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808 lines
36 KiB
C++
808 lines
36 KiB
C++
// xed25519.h - written and placed in public domain by Jeffrey Walton
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// Crypto++ specific implementation wrapped around Andrew
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// Moon's public domain curve25519-donna and ed25519-donna,
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// http://github.com/floodyberry/curve25519-donna and
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// http://github.com/floodyberry/ed25519-donna.
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// Typically the key agreement classes encapsulate their data more
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// than x25519 does below. They are a little more accessible
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// due to crypto_box operations.
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/// \file xed25519.h
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/// \brief Classes for x25519 and ed25519 operations
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/// \details This implementation integrates Andrew Moon's public domain code
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/// for curve25519-donna and ed25519-donna.
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/// \details Moving keys into and out of the library proceeds as follows.
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/// If an Integer class is accepted or returned, then the data is in big
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/// endian format. That is, the MSB is at byte position 0, and the LSB
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/// is at byte position 31. The Integer will work as expected, just like
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/// an int or a long.
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/// \details If a byte array is accepted, then the byte array is in little
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/// endian format. That is, the LSB is at byte position 0, and the MSB is
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/// at byte position 31. This follows the implementation where byte 0 is
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/// clamed with 248. That is my_arr[0] &= 248 to mask the lower 3 bits.
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/// \details PKCS8 and X509 keys encoded using ASN.1 follow little endian
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/// arrays. The format is specified in <A HREF=
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/// "http:///tools.ietf.org/html/draft-ietf-curdle-pkix">draft-ietf-curdle-pkix</A>.
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/// \details If you have a little endian array and you want to wrap it in
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/// an Integer using big endian then you can perform the following:
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/// <pre>Integer x(my_arr, SECRET_KEYLENGTH, UNSIGNED, LITTLE_ENDIAN_ORDER);</pre>
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/// \sa Andrew Moon's x22519 GitHub <A
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/// HREF="http://github.com/floodyberry/curve25519-donna">curve25519-donna</A>,
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/// ed22519 GitHub <A
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/// HREF="http://github.com/floodyberry/ed25519-donna">ed25519-donna</A>, and
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/// <A HREF="http:///tools.ietf.org/html/draft-ietf-curdle-pkix">draft-ietf-curdle-pkix</A>
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/// \since Crypto++ 8.0
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#ifndef CRYPTOPP_XED25519_H
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#define CRYPTOPP_XED25519_H
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#include "cryptlib.h"
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#include "pubkey.h"
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#include "oids.h"
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NAMESPACE_BEGIN(CryptoPP)
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class Integer;
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struct ed25519Signer;
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struct ed25519Verifier;
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// ******************** x25519 Agreement ************************* //
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/// \brief x25519 with key validation
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/// \since Crypto++ 8.0
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class x25519 : public SimpleKeyAgreementDomain, public CryptoParameters, public PKCS8PrivateKey
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{
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public:
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/// \brief Size of the private key
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/// \details SECRET_KEYLENGTH is the size of the private key, in bytes.
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CRYPTOPP_CONSTANT(SECRET_KEYLENGTH = 32)
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/// \brief Size of the public key
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/// \details PUBLIC_KEYLENGTH is the size of the public key, in bytes.
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CRYPTOPP_CONSTANT(PUBLIC_KEYLENGTH = 32)
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/// \brief Size of the shared key
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/// \details SHARED_KEYLENGTH is the size of the shared key, in bytes.
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CRYPTOPP_CONSTANT(SHARED_KEYLENGTH = 32)
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virtual ~x25519() {}
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/// \brief Create a x25519 object
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/// \details This constructor creates an empty x25519 object. It is
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/// intended for use in loading existing parameters, like CryptoBox
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/// parameters. If you are perfoming key agreement you should use a
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/// constructor that generates random parameters on construction.
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x25519() {}
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/// \brief Create a x25519 object
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/// \param y public key
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/// \param x private key
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/// \details This constructor creates a x25519 object using existing parameters.
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/// \note The public key is not validated.
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x25519(const byte y[PUBLIC_KEYLENGTH], const byte x[SECRET_KEYLENGTH]);
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/// \brief Create a x25519 object
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/// \param x private key
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/// \details This constructor creates a x25519 object using existing parameters.
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/// The public key is calculated from the private key.
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x25519(const byte x[SECRET_KEYLENGTH]);
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/// \brief Create a x25519 object
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/// \param y public key
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/// \param x private key
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/// \details This constructor creates a x25519 object using existing parameters.
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/// \note The public key is not validated.
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x25519(const Integer &y, const Integer &x);
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/// \brief Create a x25519 object
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/// \param x private key
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/// \details This constructor creates a x25519 object using existing parameters.
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/// The public key is calculated from the private key.
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x25519(const Integer &x);
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/// \brief Create a x25519 object
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/// \param rng RandomNumberGenerator derived class
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/// \details This constructor creates a new x25519 using the random number generator.
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x25519(RandomNumberGenerator &rng);
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/// \brief Create a x25519 object
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/// \param params public and private key
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/// \details This constructor creates a x25519 object using existing parameters.
