/* (C) 2007 FlexSecure GmbH 2008 Jack Lloyd * * Distributed under the terms of the Botan license */ #include #include #include #include #include #include #include #include #include #include #include namespace Botan { namespace { /******************************* * cvc CHAT values *******************************/ enum CHAT_values{ CVCA = 0xC0, DVCA_domestic = 0x80, DVCA_foreign = 0x40, IS = 0x00, IRIS = 0x02, FINGERPRINT = 0x01 }; std::string padding_and_hash_from_oid(OID const& oid) { std::string padding_and_hash = OIDS::lookup(oid); // use the hash assert(padding_and_hash.substr(0,6) == "ECDSA/"); // can only be ECDSA for now assert(padding_and_hash.find("/",0) == 5); padding_and_hash.erase(0, padding_and_hash.find("/",0) + 1); return padding_and_hash; } std::string fixed_len_seqnr(u32bit seqnr, u32bit len) { std::stringstream ss; std::string result; ss << seqnr; ss >> result; if (result.size() > len) { throw Invalid_Argument("fixed_len_seqnr(): number too high to be encoded in provided length"); } while (result.size() < len) { result.insert(0,"0"); } return result; } } namespace CVC_EAC { EAC1_1_CVC create_self_signed_cert(Private_Key const& key, EAC1_1_CVC_Options const& opt, RandomNumberGenerator& rng) { // NOTE: we ignore // the value // of opt.chr ECDSA_PrivateKey const* priv_key = dynamic_cast(&key); if (priv_key == 0) { throw Invalid_Argument("CVC_EAC::create_self_signed_cert(): unsupported key type"); } ASN1_Chr chr(opt.car.value()); AlgorithmIdentifier sig_algo; std::string padding_and_hash(eac_cvc_emsa + "(" + opt.hash_alg + ")"); sig_algo.oid = OIDS::lookup(priv_key->algo_name() + "/" + padding_and_hash); sig_algo = AlgorithmIdentifier(sig_algo.oid, AlgorithmIdentifier::USE_NULL_PARAM); std::unique_ptr signer(get_pk_signer(*priv_key, padding_and_hash)); #if 0 std::unique_ptr enc(priv_key->cvc_eac1_1_encoder()); MemoryVector enc_public_key = enc->public_key(sig_algo); #else MemoryVector enc_public_key; #endif return EAC1_1_CVC_CA::make_cert(*signer.get(), enc_public_key, opt.car, chr, opt.holder_auth_templ, opt.ced, opt.cex, rng); } EAC1_1_Req create_cvc_req(Private_Key const& key, ASN1_Chr const& chr, std::string const& hash_alg, RandomNumberGenerator& rng) { ECDSA_PrivateKey const* priv_key = dynamic_cast(&key); if (priv_key == 0) { throw Invalid_Argument("CVC_EAC::create_self_signed_cert(): unsupported key type"); } AlgorithmIdentifier sig_algo; std::string padding_and_hash(eac_cvc_emsa + "(" + hash_alg + ")"); sig_algo.oid = OIDS::lookup(priv_key->algo_name() + "/" + padding_and_hash); sig_algo = AlgorithmIdentifier(sig_algo.oid, AlgorithmIdentifier::USE_NULL_PARAM); std::unique_ptr signer(get_pk_signer(*priv_key, padding_and_hash)); #if 0 // FIXME std::unique_ptr enc(priv_key->cvc_eac1_1_encoder()); MemoryVector enc_public_key = enc->public_key(sig_algo); #else MemoryVector enc_public_key; #endif MemoryVector enc_cpi; enc_cpi.append(0x00); MemoryVector tbs = DER_Encoder() .encode(enc_cpi, OCTET_STRING, ASN1_Tag(41), APPLICATION) .raw_bytes(enc_public_key) .encode(chr) .get_contents(); MemoryVector signed_cert = EAC1_1_gen_CVC::make_signed(*signer.get(), EAC1_1_gen_CVC::build_cert_body(tbs), rng); std::shared_ptr source(new DataSource_Memory(signed_cert)); return EAC1_1_Req(source); } EAC1_1_ADO create_ado_req(Private_Key const& key, EAC1_1_Req const& req, ASN1_Car const& car, RandomNumberGenerator& rng) { ECDSA_PrivateKey const* priv_key = dynamic_cast(&key); if (priv_key == 0) { throw Invalid_Argument("CVC_EAC::create_self_signed_cert(): unsupported key type"); } std::string padding_and_hash = padding_and_hash_from_oid(req.signature_algorithm().oid); std::unique_ptr signer(get_pk_signer(*priv_key, padding_and_hash)); SecureVector tbs_bits = req.BER_encode(); tbs_bits.append(DER_Encoder().encode(car).get_contents()); MemoryVector signed_cert = EAC1_1_ADO::make_signed(*signer.get(), tbs_bits, rng); std::shared_ptr source(new DataSource_Memory(signed_cert)); return EAC1_1_ADO(source); } } // namespace CVC_EAC namespace DE_EAC { EAC1_1_CVC create_cvca(Private_Key const& key, std::string const& hash, ASN1_Car const& car, bool iris, bool fingerpr, u32bit cvca_validity_months, RandomNumberGenerator& rng) { ECDSA_PrivateKey const* priv_key = dynamic_cast(&key); if (priv_key == 0) { throw Invalid_Argument("CVC_EAC::create_self_signed_cert(): unsupported key type"); } EAC1_1_CVC_Options opts; opts.car = car; const u64bit