// eccrypto.h - originally written and placed in the public domain by Wei Dai // deterministic signatures added by by Douglas Roark /// \file eccrypto.h /// \brief Classes and functions for Elliptic Curves over prime and binary fields #ifndef CRYPTOPP_ECCRYPTO_H #define CRYPTOPP_ECCRYPTO_H #include "config.h" #include "cryptlib.h" #include "pubkey.h" #include "integer.h" #include "asn.h" #include "hmac.h" #include "sha.h" #include "gfpcrypt.h" #include "dh.h" #include "mqv.h" #include "hmqv.h" #include "fhmqv.h" #include "ecp.h" #include "ec2n.h" #include #if CRYPTOPP_MSC_VERSION # pragma warning(push) # pragma warning(disable: 4231 4275) #endif NAMESPACE_BEGIN(CryptoPP) /// \brief Elliptic Curve Parameters /// \tparam EC elliptic curve field /// \details This class corresponds to the ASN.1 sequence of the same name /// in ANSI X9.62 and SEC 1. EC is currently defined for ECP and EC2N. template class DL_GroupParameters_EC : public DL_GroupParametersImpl > { typedef DL_GroupParameters_EC ThisClass; public: typedef EC EllipticCurve; typedef typename EllipticCurve::Point Point; typedef Point Element; typedef IncompatibleCofactorMultiplication DefaultCofactorOption; virtual ~DL_GroupParameters_EC() {} /// \brief Construct an EC GroupParameters DL_GroupParameters_EC() : m_compress(false), m_encodeAsOID(true) {} /// \brief Construct an EC GroupParameters /// \param oid the OID of a curve DL_GroupParameters_EC(const OID &oid) : m_compress(false), m_encodeAsOID(true) {Initialize(oid);} /// \brief Construct an EC GroupParameters /// \param ec the elliptic curve /// \param G the base point /// \param n the order of the base point /// \param k the cofactor DL_GroupParameters_EC(const EllipticCurve &ec, const Point &G, const Integer &n, const Integer &k = Integer::Zero()) : m_compress(false), m_encodeAsOID(true) {Initialize(ec, G, n, k);} /// \brief Construct an EC GroupParameters /// \param bt BufferedTransformation with group parameters DL_GroupParameters_EC(BufferedTransformation &bt) : m_compress(false), m_encodeAsOID(true) {BERDecode(bt);} /// \brief Initialize an EC GroupParameters using {EC,G,n,k} /// \param ec the elliptic curve /// \param G the base point /// \param n the order of the base point /// \param k the cofactor /// \details This Initialize() function overload initializes group parameters from existing parameters. void Initialize(const EllipticCurve &ec, const Point &G, const Integer &n, const Integer &k = Integer::Zero()) { this->m_groupPrecomputation.SetCurve(ec); this->SetSubgroupGenerator(G); m_n = n; m_k = k; } /// \brief Initialize a DL_GroupParameters_EC {EC,G,n,k} /// \param oid the OID of a curve /// \details This Initialize() function overload initializes group parameters from existing parameters. void Initialize(const OID &oid); // NameValuePairs bool GetVoidValue(const char *name, const std::type_info &valueType, void *pValue) const; void AssignFrom(const NameValuePairs &source); // GeneratibleCryptoMaterial interface /// this implementation doesn't actually generate a curve, it just initializes the parameters with existing values /*! parameters: (Curve, SubgroupGenerator, SubgroupOrder, Cofactor (optional)), or (GroupOID) */ void GenerateRandom(RandomNumberGenerator &rng, const NameValuePairs &alg); // DL_GroupParameters const DL_FixedBasePrecomputation & GetBasePrecomputation() const {return this->m_gpc;} DL_FixedBasePrecomputation & AccessBasePrecomputation() {return this->m_gpc;} const Integer & GetSubgroupOrder() const {return m_n;} Integer GetCofactor() const; bool ValidateGroup(RandomNumberGenerator &rng, unsigned int level) const; bool ValidateElement(unsigned int level, const Element &element, const DL_FixedBasePrecomputation *precomp) const; bool FastSubgroupCheckAvailable() const {return false;} void EncodeElement(bool