boost/spirit/home/support/detail/endian/endian.hpp
// Boost endian.hpp header file -------------------------------------------------------// // (C) Copyright Darin Adler 2000 // (C) Copyright Beman Dawes 2006, 2009 // Distributed under the Boost Software License, Version 1.0. // See http://www.boost.org/LICENSE_1_0.txt // See library home page at http://www.boost.org/libs/endian //--------------------------------------------------------------------------------------// // Original design developed by Darin Adler based on classes developed by Mark // Borgerding. Four original class templates were combined into a single endian // class template by Beman Dawes, who also added the unrolled_byte_loops sign // partial specialization to correctly extend the sign when cover integer size // differs from endian representation size. // TODO: When a compiler supporting constexpr becomes available, try possible uses. #ifndef BOOST_SPIRIT_ENDIAN_HPP #define BOOST_SPIRIT_ENDIAN_HPP #if defined(_MSC_VER) #pragma once #endif #ifdef BOOST_ENDIAN_LOG # include <iostream> #endif #if defined(__BORLANDC__) || defined( __CODEGEARC__) # pragma pack(push, 1) #endif #include <boost/config.hpp> #include <boost/detail/endian.hpp> #define BOOST_MINIMAL_INTEGER_COVER_OPERATORS #define BOOST_NO_IO_COVER_OPERATORS #include <boost/spirit/home/support/detail/endian/cover_operators.hpp> #undef BOOST_NO_IO_COVER_OPERATORS #undef BOOST_MINIMAL_INTEGER_COVER_OPERATORS #include <boost/type_traits/is_signed.hpp> #include <boost/type_traits/make_unsigned.hpp> #include <boost/cstdint.hpp> #include <boost/static_assert.hpp> #include <boost/spirit/home/support/detail/scoped_enum_emulation.hpp> #include <iosfwd> #include <climits> # if CHAR_BIT != 8 # error Platforms with CHAR_BIT != 8 are not supported # endif # define BOOST_ENDIAN_DEFAULT_CONSTRUCT {} // C++03 # if defined(BOOST_ENDIAN_FORCE_PODNESS) # define BOOST_ENDIAN_NO_CTORS # endif namespace boost { namespace spirit { namespace detail { // Unrolled loops for loading and storing streams of bytes. template <typename T, std::size_t n_bytes, bool sign=boost::is_signed<T>::value > struct unrolled_byte_loops { typedef unrolled_byte_loops<T, n_bytes - 1, sign> next; static typename boost::make_unsigned<T>::type load_big(const unsigned char* bytes) { return *(bytes - 1) | (next::load_big(bytes - 1) << 8); } static typename boost::make_unsigned<T>::type load_little(const unsigned char* bytes) { return *bytes | (next::load_little(bytes + 1) << 8); } static void store_big(char* bytes, T value) { *(bytes - 1) = static_cast<char>(value); next::store_big(bytes - 1, value >> 8); } static void store_little(char* bytes, T value) { *bytes = static_cast<char>(value); next::store_little(bytes + 1, value >> 8); } }; template <typename T> struct unrolled_byte_loops<T, 1, false> { static T load_big(const unsigned char* bytes) { return *(bytes - 1); } static T load_little(const unsigned char* bytes) { return *bytes; } static void store_big(char* bytes, T value) { *(bytes - 1) = static_cast<char>(value); } static void store_little(char* bytes, T value) { *bytes = static_cast<char>(value); } }; template <typename T> struct unrolled_byte_loops<T, 1, true> { static typename boost::make_unsigned<T>::type load_big(const unsigned char* bytes) { return *(bytes - 1); } static typename boost::make_unsigned<T>::type load_little(const unsigned char* bytes) { return *bytes; } static void store_big(char* bytes, T value) { *(bytes - 1) = static_cast<char>(value); } static void store_little(char* bytes, T value) { *bytes = static_cast<char>(value); } }; template <typename T, std::size_t n_bytes> inline T load_big_endian(const void* bytes) { return static_cast<T>(unrolled_byte_loops<T, n_bytes>::load_big (static_cast<const unsigned char*>(bytes) + n_bytes)); } template <> inline float load_big_endian<float, 4>(const void* bytes) { const unsigned char *b = reinterpret_cast<const unsigned char *>( bytes); b += 3; float value; unsigned char *v = reinterpret_cast<unsigned char *>(&value); for(std::size_t i = 0; i < 4; ++i) { *v++ = *b--; } return value; } template <> inline double load_big_endian<double, 8>(const void* bytes) { const unsigned char *b = reinterpret_cast<const unsigned char *>( bytes); b += 7; double value; unsigned char *v = reinterpret_cast<unsigned char *>(&value); for(std::size_t i = 0; i < 8; ++i) { *v++ = *b--; } return value; } template <typename T, std::size_t n_bytes> inline T load_little_endian(const void* bytes) { return static_cast<T>(unrolled_byte_loops<T, n_bytes>::load_little (static_cast<const unsigned char*>(bytes))); } template <> inline float load_little_endian<float, 4>(const void* bytes) { const unsigned char *b = reinterpret_cast<const unsigned char *>( bytes); float value; unsigned char *v = reinterpret_cast<unsigned char *>(&value); for(std::size_t i = 0; i < 4; ++i) { *v++ = *b++; } return value; } template <> inline double load_little_endian<double, 8>(const void* bytes) { const unsigned char *b = reinterpret_cast<const unsigned char *>( bytes); double value; unsigned char *v = reinterpret_cast<unsigned char *>(&value); for(std::size_t i = 0; i < 8; ++i) { *v++ = *b++; } return value; } template <typename T, std::size_t n_bytes> inline void store_big_endian(void* bytes, T value) { unrolled_byte_loops<T, n_bytes>::store_big (static_cast<char*>(bytes) + n_bytes, value); } template <> inline void store_big_endian<float, 4>(void* bytes, float value) { unsigned char *b = reinterpret_cast<unsigned char *>(bytes); b += 3; const unsigned char *v = reinterpret_cast<const unsigned char *>( &value); for(std::size_t i = 0; i < 4; ++i) { *b-- = *v++; } } template <> inline void store_big_endian<double, 8>(void* bytes, double value) { unsigned char *b = reinterpret_cast<unsigned char *>(bytes); b += 7; const unsigned char *v = reinterpret_cast<const unsigned char *>( &value); for(std::size_t i = 0; i < 8; ++i) { *b-- = *v++; } } template <typename T, std::size_t n_bytes> inline void store_little_endian(void* bytes, T value) { unrolled_byte_loops<T, n_bytes>::store_little (static_cast<char*>(bytes), value); } template <> inline void store_little_endian<float, 4>(void* bytes, float value) { unsigned char *b = reinterpret_cast<unsigned char *>(bytes); const unsigned char *v = reinterpret_cast<const unsigned char *>( &value); for(std::size_t i = 0; i < 4; ++i) { *b++ = *v++; } } template <> inline void store_little_endian<double, 8>(void* bytes, double value) { unsigned char *b = reinterpret_cast<unsigned char *>(bytes); const unsigned char *v = reinterpret_cast<const unsigned char *>( &value); for(std::size_t i = 0; i < 8; ++i) { *b++ = *v++; } } } // namespace detail namespace endian { # ifdef BOOST_ENDIAN_LOG bool endian_log(true); # endif // endian class template and specializations ---------------------------------------// BOOST_SCOPED_ENUM_START(endianness) { big, little, native }; BOOST_SCOPED_ENUM_END BOOST_SCOPED_ENUM_START(alignment) { unaligned, aligned }; BOOST_SCOPED_ENUM_END template <BOOST_SCOPED_ENUM(endianness) E, typename T, std::size_t n_bits, BOOST_SCOPED_ENUM(alignment) A = alignment::unaligned> class endian; // Specializations that represent unaligned bytes. // Taking an integer type as a parameter provides a nice way to pass both // the size and signedness of the desired integer and get the appropriate // corresponding integer type for the interface. // unaligned big endian specialization template <typename T, std::size_t n_bits> class endian< endianness::big, T, n_bits, alignment::unaligned > : cover_operators< endian< endianness::big, T, n_bits >, T > { BOOST_STATIC_ASSERT( (n_bits/8)*8 == n_bits ); public: typedef T value_type; # ifndef BOOST_ENDIAN_NO_CTORS endian() BOOST_ENDIAN_DEFAULT_CONSTRUCT explicit endian(T val) { # ifdef BOOST_ENDIAN_LOG if ( endian_log ) std::clog << "big, unaligned, " << n_bits << "-bits, construct(" << val << ")\n"; # endif detail::store_big_endian<T, n_bits/8>(m_value, val); } # endif endian & operator=(T val) { detail::store_big_endian<T, n_bits/8>(m_value, val); return *this; } operator T() const { # ifdef BOOST_ENDIAN_LOG if ( endian_log ) std::clog << "big, unaligned, " << n_bits << "-bits, convert(" << detail::load_big_endian<T, n_bits/8>(m_value) << ")\n"; # endif return detail::load_big_endian<T, n_bits/8>(m_value); } private: char m_value[n_bits/8]; }; // unaligned little endian specialization template <typename T, std::size_t n_bits> class endian< endianness::little, T, n_bits, alignment::unaligned > : cover_operators< endian< endianness::little, T, n_bits >, T > { BOOST_STATIC_ASSERT( (n_bits/8)*8 == n_bits ); public: typedef T value_type; # ifndef BOOST_ENDIAN_NO_CTORS endian() BOOST_ENDIAN_DEFAULT_CONSTRUCT explicit endian(T val) { # ifdef BOOST_ENDIAN_LOG if ( endian_log ) std::clog << "little, unaligned, " << n_bits << "-bits, construct(" << val << ")\n"; # endif detail::store_little_endian<T, n_bits/8>(m_value, val); } # endif endian & operator=(T val) { detail::store_little_endian<T, n_bits/8>(m_value, val); return *this; } operator T() const { # ifdef BOOST_ENDIAN_LOG if ( endian_log ) std::clog << "little, unaligned, " << n_bits << "-bits, convert(" << detail::load_little_endian<T, n_bits/8>(m_value) << ")\n"; # endif return detail::load_little_endian<T, n_bits/8>(m_value); } private: char m_value[n_bits/8]; }; // unaligned native endian specialization template <typename T, std::size_t n_bits> class endian< endianness::native, T, n_bits, alignment::unaligned > : cover_operators< endian< endianness::native, T, n_bits >, T > { BOOST_STATIC_ASSERT( (n_bits/8)*8 == n_bits ); public: typedef T value_type; # ifndef BOOST_ENDIAN_NO_CTORS endian() BOOST_ENDIAN_DEFAULT_CONSTRUCT # ifdef BOOST_BIG_ENDIAN explicit endian(T val) { detail::store_big_endian<T, n_bits/8>(m_value, val); } # else explicit endian(T val) { detail::store_little_endian<T, n_bits/8>(m_value, val); } # endif # endif # ifdef BOOST_BIG_ENDIAN endian & operator=(T val) { detail::store_big_endian<T, n_bits/8>(m_value, val); return *this; } operator T() const { return detail::load_big_endian<T, n_bits/8>(m_value); } # else endian & operator=(T val) { detail::store_little_endian<T, n_bits/8>(m_value, val); return *this; } operator T() const { return detail::load_little_endian<T, n_bits/8>(m_value); } # endif private: char m_value[n_bits/8]; }; // Specializations that mimic built-in integer types. // These typically have the same alignment as the underlying types. // aligned big endian specialization template <typename T, std::size_t n_bits> class endian< endianness::big, T, n_bits, alignment::aligned > : cover_operators< endian< endianness::big, T, n_bits, alignment::aligned >, T > { BOOST_STATIC_ASSERT( (n_bits/8)*8 == n_bits ); BOOST_STATIC_ASSERT( sizeof(T) == n_bits/8 ); public: typedef T value_type; # ifndef BOOST_ENDIAN_NO_CTORS endian() BOOST_ENDIAN_DEFAULT_CONSTRUCT # ifdef BOOST_BIG_ENDIAN endian(T val) : m_value(val) { } # else explicit endian(T val) { detail::store_big_endian<T, sizeof(T)>(&m_value, val); } # endif # endif # ifdef BOOST_BIG_ENDIAN endian & operator=(T val) { m_value = val; return *this; } operator T() const { return m_value; } # else endian & operator=(T val) { detail::store_big_endian<T, sizeof(T)>(&m_value, val); return *this; } operator T() const { return detail::load_big_endian<T, sizeof(T)>(&m_value); } # endif private: T m_value; }; // aligned little endian specialization template <typename T, std::size_t n_bits> class endian< endianness::little, T, n_bits, alignment::aligned > : cover_operators< endian< endianness::little, T, n_bits, alignment::aligned >, T > { BOOST_STATIC_ASSERT( (n_bits/8)*8 == n_bits ); BOOST_STATIC_ASSERT( sizeof(T) == n_bits/8 ); public: typedef T value_type; # ifndef BOOST_ENDIAN_NO_CTORS endian() BOOST_ENDIAN_DEFAULT_CONSTRUCT # ifdef BOOST_LITTLE_ENDIAN endian(T val) : m_value(val) { } # else explicit endian(T val) { detail::store_little_endian<T, sizeof(T)>(&m_value, val); } # endif # endif # ifdef BOOST_LITTLE_ENDIAN endian & operator=(T val) { m_value = val; return *this; } operator T() const { return m_value; } #else endian & operator=(T val) { detail::store_little_endian<T, sizeof(T)>(&m_value, val); return *this; } operator T() const { return detail::load_little_endian<T, sizeof(T)>(&m_value); } #endif private: T m_value; }; // naming convention typedefs ------------------------------------------------------// // unaligned big endian signed integer types typedef endian< endianness::big, int_least8_t, 8 > big8_t; typedef endian< endianness::big, int_least16_t, 16 > big16_t; typedef endian< endianness::big, int_least32_t, 24 > big24_t; typedef endian< endianness::big, int_least32_t, 32 > big32_t; typedef endian< endianness::big, int_least64_t, 40 > big40_t; typedef endian< endianness::big, int_least64_t, 48 > big48_t; typedef endian< endianness::big, int_least64_t, 56 > big56_t; typedef endian< endianness::big, int_least64_t, 64 > big64_t; // unaligned big endian unsigned integer types typedef endian< endianness::big, uint_least8_t, 8 > ubig8_t; typedef endian< endianness::big, uint_least16_t, 16 > ubig16_t; typedef endian< endianness::big, uint_least32_t, 24 > ubig24_t; typedef endian< endianness::big, uint_least32_t, 32 > ubig32_t; typedef endian< endianness::big, uint_least64_t, 40 > ubig40_t; typedef endian< endianness::big, uint_least64_t, 48 > ubig48_t; typedef endian< endianness::big, uint_least64_t, 56 > ubig56_t; typedef endian< endianness::big, uint_least64_t, 64 > ubig64_t; // unaligned little endian signed integer types typedef endian< endianness::little, int_least8_t, 8 > little8_t; typedef endian< endianness::little, int_least16_t, 16 > little16_t; typedef endian< endianness::little, int_least32_t, 24 > little24_t; typedef endian< endianness::little, int_least32_t, 32 > little32_t; typedef endian< endianness::little, int_least64_t, 40 > little40_t; typedef endian< endianness::little, int_least64_t, 48 > little48_t; typedef endian< endianness::little, int_least64_t, 56 > little56_t; typedef endian< endianness::little, int_least64_t, 64 > little64_t; // unaligned little endian unsigned integer types typedef endian< endianness::little, uint_least8_t, 8 > ulittle8_t; typedef