) break; } if(!op) throw Lookup_Error("PK_Encryptor_EME: No working engine for " + key.algo_name()); eme = (eme_name == "Raw") ? 0 : get_eme(eme_name); } /* * Encrypt a message */ SecureVector PK_Encryptor_EME::enc(const byte in[], size_t length, RandomNumberGenerator& rng) const { if(eme) { SecureVector encoded = eme->encode(in, length, op->max_input_bits(), rng); if(8*(encoded.size() - 1) + high_bit(encoded[0]) > op->max_input_bits()) throw Invalid_Argument("PK_Encryptor_EME: Input is too large"); return op->encrypt(&encoded[0], encoded.size(), rng); } else { if(8*(length - 1) + high_bit(in[0]) > op->max_input_bits()) throw Invalid_Argument("PK_Encryptor_EME: Input is too large"); return op->encrypt(&in[0], length, rng); } } /* * Return the max size, in bytes, of a message */ size_t PK_Encryptor_EME::maximum_input_size() const { if(!eme) return (op->max_input_bits() / 8); else return eme->maximum_input_size(op->max_input_bits()); } /* * PK_Decryptor_EME Constructor */ PK_Decryptor_EME::PK_Decryptor_EME(const Private_Key& key, const std::string& eme_name) { Algorithm_Factory::Engine_Iterator i(global_state().algorithm_factory()); while(const Engine* engine = i.next()) { op = engine->get_decryption_op(key); if(op) break; } if(!op) throw Lookup_Error("PK_Decryptor_EME: No working engine for " + key.algo_name()); eme = (eme_name == "Raw") ? 0 : get_eme(eme_name); } /* * Decrypt a message */ SecureVector PK_Decryptor_EME::dec(const byte msg[], size_t length) const { try { SecureVector decrypted = op->decrypt(msg, length); if(eme) return eme->decode(decrypted, op->max_input_bits()); else return decrypted; } catch(Invalid_Argument) { throw Decoding_Error("PK_Decryptor_EME: Input is invalid"); } } /* * PK_Signer Constructor */ PK_Signer::PK_Signer(const Private_Key& key, const std::string& emsa_name, Signature_Format format, Fault_Protection prot) { Algorithm_Factory::Engine_Iterator i(global_state().algorithm_factory()); op = 0; verify_op = 0; while(const Engine* engine = i.next()) { if(!op) op = engine->get_signature_op(key); if(!verify_op && prot == ENABLE_FAULT_PROTECTION) verify_op = engine->get_verify_op(key); if(op && (verify_op || prot == DISABLE_FAULT_PROTECTION)) break; } if(!op || (!verify_op && prot == ENABLE_FAULT_PROTECTION)) throw Lookup_Error("PK_Signer: No working engine for " + key.algo_name()); emsa = get_emsa(emsa_name); sig_format = format; } /* * Sign a message */ SecureVector PK_Signer::sign_message(const byte msg[], size_t length, RandomNumberGenerator& rng) { update(msg, length); return signature(rng); } /* * Add more to the message to be signed */ void PK_Signer::update(const byte in[], size_t length) { emsa->update(in, length); } /* * Check the signature we just created, to help prevent fault attacks */ bool PK_Signer::self_test_signature(const MemoryRegion& msg, const MemoryRegion& sig) const { if(!verify_op) return true; // checking disabled, assume ok if(verify_op->with_recovery()) { SecureVector recovered = verify_op->verify_mr(&sig[0], sig.size()); if(msg.size() > recovered.size()) { size_t extra_0s = msg.size() - recovered.size(); for(size_t i = 0; i != extra_0s; ++i) if(msg[i] != 0) return false; return same_mem(&msg[extra_0s], &recovered[0], recovered.size()); } return (recovered == msg); } else return verify_op->verify(&msg[0], msg.size(), &sig[0], sig.size()); } /* * Create a signature */ SecureVector PK_Signer::signature(RandomNumberGenerator& rng) { SecureVector encoded = emsa->encoding_of(emsa->raw_data(), op->max_input_bits(), rng); SecureVector plain_sig = op->sign(&encoded[0], encoded.size(), rng); BOTAN_ASSERT(self_test_signature(encoded, plain_sig), "PK_Signer