/* * PKCS#11 Mechanism * (C) 2016 Daniel Neus, Sirrix AG * (C) 2016 Philipp Weber, Sirrix AG * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include #include #include namespace Botan { namespace PKCS11 { namespace { using PSS_Params = std::tuple; // maps a PSS mechanism type to the number of bytes used for the salt, the mechanism type of the underlying hash algorithm and the MGF static const std::map PssOptions = { { MechanismType::RsaPkcsPss, PSS_Params(0, MechanismType::Sha1, MGF::Mgf1Sha1) }, { MechanismType::Sha1RsaPkcsPss, PSS_Params(20, MechanismType::Sha1, MGF::Mgf1Sha1) }, { MechanismType::Sha224RsaPkcsPss, PSS_Params(28, MechanismType::Sha224, MGF::Mgf1Sha224) }, { MechanismType::Sha256RsaPkcsPss, PSS_Params(32, MechanismType::Sha256, MGF::Mgf1Sha256) }, { MechanismType::Sha384RsaPkcsPss, PSS_Params(48, MechanismType::Sha384, MGF::Mgf1Sha384) }, { MechanismType::Sha512RsaPkcsPss, PSS_Params(64, MechanismType::Sha512, MGF::Mgf1Sha512) } }; struct MechanismData { explicit MechanismData(MechanismType _type) : type(_type) {} MechanismData(MechanismData const&) = default; MechanismData& operator=(MechanismData const&) = default; virtual ~MechanismData() = default; // the mechanism to perform MechanismType type; }; struct RSA_SignMechanism : public MechanismData { explicit RSA_SignMechanism(MechanismType _type) : MechanismData(_type), hash(static_cast(0)), mgf(static_cast(0)), salt_size(0) { auto pss_option = PssOptions.find(type); if(pss_option != PssOptions.end()) { hash = std::get<1>(pss_option->second); mgf = std::get<2>(pss_option->second); salt_size = std::get<0>(pss_option->second); } } // hash algorithm used in the PSS encoding; if the signature mechanism does not include message hashing, // then this value must be the mechanism used by the application to generate the message hash; // if the signature mechanism includes hashing, then this value must match the hash algorithm indicated by the signature mechanism MechanismType hash; // mask generation function to use on the encoded block MGF mgf; // length, in bytes, of the salt value used in the PSS encoding; typical values are the length of the message hash and zero size_t salt_size; }; // note: when updating this map, update the documentation for `MechanismWrapper::create_rsa_sign_mechanism` static std::map SignMechanisms = { { "Raw", RSA_SignMechanism(MechanismType::RsaX509) }, { "EMSA2(Raw)", RSA_SignMechanism(MechanismType::RsaX931) }, { "EMSA2(SHA-1)", RSA_SignMechanism(MechanismType::Sha1RsaX931) }, // RSASSA PKCS#1 v1.5 { "EMSA3(Raw)", RSA_SignMechanism(MechanismType::RsaPkcs) }, { "EMSA3(SHA-1)", RSA_SignMechanism(MechanismType::Sha1RsaPkcs) }, { "EMSA3(SHA-224)", RSA_SignMechanism(MechanismType::Sha224RsaPkcs) }, { "EMSA3(SHA-256)", RSA_SignMechanism(MechanismType::Sha256RsaPkcs) }, { "EMSA3(SHA-384)", RSA_SignMechanism(MechanismType::Sha384RsaPkcs) }, { "EMSA3(SHA-512)", RSA_SignMechanism(MechanismType::Sha512RsaPkcs) }, // RSASSA PKCS#1 PSS { "EMSA4(Raw)", RSA_SignMechanism(MechanismType::RsaPkcsPss) }, { "EMSA4(SHA-1)", RSA_SignMechanism(MechanismType::Sha1RsaPkcsPss) }, { "EMSA4(SHA-224)", RSA_SignMechanism(MechanismType::Sha224RsaPkcsPss) }, { "EMSA4(SHA-256)", RSA_SignMechanism(MechanismType::Sha256RsaPkcsPss) }, { "EMSA4(SHA-384)", RSA_SignMechanism(MechanismType::Sha384RsaPkcsPss) }, { "EMSA4(SHA-512)", RSA_SignMechanism(MechanismType::Sha512RsaPkcsPss) }, { "ISO9796", RSA_SignMechanism(MechanismType::Rsa9796) } }; struct RSA_CryptMechanism : public MechanismData { RSA_CryptMechanism(MechanismType _type, size_t _padding_size, MechanismType _hash, MGF _mgf) : MechanismData(_type), hash(_hash), mgf(_mgf), padding_size(_padding_size) {} RSA_CryptMechanism(MechanismType _type, size_t _padding_size) : RSA_CryptMechanism(_type, _padding_size, static_cast(0), static_cast(0)) {} // mechanism ID of the message digest algorithm used to calculate the digest of the encoding parameter MechanismType hash; // mask generation function to use on the encoded block MGF mgf; // number of bytes required for the padding size_t padding_size; }; // note: when updating this map, update the documentation for `MechanismWrapper::create_rsa_crypt_mechanism` static const std::map CryptMechanisms = { { "Raw", RSA_CryptMechanism(MechanismType::RsaX509, 0) }, { "EME-PKCS1-v1_5", RSA_CryptMechanism(MechanismType::RsaPkcs, 11) }, { "OAEP(SHA-1)", RSA_CryptMechanism(MechanismType::RsaPkcsOaep, 2 + 2 * 20, MechanismType::Sha1, MGF::Mgf1Sha1) }, { "OAEP(SHA-224)", RSA_CryptMechanism(MechanismType::RsaPkcsOaep, 2 + 2 * 28, MechanismType::Sha224, MGF::Mgf1Sha224) }, { "OAEP(SHA-256)", RSA_CryptMechanism(MechanismType::RsaPkcsOaep, 2 + 2 * 32, MechanismType::Sha256, MGF::Mgf1Sha256) }, { "OAEP(SHA-384)", RSA_CryptMechanism(MechanismType::RsaPkcsOaep, 2 + 2 * 48, MechanismType::Sha384, MGF::Mgf1Sha384) }, { "OAEP(SHA-512)", RSA_CryptMechanism(MechanismType::RsaPkcsOaep, 2 + 2 * 64, MechanismType::Sha512, MGF::Mgf1Sha512) } }; // note: when updating this map, update the documentation for `MechanismWrapper::create_ecdsa_mechanism` static std::map EcdsaHash = { { "Raw", MechanismType::Ecdsa }, { "SHA-160", MechanismType::EcdsaSha1 }, { "SHA-224", MechanismType::EcdsaSha224 }, { "SHA-256", MechanismType::EcdsaSha256 }, { "SHA-384", MechanismType::EcdsaSha384 }, { "SHA-512", MechanismType::EcdsaSha512 } }; // note: when updating this map, update the documentation for `MechanismWrapper::create_ecdh_mechanism` static std::map EcdhHash = { { "Raw", KeyDerivation::Null }, { "SHA-160", KeyDerivation::Sha1Kdf }, { "SHA-224", KeyDerivation::Sha224Kdf }, { "SHA-256", KeyDerivation::Sha256Kdf }, { "SHA-384", KeyDerivation::Sha384Kdf }, { "SHA-512", KeyDerivation::Sha512Kdf } }; } MechanismWrapper::MechanismWrapper(MechanismType mechanism_type) : m_mechanism( { static_cast(mechanism_type), nullptr, 0 }), m_parameters(nullptr) {} MechanismWrapper MechanismWrapper::create_rsa_crypt_mechanism(const std::string& padding) { auto mechanism_info_it = CryptMechanisms.find(padding); if(mechanism_info_it == CryptMechanisms.end()) { // at this point it would be possible to support additional configurations that are not predefined above by parsing `padding` throw Lookup_Error("PKCS#11 RSA encrypt/decrypt does not support EME " + padding); } RSA_CryptMechanism mechanism_info = mechanism_info_it->second; MechanismWrapper mech(mechanism_info.type); if(mechanism_info.type == MechanismType::RsaPkcsOaep) { mech.m_parameters = std::make_shared(); mech.m_parameters->oaep_params.hashAlg = static_cast(mechanism_info.hash); mech.m_parameters->oaep_params.mgf = static_cast(mechanism_info.mgf); mech.m_parameters->oaep_params.source = CKZ_DATA_SPECIFIED; mech.m_parameters->oaep_params.pSourceData = nullptr; mech.m_parameters->oaep_params.ulSourceDataLen = 0; mech.m_mechanism.pParameter = mech.m_parameters.get(); mech.m_mechanism.ulParameterLen = sizeof(RsaPkcsOaepParams); } mech.m_padding_size = mechanism_info.padding_size; return mech; } MechanismWrapper MechanismWrapper::create_rsa_sign_mechanism(const std::string& padding) { auto mechanism_info_it = SignMechanisms.find(padding); if(mechanism_info_it == SignMechanisms.end()) { // at this point it would be possible to support additional configurations that are not predefined above by parsing `padding` throw Lookup_Error("PKCS#11 RSA sign/verify does not support EMSA " + padding); } RSA_SignMechanism mechanism_info = mechanism_info_it->second; MechanismWrapper mech(mechanism_info.type); if(PssOptions.find(mechanism_info.type) != PssOptions.end()) { mech.m_parameters = std::make_shared(); mech.m_parameters->pss_params.hashAlg = static_cast(mechanism_info.hash); mech.m_parameters->pss_params.mgf = static_cast(mechanism_info.mgf); mech.m_parameters->pss_params.sLen = mechanism_info.salt_size; mech.m_mechanism.pParameter = mech.m_parameters.get(); mech.m_mechanism.ulParameterLen = sizeof(RsaPkcsPssParams); } return mech; } MechanismWrapper MechanismWrapper::create_ecdsa_mechanism(const std::string& hash) { std::string hash_name = hash; if(hash_name != "Raw") { hash_name = hash_for_emsa(hash); } auto mechanism_type = EcdsaHash.find(hash_name); if(mechanism_type == EcdsaHash.end()) { throw Lookup_Error("PKCS#11 ECDSA sign/verify does not support " + hash); } return MechanismWrapper(mechanism_type->second); } MechanismWrapper MechanismWrapper::create_ecdh_mechanism(const std::string& params) { std::vector param_parts = split_on(params, ','); if(param_parts.empty() || param_parts.size() > 2) throw Invalid_Argument("PKCS #11 ECDH key derivation bad params " + params); const bool use_cofactor = (param_parts[0] == "Cofactor") || (param_parts.size() == 2 && param_parts[1] == "Cofactor"); std::string kdf_name = (param_parts[0] == "Cofactor" ? param_parts[1] : param_parts[0]); std::string hash = kdf_name; if(kdf_name != "Raw") { SCAN_Name kdf_hash(kdf_name); if(kdf_hash.arg_count() > 0) { hash = kdf_hash.arg(0); } } auto kdf = EcdhHash.find(hash); if(kdf == EcdhHash.end()) { throw Lookup_Error("PKCS#11 ECDH key derivation does not support KDF " + kdf_name); } MechanismWrapper mech(use_cofactor ? MechanismType::Ecdh1CofactorDerive : MechanismType::Ecdh1Derive); mech.m_parameters = std::make_shared(); mech.m_parameters->ecdh_params.kdf = static_cast(kdf->second); mech.m_mechanism.pParameter = mech.m_parameters.get(); mech.m_mechanism.ulParameterLen = sizeof(Ecdh1DeriveParams); return mech; } } }