// basisu.h // Copyright (C) 2019-2026 Binomial LLC. All Rights Reserved. // Important: If compiling with gcc, be sure strict aliasing is disabled: -fno-strict-aliasing // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #pragma once #ifndef BASISD_SUPPORT_XUASTC #define BASISD_SUPPORT_XUASTC 1 #endif #ifdef _MSC_VER #pragma warning (disable : 4201) #pragma warning (disable : 4127) // warning C4127: conditional expression is constant #pragma warning (disable : 4530) // C++ exception handler used, but unwind semantics are not enabled. #endif // _MSC_VER #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "basisu_containers.h" // We never use min/max macros, slam them to off. #ifdef max #undef max #endif #ifdef min #undef min #endif #ifdef _WIN32 #define strcasecmp _stricmp #endif // Set to one to enable debug printf()'s when any errors occur, for development/debugging. Especially useful for WebGL development. #ifndef BASISU_FORCE_DEVEL_MESSAGES // Do not check in as 1! #define BASISU_FORCE_DEVEL_MESSAGES 0 #endif #define BASISU_NOTE_UNUSED(x) (void)(x) #define BASISU_ARRAY_SIZE(x) (sizeof(x) / sizeof(x[0])) #define BASISU_NO_EQUALS_OR_COPY_CONSTRUCT(x) x(const x &) = delete; x& operator= (const x &) = delete; #define BASISU_ASSUME(x) static_assert(x, #x); #define BASISU_OFFSETOF(s, m) offsetof(s, m) #define BASISU_STRINGIZE(x) #x #define BASISU_STRINGIZE2(x) BASISU_STRINGIZE(x) #if BASISU_FORCE_DEVEL_MESSAGES #define BASISU_DEVEL_ERROR(...) do { basisu::debug_printf(__VA_ARGS__); } while(0) #else #define BASISU_DEVEL_ERROR(...) #endif namespace basisu { // Types/utilities #ifdef _WIN32 const char BASISU_PATH_SEPERATOR_CHAR = '\\'; #else const char BASISU_PATH_SEPERATOR_CHAR = '/'; #endif typedef basisu::vector uint8_vec; typedef basisu::vector int16_vec; typedef basisu::vector uint16_vec; typedef basisu::vector uint_vec; typedef basisu::vector size_t_vec; typedef basisu::vector uint64_vec; typedef basisu::vector int_vec; typedef basisu::vector bool_vec; typedef basisu::vector float_vec; typedef basisu::vector double_vec; void enable_debug_printf(bool enabled); void debug_printf(const char *pFmt, ...); void debug_puts(const char* p); template inline void fmt_debug_printf(const char* pFmt, Args&&... args) { std::string res; if (!fmt_variants(res, pFmt, fmt_variant_vec{ fmt_variant(std::forward(args))... })) return; debug_puts(res.c_str()); } #if defined(__GNUC__) && !defined(__clang__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wclass-memaccess" #endif template inline void clear_obj(T& obj) { memset((void *)&obj, 0, sizeof(obj)); } #if defined(__GNUC__) && !defined(__clang__) #pragma GCC diagnostic pop #endif constexpr double cPiD = 3.14159265358979323846264338327950288; constexpr float REALLY_SMALL_FLOAT_VAL = .000000125f; constexpr float SMALL_FLOAT_VAL = .0000125f; constexpr float BIG_FLOAT_VAL = 1e+30f; template inline T0 lerp(T0 a, T0 b, T1 c) { return a + (b - a) * c; } inline float clampf(float value, float low, float high) { if (value < low) value = low; else if (value > high) value = high; return value; } inline float saturate(float value) { return clampf(value, 0, 1.0f); } inline uint8_t minimumub(uint8_t a, uint8_t b) { return (a < b) ? a : b; } inline uint32_t minimumu(uint32_t a, uint32_t b) { return (a < b) ? a : b; } inline int32_t minimumi(int32_t a, int32_t b) { return (a < b) ? a : b; } inline float minimumf(float a, float b) { return (a < b) ? a : b; } inline uint8_t maximumub(uint8_t a, uint8_t b) { return (a > b) ? a : b; } inline uint32_t maximumu(uint32_t a, uint32_t b) { return (a > b) ? a : b; } inline int32_t maximumi(int32_t a, int32_t b) { return (a > b) ? a : b; } inline float maximumf(float a, float b) { return (a > b) ? a : b; } inline int squarei(int i) { return i * i; } inline float squaref(float i) { return i * i; } inline double squared(double i) { return i * i; } template inline T square(T a) { return a * a; } template inline T sign(T a) { return (a < 0) ? (T)-1 : ((a == 0) ? (T)0 : (T)1); } inline int imod(int i, int d) { assert(i != INT_MIN); if (i >= 0) return i % d; int r = (-i) % d; return (r == 0) ? 