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/// The <tt>params</tt> can be created with <tt>Save</tt>.
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/// \note The public key is not validated.
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x25519(BufferedTransformation ¶ms);
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/// \brief Create a x25519 object
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/// \param oid an object identifier
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/// \details This constructor creates a new x25519 using the specified OID. The public
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/// and private points are uninitialized.
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x25519(const OID &oid);
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/// \brief Clamp a private key
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/// \param x private key
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/// \details ClampKeys() clamps a private key and then regenerates the
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/// public key from the private key.
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void ClampKey(byte x[SECRET_KEYLENGTH]) const;
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/// \brief Determine if private key is clamped
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/// \param x private key
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bool IsClamped(const byte x[SECRET_KEYLENGTH]) const;
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/// \brief Test if a key has small order
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/// \param y public key
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bool IsSmallOrder(const byte y[PUBLIC_KEYLENGTH]) const;
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/// \brief Get the Object Identifier
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/// \returns the Object Identifier
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/// \details The default OID is from RFC 8410 using <tt>id-X25519</tt>.
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/// The default private key format is RFC 5208.
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OID GetAlgorithmID() const {
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return m_oid.Empty() ? ASN1::X25519() : m_oid;
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}
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/// \brief Set the Object Identifier
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/// \param oid the new Object Identifier
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void SetAlgorithmID(const OID& oid) {
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m_oid = oid;
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}
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// CryptoParameters
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bool Validate(RandomNumberGenerator &rng, unsigned int level) const;
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bool GetVoidValue(const char *name, const std::type_info &valueType, void *pValue) const;
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void AssignFrom(const NameValuePairs &source);
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// CryptoParameters
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CryptoParameters & AccessCryptoParameters() {return *this;}
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/// \brief DER encode ASN.1 object
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/// \param bt BufferedTransformation object
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/// \details Save() will write the OID associated with algorithm or scheme.
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/// In the case of public and private keys, this function writes the
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/// subjectPubicKeyInfo parts.
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/// \details The default OID is from RFC 8410 using <tt>id-X25519</tt>.
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/// The default private key format is RFC 5208, which is the old format.
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/// The old format provides the best interop, and keys will work
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/// with OpenSSL.
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/// \sa <A HREF="http://tools.ietf.org/rfc/rfc5958.txt">RFC 5958, Asymmetric
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/// Key Packages</A>
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void Save(BufferedTransformation &bt) const {
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DEREncode(bt, 0);
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}
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/// \brief DER encode ASN.1 object
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/// \param bt BufferedTransformation object
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/// \param v1 flag indicating v1
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/// \details Save() will write the OID associated with algorithm or scheme.
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/// In the case of public and private keys, this function writes the
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/// subjectPubicKeyInfo parts.
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/// \details The default OID is from RFC 8410 using <tt>id-X25519</tt>.
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/// The default private key format is RFC 5208.
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/// \details v1 means INTEGER 0 is written. INTEGER 0 means
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/// RFC 5208 format, which is the old format. The old format provides
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/// the best interop, and keys will work with OpenSSL. The other
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/// option uses INTEGER 1. INTEGER 1 means RFC 5958 format,
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/// which is the new format.
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/// \sa <A HREF="http://tools.ietf.org/rfc/rfc5958.txt">RFC 5958, Asymmetric
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/// Key Packages</A>
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void Save(BufferedTransformation &bt, bool v1) const {
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DEREncode(bt, v1 ? 0 : 1);
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}
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/// \brief BER decode ASN.1 object
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/// \param bt BufferedTransformation object
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/// \sa <A HREF="http://tools.ietf.org/rfc/rfc5958.txt">RFC 5958, Asymmetric
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/// Key Packages</A>
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void Load(BufferedTransformation &bt) {
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BERDecode(bt);
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}
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// PKCS8PrivateKey
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void BERDecode(BufferedTransformation &bt);
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void DEREncode(BufferedTransformation &bt) const { DEREncode(bt, 0); }
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void BERDecodePrivateKey(BufferedTransformation &bt, bool parametersPresent, size_t size);
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void DEREncodePrivateKey(BufferedTransformation &bt) const;
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/// \brief DER encode ASN.1 object
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/// \param bt BufferedTransformation object
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/// \param version indicates version
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/// \details DEREncode() will write the OID associated with algorithm or
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/// scheme. In the case of public and private keys, this function writes
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/// the subjectPubicKeyInfo parts.
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/// \details The default OID is from RFC 8410 using <tt>id-X25519</tt>.
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/// The default private key format is RFC 5208.
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/// \details The value of version is written as the INTEGER. INTEGER 0 means
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/// RFC 5208 format, which is the old format. The old format provides
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/// the best interop, and keys will work with OpenSSL. The INTEGER 1
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/// means RFC 5958 format, which is the new format.
