ext-cryptopp/sha.h

199 lines
9.9 KiB
C++

// sha.h - originally written and placed in the public domain by Wei Dai
/// \file sha.h
/// \brief Classes for SHA-1 and SHA-2 family of message digests
/// \since SHA1 since Crypto++ 1.0, SHA2 since Crypto++ 4.0,
/// ARM SHA since Crypto++ 6.0, Intel SHA since Crypto++ 6.0
#ifndef CRYPTOPP_SHA_H
#define CRYPTOPP_SHA_H
#include "config.h"
#include "iterhash.h"
#if (CRYPTOPP_BOOL_X86)
# define SHA_X86_ALIGN16 true
#else
# define SHA_X86_ALIGN16 false
#endif
NAMESPACE_BEGIN(CryptoPP)
/// \class SHA1
/// \brief SHA-1 message digest
/// \sa <a href="http://www.weidai.com/scan-mirror/md.html#SHA-1">SHA-1</a>
/// \since Crypto++ 1.0, Intel SHA extensions since Crypto++ 6.0
class CRYPTOPP_DLL SHA1 : public IteratedHashWithStaticTransform<word32, BigEndian, 64, 20, SHA1>
{
public:
/// \brief Initialize state array
/// \param state the state of the hash
/// \details InitState sets a state array to SHA1 initial values
/// \details Hashes which derive from IteratedHashWithStaticTransform provide static
/// member functions InitState and Transform. External classes, like SEAL and MDC,
/// can initialize state with a user provided key and operate the hash on the data
/// with the user supplied state.
/// \note On Intel platforms the state array must be 16-byte aligned for SSE2.
static void CRYPTOPP_API InitState(HashWordType *state);
/// \brief Operate the hash
/// \param digest the state of the hash
/// \param data the data to be digested
/// \details Transform operates the hash on <tt>data</tt>. When the call is invoked
/// <tt>digest</tt> holds initial state. Upon return <tt>digest</tt> holds the hash
/// or updated state.
/// \details Hashes which derive from IteratedHashWithStaticTransform provide static
/// member functions InitState and Transform. External classes, like SEAL and MDC,
/// can initialize state with a user provided key and operate the hash on the data
/// with the user supplied state.
/// \note On Intel platforms the state array and data must be 16-byte aligned for SSE2.
static void CRYPTOPP_API Transform(HashWordType *digest, const HashWordType *data);
/// \brief The algorithm name
/// \returns C-style string "SHA-1"
CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "SHA-1";}
protected:
size_t HashMultipleBlocks(const HashWordType *input, size_t length);
};
/// \class SHA256
/// \brief SHA-256 message digest
/// \sa <a href="http://www.weidai.com/scan-mirror/md.html#SHA-256">SHA-256</a>
/// \since Crypto++ 4.0, Intel SHA extensions since Crypto++ 6.0
class CRYPTOPP_DLL SHA256 : public IteratedHashWithStaticTransform<word32, BigEndian, 64, 32, SHA256, 32, true>
{
public:
/// \brief Initialize state array
/// \param state the state of the hash
/// \details InitState sets a state array to SHA256 initial values
/// \details Hashes which derive from IteratedHashWithStaticTransform provide static
/// member functions InitState and Transform. External classes, like SEAL and MDC,
/// can initialize state with a user provided key and operate the hash on the data
/// with the user supplied state.
/// \note On Intel platforms the state array must be 16-byte aligned for SSE2.
static void CRYPTOPP_API InitState(HashWordType *state);
/// \brief Operate the hash
/// \param digest the state of the hash
/// \param data the data to be digested
/// \details Transform operates the hash on <tt>data</tt>. When the call is invoked
/// <tt>digest</tt> holds initial state. Upon return <tt>digest</tt> holds the hash
/// or updated state.
/// \details Hashes which derive from IteratedHashWithStaticTransform provide static
/// member functions InitState and Transform. External classes, like SEAL and MDC,
/// can initialize state with a user provided key and operate the hash on the data
/// with the user supplied state.
/// \note On Intel platforms the state array and data must be 16-byte aligned for SSE2.
static void CRYPTOPP_API Transform(HashWordType *digest, const HashWordType *data);
/// \brief The algorithm name
/// \returns C-style string "SHA-256"
CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "SHA-256";}
protected:
size_t HashMultipleBlocks(const HashWordType *input, size_t length);
};
/// \class SHA224
/// \brief SHA-224 message digest
/// \sa <a href="http://www.weidai.com/scan-mirror/md.html#SHA-224">SHA-224</a>
/// \since Crypto++ 4.0, Intel SHA extensions since Crypto++ 6.0
class CRYPTOPP_DLL SHA224 : public IteratedHashWithStaticTransform<word32, BigEndian, 64, 32, SHA224, 28, true>
{
public:
/// \brief Initialize state array
/// \param state the state of the hash
/// \details InitState sets a state array to SHA224 initial values
/// \details Hashes which derive from IteratedHashWithStaticTransform provide static
/// member functions InitState and Transform. External classes, like SEAL and MDC,
/// can initialize state with a user provided key and operate the hash on the data
/// with the user supplied state.
