/* * Load/Store Operators * (C) 1999-2007 Jack Lloyd * 2007 Yves Jerschow * * Distributed under the terms of the Botan license */ #ifndef BOTAN_LOAD_STORE_H__ #define BOTAN_LOAD_STORE_H__ #include #include #include #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK #if defined(BOTAN_TARGET_CPU_IS_BIG_ENDIAN) #define BOTAN_ENDIAN_N2B(x) (x) #define BOTAN_ENDIAN_B2N(x) (x) #define BOTAN_ENDIAN_N2L(x) reverse_bytes(x) #define BOTAN_ENDIAN_L2N(x) reverse_bytes(x) #elif defined(BOTAN_TARGET_CPU_IS_LITTLE_ENDIAN) #define BOTAN_ENDIAN_N2L(x) (x) #define BOTAN_ENDIAN_L2N(x) (x) #define BOTAN_ENDIAN_N2B(x) reverse_bytes(x) #define BOTAN_ENDIAN_B2N(x) reverse_bytes(x) #endif #endif namespace Botan { /* * Byte Extraction Function */ template inline byte get_byte(u32bit byte_num, T input) { return (input >> ((sizeof(T)-1-(byte_num&(sizeof(T)-1))) << 3)); } /* * Byte to Word Conversions */ inline u16bit make_u16bit(byte i0, byte i1) { return ((static_cast(i0) << 8) | i1); } inline u32bit make_u32bit(byte i0, byte i1, byte i2, byte i3) { return ((static_cast(i0) << 24) | (static_cast(i1) << 16) | (static_cast(i2) << 8) | (static_cast(i3))); } inline u64bit make_u64bit(byte i0, byte i1, byte i2, byte i3, byte i4, byte i5, byte i6, byte i7) { return ((static_cast(i0) << 56) | (static_cast(i1) << 48) | (static_cast(i2) << 40) | (static_cast(i3) << 32) | (static_cast(i4) << 24) | (static_cast(i5) << 16) | (static_cast(i6) << 8) | (static_cast(i7))); } /* * Endian-Specific Word Loading Operations */ template inline T load_be(const byte in[], u32bit off) { in += off * sizeof(T); T out = 0; for(u32bit j = 0; j != sizeof(T); j++) out = (out << 8) | in[j]; return out; } template inline T load_le(const byte in[], u32bit off) { in += off * sizeof(T); T out = 0; for(u32bit j = 0; j != sizeof(T); j++) out = (out << 8) | in[sizeof(T)-1-j]; return out; } template<> inline u16bit load_be(const byte in[], u32bit off) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK return BOTAN_ENDIAN_N2B(*(reinterpret_cast(in) + off)); #else in += off * sizeof(u16bit); return make_u16bit(in[0], in[1]); #endif } template<> inline u16bit load_le(const byte in[], u32bit off) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK return BOTAN_ENDIAN_N2L(*(reinterpret_cast(in) + off)); #else in += off * sizeof(u16bit); return make_u16bit(in[1], in[0]); #endif } template<> inline u32bit load_be(const byte in[], u32bit off) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK return BOTAN_ENDIAN_N2B(*(reinterpret_cast(in) + off)); #else in += off * sizeof(u32bit); return make_u32bit(in[0], in[1], in[2], in[3]); #endif } template<> inline u32bit load_le(const byte in[], u32bit off) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK return BOTAN_ENDIAN_N2L(*(reinterpret_cast(in) + off)); #else in += off * sizeof(u32bit); return make_u32bit(in[3], in[2], in[1], in[0]); #endif } template<> inline u64bit load_be(const byte in[], u32bit off) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK return BOTAN_ENDIAN_N2B(*(reinterpret_cast(in) + off)); #else in += off * sizeof(u64bit); return make_u64bit(in[0], in[1], in[2], in[3], in[4], in[5], in[6], in[7]); #endif } template<> inline u64bit load_le(const byte in[], u32bit off) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK return BOTAN_ENDIAN_N2L(*(reinterpret_cast(in) + off)); #else in += off * sizeof(u64bit); return make_u64bit(in[7], in[6], in[5], in[4], in[3], in[2], in[1], in[0]); #endif } template inline void load_le(const byte in[], T& x0, T& x1) { x0 = load_le(in, 0); x1 = load_le(in, 1); } template inline void load_le(const byte in[], T& x0, T& x1, T& x2, T& x3) { x0 = load_le(in, 0); x1 = load_le(in, 1); x2 = load_le(in, 2); x3 = load_le(in, 3); } template inline void load_le(const byte in[], T& x0, T& x1, T& x2, T& x3, T& x4, T& x5, T& x6, T& x7) { x0 = load_le(in, 0); x1 = load_le(in, 1); x2 = load_le(in, 2); x3 = load_le(in, 3); x4 = load_le(in, 4); x5 = load_le(in, 5); x6 = load_le(in, 6); x7 = load_le(in, 7); } template inline void load_le(T out[], const byte in[], u32bit count) { #if defined(BOTAN_TARGET_CPU_HAS_KNOWN_ENDIANNESS) std::memcpy(out, in, sizeof(T)*count); #if defined(BOTAN_TARGET_CPU_IS_BIG_ENDIAN) const u32bit blocks = count - (count % 4); const u32bit left = count - blocks; for(u32bit i = 0; i != blocks; i += 4) bswap_4(out + i); for(u32bit i = 0; i != left; ++i) out[blocks+i] = reverse_bytes(out[blocks+i]); #endif #else for(u32bit i = 0; i != count; ++i) out[i] = load_le(in, i); #endif } template inline void load_be(const byte in[], T& x0, T& x1) { x0 = load_be(in, 0); x1 = load_be(in, 1); } template inline void load_be(const byte in[], T& x0, T& x1, T& x2, T& x3) { x0 = load_be(in, 0); x1 = load_be(in, 1); x2 = load_be(in, 2); x3 = load_be(in, 3); } template inline void load_be(const byte in[], T& x0, T& x1, T& x2, T& x3, T& x4, T& x5, T& x6, T& x7) { x0 = load_be(in, 0); x1 = load_be(in, 1); x2 = load_be(in, 2); x3 = load_be(in, 3); x4 = load_be(in, 4); x5 = load_be(in, 5); x6 = load_be(in, 6); x7 = load_be(in, 7); } template inline void load_be(T out[], const byte in[], u32bit count) { #if defined(BOTAN_TARGET_CPU_HAS_KNOWN_ENDIANNESS) std::memcpy(out, in, sizeof(T)*count); #if defined(BOTAN_TARGET_CPU_IS_LITTLE_ENDIAN) const u32bit blocks = count - (count % 4); const u32bit left = count - blocks; for(u32bit i = 0; i != blocks; i += 4) bswap_4(out + i); for(u32bit i = 0; i != left; ++i) out[blocks+i] = reverse_bytes(out[blocks+i]); #endif #else for(u32bit i = 0; i != count; ++i) out[i] = load_be(in, i); #endif } /* * Endian-Specific Word Storing Operations */ inline void store_be(u16bit in, byte out[2]) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK *reinterpret_cast(out) = BOTAN_ENDIAN_B2N(in); #else out[0] = get_byte(0, in); out[1] = get_byte(1, in); #endif } inline void store_le(u16bit in, byte out[2]) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK *reinterpret_cast(out) = BOTAN_ENDIAN_L2N(in); #else out[0] = get_byte(1, in); out[1] = get_byte(0, in); #endif } inline void store_be(u32bit in, byte out[4]) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK *reinterpret_cast(out) = BOTAN_ENDIAN_B2N(in); #else out[0] = get_byte(0, in); out[1] = get_byte(1, in); out[2] = get_byte(2, in); out[3] = get_byte(3, in); #endif } inline void store_le(u32bit in, byte out[4]) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK *reinterpret_cast(out) = BOTAN_ENDIAN_L2N(in); #else out[0] = get_byte(3, in); out[1] = get_byte(2, in); out[2] = get_byte(1, in); out[3] = get_byte(0, in); #endif } inline void store_be(u64bit in, byte out[8]) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK *reinterpret_cast(out) = BOTAN_ENDIAN_B2N(in); #else out[0] = get_byte(0, in); out[1] = get_byte(1, in); out[2] = get_byte(2, in); out[3] = get_byte(3, in); out[4] = get_byte(4, in); out[5] = get_byte(5, in); out[6] = get_byte(6, in); out[7] = get_byte(7, in); #endif } inline void store_le(u64bit in, byte out[8]) { #if BOTAN_TARGET_UNALIGNED_MEMORY_ACCESS_OK *reinterpret_cast(out) = BOTAN_ENDIAN_L2N(in); #else out[0] = get_byte(7, in); out[1] = get_byte(6, in); out[2] = get_byte(5, in); out[3] = get_byte(4, in); out[4] = get_byte(3, in); out[5] = get_byte(2, in); out[6] = get_byte(1, in); out[7] = get_byte(0, in); #endif } template inline void store_le(byte out[], T x0, T x1) { store_le(x0, out + (0 * sizeof(T))); store_le(x1, out + (1 * sizeof(T))); } template inline void store_be(byte out[], T x0, T x1) { store_be(x0, out + (0 * sizeof(T))); store_be(x1, out + (1 * sizeof(T))); } template inline void store_le(byte out[], T x0, T x1, T x2, T x3) { store_le(x0, out + (0 * sizeof(T))); store_le(x1, out + (1 * sizeof(T))); store_le(x2, out + (2 * sizeof(T))); store_le(x3, out + (3 * sizeof(T))); } template inline void store_be(byte out[], T x0, T x1, T x2, T x3) { store_be(x0, out + (0 * sizeof(T))); store_be(x1, out + (1 * sizeof(T))); store_be(x2, out + (2 * sizeof(T))); store_be(x3, out + (3 * sizeof(T))); } template inline void store_le(byte out[], T x0, T x1, T x2, T x3, T x4, T x5, T x6, T x7) { store_le(x0, out + (0 * sizeof(T))); store_le(x1, out + (1 * sizeof(T))); store_le(x2, out + (2 * sizeof(T))); store_le(x3, out + (3 * sizeof(T))); store_le(x4, out + (4 * sizeof(T))); store_le(x5, out + (5 * sizeof(T))); store_le(x6, out + (6 * sizeof(T))); store_le(x7, out + (7 * sizeof(T))); } template inline void store_be(byte out[], T x0, T x1, T x2, T x3, T x4, T x5, T x6, T x7) { store_be(x0, out + (0 * sizeof(T))); store_be(x1, out + (1 * sizeof(T))); store_be(x2, out + (2 * sizeof(T))); store_be(x3, out + (3 * sizeof(T))); store_be(x4, out + (4 * sizeof(T))); store_be(x5, out + (5 * sizeof(T))); store_be(x6, out + (6 * sizeof(T))); store_be(x7, out + (7 * sizeof(T))); } } #endif