reversible, const Element &element, byte *encoded) const { if (reversible) GetCurve().EncodePoint(encoded, element, m_compress); else element.x.Encode(encoded, GetEncodedElementSize(false)); } virtual unsigned int GetEncodedElementSize(bool reversible) const { if (reversible) return GetCurve().EncodedPointSize(m_compress); else return GetCurve().GetField().MaxElementByteLength(); } Element DecodeElement(const byte *encoded, bool checkForGroupMembership) const { Point result; if (!GetCurve().DecodePoint(result, encoded, GetEncodedElementSize(true))) throw DL_BadElement(); if (checkForGroupMembership && !ValidateElement(1, result, NULLPTR)) throw DL_BadElement(); return result; } Integer ConvertElementToInteger(const Element &element) const; Integer GetMaxExponent() const {return GetSubgroupOrder()-1;} bool IsIdentity(const Element &element) const {return element.identity;} void SimultaneousExponentiate(Element *results, const Element &base, const Integer *exponents, unsigned int exponentsCount) const; static std::string CRYPTOPP_API StaticAlgorithmNamePrefix() {return "EC";} // ASN1Key OID GetAlgorithmID() const; // used by MQV Element MultiplyElements(const Element &a, const Element &b) const; Element CascadeExponentiate(const Element &element1, const Integer &exponent1, const Element &element2, const Integer &exponent2) const; // non-inherited // enumerate OIDs for recommended parameters, use OID() to get first one static OID CRYPTOPP_API GetNextRecommendedParametersOID(const OID &oid); void BERDecode(BufferedTransformation &bt); void DEREncode(BufferedTransformation &bt) const; void SetPointCompression(bool compress) {m_compress = compress;} bool GetPointCompression() const {return m_compress;} void SetEncodeAsOID(bool encodeAsOID) {m_encodeAsOID = encodeAsOID;} bool GetEncodeAsOID() const {return m_encodeAsOID;} const EllipticCurve& GetCurve() const {return this->m_groupPrecomputation.GetCurve();} bool operator==(const ThisClass &rhs) const {return this->m_groupPrecomputation.GetCurve() == rhs.m_groupPrecomputation.GetCurve() && this->m_gpc.GetBase(this->m_groupPrecomputation) == rhs.m_gpc.GetBase(rhs.m_groupPrecomputation);} protected: unsigned int FieldElementLength() const {return GetCurve().GetField().MaxElementByteLength();} unsigned int ExponentLength() const {return m_n.ByteCount();} OID m_oid; // set if parameters loaded from a recommended curve Integer m_n; // order of base point mutable Integer m_k; // cofactor mutable bool m_compress, m_encodeAsOID; // presentation details }; inline std::ostream& operator<<(std::ostream& os, const DL_GroupParameters_EC::Element& obj); /// \brief Elliptic Curve Discrete Log (DL) public key /// \tparam EC elliptic curve field template class DL_PublicKey_EC : public DL_PublicKeyImpl > { public: typedef typename EC::Point Element; virtual ~DL_PublicKey_EC() {} /// \brief Initialize an EC Public Key using {GP,Q} /// \param params group parameters /// \param Q the public point /// \details This Initialize() function overload initializes a public key from existing parameters. void Initialize(const DL_GroupParameters_EC ¶ms, const Element &Q) {this->AccessGroupParameters() = params; this->SetPublicElement(Q);} /// \brief Initialize an EC Public Key using {EC,G,n,Q} /// \param ec the elliptic curve /// \param G the base point /// \param n the order of the base point /// \param Q the public point /// \details This Initialize() function overload initializes a public key from existing parameters. void Initialize(const EC &ec, const Element &G, const Integer &n, const Element &Q) {this->AccessGroupParameters().Initialize(ec, G, n); this->SetPublicElement(Q);} // X509PublicKey void BERDecodePublicKey(BufferedTransformation &bt, bool parametersPresent, size_t size); void DEREncodePublicKey(BufferedTransformation &bt) const; }; /// \brief Elliptic Curve Discrete Log (DL) private key /// \tparam EC elliptic curve field template class DL_PrivateKey_EC : public DL_PrivateKeyImpl > { public: typedef typename EC::Point Element; virtual ~DL_PrivateKey_EC(); /// \brief Initialize an EC Private Key using {GP,x} /// \param params group parameters /// \param x the private exponent /// \details This Initialize() function overload initializes a private key from existing parameters. void Initialize(const DL_GroupParameters_EC ¶ms, const Integer &x) {this->AccessGroupParameters() = params; this->SetPrivateExponent(x);} /// \brief Initialize an EC Private Key using {EC,G,n,x} /// \param ec the elliptic curve /// \param G the base point /// \param n the order of the base point /// \param x the private exponent /// \details This Initialize() function overload initializes a private key from existing parameters. void Initialize(const EC &ec, const Element &G, const Integer &n, const Integer &x) {this->AccessGroupParameters().Initialize(ec, G, n); this->SetPrivateExponent(x);} /// \brief Create an EC private key /// \param rng a RandomNumberGenerator derived class /// \param params the EC group parameters /// \details This function overload of Initialize() creates a new private key because it /// takes a RandomNumberGenerator() as a parameter. If you have an existing keypair, /// then use one of the other Initialize() overloads. void Initialize(RandomNumberGenerator &rng, const DL_GroupParameters_EC ¶ms) {this->GenerateRandom(rng, params);} /// \brief Create an EC private key /// \param rng a RandomNumberGenerator derived class /// \param ec the elliptic curve /// \param G the base point /// \param n the order of the base point /// \details This function overload of Initialize() creates a new private key because it /// takes a RandomNumberGenerator() as a parameter. If you have an existing keypair, /// then use one of the other Initialize() overloads. void Initialize(RandomNumberGenerator &rng, const EC &ec, const Element &G, const Integer &n) {this->GenerateRandom(rng, DL_GroupParameters_EC(ec, G, n));} // PKCS8PrivateKey void BERDecodePrivateKey(BufferedTransformation &bt, bool parametersPresent, size_t size); void DEREncodePrivateKey(BufferedTransformation &bt) const; }; // Out-of-line dtor due to AIX and GCC, http://github.com/weidai11/cryptopp/issues/499 template DL_PrivateKey_EC::~DL_PrivateKey_EC() {} /// \brief Elliptic Curve Diffie-Hellman /// \tparam EC elliptic curve field /// \tparam COFACTOR_OPTION cofactor multiplication option /// \sa CofactorMultiplicationOption, Elliptic Curve Diffie-Hellman, AKA ECDH /// \since Crypto++ 3.0 template ::DefaultCofactorOption> struct ECDH { typedef DH_Domain, COFACTOR_OPTION> Domain; }; /// \brief Elliptic Curve Menezes-Qu-Vanstone /// \tparam EC elliptic curve field /// \tparam COFACTOR_OPTION cofactor multiplication option /// \sa CofactorMultiplicationOption, Elliptic Curve Menezes-Qu-Vanstone, AKA ECMQV template ::DefaultCofactorOption> struct ECMQV { typedef MQV_Domain, COFACTOR_OPTION> Domain; }; /// \brief Hashed Elliptic Curve Menezes-Qu-Vanstone /// \tparam EC elliptic curve field /// \tparam COFACTOR_OPTION cofactor multiplication option /// \details This implementation follows Hugo Krawczyk's HMQV: A High-Performance /// Secure Diffie-Hellman Protocol. Note: this implements HMQV only. HMQV-C with Key Confirmation is not provided. /// \sa CofactorMultiplicationOption template ::DefaultCofactorOption, class HASH = SHA256> struct ECHMQV { typedef HMQV_Domain, COFACTOR_OPTION, HASH> Domain; }; typedef ECHMQV< ECP, DL_GroupParameters_EC< ECP >::DefaultCofactorOption, SHA1 >::Domain ECHMQV160; typedef ECHMQV< ECP, DL_GroupParameters_EC< ECP >::DefaultCofactorOption, SHA256 >::Domain ECHMQV256; typedef