/* ScummVM - Graphic Adventure Engine * * ScummVM is the legal property of its developers, whose names * are too numerous to list here. Please refer to the COPYRIGHT * file distributed with this source distribution. * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * */ #ifndef COMMON_ENDIAN_H #define COMMON_ENDIAN_H #include "common/scummsys.h" /** * @defgroup common_endian Endian conversions * @ingroup common * * @brief Functions and macros for endian conversions and byteswap conversions. * * @details * - SWAP_BYTES_??(a) - Reverse byte order * - SWAP_CONSTANT_??(a) - Reverse byte order, implemented as a macro. * Use with compile-time constants only, the result will be a compile-time constant as well. * Unlike most other functions, these can be used for e.g. switch-case labels. * - READ_UINT??(a) - Read native value from pointer @p a. * - READ_??_UINT??(a) - Read LE/BE value from pointer @p a and convert it to native. * - WRITE_??_UINT??(a, v) - Write a native value @p v to pointer @p a with LE/BE encoding. * - TO_??_??(a) - Convert native value @p v to LE/BE. * - FROM_??_??(a) - Convert LE/BE value @p v to native. * - CONSTANT_??_??(a) - Convert LE/BE value @p v to native, implemented as a macro. * Use with compile-time constants only, the result will be a compile-time constant as well. * Unlike most other functions these, can be used for e.g. switch-case labels. * * @{ */ // Sanity check #if !defined(SCUMM_LITTLE_ENDIAN) && !defined(SCUMM_BIG_ENDIAN) # error No endianness defined #endif /** * Swap the bytes in a 64-bit word in order to convert LE encoded data to BE * and vice versa. Use with compile-time constants only. */ #define SWAP_CONSTANT_64(a) \ ((uint64)((((a) >> 56) & 0x000000FF) | \ (((a) >> 40) & 0x0000FF00) | \ (((a) >> 24) & 0x00FF0000) | \ (((a) >> 8) & 0xFF000000) | \ (((a) & 0xFF000000) << 8) | \ (((a) & 0x00FF0000) << 24) | \ (((a) & 0x0000FF00) << 40) | \ (((a) & 0x000000FF) << 56) )) /** * Swap the bytes in a 32-bit word in order to convert LE encoded data to BE * and vice versa. Use with compile-time constants only. */ #define SWAP_CONSTANT_32(a) \ ((uint32)((((a) >> 24) & 0x00FF) | \ (((a) >> 8) & 0xFF00) | \ (((a) & 0xFF00) << 8) | \ (((a) & 0x00FF) << 24) )) /** * Swap the bytes in a 16-bit word in order to convert LE encoded data to BE * and vice versa. Use with compile-time constants only. */ #define SWAP_CONSTANT_16(a) \ ((uint16)((((a) >> 8) & 0x00FF) | \ (((a) << 8) & 0xFF00) )) /** * Swap the bytes in a 16-bit word in order to convert LE encoded data to BE * and vice versa. */ // compiler-specific variants come first, fallback last #if GCC_ATLEAST(4, 8) || defined(__clang__) FORCEINLINE uint16 SWAP_BYTES_16(uint16 a) { return __builtin_bswap16(a); } #elif defined(_MSC_VER) FORCEINLINE uint16 SWAP_BYTES_16(uint16 a) { return _byteswap_ushort(a); } #else inline uint16 SWAP_BYTES_16(const uint16 a) { return (a >> 8) | (a << 8); } #endif /** * Swap the bytes in a 32-bit word in order to convert LE encoded data to BE * and vice versa. */ // compiler-specific variants come first, fallback last #if defined(__GNUC__) FORCEINLINE uint32 SWAP_BYTES_32(uint32 a) { return __builtin_bswap32(a); } #elif defined(_MSC_VER) FORCEINLINE uint32 SWAP_BYTES_32(uint32 