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void DEREncode(BufferedTransformation &bt, int version) const;
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/// \brief Determine if OID is valid for this object
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/// \details BERDecodeAndCheckAlgorithmID() parses the OID from
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/// <tt>bt</tt> and determines if it valid for this object. The
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/// problem in practice is there are multiple OIDs available to
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/// denote curve25519 operations. The OIDs include an old GNU
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/// OID used by SSH, OIDs specified in draft-josefsson-pkix-newcurves,
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/// and OIDs specified in draft-ietf-curdle-pkix.
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/// \details By default BERDecodeAndCheckAlgorithmID() accepts an
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/// OID set by the user, <tt>ASN1::curve25519()</tt> and <tt>ASN1::X25519()</tt>.
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/// <tt>ASN1::curve25519()</tt> is generic and says "this key is valid for
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/// curve25519 operations". <tt>ASN1::X25519()</tt> is specific and says
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/// "this key is valid for x25519 key exchange."
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void BERDecodeAndCheckAlgorithmID(BufferedTransformation& bt);
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// DL_PrivateKey
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void GenerateRandom(RandomNumberGenerator &rng, const NameValuePairs ¶ms);
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// SimpleKeyAgreementDomain
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unsigned int AgreedValueLength() const {return SHARED_KEYLENGTH;}
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unsigned int PrivateKeyLength() const {return SECRET_KEYLENGTH;}
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unsigned int PublicKeyLength() const {return PUBLIC_KEYLENGTH;}
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// SimpleKeyAgreementDomain
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void GeneratePrivateKey(RandomNumberGenerator &rng, byte *privateKey) const;
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void GeneratePublicKey(RandomNumberGenerator &rng, const byte *privateKey, byte *publicKey) const;
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bool Agree(byte *agreedValue, const byte *privateKey, const byte *otherPublicKey, bool validateOtherPublicKey=true) const;
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protected:
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// Create a public key from a private key
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void SecretToPublicKey(byte y[PUBLIC_KEYLENGTH], const byte x[SECRET_KEYLENGTH]) const;
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protected:
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FixedSizeSecBlock<byte, SECRET_KEYLENGTH> m_sk;
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FixedSizeSecBlock<byte, PUBLIC_KEYLENGTH> m_pk;
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OID m_oid; // preferred OID
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};
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// ****************** ed25519 Signer *********************** //
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/// \brief ed25519 message accumulator
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/// \details ed25519 buffers the entire message, and does not
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/// digest the message incrementally. You should be careful with
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/// large messages like files on-disk. The behavior is by design
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/// because Bernstein feels small messages should be authenticated;
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/// and larger messages will be digested by the application.
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/// \details The accumulator is used for signing and verification.
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/// The first 64-bytes of storage is reserved for the signature.
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/// During signing the signature storage is unused. During
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/// verification the first 64 bytes holds the signature. The
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/// signature is provided by the PK_Verifier framework and the
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/// call to PK_Signer::InputSignature. Member functions data()
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/// and size() refer to the accumulated message. Member function
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/// signature() refers to the signature with an implicit size of
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/// SIGNATURE_LENGTH bytes.
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/// \details Applications which digest large messages, like an ISO
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/// disk file, should take care because the design effectively
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/// disgorges the format operation from the signing operation.
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/// Put another way, be careful to ensure what you are signing is
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/// is in fact a digest of the intended message, and not a different
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/// message digest supplied by an attacker.
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struct ed25519_MessageAccumulator : public PK_MessageAccumulator
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{
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CRYPTOPP_CONSTANT(RESERVE_SIZE=2048+64)
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CRYPTOPP_CONSTANT(SIGNATURE_LENGTH=64)
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/// \brief Create a message accumulator
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ed25519_MessageAccumulator() {
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Restart();
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}
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/// \brief Create a message accumulator
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/// \details ed25519 does not use a RNG. You can safely use
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/// NullRNG() because IsProbablistic returns false.
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ed25519_MessageAccumulator(RandomNumberGenerator &rng) {
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CRYPTOPP_UNUSED(rng); Restart();
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}
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/// \brief Add data to the accumulator
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/// \param msg pointer to the data to accumulate
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/// \param len the size of the data, in bytes
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void Update(const byte* msg, size_t len) {
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if (msg && len)
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m_msg.insert(m_msg.end(), msg, msg+len);
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}
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/// \brief Reset the accumulator
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void Restart() {
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m_msg.reserve(RESERVE_SIZE);
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m_msg.resize(SIGNATURE_LENGTH);
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}
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/// \brief Retrieve pointer to signature buffer
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/// \returns pointer to signature buffer
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byte* signature() {
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return &m_msg[0];
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}
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/// \brief Retrieve pointer to signature buffer
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/// \returns pointer to signature buffer
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const byte* signature() const {
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return &m_msg[0];
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}
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/// \brief Retrieve pointer to data buffer
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/// \returns pointer to data buffer
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const byte* data() const {
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return &m_msg[0]+SIGNATURE_LENGTH;
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}
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/// \brief Retrieve size of data buffer
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/// \returns size of the data buffer, in bytes
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size_t size() const {
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return m_msg.size()-SIGNATURE_LENGTH;
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}
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protected:
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// TODO: Find an equivalent Crypto++ structure.