ECHMQV< ECP, DL_GroupParameters_EC< ECP >::DefaultCofactorOption, SHA384 >::Domain ECHMQV384; typedef ECHMQV< ECP, DL_GroupParameters_EC< ECP >::DefaultCofactorOption, SHA512 >::Domain ECHMQV512; /// \brief Fully Hashed Elliptic Curve Menezes-Qu-Vanstone /// \tparam EC elliptic curve field /// \tparam COFACTOR_OPTION cofactor multiplication option /// \details This implementation follows Augustin P. Sarr and Philippe Elbaz–Vincent, and Jean–Claude Bajard's /// A Secure and Efficient Authenticated Diffie-Hellman Protocol. /// Note: this is FHMQV, Protocol 5, from page 11; and not FHMQV-C. /// \sa CofactorMultiplicationOption template ::DefaultCofactorOption, class HASH = SHA256> struct ECFHMQV { typedef FHMQV_Domain, COFACTOR_OPTION, HASH> Domain; }; typedef ECFHMQV< ECP, DL_GroupParameters_EC< ECP >::DefaultCofactorOption, SHA1 >::Domain ECFHMQV160; typedef ECFHMQV< ECP, DL_GroupParameters_EC< ECP >::DefaultCofactorOption, SHA256 >::Domain ECFHMQV256; typedef ECFHMQV< ECP, DL_GroupParameters_EC< ECP >::DefaultCofactorOption, SHA384 >::Domain ECFHMQV384; typedef ECFHMQV< ECP, DL_GroupParameters_EC< ECP >::DefaultCofactorOption, SHA512 >::Domain ECFHMQV512; /// \brief Elliptic Curve Discrete Log (DL) keys /// \tparam EC elliptic curve field template struct DL_Keys_EC { typedef DL_PublicKey_EC PublicKey; typedef DL_PrivateKey_EC PrivateKey; }; // Forward declaration; documented below template struct ECDSA; /// \brief Elliptic Curve DSA keys /// \tparam EC elliptic curve field /// \since Crypto++ 3.2 template struct DL_Keys_ECDSA { typedef DL_PublicKey_EC PublicKey; typedef DL_PrivateKey_WithSignaturePairwiseConsistencyTest, ECDSA > PrivateKey; }; /// \brief Elliptic Curve DSA (ECDSA) signature algorithm /// \tparam EC elliptic curve field /// \since Crypto++ 3.2 template class DL_Algorithm_ECDSA : public DL_Algorithm_GDSA { public: CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "ECDSA";} }; /// \brief Elliptic Curve DSA (ECDSA) signature algorithm based on RFC 6979 /// \tparam EC elliptic curve field /// \sa RFC 6979, Deterministic Usage of the /// Digital Signature Algorithm (DSA) and Elliptic Curve Digital Signature Algorithm (ECDSA) /// \since Crypto++ 6.0 template class DL_Algorithm_ECDSA_RFC6979 : public DL_Algorithm_DSA_RFC6979 { public: CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "ECDSA-RFC6979";} }; /// \brief Elliptic Curve NR (ECNR) signature algorithm /// \tparam EC elliptic curve field template class DL_Algorithm_ECNR : public DL_Algorithm_NR { public: CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "ECNR";} }; /// \brief Elliptic Curve DSA (ECDSA) signature scheme /// \tparam EC elliptic curve field /// \tparam H HashTransformation derived class /// \sa ECDSA /// \since Crypto++ 3.2 template struct ECDSA : public DL_SS, DL_Algorithm_ECDSA, DL_SignatureMessageEncodingMethod_DSA, H> { }; /// \brief Elliptic Curve DSA (ECDSA) deterministic signature scheme /// \tparam EC elliptic curve field /// \tparam H HashTransformation derived class /// \sa Deterministic Usage of the /// Digital Signature Algorithm (DSA) and Elliptic Curve Digital Signature Algorithm (ECDSA) /// \since Crypto++ 6.0 template struct ECDSA_RFC6979 : public DL_SS< DL_Keys_ECDSA, DL_Algorithm_ECDSA_RFC6979, DL_SignatureMessageEncodingMethod_DSA, H, ECDSA_RFC6979 > { static std::string CRYPTOPP_API StaticAlgorithmName() {return std::string("ECDSA-RFC6979/") + H::StaticAlgorithmName();} }; /// \brief Elliptic Curve NR (ECNR) signature scheme /// \tparam EC elliptic curve field /// \tparam H HashTransformation derived class template struct ECNR : public DL_SS, DL_Algorithm_ECNR, DL_SignatureMessageEncodingMethod_NR, H> { }; // ****************************************** template class DL_PublicKey_ECGDSA; template class DL_PrivateKey_ECGDSA; /// \brief Elliptic