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Fix typos
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@ -294,7 +294,7 @@ public:
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/// \brief Calculates the greatest common denominator in the ring
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/// \param a the first element
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/// \param b the second element
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/// \return the the greatest common denominator of a and b.
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/// \return the greatest common denominator of a and b.
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virtual const Element& Gcd(const Element &a, const Element &b) const;
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protected:
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@ -28,7 +28,7 @@
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/// The <tt>0x00</tt> indicates the low 64-bits of <tt>a</tt> and <tt>b</tt>
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/// are multiplied.
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/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
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/// is MSB and numbered 127, while the the rightmost bit is LSB and
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/// is MSB and numbered 127, while the rightmost bit is LSB and
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/// numbered 0.
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/// \since Crypto++ 8.0
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inline uint64x2_t PMULL_00(const uint64x2_t a, const uint64x2_t b)
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@ -58,7 +58,7 @@ inline uint64x2_t PMULL_00(const uint64x2_t a, const uint64x2_t b)
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/// The <tt>0x01</tt> indicates the low 64-bits of <tt>a</tt> and high
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/// 64-bits of <tt>b</tt> are multiplied.
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/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
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/// is MSB and numbered 127, while the the rightmost bit is LSB and
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/// is MSB and numbered 127, while the rightmost bit is LSB and
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/// numbered 0.
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/// \since Crypto++ 8.0
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inline uint64x2_t PMULL_01(const uint64x2_t a, const uint64x2_t b)
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@ -88,7 +88,7 @@ inline uint64x2_t PMULL_01(const uint64x2_t a, const uint64x2_t b)
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/// The <tt>0x10</tt> indicates the high 64-bits of <tt>a</tt> and low
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/// 64-bits of <tt>b</tt> are multiplied.
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/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
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/// is MSB and numbered 127, while the the rightmost bit is LSB and
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/// is MSB and numbered 127, while the rightmost bit is LSB and
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/// numbered 0.
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/// \since Crypto++ 8.0
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inline uint64x2_t PMULL_10(const uint64x2_t a, const uint64x2_t b)
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@ -118,7 +118,7 @@ inline uint64x2_t PMULL_10(const uint64x2_t a, const uint64x2_t b)
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/// The <tt>0x11</tt> indicates the high 64-bits of <tt>a</tt> and <tt>b</tt>
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/// are multiplied.
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/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
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/// is MSB and numbered 127, while the the rightmost bit is LSB and
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/// is MSB and numbered 127, while the rightmost bit is LSB and
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/// numbered 0.
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/// \since Crypto++ 8.0
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inline uint64x2_t PMULL_11(const uint64x2_t a, const uint64x2_t b)
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@ -1340,7 +1340,7 @@ public:
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/// \return the maximum length of encrypted data
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virtual lword MaxMessageLength() const =0;
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/// \brief Provides the the maximum length of AAD
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/// \brief Provides the maximum length of AAD
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/// \return the maximum length of AAD that can be input after the encrypted data
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virtual lword MaxFooterLength() const {return 0;}
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@ -2725,7 +2725,7 @@ public:
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/// \param parameters a set of NameValuePairs to initialize this object
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/// \return the result of the decryption operation
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/// \details If DecodingResult::isValidCoding is true, then DecodingResult::messageLength
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/// is valid and holds the the actual length of the plaintext recovered. The result is undefined
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/// is valid and holds the actual length of the plaintext recovered. The result is undefined
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/// if decryption failed. If DecodingResult::isValidCoding is false, then DecodingResult::messageLength
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/// is undefined.
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/// \pre <tt>COUNTOF(plaintext) == MaxPlaintextLength(ciphertextLength)</tt> ensures the output
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@ -2751,7 +2751,7 @@ public:
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/// \param parameters a set of NameValuePairs to initialize this object
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/// \return the result of the decryption operation
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/// \details If DecodingResult::isValidCoding is true, then DecodingResult::messageLength
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/// is valid and holds the the actual length of the plaintext recovered. The result is undefined
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/// is valid and holds the actual length of the plaintext recovered. The result is undefined
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/// if decryption failed. If DecodingResult::isValidCoding is false, then DecodingResult::messageLength
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/// is undefined.