/// \note On Intel platforms the state array must be 16-byte aligned for SSE2.
static void CRYPTOPP_API InitState(HashWordType *state);
/// \brief Operate the hash
/// \param digest the state of the hash
/// \param data the data to be digested
/// \details Transform operates the hash on <tt>data</tt>. When the call is invoked
/// <tt>digest</tt> holds initial state. Upon return <tt>digest</tt> holds the hash
/// or updated state.
/// \details Hashes which derive from IteratedHashWithStaticTransform provide static
/// member functions InitState and Transform. External classes, like SEAL and MDC,
/// can initialize state with a user provided key and operate the hash on the data
/// with the user supplied state.
/// \note On Intel platforms the state array and data must be 16-byte aligned for SSE2.
static void CRYPTOPP_API Transform(HashWordType *digest, const HashWordType *data) {SHA256::Transform(digest, data);}
/// \brief The algorithm name
/// \returns C-style string "SHA-224"
CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "SHA-224";}
protected:
size_t HashMultipleBlocks(const HashWordType *input, size_t length);
};
/// \class SHA512
/// \brief SHA-512 message digest
/// \sa <a href="http://www.weidai.com/scan-mirror/md.html#SHA-512">SHA-512</a>
/// \since Crypto++ 4.0
class CRYPTOPP_DLL SHA512 : public IteratedHashWithStaticTransform<word64, BigEndian, 128, 64, SHA512, 64, SHA_X86_ALIGN16>
{
public:
/// \brief Initialize state array
/// \param state the state of the hash
/// \details InitState sets a state array to SHA512 initial values
/// \details Hashes which derive from IteratedHashWithStaticTransform provide static
/// member functions InitState and Transform. External classes, like SEAL and MDC,
/// can initialize state with a user provided key and operate the hash on the data
/// with the user supplied state.
/// \note On Intel platforms the state array must be 16-byte aligned for SSE2.
static void CRYPTOPP_API InitState(HashWordType *state);
/// \brief Operate the hash
/// \param digest the state of the hash
/// \param data the data to be digested
/// \details Transform operates the hash on <tt>data</tt>. When the call is invoked
/// <tt>digest</tt> holds initial state. Upon return <tt>digest</tt> holds the hash
/// or updated state.
/// \details Hashes which derive from IteratedHashWithStaticTransform provide static
/// member functions InitState and Transform. External classes, like SEAL and MDC,
/// can initialize state with a user provided key and operate the hash on the data
/// with the user supplied state.
/// \note On Intel platforms the state array and data must be 16-byte aligned for SSE2.
static void CRYPTOPP_API Transform(HashWordType *digest, const HashWordType *data);
/// \brief The algorithm name
/// \returns C-style string "SHA-512"
CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "SHA-512";}
};
/// \class SHA384
/// \brief SHA-384 message digest
/// \sa <a href="http://www.weidai.com/scan-mirror/md.html#SHA-384">SHA-384</a>
/// \since Crypto++ 4.0
class CRYPTOPP_DLL SHA384 : public IteratedHashWithStaticTransform<word64, BigEndian, 128, 64, SHA384, 48, SHA_X86_ALIGN16>
{
public:
/// \brief Initialize state array
/// \param state the state of the hash
/// \details InitState sets a state array to SHA384 initial values
/// \details Hashes which derive from IteratedHashWithStaticTransform provide static
/// member functions InitState and Transform. External classes, like SEAL and MDC,
/// can initialize state with a user provided key and operate the hash on the data
/// with the user supplied state.
/// \note On Intel platforms the state array must be 16-byte aligned for SSE2.
static void CRYPTOPP_API InitState(HashWordType *state);
/// \brief Operate the hash
/// \param digest the state of the hash
/// \param data the data to be digested
/// \details Transform operates the hash on <tt>data</tt>. When the call is invoked
/// <tt>digest</tt> holds initial state. Upon return <tt>digest</tt> holds the hash
/// or updated state.
/// \details Hashes which derive from IteratedHashWithStaticTransform provide static
/// member functions InitState and Transform. External classes, like SEAL and MDC,
/// can initialize state with a user provided key and operate the hash on the data
/// with the user supplied state.
/// \note On Intel platforms the state array and data must be 16-byte aligned for SSE2.
static void CRYPTOPP_API Transform(HashWordType *digest, const HashWordType *data) {SHA512::Transform(digest, data);}
/// \brief The algorithm name
/// \returns C-style string "SHA-384"
CRYPTOPP_STATIC_CONSTEXPR const char* CRYPTOPP_API StaticAlgorithmName() {return "SHA-384";}
};
NAMESPACE_END
#endif