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std::vector<byte, AllocatorWithCleanup<byte> > m_msg;
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};
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/// \brief Ed25519 private key
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/// \details ed25519PrivateKey is somewhat of a hack. It needed to
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/// provide DL_PrivateKey interface to fit into the existing
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/// framework, but it lacks a lot of the internals of a true
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/// DL_PrivateKey. The missing pieces include GroupParameters
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/// and Point, which provide the low level field operations
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/// found in traditional implementations like NIST curves over
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/// prime and binary fields.
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/// \details ed25519PrivateKey is also unusual because the
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/// class members of interest are byte arrays and not Integers.
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/// In addition, the byte arrays are little-endian meaning
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/// LSB is at element 0 and the MSB is at element 31.
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/// If you call GetPrivateExponent() then the little-endian byte
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/// array is converted to a big-endian Integer() so it can be
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/// returned the way a caller expects. And calling
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/// SetPrivateExponent perfoms a similar internal conversion.
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/// \since Crypto++ 8.0
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struct ed25519PrivateKey : public PKCS8PrivateKey
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{
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/// \brief Size of the private key
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/// \details SECRET_KEYLENGTH is the size of the private key, in bytes.
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CRYPTOPP_CONSTANT(SECRET_KEYLENGTH = 32)
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/// \brief Size of the public key
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/// \details PUBLIC_KEYLENGTH is the size of the public key, in bytes.
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CRYPTOPP_CONSTANT(PUBLIC_KEYLENGTH = 32)
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/// \brief Size of the siganture
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/// \details SIGNATURE_LENGTH is the size of the signature, in bytes.
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/// ed25519 is a DL-based signature scheme. The signature is the
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/// concatenation of <tt>r || s</tt>.
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CRYPTOPP_CONSTANT(SIGNATURE_LENGTH = 64)
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// CryptoMaterial
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bool Validate(RandomNumberGenerator &rng, unsigned int level) const;
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bool GetVoidValue(const char *name, const std::type_info &valueType, void *pValue) const;
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void AssignFrom(const NameValuePairs &source);
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// GroupParameters
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OID GetAlgorithmID() const {
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return m_oid.Empty() ? ASN1::Ed25519() : m_oid;
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}
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/// \brief DER encode ASN.1 object
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/// \param bt BufferedTransformation object
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/// \details Save() will write the OID associated with algorithm or scheme.
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/// In the case of public and private keys, this function writes the
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/// subjectPubicKeyInfo parts.
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/// \details The default OID is from RFC 8410 using <tt>id-Ed25519</tt>.
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/// The default private key format is RFC 5208, which is the old format.
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/// The old format provides the best interop, and keys will work
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/// with OpenSSL.
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/// \sa <A HREF="http://tools.ietf.org/rfc/rfc5958.txt">RFC 5958, Asymmetric
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/// Key Packages</A>
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void Save(BufferedTransformation &bt) const {
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DEREncode(bt, 0);
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}
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/// \brief DER encode ASN.1 object
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/// \param bt BufferedTransformation object
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/// \param v1 flag indicating v1
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/// \details Save() will write the OID associated with algorithm or scheme.
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/// In the case of public and private keys, this function writes the
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/// subjectPubicKeyInfo parts.
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/// \details The default OID is from RFC 8410 using <tt>id-Ed25519</tt>.
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/// The default private key format is RFC 5208.
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/// \details v1 means INTEGER 0 is written. INTEGER 0 means
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/// RFC 5208 format, which is the old format. The old format provides
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/// the best interop, and keys will work with OpenSSL. The other
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/// option uses INTEGER 1. INTEGER 1 means RFC 5958 format,
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/// which is the new format.
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/// \sa <A HREF="http://tools.ietf.org/rfc/rfc5958.txt">RFC 5958, Asymmetric
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/// Key Packages</A>
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void Save(BufferedTransformation &bt, bool v1) const {
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DEREncode(bt, v1 ? 0 : 1);
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}
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/// \brief BER decode ASN.1 object
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/// \param bt BufferedTransformation object
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/// \sa <A HREF="http://tools.ietf.org/rfc/rfc5958.txt">RFC 5958, Asymmetric
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/// Key Packages</A>
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void Load(BufferedTransformation &bt) {
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BERDecode(bt);
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}
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/// \brief Initializes a public key from this key
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/// \param pub reference to a public key
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void MakePublicKey(PublicKey &pub) const;
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// PKCS8PrivateKey
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void BERDecode(BufferedTransformation &bt);
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void DEREncode(BufferedTransformation &bt) const { DEREncode(bt, 0); }
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void BERDecodePrivateKey(BufferedTransformation &bt, bool parametersPresent, size_t size);
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void DEREncodePrivateKey(BufferedTransformation &bt) const;
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/// \brief DER encode ASN.1 object
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/// \param bt BufferedTransformation object
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/// \param version indicates version
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/// \details DEREncode() will write the OID associated with algorithm or
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/// scheme. In the case of public and private keys, this function writes
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/// the subjectPubicKeyInfo parts.