a) { return _byteswap_ulong(a); } // generic fallback #else inline uint32 SWAP_BYTES_32(uint32 a) { const uint16 low = (uint16)a, high = (uint16)(a >> 16); return ((uint32)(uint16)((low >> 8) | (low << 8)) << 16) | (uint16)((high >> 8) | (high << 8)); } #endif /** * Swap the bytes in a 64-bit word in order to convert LE encoded data to BE * and vice versa. */ // compiler-specific variants come first, fallback last #if defined(__GNUC__) FORCEINLINE uint64 SWAP_BYTES_64(uint64 a) { return __builtin_bswap64(a); } #elif defined(_MSC_VER) FORCEINLINE uint64 SWAP_BYTES_64(uint64 a) { return _byteswap_uint64(a); } // generic fallback #else inline uint64 SWAP_BYTES_64(uint64 a) { uint32 low = (uint32)a, high = (uint32)(a >> 32); uint16 lowLow = (uint16)low, lowHigh = (uint16)(low >> 16), highLow = (uint16)high, highHigh = (uint16)(high >> 16); return ((uint64)(((uint32)(uint16)((lowLow >> 8) | (lowLow << 8)) << 16) | (uint16)((lowHigh >> 8) | (lowHigh << 8))) << 32) | (((uint32)(uint16)((highLow >> 8) | (highLow << 8)) << 16) | (uint16)((highHigh >> 8) | (highHigh << 8))); } #endif /** * A wrapper macro used around four character constants, like 'DATA', to * ensure portability. Typical usage: MKTAG('D','A','T','A'). * * This is required because the C/C++ standard does not define the endianess to * be used for character constants. Hence, if one uses multi-byte character * constants, a potential portability problem opens up. */ #define MKTAG(a0,a1,a2,a3) ((uint32)((a3) | ((a2) << 8) | ((a1) << 16) | ((a0) << 24))) /** * A wrapper macro used around two character constants, like 'wb', to * ensure portability. Typical usage: MKTAG16('w','b'). */ #define MKTAG16(a0,a1) ((uint16)((a1) | ((a0) << 8))) /** @name Functions for reading and writing native integers * @brief Functions for reading and writing native integer values. * They also transparently handle the need for alignment. * @{ */ // Test for GCC and compatible. These implementations will automatically use // CPU-specific instructions for unaligned data when they are available (eg. // MIPS). #if defined(__GNUC__) FORCEINLINE uint16 READ_UINT16(const void *ptr) { struct Unaligned16 { uint16 val; } __attribute__ ((__packed__, __may_alias__)); return ((const Unaligned16 *)ptr)->val; } FORCEINLINE uint32 READ_UINT32(const void *ptr) { struct Unaligned32 { uint32 val; } __attribute__ ((__packed__, __may_alias__)); return ((const Unaligned32 *)ptr)->val; } FORCEINLINE void WRITE_UINT16(void *ptr, uint16 value) { struct Unaligned16 { uint16 val; } __attribute__ ((__packed__, __may_alias__)); ((Unaligned16 *)ptr)->val = value; } FORCEINLINE void WRITE_UINT32(void *ptr, uint32 value) { struct Unaligned32 { uint32 val; } __attribute__ ((__packed__, __may_alias__)); ((Unaligned32 *)ptr)->val = value; } FORCEINLINE uint64 READ_UINT64(const void *ptr) { struct Unaligned64 { uint64 val; } __attribute__ ((__packed__, __may_alias__)); return ((const Unaligned64 *)ptr)->val; } FORCEINLINE void WRITE_UINT64(void *ptr, uint64 value) { struct Unaligned64 { uint64 val; } __attribute__((__packed__, __may_alias__)); ((Unaligned64 *)ptr)->val = value; } #elif !defined(SCUMM_NEED_ALIGNMENT) FORCEINLINE uint16 READ_UINT16(const void *ptr) { return *(const uint16 *)(ptr); } FORCEINLINE uint32 READ_UINT32(const void *ptr) { return *(const uint32 *)(ptr); } FORCEINLINE void WRITE_UINT16(void *ptr, uint16 value) { *(uint16 *)(ptr) = value; } FORCEINLINE void WRITE_UINT32(void *ptr, uint32 value) { *(uint32 *)(ptr) = value; } FORCEINLINE uint64 READ_UINT64(const void *ptr) { return *(const uint64 *)(ptr); } FORCEINLINE void WRITE_UINT64(void *ptr, uint64 value) { *(uint64 *)(ptr) = value; } // use software fallback by loading each byte explicitely #else # if defined(SCUMM_LITTLE_ENDIAN) inline uint16 READ_UINT16(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return (b[1] << 8) | b[0]; } inline uint32 READ_UINT32(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return (b[3] << 24) | (b[2] << 16) | (b[1] << 8) | (b[0]); } inline void WRITE_UINT16(void *ptr, uint16 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 0); b[1] = (uint8)(value >> 8); } inline void WRITE_UINT32(void *ptr, uint32 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 0); b[1] = (uint8)(value >> 8); b[2] = (uint8)(value >> 16); b[3] = (uint8)(value >> 24); } inline uint64 READ_UINT64(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return ((uint64)b[7] << 56) | ((uint64)b[6] << 48) | ((uint64)b[5] << 40) | ((uint64)b[4] << 32) | ((uint64)b[3] << 24) | ((uint64)b[2] << 16) | ((uint64)b[1] << 8) | ((uint64)b[0]); } inline void WRITE_UINT64(void *ptr, uint64 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 0); b[1] = (uint8)(value >> 8); b[2] = (uint8)(value >> 16); b[3] = (uint8)(value >> 24); b[4] = (uint8)(value >> 32); b[5] = (uint8)(value >> 40); b[6] = (uint8)(value >> 48); b[7] = (uint8)(value >> 56); } # elif defined(SCUMM_BIG_ENDIAN) inline uint16 READ_UINT16(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return (b[0] << 8) | b[1]; } inline uint32 READ_UINT32(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return (b[0] << 24) | (b[1] << 16) | (b[2] << 8) | (b[3]); } inline void WRITE_UINT16(void *ptr, uint16 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 8); b[1] = (uint8)(value >> 0); } inline void WRITE_UINT32(void *ptr, uint32 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 24); b[1] = (uint8)(value >> 16); b[2] = (uint8)(value >> 8); b[3] = (uint8)(value >> 0); } inline uint64 READ_UINT64(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return ((uint64)b[0] << 56) | ((uint64)b[1] << 48) | ((uint64)b[2] << 40) | ((uint64)b[3] << 32) | ((uint64)b[4] << 24) | ((uint64)b[5] << 16) | ((uint64)b[6] << 8) | ((uint64)b[7]); } inline void WRITE_UINT64(void *ptr, uint64 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 56); b[1] = (uint8)(value >> 48); b[2] = (uint8)(value >> 40); b[3] = (uint8)(value >> 32); b[4] = (uint8)(value >> 24); b[5] = (uint8)(value >> 16); b[6] = (uint8)(value >> 8); b[7] = (uint8)(value >> 0); } # endif /** @} */ #endif /** @name Map functions for reading/writing BE/LE integers depending on native endianess * @{ */ #if defined(SCUMM_LITTLE_ENDIAN) #define READ_LE_UINT16(a) READ_UINT16(a) #define READ_LE_UINT32(a) READ_UINT32(a) #define WRITE_LE_UINT16(a, v) WRITE_UINT16(a, v) #define WRITE_LE_UINT32(a, v) WRITE_UINT32(a, v) #define FROM_LE_32(a) ((uint32)(a)) #define FROM_LE_16(a) ((uint16)(a)) #define