current_time = system_time(); opts.ced = ASN1_Ced(current_time); opts.cex = ASN1_Cex(opts.ced); opts.cex.add_months(cvca_validity_months); opts.holder_auth_templ = (CVCA | (iris * IRIS) | (fingerpr * FINGERPRINT)); opts.hash_alg = hash; return Botan::CVC_EAC::create_self_signed_cert(*priv_key, opts, rng); } EAC1_1_CVC link_cvca(EAC1_1_CVC const& signer, Private_Key const& key, EAC1_1_CVC const& signee, RandomNumberGenerator& rng) { ECDSA_PrivateKey const* priv_key = dynamic_cast(&key); if (priv_key == 0) { throw Invalid_Argument("CVC_EAC::create_self_signed_cert(): unsupported key type"); } ASN1_Ced ced(system_time()); ASN1_Cex cex(signee.get_cex()); if (*static_cast(&ced) > *static_cast(&cex)) { std::string detail("link_cvca(): validity periods of provided certificates don't overlap: currend time = ced = "); detail += ced.as_string(); detail += ", signee.cex = "; detail += cex.as_string(); throw Invalid_Argument(detail); } if (signer.signature_algorithm() != signee.signature_algorithm()) { throw Invalid_Argument("link_cvca(): signature algorithms of signer and signee donĀ“t match"); } AlgorithmIdentifier sig_algo = signer.signature_algorithm(); std::string padding_and_hash = padding_and_hash_from_oid(sig_algo.oid); std::unique_ptr pk_signer(get_pk_signer(*priv_key, padding_and_hash)); std::unique_ptr pk = signee.subject_public_key(); ECDSA_PublicKey* subj_pk = dynamic_cast(pk.get()); subj_pk->set_parameter_encoding(ENC_EXPLICIT); #if 0 std::unique_ptr enc(subj_pk->cvc_eac1_1_encoder()); MemoryVector enc_public_key = enc->public_key(sig_algo); #else MemoryVector enc_public_key; #endif return EAC1_1_CVC_CA::make_cert(*pk_signer.get(), enc_public_key, signer.get_car(), signee.get_chr(), signer.get_chat_value(), ced, cex, rng); } EAC1_1_CVC sign_request(EAC1_1_CVC const& signer_cert, Private_Key const& key, EAC1_1_Req const& signee, u32bit seqnr, u32bit seqnr_len, bool domestic, u32bit dvca_validity_months, u32bit ca_is_validity_months, RandomNumberGenerator& rng) { ECDSA_PrivateKey const* priv_key = dynamic_cast(&key); if (priv_key == 0) { throw Invalid_Argument("CVC_EAC::create_self_signed_cert(): unsupported key type"); } std::string chr_str = signee.get_chr().value(); chr_str.append(fixed_len_seqnr(seqnr, seqnr_len)); ASN1_Chr chr(chr_str); std::string padding_and_hash = padding_and_hash_from_oid(signee.signature_algorithm().oid); std::unique_ptr pk_signer(get_pk_signer(*priv_key, padding_and_hash)); std::unique_ptr pk = signee.subject_public_key(); ECDSA_PublicKey* subj_pk = dynamic_cast(pk.get()); std::unique_ptr signer_pk = signer_cert.subject_public_key(); // for the case that the domain parameters are not set... // (we use those from the signer because they must fit) subj_pk->set_domain_parameters(priv_key->domain_parameters()); subj_pk->set_parameter_encoding(ENC_IMPLICITCA); #if 0 // FIXME std::unique_ptr enc(subj_pk->cvc_eac1_1_encoder()); MemoryVector enc_public_key = enc->public_key(sig_algo); #else MemoryVector enc_public_key; #endif AlgorithmIdentifier sig_algo(signer_cert.signature_algorithm()); const u64bit current_time = system_time(); ASN1_Ced ced(current_time); u32bit chat_val; u32bit chat_low = signer_cert.get_chat_value() & 0x3; // take the chat rights from signer ASN1_Cex cex(ced); if ((signer_cert.get_chat_value() & CVCA) == CVCA) { // we sign a dvca cex.add_months(dvca_validity_months); if (domestic) { chat_val = DVCA_domestic | chat_low; } else { chat_val = DVCA_foreign | chat_low; } } else if ((signer_cert.get_chat_value() & DVCA_domestic) == DVCA_domestic || (signer_cert.get_chat_value() & DVCA_foreign) == DVCA_foreign) { cex.add_months(ca_is_validity_months); chat_val = IS | chat_low; } else { throw Invalid_Argument("sign_request(): encountered illegal value for CHAT"); // (IS cannot sign certificates) } return EAC1_1_CVC_CA::make_cert(*pk_signer.get(), enc_public_key, ASN1_Car(signer_cert.get_chr().iso_8859()), chr, chat_val, ced, cex, rng); } EAC1_1_Req create_cvc_req(Private_Key const& prkey, ASN1_Chr const& chr, std::string const& hash_alg, RandomNumberGenerator& rng) { ECDSA_PrivateKey const* priv_key = dynamic_cast(&prkey); if (priv_key == 0) { throw Invalid_Argument("CVC_EAC::create_self_signed_cert(): unsupported key type"); } ECDSA_PrivateKey key(*priv_key); key.set_parameter_encoding(ENC_IMPLICITCA); return Botan::CVC_EAC::create_cvc_req(key, chr, hash_alg, rng); } } // namespace DE_EAC }