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/// \details The default OID is from RFC 8410 using <tt>id-X25519</tt>.
|
|
/// The default private key format is RFC 5208.
|
|
/// \details The value of version is written as the INTEGER. INTEGER 0 means
|
|
/// RFC 5208 format, which is the old format. The old format provides
|
|
/// the best interop, and keys will work with OpenSSL. The INTEGER 1
|
|
/// means RFC 5958 format, which is the new format.
|
|
void DEREncode(BufferedTransformation &bt, int version) const;
|
|
|
|
/// \brief Determine if OID is valid for this object
|
|
/// \details BERDecodeAndCheckAlgorithmID() parses the OID from
|
|
/// <tt>bt</tt> and determines if it valid for this object. The
|
|
/// problem in practice is there are multiple OIDs available to
|
|
/// denote curve25519 operations. The OIDs include an old GNU
|
|
/// OID used by SSH, OIDs specified in draft-josefsson-pkix-newcurves,
|
|
/// and OIDs specified in draft-ietf-curdle-pkix.
|
|
/// \details By default BERDecodeAndCheckAlgorithmID() accepts an
|
|
/// OID set by the user, <tt>ASN1::curve25519()</tt> and <tt>ASN1::Ed25519()</tt>.
|
|
/// <tt>ASN1::curve25519()</tt> is generic and says "this key is valid for
|
|
/// curve25519 operations". <tt>ASN1::Ed25519()</tt> is specific and says
|
|
/// "this key is valid for ed25519 signing."
|
|
void BERDecodeAndCheckAlgorithmID(BufferedTransformation& bt);
|
|
|
|
// PKCS8PrivateKey
|
|
void GenerateRandom(RandomNumberGenerator &rng, const NameValuePairs ¶ms);
|
|
void SetPrivateExponent(const byte x[SECRET_KEYLENGTH]);
|
|
void SetPrivateExponent(const Integer &x);
|
|
const Integer& GetPrivateExponent() const;
|
|
|
|
/// \brief Test if a key has small order
|
|
/// \param y public key
|
|
bool IsSmallOrder(const byte y[PUBLIC_KEYLENGTH]) const;
|
|
|
|
/// \brief Retrieve private key byte array
|
|
/// \returns the private key byte array
|
|
/// \details GetPrivateKeyBytePtr() is used by signing code to call ed25519_sign.
|
|
const byte* GetPrivateKeyBytePtr() const {
|
|
return m_sk.begin();
|
|
}
|
|
|
|
/// \brief Retrieve public key byte array
|
|
/// \returns the public key byte array
|
|
/// \details GetPublicKeyBytePtr() is used by signing code to call ed25519_sign.
|
|
const byte* GetPublicKeyBytePtr() const {
|
|
return m_pk.begin();
|
|
}
|
|
|
|
protected:
|
|
// Create a public key from a private key
|
|
void SecretToPublicKey(byte y[PUBLIC_KEYLENGTH], const byte x[SECRET_KEYLENGTH]) const;
|
|
|
|
protected:
|
|
FixedSizeSecBlock<byte, SECRET_KEYLENGTH> m_sk;
|
|
FixedSizeSecBlock<byte, PUBLIC_KEYLENGTH> m_pk;
|
|
OID m_oid; // preferred OID
|
|
mutable Integer m_x; // for DL_PrivateKey
|
|
};
|
|
|
|
/// \brief Ed25519 signature algorithm
|
|
/// \since Crypto++ 8.0
|
|
struct ed25519Signer : public PK_Signer
|
|
{
|
|
/// \brief Size of the private key
|
|
/// \details SECRET_KEYLENGTH is the size of the private key, in bytes.
|
|
CRYPTOPP_CONSTANT(SECRET_KEYLENGTH = 32)
|
|
/// \brief Size of the public key
|
|
/// \details PUBLIC_KEYLENGTH is the size of the public key, in bytes.
|
|
CRYPTOPP_CONSTANT(PUBLIC_KEYLENGTH = 32)
|
|
/// \brief Size of the siganture
|
|
/// \details SIGNATURE_LENGTH is the size of the signature, in bytes.
|
|
/// ed25519 is a DL-based signature scheme. The signature is the
|
|
/// concatenation of <tt>r || s</tt>.
|
|
CRYPTOPP_CONSTANT(SIGNATURE_LENGTH = 64)
|
|
typedef Integer Element;
|
|
|
|
virtual ~ed25519Signer() {}
|
|
|
|
/// \brief Create a ed25519Signer object
|
|
ed25519Signer() {}
|
|
|
|
/// \brief Create a ed25519Signer object
|
|
/// \param y public key
|
|
/// \param x private key
|
|
/// \details This constructor creates a ed25519Signer object using existing parameters.
|
|
/// \note The public key is not validated.
|
|
ed25519Signer(const byte y[PUBLIC_KEYLENGTH], const byte x[SECRET_KEYLENGTH]);
|
|
|
|
/// \brief Create a ed25519Signer object
|
|
/// \param x private key
|
|
/// \details This constructor creates a ed25519Signer object using existing parameters.
|
|
/// The public key is calculated from the private key.