endian< endianness::little, uint_least16_t, 16 > ulittle16_t; typedef endian< endianness::little, uint_least32_t, 24 > ulittle24_t; typedef endian< endianness::little, uint_least32_t, 32 > ulittle32_t; typedef endian< endianness::little, uint_least64_t, 40 > ulittle40_t; typedef endian< endianness::little, uint_least64_t, 48 > ulittle48_t; typedef endian< endianness::little, uint_least64_t, 56 > ulittle56_t; typedef endian< endianness::little, uint_least64_t, 64 > ulittle64_t; // unaligned native endian signed integer types typedef endian< endianness::native, int_least8_t, 8 > native8_t; typedef endian< endianness::native, int_least16_t, 16 > native16_t; typedef endian< endianness::native, int_least32_t, 24 > native24_t; typedef endian< endianness::native, int_least32_t, 32 > native32_t; typedef endian< endianness::native, int_least64_t, 40 > native40_t; typedef endian< endianness::native, int_least64_t, 48 > native48_t; typedef endian< endianness::native, int_least64_t, 56 > native56_t; typedef endian< endianness::native, int_least64_t, 64 > native64_t; // unaligned native endian unsigned integer types typedef endian< endianness::native, uint_least8_t, 8 > unative8_t; typedef endian< endianness::native, uint_least16_t, 16 > unative16_t; typedef endian< endianness::native, uint_least32_t, 24 > unative24_t; typedef endian< endianness::native, uint_least32_t, 32 > unative32_t; typedef endian< endianness::native, uint_least64_t, 40 > unative40_t; typedef endian< endianness::native, uint_least64_t, 48 > unative48_t; typedef endian< endianness::native, uint_least64_t, 56 > unative56_t; typedef endian< endianness::native, uint_least64_t, 64 > unative64_t; #define BOOST_HAS_INT16_T #define BOOST_HAS_INT32_T #define BOOST_HAS_INT64_T // These types only present if platform has exact size integers: // aligned big endian signed integer types // aligned big endian unsigned integer types // aligned little endian signed integer types // aligned little endian unsigned integer types // aligned native endian typedefs are not provided because // <cstdint> types are superior for this use case # if defined(BOOST_HAS_INT16_T) typedef endian< endianness::big, int16_t, 16, alignment::aligned > aligned_big16_t; typedef endian< endianness::big, uint16_t, 16, alignment::aligned > aligned_ubig16_t; typedef endian< endianness::little, int16_t, 16, alignment::aligned > aligned_little16_t; typedef endian< endianness::little, uint16_t, 16, alignment::aligned > aligned_ulittle16_t; # endif # if defined(BOOST_HAS_INT32_T) typedef endian< endianness::big, int32_t, 32, alignment::aligned > aligned_big32_t; typedef endian< endianness::big, uint32_t, 32, alignment::aligned > aligned_ubig32_t; typedef endian< endianness::little, int32_t, 32, alignment::aligned > aligned_little32_t; typedef endian< endianness::little, uint32_t, 32, alignment::aligned > aligned_ulittle32_t; # endif # if defined(BOOST_HAS_INT64_T) typedef endian< endianness::big, int64_t, 64, alignment::aligned > aligned_big64_t; typedef endian< endianness::big, uint64_t, 64, alignment::aligned > aligned_ubig64_t; typedef endian< endianness::little, int64_t, 64, alignment::aligned > aligned_little64_t; typedef endian< endianness::little, uint64_t, 64, alignment::aligned > aligned_ulittle64_t; # endif } // namespace endian }} // namespace boost::spirit // import the namespace above into boost::endian namespace boost { namespace endian { using namespace boost::spirit::endian; }} #if defined(__BORLANDC__) || defined( __CODEGEARC__) # pragma pack(pop) #endif #endif // BOOST_SPIRIT_ENDIAN_HPP