FROM_BE_32(a) SWAP_BYTES_32(a) #define FROM_BE_16(a) SWAP_BYTES_16(a) #define TO_LE_32(a) ((uint32)(a)) #define TO_LE_16(a) ((uint16)(a)) #define TO_BE_32(a) SWAP_BYTES_32(a) #define TO_BE_16(a) SWAP_BYTES_16(a) #define CONSTANT_LE_32(a) ((uint32)(a)) #define CONSTANT_LE_16(a) ((uint16)(a)) #define CONSTANT_BE_32(a) SWAP_CONSTANT_32(a) #define CONSTANT_BE_16(a) SWAP_CONSTANT_16(a) #define READ_LE_UINT64(a) READ_UINT64(a) #define WRITE_LE_UINT64(a, v) WRITE_UINT64(a, v) #define FROM_LE_64(a) ((uint64)(a)) #define FROM_BE_64(a) SWAP_BYTES_64(a) #define TO_LE_64(a) ((uint64)(a)) #define TO_BE_64(a) SWAP_BYTES_64(a) #define CONSTANT_LE_64(a) ((uint64)(a)) #define CONSTANT_BE_64(a) SWAP_CONSTANT_64(a) /** @} */ /** @name Functions for directly reading/writing and inverting * @brief Use these in case the unaligned load and byteswap take * a lot of instructions. * @{ */ # if defined(SCUMM_NEED_ALIGNMENT) && !defined(__mips__) inline uint16 READ_BE_UINT16(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return (b[0] << 8) | b[1]; } inline uint32 READ_BE_UINT32(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return (b[0] << 24) | (b[1] << 16) | (b[2] << 8) | (b[3]); } inline void WRITE_BE_UINT16(void *ptr, uint16 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 8); b[1] = (uint8)(value >> 0); } inline void WRITE_BE_UINT32(void *ptr, uint32 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 24); b[1] = (uint8)(value >> 16); b[2] = (uint8)(value >> 8); b[3] = (uint8)(value >> 0); } inline uint64 READ_BE_UINT64(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return ((uint64)b[0] << 56) | ((uint64)b[1] << 48) | ((uint64)b[2] << 40) | ((uint64)b[3] << 32) | ((uint64)b[4] << 24) | ((uint64)b[5] << 16) | ((uint64)b[6] << 8) | ((uint64)b[7]); } inline void WRITE_BE_UINT64(void *ptr, uint64 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 56); b[1] = (uint8)(value >> 48); b[2] = (uint8)(value >> 40); b[3] = (uint8)(value >> 32); b[4] = (uint8)(value >> 24); b[5] = (uint8)(value >> 16); b[6] = (uint8)(value >> 8); b[7] = (uint8)(value >> 0); } # else inline uint16 READ_BE_UINT16(const void *ptr) { return SWAP_BYTES_16(READ_UINT16(ptr)); } inline uint32 READ_BE_UINT32(const void *ptr) { return SWAP_BYTES_32(READ_UINT32(ptr)); } inline void WRITE_BE_UINT16(void *ptr, uint16 value) { WRITE_UINT16(ptr, SWAP_BYTES_16(value)); } inline void WRITE_BE_UINT32(void *ptr, uint32 value) { WRITE_UINT32(ptr, SWAP_BYTES_32(value)); } inline uint64 READ_BE_UINT64(const void *ptr) { return SWAP_BYTES_64(READ_UINT64(ptr)); } inline void WRITE_BE_UINT64(void *ptr, uint64 value) { WRITE_UINT64(ptr, SWAP_BYTES_64(value)); } # endif // if defined(SCUMM_NEED_ALIGNMENT) #elif defined(SCUMM_BIG_ENDIAN) #define READ_BE_UINT16(a) READ_UINT16(a) #define READ_BE_UINT32(a) READ_UINT32(a) #define WRITE_BE_UINT16(a, v) WRITE_UINT16(a, v) #define WRITE_BE_UINT32(a, v) WRITE_UINT32(a, v) #define FROM_LE_32(a) SWAP_BYTES_32(a) #define FROM_LE_16(a) SWAP_BYTES_16(a) #define FROM_BE_32(a) ((uint32)(a)) #define FROM_BE_16(a) ((uint16)(a)) #define TO_LE_32(a) SWAP_BYTES_32(a) #define TO_LE_16(a) SWAP_BYTES_16(a) #define TO_BE_32(a) ((uint32)(a)) #define TO_BE_16(a) ((uint16)(a)) #define CONSTANT_LE_32(a) SWAP_CONSTANT_32(a) #define