|
|
ed25519Signer(const byte x[SECRET_KEYLENGTH]);
|
|
|
|
/// \brief Create a ed25519Signer object
|
|
/// \param y public key
|
|
/// \param x private key
|
|
/// \details This constructor creates a ed25519Signer object using existing parameters.
|
|
/// \note The public key is not validated.
|
|
ed25519Signer(const Integer &y, const Integer &x);
|
|
|
|
/// \brief Create a ed25519Signer object
|
|
/// \param x private key
|
|
/// \details This constructor creates a ed25519Signer object using existing parameters.
|
|
/// The public key is calculated from the private key.
|
|
ed25519Signer(const Integer &x);
|
|
|
|
/// \brief Create a ed25519Signer object
|
|
/// \param rng RandomNumberGenerator derived class
|
|
/// \details This constructor creates a new ed25519Signer using the random number generator.
|
|
ed25519Signer(RandomNumberGenerator &rng);
|
|
|
|
/// \brief Create a ed25519Signer object
|
|
/// \param params public and private key
|
|
/// \details This constructor creates a ed25519Signer object using existing parameters.
|
|
/// The <tt>params</tt> can be created with <tt>Save</tt>.
|
|
/// \note The public key is not validated.
|
|
ed25519Signer(BufferedTransformation ¶ms);
|
|
|
|
// DL_ObjectImplBase
|
|
/// \brief Retrieves a reference to a Private Key
|
|
/// \details AccessKey() retrieves a non-const reference to a private key.
|
|
PrivateKey& AccessKey() { return m_key; }
|
|
PrivateKey& AccessPrivateKey() { return m_key; }
|
|
|
|
/// \brief Retrieves a reference to a Private Key
|
|
/// \details AccessKey() retrieves a const reference to a private key.
|
|
const PrivateKey& GetKey() const { return m_key; }
|
|
const PrivateKey& GetPrivateKey() const { return m_key; }
|
|
|
|
// DL_SignatureSchemeBase
|
|
size_t SignatureLength() const { return SIGNATURE_LENGTH; }
|
|
size_t MaxRecoverableLength() const { return 0; }
|
|
size_t MaxRecoverableLengthFromSignatureLength(size_t signatureLength) const {
|
|
CRYPTOPP_UNUSED(signatureLength); return 0;
|
|
}
|
|
|
|
bool IsProbabilistic() const { return false; }
|
|
bool AllowNonrecoverablePart() const { return false; }
|
|
bool RecoverablePartFirst() const { return false; }
|
|
|
|
PK_MessageAccumulator* NewSignatureAccumulator(RandomNumberGenerator &rng) const {
|
|
return new ed25519_MessageAccumulator(rng);
|
|
}
|
|
|
|
void InputRecoverableMessage(PK_MessageAccumulator &messageAccumulator, const byte *recoverableMessage, size_t recoverableMessageLength) const {
|
|
CRYPTOPP_UNUSED(messageAccumulator); CRYPTOPP_UNUSED(recoverableMessage);
|
|
CRYPTOPP_UNUSED(recoverableMessageLength);
|
|
throw NotImplemented("ed25519Signer: this object does not support recoverable messages");
|
|
}
|
|
|
|
size_t SignAndRestart(RandomNumberGenerator &rng, PK_MessageAccumulator &messageAccumulator, byte *signature, bool restart) const;
|
|
|
|
/// \brief Sign a stream
|
|
/// \param rng a RandomNumberGenerator derived class
|
|
/// \param stream an std::istream derived class
|
|
/// \param signature a block of bytes for the signature
|
|
/// \return actual signature length
|
|
/// \details SignStream() handles large streams. The Stream functions were added to
|
|
/// ed25519 for signing and verifying files that are too large for a memory allocation.
|
|
/// The functions are not present in other library signers and verifiers.
|
|
/// \details ed25519 is a determinsitic signature scheme. <tt>IsProbabilistic()</tt>
|
|
/// returns false and the random number generator can be <tt>NullRNG()</tt>.
|
|
/// \pre <tt>COUNTOF(signature) == MaxSignatureLength()</tt>
|
|
/// \since Crypto++ 8.1
|
|
size_t SignStream (RandomNumberGenerator &rng, std::istream& stream, byte *signature) const;
|
|
|
|
protected:
|
|
ed25519PrivateKey m_key;
|
|
};
|
|
|
|
// ****************** ed25519 Verifier *********************** //
|
|
|
|
/// \brief Ed25519 public key
|
|
/// \details ed25519PublicKey is somewhat of a hack. It needed to
|
|
/// provide DL_PublicKey interface to fit into the existing
|
|
/// framework, but it lacks a lot of the internals of a true
|
|
/// DL_PublicKey. The missing pieces include GroupParameters
|
|
/// and Point, which provide the low level field operations
|
|
/// found in traditional implementations like NIST curves over
|
|
/// prime and binary fields.
|
|
/// \details ed25519PublicKey is also unusual because the
|
|
/// class members of interest are byte arrays and not Integers.
|
|
/// In addition, the byte arrays are little-endian meaning
|
|
/// LSB is at element 0 and the MSB is at element 31.