Curve German DSA key for ISO/IEC 15946 /// \tparam EC elliptic curve field /// \sa ECGDSA /// \since Crypto++ 6.0 template class DL_PrivateKey_ECGDSA : public DL_PrivateKeyImpl > { public: typedef typename EC::Point Element; virtual ~DL_PrivateKey_ECGDSA() {} /// \brief Initialize an EC Private Key using {GP,x} /// \param params group parameters /// \param x the private exponent /// \details This Initialize() function overload initializes a private key from existing parameters. void Initialize(const DL_GroupParameters_EC ¶ms, const Integer &x) { this->AccessGroupParameters() = params; this->SetPrivateExponent(x); CRYPTOPP_ASSERT(x>=1 && x<=params.GetSubgroupOrder()-1); } /// \brief Initialize an EC Private Key using {EC,G,n,x} /// \param ec the elliptic curve /// \param G the base point /// \param n the order of the base point /// \param x the private exponent /// \details This Initialize() function overload initializes a private key from existing parameters. void Initialize(const EC &ec, const Element &G, const Integer &n, const Integer &x) { this->AccessGroupParameters().Initialize(ec, G, n); this->SetPrivateExponent(x); CRYPTOPP_ASSERT(x>=1 && x<=this->AccessGroupParameters().GetSubgroupOrder()-1); } /// \brief Create an EC private key /// \param rng a RandomNumberGenerator derived class /// \param params the EC group parameters /// \details This function overload of Initialize() creates a new private key because it /// takes a RandomNumberGenerator() as a parameter. If you have an existing keypair, /// then use one of the other Initialize() overloads. void Initialize(RandomNumberGenerator &rng, const DL_GroupParameters_EC ¶ms) {this->GenerateRandom(rng, params);} /// \brief Create an EC private key /// \param rng a RandomNumberGenerator derived class /// \param ec the elliptic curve /// \param G the base point /// \param n the order of the base point /// \details This function overload of Initialize() creates a new private key because it /// takes a RandomNumberGenerator() as a parameter. If you have an existing keypair, /// then use one of the other Initialize() overloads. void Initialize(RandomNumberGenerator &rng, const EC &ec, const Element &G, const Integer &n) {this->GenerateRandom(rng, DL_GroupParameters_EC(ec, G, n));} virtual void MakePublicKey(DL_PublicKey_ECGDSA &pub) const { const DL_GroupParameters& params = this->GetAbstractGroupParameters(); pub.AccessAbstractGroupParameters().AssignFrom(params); const Integer &xInv = this->GetPrivateExponent().InverseMod(params.GetSubgroupOrder()); pub.SetPublicElement(params.ExponentiateBase(xInv)); CRYPTOPP_ASSERT(xInv.NotZero()); } virtual bool GetVoidValue(const char *name, const std::type_info &valueType, void *pValue) const { return GetValueHelper, DL_PrivateKey_ECGDSA >(this, name, valueType, pValue).Assignable(); } virtual void AssignFrom(const NameValuePairs &source) { AssignFromHelper, DL_PrivateKey_ECGDSA >(this, source); } // PKCS8PrivateKey void BERDecodePrivateKey(BufferedTransformation &bt, bool parametersPresent, size_t size); void DEREncodePrivateKey(BufferedTransformation &bt) const; }; /// \brief Elliptic Curve German DSA key for ISO/IEC 15946 /// \tparam EC elliptic curve field /// \sa ECGDSA /// \since Crypto++ 6.0 template class DL_PublicKey_ECGDSA : public DL_PublicKeyImpl > { typedef DL_PublicKey_ECGDSA ThisClass; public: typedef typename EC::Point Element; virtual ~DL_PublicKey_ECGDSA() {} /// \brief Initialize an EC Public Key using {GP,Q} /// \param params group parameters /// \param Q the public point /// \details This Initialize() function overload initializes a public key from existing parameters. void Initialize(const DL_GroupParameters_EC ¶ms, const Element &Q) {this->AccessGroupParameters() = params; this->SetPublicElement(Q);} /// \brief Initialize an