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/// \pre <tt>COUNTOF(plaintext) == MaxPlaintextLength(ciphertextLength)</tt> ensures the output
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2
ec2n.h
2
ec2n.h
@ -44,7 +44,7 @@ public:
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/// \brief Construct an EC2N from BER encoded parameters
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/// \param bt BufferedTransformation derived object
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/// \details This constructor will decode and extract the the fields fieldID and curve of the sequence ECParameters
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/// \details This constructor will decode and extract the fields fieldID and curve of the sequence ECParameters
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EC2N(BufferedTransformation &bt);
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/// \brief Encode the fields fieldID and curve of the sequence ECParameters
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2
ecp.h
2
ecp.h
@ -54,7 +54,7 @@ public:
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/// \brief Construct an ECP from BER encoded parameters
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/// \param bt BufferedTransformation derived object
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/// \details This constructor will decode and extract the the fields
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/// \details This constructor will decode and extract the fields
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/// fieldID and curve of the sequence ECParameters
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ECP(BufferedTransformation &bt);
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@ -90,14 +90,14 @@ public:
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virtual void Precompute(const DL_GroupPrecomputation<Element> &group, unsigned int maxExpBits, unsigned int storage) =0;
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/// \brief Retrieve previously saved precomputation
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/// \param group the the group
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/// \param group the group
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/// \param storedPrecomputation BufferedTransformation with the saved precomputation
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/// \throw NotImplemented
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/// \sa SupportsPrecomputation(), Precompute()
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virtual void Load(const DL_GroupPrecomputation<Element> &group, BufferedTransformation &storedPrecomputation) =0;
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/// \brief Save precomputation for later use
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/// \param group the the group
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/// \param group the group
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/// \param storedPrecomputation BufferedTransformation to write the precomputation
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/// \throw NotImplemented
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/// \sa SupportsPrecomputation(), Precompute()
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@ -181,7 +181,7 @@ CRYPTOPP_DLL Integer CRYPTOPP_API CRT(const Integer &xp, const Integer &p, const
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/// \brief Calculate the Jacobi symbol
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/// \param a the first term
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/// \param b the second term
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/// \return the the Jacobi symbol.
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/// \return the Jacobi symbol.
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/// \details Jacobi symbols are calculated using the following rules:
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/// -# if <tt>b</tt> is prime, then <tt>Jacobi(a, b)</tt>, then return 0
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/// -# if <tt>a%b</tt>==0 AND <tt>a</tt> is quadratic residue <tt>mod b</tt>, then return 1
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@ -305,7 +305,7 @@ public:
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const Integer& SubPrime() const {return q;}
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/// \brief Retrieve the generator
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/// \return Generator() returns the the generator g.
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/// \return Generator() returns the generator g.
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const Integer& Generator() const {return g;}
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private:
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2
ossig.h
2
ossig.h
@ -29,7 +29,7 @@ extern "C" {
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/// \brief Null signal handler function
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/// \param unused the signal number
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/// \details NullSignalHandler is provided as a stand alone function with external "C" linkage
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/// and not a static member function due to the the member function's implicit
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/// and not a static member function due to the member function's implicit
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/// external "C++" linkage.
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/// \sa SignalHandler, SignalHandlerFn
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extern "C" {
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@ -2510,7 +2510,7 @@ inline uint64x2_p VecPolyMultiply(const uint64x2_p& a, const uint64x2_p& b)
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/// The <tt>0x00</tt> indicates the low 64-bits of <tt>a</tt> and <tt>b</tt>
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/// are multiplied.
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/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
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/// is MSB and numbered 127, while the the rightmost bit is LSB and numbered 0.
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/// is MSB and numbered 127, while the rightmost bit is LSB and numbered 0.
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/// \par Wraps
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/// __vpmsumd, __builtin_altivec_crypto_vpmsumd and __builtin_crypto_vpmsumd.
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/// \since Crypto++ 8.0
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@ -2532,7 +2532,7 @@ inline uint64x2_p VecIntelMultiply00(const uint64x2_p& a, const uint64x2_p& b)
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/// The <tt>0x01</tt> indicates the low 64-bits of <tt>a</tt> and high
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/// 64-bits of <tt>b</tt> are multiplied.
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/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
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/// is MSB and numbered 127, while the the rightmost bit is LSB and numbered 0.
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/// is MSB and numbered 127, while the rightmost bit is LSB and numbered 0.
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/// \par Wraps
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/// __vpmsumd, __builtin_altivec_crypto_vpmsumd and __builtin_crypto_vpmsumd.
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/// \since Crypto++ 8.0
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@ -2554,7 +2554,7 @@ inline uint64x2_p VecIntelMultiply01(const uint64x2_p& a, const uint64x2_p& b)
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/// The <tt>0x10</tt> indicates the high 64-bits of <tt>a</tt> and low
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/// 64-bits of <tt>b</tt> are multiplied.
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/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
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/// is MSB and numbered 127, while the the rightmost bit is LSB and numbered 0.
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/// is MSB and numbered 127, while the rightmost bit is LSB and numbered 0.