CONSTANT_LE_16(a) SWAP_CONSTANT_16(a) #define CONSTANT_BE_32(a) ((uint32)(a)) #define CONSTANT_BE_16(a) ((uint16)(a)) #define READ_BE_UINT64(a) READ_UINT64(a) #define WRITE_BE_UINT64(a, v) WRITE_UINT64(a, v) #define FROM_LE_64(a) SWAP_BYTES_64(a) #define FROM_BE_64(a) ((uint64)(a)) #define TO_LE_64(a) SWAP_BYTES_64(a) #define TO_BE_64(a) ((uint64)(a)) #define CONSTANT_LE_64(a) SWAP_CONSTANT_64(a) #define CONSTANT_BE_64(a) ((uint64)(a)) // if the unaligned load and the byteswap take alot instructions its better to directly read and invert # if defined(SCUMM_NEED_ALIGNMENT) && !defined(__mips__) inline uint16 READ_LE_UINT16(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return (b[1] << 8) | b[0]; } inline uint32 READ_LE_UINT32(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return (b[3] << 24) | (b[2] << 16) | (b[1] << 8) | (b[0]); } inline void WRITE_LE_UINT16(void *ptr, uint16 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 0); b[1] = (uint8)(value >> 8); } inline void WRITE_LE_UINT32(void *ptr, uint32 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 0); b[1] = (uint8)(value >> 8); b[2] = (uint8)(value >> 16); b[3] = (uint8)(value >> 24); } inline uint64 READ_LE_UINT64(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return ((uint64)b[7] << 56) | ((uint64)b[6] << 48) | ((uint64)b[5] << 40) | ((uint64)b[4] << 32) | ((uint64)b[3] << 24) | ((uint64)b[2] << 16) | ((uint64)b[1] << 8) | ((uint64)b[0]); } inline void WRITE_LE_UINT64(void *ptr, uint64 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 0); b[1] = (uint8)(value >> 8); b[2] = (uint8)(value >> 16); b[3] = (uint8)(value >> 24); b[4] = (uint8)(value >> 32); b[5] = (uint8)(value >> 40); b[6] = (uint8)(value >> 48); b[7] = (uint8)(value >> 56); } # else inline uint16 READ_LE_UINT16(const void *ptr) { return SWAP_BYTES_16(READ_UINT16(ptr)); } inline uint32 READ_LE_UINT32(const void *ptr) { return SWAP_BYTES_32(READ_UINT32(ptr)); } inline void WRITE_LE_UINT16(void *ptr, uint16 value) { WRITE_UINT16(ptr, SWAP_BYTES_16(value)); } inline void WRITE_LE_UINT32(void *ptr, uint32 value) { WRITE_UINT32(ptr, SWAP_BYTES_32(value)); } inline uint64 READ_LE_UINT64(const void *ptr) { return SWAP_BYTES_64(READ_UINT64(ptr)); } inline void WRITE_LE_UINT64(void *ptr, uint64 value) { WRITE_UINT64(ptr, SWAP_BYTES_64(value)); } # endif // if defined(SCUMM_NEED_ALIGNMENT) #endif // if defined(SCUMM_LITTLE_ENDIAN) inline uint32 READ_LE_UINT24(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return (b[2] << 16) | (b[1] << 8) | (b[0]); } inline void WRITE_LE_UINT24(void *ptr, uint32 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 0); b[1] = (uint8)(value >> 8); b[2] = (uint8)(value >> 16); } inline uint32 READ_BE_UINT24(const void *ptr) { const uint8 *b = (const uint8 *)ptr; return (b[0] << 16) | (b[1] << 8) | (b[2]); } inline void WRITE_BE_UINT24(void *ptr, uint32 value) { uint8 *b = (uint8 *)ptr; b[0] = (uint8)(value >> 16); b[1] = (uint8)(value >> 8); b[2] = (uint8)(value >> 0); } #ifdef SCUMM_LITTLE_ENDIAN #define READ_UINT24(a) READ_LE_UINT24(a) #define WRITE_UINT24(a,b) WRITE_LE_UINT24(a,b) #else #define READ_UINT24(a) READ_BE_UINT24(a) #define WRITE_UINT24(a,b) WRITE_BE_UINT24(a,b) #endif union SwapFloat { float f; uint32 u32; }; STATIC_ASSERT(sizeof(float) == sizeof(uint32), Unexpected_size_of_float); inline float READ_LE_FLOAT32(const void *ptr) { SwapFloat swap; swap.u32 = READ_LE_UINT32(ptr); return swap.f; } inline void WRITE_LE_FLOAT32(void *ptr, float value) { SwapFloat swap; swap.f = value; WRITE_LE_UINT32(ptr, swap.u32); } inline float READ_BE_FLOAT32(const void *ptr) { SwapFloat swap; swap.u32 = READ_BE_UINT32(ptr); return swap.f; } inline void WRITE_BE_FLOAT32(void *ptr, float value) { SwapFloat swap; swap.f = value; WRITE_BE_UINT32(ptr, swap.u32); } #ifdef SCUMM_LITTLE_ENDIAN #define READ_FLOAT32(a) READ_LE_FLOAT32(a) #define WRITE_FLOAT32(a,b) WRITE_LE_FLOAT32(a,b) #else #define READ_FLOAT32(a) READ_BE_FLOAT32(a) #define WRITE_FLOAT32(a,b) WRITE_BE_FLOAT32(a,b) #endif #ifdef SCUMM_FLOAT_WORD_LITTLE_ENDIAN union SwapDouble { double d; uint64 u64; struct { uint32 low, high; } u32; }; #else union SwapDouble { double d; uint64 u64; struct { uint32 high, low; } u32; }; #endif #ifndef __DC__ STATIC_ASSERT(sizeof(double) == sizeof(uint64), Unexpected_size_of_double); #endif inline double READ_LE_FLOAT64(const void *ptr) { SwapDouble swap; const uint8 *b = (const uint8 *)ptr; swap.u32.low = READ_LE_UINT32(b); swap.u32.high = READ_LE_UINT32(b + 4); return swap.d; } inline void WRITE_LE_FLOAT64(void *ptr, double value) { SwapDouble swap; swap.d = value; uint8 *b = (uint8 *)ptr; WRITE_LE_UINT32(b, swap.u32.low); WRITE_LE_UINT32(b + 4, swap.u32.high); } inline double READ_BE_FLOAT64(const void *ptr) { SwapDouble swap; const uint8 *b = (const uint8 *)ptr; swap.u32.high = READ_BE_UINT32(b); swap.u32.low = READ_BE_UINT32(b + 4); return swap.d; } inline void WRITE_BE_FLOAT64(void *ptr, double value) { SwapDouble swap; swap.d = value; uint8 *b = (uint8 *)ptr; WRITE_BE_UINT32(b, swap.u32.high); WRITE_BE_UINT32(b + 4, swap.u32.low); } inline double READ_FPA_FLOAT64(const void *ptr) { SwapDouble swap; const uint8 *b = (const uint8 *)ptr; swap.u32.high = READ_LE_UINT32(b); swap.u32.low = READ_LE_UINT32(b + 4); return swap.d; } inline void WRITE_FPA_FLOAT64(void *ptr, double value) { SwapDouble swap; swap.d = value; uint8 *b = (uint8 *)ptr; WRITE_LE_UINT32(b, swap.u32.high); WRITE_LE_UINT32(b + 4, swap.u32.low); } inline double READ_FLOAT64(const void *ptr) { SwapDouble swap; swap.u64 = READ_UINT64(ptr); return swap.d; } inline void WRITE_FLOAT64(void *ptr, double value) { SwapDouble swap; swap.d = value; WRITE_UINT64(ptr, swap.u64); } inline int16 READ_LE_INT16(const void *ptr) { return static_cast(READ_LE_UINT16(ptr)); } inline void WRITE_LE_INT16(void *ptr, int16 value) { WRITE_LE_UINT16(ptr, static_cast(value)); } inline int16 READ_BE_INT16(const void *ptr) { return static_cast(READ_BE_UINT16(ptr)); } inline void WRITE_BE_INT16(void *ptr, int16 value) { WRITE_BE_UINT16(ptr, static_cast(value)); } inline int32 READ_LE_INT32(const void *ptr) { return static_cast(READ_LE_UINT32(ptr)); } inline void WRITE_LE_INT32(void *ptr, int32 value) { WRITE_LE_UINT32(ptr, static_cast(value)); } inline int32 READ_BE_INT32(const void *ptr) { return static_cast(READ_BE_UINT32(ptr)); } inline void WRITE_BE_INT32(void *ptr, int32 value) { WRITE_BE_UINT32(ptr, static_cast(value)); } /** @} */ /** @} */ #endif