EC Public Key using {EC,G,n,Q} /// \param ec the elliptic curve /// \param G the base point /// \param n the order of the base point /// \param Q the public point /// \details This Initialize() function overload initializes a public key from existing parameters. void Initialize(const EC &ec, const Element &G, const Integer &n, const Element &Q) {this->AccessGroupParameters().Initialize(ec, G, n); this->SetPublicElement(Q);} virtual void AssignFrom(const NameValuePairs &source) { DL_PrivateKey_ECGDSA *pPrivateKey = NULLPTR; if (source.GetThisPointer(pPrivateKey)) pPrivateKey->MakePublicKey(*this); else { this->AccessAbstractGroupParameters().AssignFrom(source); AssignFromHelper(this, source) CRYPTOPP_SET_FUNCTION_ENTRY(PublicElement); } } // DL_PublicKey virtual void SetPublicElement(const Element &y) {this->AccessPublicPrecomputation().SetBase(this->GetAbstractGroupParameters().GetGroupPrecomputation(), y);} // X509PublicKey void BERDecodePublicKey(BufferedTransformation &bt, bool parametersPresent, size_t size); void DEREncodePublicKey(BufferedTransformation &bt) const; }; /// \brief Elliptic Curve German DSA keys for ISO/IEC 15946 /// \tparam EC elliptic curve field /// \sa ECGDSA /// \since Crypto++ 6.0 template struct DL_Keys_ECGDSA { typedef DL_PublicKey_ECGDSA PublicKey; typedef DL_PrivateKey_ECGDSA PrivateKey; }; /// \brief Elliptic Curve German DSA signature algorithm /// \tparam EC elliptic curve field /// \sa ECGDSA /// \since Crypto++ 6.0 template class DL_Algorithm_ECGDSA : public DL_Algorithm_GDSA_ISO15946 { public: CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "ECGDSA";} }; /// \brief Elliptic Curve German Digital Signature Algorithm signature scheme /// \tparam EC elliptic curve field /// \tparam H HashTransformation derived class /// \sa Erwin Hess, Marcus Schafheutle, and Pascale Serf The Digital Signature Scheme /// ECGDSA (October 24, 2006) /// \since Crypto++ 6.0 template struct ECGDSA : public DL_SS< DL_Keys_ECGDSA, DL_Algorithm_ECGDSA, DL_SignatureMessageEncodingMethod_DSA, H> { static std::string CRYPTOPP_API StaticAlgorithmName() {return std::string("ECGDSA-ISO15946/") + H::StaticAlgorithmName();} }; // ****************************************** /// \brief Elliptic Curve Integrated Encryption Scheme /// \tparam COFACTOR_OPTION cofactor multiplication option /// \tparam HASH HashTransformation derived class used for key derivation and MAC computation /// \tparam DHAES_MODE flag indicating if the MAC includes additional context parameters such as u·V, v·U and label /// \tparam LABEL_OCTETS flag indicating if the label size is specified in octets or bits /// \details ECIES is an Elliptic Curve based Integrated Encryption Scheme (IES). The scheme combines a Key Encapsulation /// Method (KEM) with a Data Encapsulation Method (DEM) and a MAC tag. The scheme is /// IND-CCA2, which is a strong notion of security. /// You should prefer an Integrated Encryption Scheme over homegrown schemes. /// \details If you desire an Integrated Encryption Scheme with Crypto++ 4.2 compatibility, then use the ECIES_P1363. /// If you desire an Integrated Encryption Scheme compatible with Bouncy Castle 1.54 and Botan 1.11 compatibility, then use the ECIES /// template class with NoCofactorMultiplication, DHAES_MODE=true and LABEL_OCTETS=false. /// \details The default template parameters ensure compatibility with Bouncy Castle 1.54 and Botan 1.11. The combination of /// IncompatibleCofactorMultiplication and DHAES_MODE=true is recommended for best efficiency and security. /// SHA1 is used for compatibility reasons, but it can be changed if desired. /// \sa DLIES, ECIES_P1363, Elliptic Curve Integrated Encryption Scheme (ECIES), /// Martínez, Encinas, and Ávila's A Survey of the Elliptic /// Curve Integrated Encryption Schemes /// \since