|
|
/// If you call GetPublicElement() then the little-endian byte
|
|
/// array is converted to a big-endian Integer() so it can be
|
|
/// returned the way a caller expects. And calling
|
|
/// SetPublicElement() perfoms a similar internal conversion.
|
|
/// \since Crypto++ 8.0
|
|
struct ed25519PublicKey : public X509PublicKey
|
|
{
|
|
/// \brief Size of the public key
|
|
/// \details PUBLIC_KEYLENGTH is the size of the public key, in bytes.
|
|
CRYPTOPP_CONSTANT(PUBLIC_KEYLENGTH = 32)
|
|
typedef Integer Element;
|
|
|
|
OID GetAlgorithmID() const {
|
|
return m_oid.Empty() ? ASN1::Ed25519() : m_oid;
|
|
}
|
|
|
|
/// \brief DER encode ASN.1 object
|
|
/// \param bt BufferedTransformation object
|
|
/// \details Save() will write the OID associated with algorithm or scheme.
|
|
/// In the case of public and private keys, this function writes the
|
|
/// subjectPubicKeyInfo parts.
|
|
/// \details The default OID is from RFC 8410 using <tt>id-X25519</tt>.
|
|
/// The default private key format is RFC 5208, which is the old format.
|
|
/// The old format provides the best interop, and keys will work
|
|
/// with OpenSSL.
|
|
void Save(BufferedTransformation &bt) const {
|
|
BEREncode(bt);
|
|
}
|
|
|
|
/// \brief BER decode ASN.1 object
|
|
/// \param bt BufferedTransformation object
|
|
/// \sa <A HREF="http://tools.ietf.org/rfc/rfc5958.txt">RFC 5958, Asymmetric
|
|
/// Key Packages</A>
|
|
void Load(BufferedTransformation &bt) {
|
|
BERDecode(bt);
|
|
}
|
|
|
|
// X509PublicKey
|
|
void BERDecode(BufferedTransformation &bt);
|
|
void DEREncode(BufferedTransformation &bt) const;
|
|
void BERDecodePublicKey(BufferedTransformation &bt, bool parametersPresent, size_t size);
|
|
void DEREncodePublicKey(BufferedTransformation &bt) const;
|
|
|
|
/// \brief Determine if OID is valid for this object
|
|
/// \details BERDecodeAndCheckAlgorithmID() parses the OID from
|
|
/// <tt>bt</tt> and determines if it valid for this object. The
|
|
/// problem in practice is there are multiple OIDs available to
|
|
/// denote curve25519 operations. The OIDs include an old GNU
|
|
/// OID used by SSH, OIDs specified in draft-josefsson-pkix-newcurves,
|
|
/// and OIDs specified in draft-ietf-curdle-pkix.
|
|
/// \details By default BERDecodeAndCheckAlgorithmID() accepts an
|
|
/// OID set by the user, <tt>ASN1::curve25519()</tt> and <tt>ASN1::Ed25519()</tt>.
|
|
/// <tt>ASN1::curve25519()</tt> is generic and says "this key is valid for
|
|
/// curve25519 operations". <tt>ASN1::Ed25519()</tt> is specific and says
|
|
/// "this key is valid for ed25519 signing."
|
|
void BERDecodeAndCheckAlgorithmID(BufferedTransformation& bt);
|
|
|
|
bool Validate(RandomNumberGenerator &rng, unsigned int level) const;
|
|
bool GetVoidValue(const char *name, const std::type_info &valueType, void *pValue) const;
|
|
void AssignFrom(const NameValuePairs &source);
|
|
|
|
// DL_PublicKey
|
|
void SetPublicElement(const byte y[PUBLIC_KEYLENGTH]);
|
|
void SetPublicElement(const Element &y);
|
|
const Element& GetPublicElement() const;
|
|
|
|
/// \brief Retrieve public key byte array
|
|
/// \returns the public key byte array
|
|
/// \details GetPublicKeyBytePtr() is used by signing code to call ed25519_sign.
|
|
const byte* GetPublicKeyBytePtr() const {
|
|
return m_pk.begin();
|
|
}
|
|
|
|
protected:
|
|
FixedSizeSecBlock<byte, PUBLIC_KEYLENGTH> m_pk;
|
|
OID m_oid; // preferred OID
|
|
mutable Integer m_y; // for DL_PublicKey
|
|
};
|
|
|
|
/// \brief Ed25519 signature verification algorithm
|
|
/// \since Crypto++ 8.0
|
|
struct ed25519Verifier : public PK_Verifier
|
|
{
|
|
CRYPTOPP_CONSTANT(PUBLIC_KEYLENGTH = 32)
|
|
CRYPTOPP_CONSTANT(SIGNATURE_LENGTH = 64)
|
|
typedef Integer Element;
|
|
|
|
virtual ~ed25519Verifier() {}
|
|
|
|
/// \brief Create a ed25519Verifier object
|
|
ed25519Verifier() {}
|
|
|
|
/// \brief Create a ed25519Verifier object
|
|
/// \param y public key
|
|
/// \details This constructor creates a ed25519Verifier object using existing parameters.