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/// \par Wraps
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/// __vpmsumd, __builtin_altivec_crypto_vpmsumd and __builtin_crypto_vpmsumd.
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/// \since Crypto++ 8.0
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@ -2576,7 +2576,7 @@ inline uint64x2_p VecIntelMultiply10(const uint64x2_p& a, const uint64x2_p& b)
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/// The <tt>0x11</tt> indicates the high 64-bits of <tt>a</tt> and <tt>b</tt>
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/// are multiplied.
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/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
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/// is MSB and numbered 127, while the the rightmost bit is LSB and numbered 0.
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/// is MSB and numbered 127, while the rightmost bit is LSB and numbered 0.
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/// \par Wraps
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/// __vpmsumd, __builtin_altivec_crypto_vpmsumd and __builtin_crypto_vpmsumd.
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/// \since Crypto++ 8.0
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4
pssr.h
4
pssr.h
@ -66,8 +66,8 @@ template<> class PSSR_MEM_BaseWithHashId<false> : public PSSR_MEM_Base {};
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/// \tparam SALT_LEN length of the salt
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/// \tparam MIN_PAD_LEN minimum length of the pad
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/// \tparam USE_HASH_ID flag indicating whether the HashId is used
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/// \details If ALLOW_RECOVERY is true, the the signature scheme provides message recovery. If
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/// ALLOW_RECOVERY is false, the the signature scheme is appendix, and the message must be
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/// \details If ALLOW_RECOVERY is true, the signature scheme provides message recovery. If
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/// ALLOW_RECOVERY is false, the signature scheme is appendix, and the message must be
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/// provided during verification.
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/// \since Crypto++ 2.1
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template <bool ALLOW_RECOVERY, class MGF=P1363_MGF1, int SALT_LEN=-1, int MIN_PAD_LEN=0, bool USE_HASH_ID=false>
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10
pubkey.h
10
pubkey.h
@ -87,7 +87,7 @@ public:
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/// \details The default implementation returns <tt>PreimageBound() - 1</tt>.
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virtual Integer MaxPreimage() const {return --PreimageBound();}
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/// \brief Returns the maximum size of a message after the trapdoor function is applied bound to a public key
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/// \return the the maximum size of a message after the trapdoor function is applied bound to a public key
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/// \return the maximum size of a message after the trapdoor function is applied bound to a public key
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/// \details The default implementation returns <tt>ImageBound() - 1</tt>.
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virtual Integer MaxImage() const {return --ImageBound();}
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};
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@ -692,7 +692,7 @@ public:
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/// \brief Generate and apply mask
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/// \param hash HashTransformation derived class
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/// \param output the destination byte array
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/// \param outputLength the size fo the the destination byte array
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/// \param outputLength the size fo the destination byte array
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/// \param input the message to hash
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/// \param inputLength the size of the message
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/// \param mask flag indicating whether to apply the mask
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@ -703,7 +703,7 @@ public:
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/// \brief P1363 mask generation function
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/// \param hash HashTransformation derived class
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/// \param output the destination byte array
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/// \param outputLength the size fo the the destination byte array
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/// \param outputLength the size fo the destination byte array
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/// \param input the message to hash
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/// \param inputLength the size of the message
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/// \param derivationParams additional derivation parameters
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@ -727,7 +727,7 @@ public:
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/// \brief P1363 mask generation function
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/// \param hash HashTransformation derived class
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/// \param output the destination byte array
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/// \param outputLength the size fo the the destination byte array
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/// \param outputLength the size fo the destination byte array
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/// \param input the message to hash
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/// \param inputLength the size of the message
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/// \param mask flag indicating whether to apply the mask
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@ -751,7 +751,7 @@ class P1363_KDF2
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public:
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/// \brief P1363 key derivation function
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/// \param output the destination byte array
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/// \param outputLength the size fo the the destination byte array
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/// \param outputLength the size fo the destination byte array
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/// \param input the message to hash
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/// \param inputLength the size of the message
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/// \param derivationParams additional derivation parameters
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2
rdrand.h
2
rdrand.h
@ -20,7 +20,7 @@
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// GenerateBlock unconditionally retries and always fulfills the request.
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// Throughput varies wildly depending on processor and manufacturer. A Core i5 or
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// Core i7 RDRAND can generate at over 200 MiB/s. It is below the theroetical
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// Core i7 RDRAND can generate at over 200 MiB/s. It is below theroetical
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// maximum, but it takes about 5 instructions to generate, retry and store a
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// result. A low-end Celeron may perform RDRAND at about 7 MiB/s. RDSEED
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// performs at about 1/4 to 1/2 the rate of RDRAND. AMD RDRAND performed poorly
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