Crypto++ 4.0, Crypto++ 5.7 for Bouncy Castle and Botan compatibility template struct ECIES : public DL_ES< DL_Keys_EC, DL_KeyAgreementAlgorithm_DH, DL_KeyDerivationAlgorithm_P1363 >, DL_EncryptionAlgorithm_Xor, DHAES_MODE, LABEL_OCTETS>, ECIES > { // TODO: fix this after name is standardized CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "ECIES";} }; /// \brief Elliptic Curve Integrated Encryption Scheme for P1363 /// \tparam COFACTOR_OPTION cofactor multiplication option /// \tparam HASH HashTransformation derived class used for key derivation and MAC computation /// \details ECIES_P1363 is an Elliptic Curve based Integrated Encryption Scheme (IES) for P1363. The scheme combines a Key Encapsulation /// Method (KEM) with a Data Encapsulation Method (DEM) and a MAC tag. The scheme is /// IND-CCA2, which is a strong notion of security. /// You should prefer an Integrated Encryption Scheme over homegrown schemes. /// \details The library's original implementation is based on an early P1363 draft, which itself appears to be based on an early Certicom /// SEC-1 draft (or an early SEC-1 draft was based on a P1363 draft). Crypto++ 4.2 used the early draft in its Integrated Enryption /// Schemes with NoCofactorMultiplication, DHAES_MODE=false and LABEL_OCTETS=true. /// \details If you desire an Integrated Encryption Scheme with Crypto++ 4.2 compatibility, then use the ECIES_P1363. /// If you desire an Integrated Encryption Scheme compatible with Bouncy Castle 1.54 and Botan 1.11 compatibility, then use the ECIES /// template class with NoCofactorMultiplication, DHAES_MODE=true and LABEL_OCTETS=false. /// \details The default template parameters ensure compatibility with P1363. The combination of /// IncompatibleCofactorMultiplication and DHAES_MODE=true is recommended for best efficiency and security. /// SHA1 is used for compatibility reasons, but it can be changed if desired. /// \sa DLIES, ECIES, Elliptic Curve Integrated Encryption Scheme (ECIES), /// Martínez, Encinas, and Ávila's A Survey of the Elliptic /// Curve Integrated Encryption Schemes /// \since Crypto++ 4.0 template struct ECIES_P1363 : public DL_ES< DL_Keys_EC, DL_KeyAgreementAlgorithm_DH, DL_KeyDerivationAlgorithm_P1363 >, DL_EncryptionAlgorithm_Xor, false, true>, ECIES > { // TODO: fix this after name is standardized CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "ECIES-P1363";} }; NAMESPACE_END #ifdef CRYPTOPP_MANUALLY_INSTANTIATE_TEMPLATES #include "eccrypto.cpp" #endif NAMESPACE_BEGIN(CryptoPP) CRYPTOPP_DLL_TEMPLATE_CLASS DL_GroupParameters_EC; CRYPTOPP_DLL_TEMPLATE_CLASS DL_GroupParameters_EC; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PublicKeyImpl >; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PublicKeyImpl >; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PublicKey_EC; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PublicKey_EC; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PublicKey_ECGDSA; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PublicKey_ECGDSA; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PrivateKeyImpl >; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PrivateKeyImpl >; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PrivateKey_EC; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PrivateKey_EC; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PrivateKey_ECGDSA; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PrivateKey_ECGDSA; CRYPTOPP_DLL_TEMPLATE_CLASS DL_Algorithm_GDSA; CRYPTOPP_DLL_TEMPLATE_CLASS DL_Algorithm_GDSA; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PrivateKey_WithSignaturePairwiseConsistencyTest, ECDSA >; CRYPTOPP_DLL_TEMPLATE_CLASS DL_PrivateKey_WithSignaturePairwiseConsistencyTest, ECDSA >; NAMESPACE_END #if CRYPTOPP_MSC_VERSION # pragma warning(pop) #endif #endif