|
|
/// \note The public key is not validated.
|
|
ed25519Verifier(const byte y[PUBLIC_KEYLENGTH]);
|
|
|
|
/// \brief Create a ed25519Verifier object
|
|
/// \param y public key
|
|
/// \details This constructor creates a ed25519Verifier object using existing parameters.
|
|
/// \note The public key is not validated.
|
|
ed25519Verifier(const Integer &y);
|
|
|
|
/// \brief Create a ed25519Verifier object
|
|
/// \param params public and private key
|
|
/// \details This constructor creates a ed25519Verifier object using existing parameters.
|
|
/// The <tt>params</tt> can be created with <tt>Save</tt>.
|
|
/// \note The public key is not validated.
|
|
ed25519Verifier(BufferedTransformation ¶ms);
|
|
|
|
/// \brief Create a ed25519Verifier object
|
|
/// \param signer ed25519 signer object
|
|
/// \details This constructor creates a ed25519Verifier object using existing parameters.
|
|
/// The <tt>params</tt> can be created with <tt>Save</tt>.
|
|
/// \note The public key is not validated.
|
|
ed25519Verifier(const ed25519Signer& signer);
|
|
|
|
// DL_ObjectImplBase
|
|
/// \brief Retrieves a reference to a Public Key
|
|
/// \details AccessKey() retrieves a non-const reference to a public key.
|
|
PublicKey& AccessKey() { return m_key; }
|
|
PublicKey& AccessPublicKey() { return m_key; }
|
|
|
|
/// \brief Retrieves a reference to a Public Key
|
|
/// \details GetKey() retrieves a const reference to a public key.
|
|
const PublicKey& GetKey() const { return m_key; }
|
|
const PublicKey& GetPublicKey() const { return m_key; }
|
|
|
|
// DL_SignatureSchemeBase
|
|
size_t SignatureLength() const { return SIGNATURE_LENGTH; }
|
|
size_t MaxRecoverableLength() const { return 0; }
|
|
size_t MaxRecoverableLengthFromSignatureLength(size_t signatureLength) const {
|
|
CRYPTOPP_UNUSED(signatureLength); return 0;
|
|
}
|
|
|
|
bool IsProbabilistic() const { return false; }
|
|
bool AllowNonrecoverablePart() const { return false; }
|
|
bool RecoverablePartFirst() const { return false; }
|
|
|
|
ed25519_MessageAccumulator* NewVerificationAccumulator() const {
|
|
return new ed25519_MessageAccumulator;
|
|
}
|
|
|
|
void InputSignature(PK_MessageAccumulator &messageAccumulator, const byte *signature, size_t signatureLength) const {
|
|
CRYPTOPP_ASSERT(signature != NULLPTR);
|
|
CRYPTOPP_ASSERT(signatureLength == SIGNATURE_LENGTH);
|
|
ed25519_MessageAccumulator& accum = static_cast<ed25519_MessageAccumulator&>(messageAccumulator);
|
|
if (signature && signatureLength)
|
|
std::memcpy(accum.signature(), signature, STDMIN((size_t)SIGNATURE_LENGTH, signatureLength));
|
|
}
|
|
|
|
bool VerifyAndRestart(PK_MessageAccumulator &messageAccumulator) const;
|
|
|
|
/// \brief Check whether input signature is a valid signature for input message
|
|
/// \param stream an std::istream derived class
|
|
/// \param signature a pointer to the signature over the message
|
|
/// \param signatureLen the size of the signature
|
|
/// \return true if the signature is valid, false otherwise
|
|
/// \details VerifyStream() handles large streams. The Stream functions were added to
|
|
/// ed25519 for signing and verifying files that are too large for a memory allocation.
|
|
/// The functions are not present in other library signers and verifiers.
|
|
/// \since Crypto++ 8.1
|
|
bool VerifyStream(std::istream& stream, const byte *signature, size_t signatureLen) const;
|
|
|
|
DecodingResult RecoverAndRestart(byte *recoveredMessage, PK_MessageAccumulator &messageAccumulator) const {
|
|
CRYPTOPP_UNUSED(recoveredMessage); CRYPTOPP_UNUSED(messageAccumulator);
|
|
throw NotImplemented("ed25519Verifier: this object does not support recoverable messages");
|
|
}
|
|
|
|
protected:
|
|
ed25519PublicKey m_key;
|
|
};
|
|
|
|
/// \brief Ed25519 signature scheme
|
|
/// \sa <A HREF="http://cryptopp.com/wiki/Ed25519">Ed25519</A> on the Crypto++ wiki.
|
|
/// \since Crypto++ 8.0
|
|
struct ed25519
|
|
{
|
|
/// \brief ed25519 Signer
|
|
typedef ed25519Signer Signer;
|
|
/// \brief ed25519 Verifier
|
|
typedef ed25519Verifier Verifier;
|
|
};
|
|
|
|
NAMESPACE_END // CryptoPP
|
|
|
|
#endif // CRYPTOPP_XED25519_H
|