consistency check failed"); if(op->message_parts() == 1 || sig_format == IEEE_1363) return plain_sig; if(sig_format == DER_SEQUENCE) { if(plain_sig.size() % op->message_parts()) throw Encoding_Error("PK_Signer: strange signature size found"); const size_t SIZE_OF_PART = plain_sig.size() / op->message_parts(); std::vector sig_parts(op->message_parts()); for(size_t j = 0; j != sig_parts.size(); ++j) sig_parts[j].binary_decode(&plain_sig[SIZE_OF_PART*j], SIZE_OF_PART); return DER_Encoder() .start_cons(SEQUENCE) .encode_list(sig_parts) .end_cons() .get_contents(); } else throw Encoding_Error("PK_Signer: Unknown signature format " + to_string(sig_format)); } /* * PK_Verifier Constructor */ PK_Verifier::PK_Verifier(const Public_Key& key, const std::string& emsa_name, Signature_Format format) { Algorithm_Factory::Engine_Iterator i(global_state().algorithm_factory()); while(const Engine* engine = i.next()) { op = engine->get_verify_op(key); if(op) break; } if(!op) throw Lookup_Error("PK_Verifier: No working engine for " + key.algo_name()); emsa = get_emsa(emsa_name); sig_format = format; } /* * Set the signature format */ void PK_Verifier::set_input_format(Signature_Format format) { if(op->message_parts() == 1 && format != IEEE_1363) throw Invalid_State("PK_Verifier: This algorithm always uses IEEE 1363"); sig_format = format; } /* * Verify a message */ bool PK_Verifier::verify_message(const byte msg[], size_t msg_length, const byte sig[], size_t sig_length) { update(msg, msg_length); return check_signature(sig, sig_length); } /* * Append to the message */ void PK_Verifier::update(const byte in[], size_t length) { emsa->update(in, length); } /* * Check a signature */ bool PK_Verifier::check_signature(const byte sig[], size_t length) { try { if(sig_format == IEEE_1363) return validate_signature(emsa->raw_data(), sig, length); else if(sig_format == DER_SEQUENCE) { BER_Decoder decoder(sig, length); BER_Decoder ber_sig = decoder.start_cons(SEQUENCE); size_t count = 0; SecureVector real_sig; while(ber_sig.more_items()) { BigInt sig_part; ber_sig.decode(sig_part); real_sig += BigInt::encode_1363(sig_part, op->message_part_size()); ++count; } if(count != op->message_parts()) throw Decoding_Error("PK_Verifier: signature size invalid"); return validate_signature(emsa->raw_data(), &real_sig[0], real_sig.size()); } else throw Decoding_Error("PK_Verifier: Unknown signature format " + to_string(sig_format)); } catch(Invalid_Argument) { return false; } } /* * Verify a signature */ bool PK_Verifier::validate_signature(const MemoryRegion& msg, const byte sig[], size_t sig_len) { if(op->with_recovery()) { SecureVector output_of_key = op->verify_mr(sig, sig_len); return emsa->verify(output_of_key, msg, op->max_input_bits()); } else { Null_RNG rng; SecureVector encoded = emsa->encoding_of(msg, op->max_input_bits(), rng); return op->verify(&encoded[0], encoded.size(), sig, sig_len); } } /* * PK_Key_Agreement Constructor */ PK_Key_Agreement::PK_Key_Agreement(const PK_Key_Agreement_Key& key, const std::string& kdf_name) { Algorithm_Factory::Engine_Iterator i(global_state().algorithm_factory()); while(const Engine* engine = i.next()) { op = engine->get_key_agreement_op(key); if(op) break; } if(!op) throw Lookup_Error("PK_Key_Agreement: No working engine for " + key.algo_name()); kdf = (kdf_name == "Raw") ? 0 : get_kdf(kdf_name); } SymmetricKey PK_Key_Agreement::derive_key(size_t key_len, const byte in[], size_t in_len, const byte params[], size_t params_len) const { SecureVector z = op->agree(in, in_len); if(!kdf) return z; return kdf->derive_key(key_len, z, params, params_len); } }