0 : d - r; } inline uint8_t safe_cast_uint8(uint32_t x) { assert(x <= UINT8_MAX); return (uint8_t)x; } inline int8_t safe_cast_int8(int32_t x) { assert((x >= INT8_MIN) && (x <= INT8_MAX)); return (int8_t)x; } inline uint16_t safe_cast_uint16(uint32_t x) { assert(x <= UINT16_MAX); return (uint16_t)x; } inline int16_t safe_cast_int16(int32_t x) { assert((x >= INT16_MIN) && (x <= INT16_MAX)); return (int16_t)x; } inline bool equal_tol(float a, float b, float t) { return fabsf(a - b) <= ((maximum(fabsf(a), fabsf(b)) + 1.0f) * t); } inline bool equal_tol(double a, double b, double t) { return fabs(a - b) <= ((maximum(fabs(a), fabs(b)) + 1.0f) * t); } template inline T prev_wrap(T i, T n) { T temp = i - 1; if (temp < 0) temp = n - 1; return temp; } template inline T next_wrap(T i, T n) { T temp = i + 1; if (temp >= n) temp = 0; return temp; } inline uint32_t iabs(int32_t i) { return (i < 0) ? static_cast(-i) : static_cast(i); } inline uint64_t iabs64(int64_t i) { return (i < 0) ? static_cast(-i) : static_cast(i); } template inline void clear_vector(T &vec) { vec.erase(vec.begin(), vec.end()); } template inline typename T::value_type *enlarge_vector(T &vec, size_t n) { size_t cs = vec.size(); vec.resize(cs + n); return &vec[cs]; } inline bool is_pow2(uint32_t x) { return x && ((x & (x - 1U)) == 0U); } inline bool is_pow2(uint64_t x) { return x && ((x & (x - 1U)) == 0U); } template inline T range_check(T v, T minv, T maxv) { assert(v >= minv && v <= maxv); BASISU_NOTE_UNUSED(minv); BASISU_NOTE_UNUSED(maxv); return v; } template inline T range_check(T v, T maxv) { assert(v <= maxv); BASISU_NOTE_UNUSED(maxv); return v; } template inline T open_range_check(T v, T minv, T maxv) { assert(v >= minv && v < maxv); BASISU_NOTE_UNUSED(minv); BASISU_NOTE_UNUSED(maxv); return v; } template inline T open_range_check(T v, T maxv) { assert(v < maxv); BASISU_NOTE_UNUSED(maxv); return v; } // Open interval inline bool is_in_bounds(int v, int l, int h) { return (v >= l) && (v < h); } // Closed interval inline bool is_in_range(int v, int l, int h) { return (v >= l) && (v <= h); } inline bool is_in_range(float v, float l, float h) { return (v >= l) && (v <= h); } inline uint32_t total_bits(uint32_t v) { uint32_t l = 0; for ( ; v > 0U; ++l) v >>= 1; return l; } template inline T saturate(T val) { return clamp(val, 0.0f, 1.0f); } inline uint32_t get_bit(uint32_t src, int ndx) { assert(is_in_bounds(ndx, 0, 32)); return (src >> ndx) & 1; } inline bool is_bit_set(uint32_t src, int ndx) { return get_bit(src, ndx) != 0; } inline uint32_t get_bits(uint32_t val, int low, int high) { const int num_bits = (high - low) + 1; assert(is_in_range(num_bits, 1, 32)); val >>= low; if (num_bits != 32) val &= ((1u << num_bits) - 1); return val; } template inline void append_vector(T &vec, const R *pObjs, size_t n) { if (n) { if (vec.size()) { assert((pObjs + n) <= vec.begin() || (pObjs >= vec.end())); } const size_t cur_s = vec.size(); vec.resize(cur_s + n); memcpy(&vec[cur_s], pObjs, sizeof(R) * n); } } template inline void append_vector(T &vec, const T &other_vec) { assert(&vec != &other_vec); if (other_vec.size()) append_vector(vec, &other_vec[0], other_vec.size()); } template inline void vector_ensure_element_is_valid(T &vec, size_t idx) { if (idx >= vec.size()) vec.resize(idx + 1); } template inline void vector_sort(T &vec) { if (vec.size()) std::sort(vec.begin(), vec.end()); } template inline bool unordered_set_contains(T& set, const U&obj) { return set.find(obj) != set.end(); } template int vector_find(const T &vec, const typename T::value_type &obj) { assert(vec.size() <= INT_MAX); for (size_t i = 0; i < vec.size(); i++) if (vec[i] == obj) return static_cast(i); return -1; } template void vector_set_all(T &vec, const typename T::value_type &obj) { for (size_t i = 0; i < vec.size(); i++) vec[i] = obj; } inline uint64_t read_be64(const void *p) { uint64_t val = 0; for (uint32_t i = 0; i < 8; i++) val |= (static_cast(static_cast(p)[7 - i]) << (i * 8)); return val; } inline void write_be64(void *p, uint64_t x) { for (uint32_t i = 0; i < 8; i++) static_cast(p)[7 - i] = static_cast(x >> (i * 8)); } static inline uint16_t byteswap16(uint16_t x) { return static_cast((x << 8) | (x >> 8)); } static inline uint32_t byteswap32(uint32_t x) { return ((x << 24) | ((x << 8) & 0x00FF0000) | ((x >> 8) & 0x0000FF00) | (x >> 24)); } inline uint32_t floor_log2i(uint32_t v) { uint32_t b = 0; for (; v > 1U; ++b) v >>= 1; return b; } inline uint32_t ceil_log2i(uint32_t v) { uint32_t b = floor_log2i(v); if ((b != 32) && (v > (1U << b))) ++b; return b; } inline int posmod(int x, int y) { if (x >= 0) return (x < y) ? x : (x % y); int m = (-x) % y; return (m != 0) ? (y - m) : m; } inline float posmodf(float x, float y) { float m = fmodf(x, y); if (m < 0.0f) m += y; return m; } inline bool do_excl_ranges_overlap(int la, int ha, int lb, int hb) { assert(la < ha && lb < hb); if ((ha <= lb) || (la >= hb)) return false; return true; } static inline uint32_t read_le_word(const uint8_t* pBytes) { return (pBytes[1] << 8U) | (pBytes[0]); } static inline uint32_t read_le_dword(const uint8_t *pBytes) { return (pBytes[3] << 24U) | (pBytes[2] << 16U) | (pBytes[1] << 8U) | (pBytes[0]); } static inline void write_le_dword(uint8_t* pBytes, uint32_t val) { pBytes[0] = (uint8_t)val; pBytes[1] = (uint8_t)(val >> 8U); pBytes[2] = (uint8_t)(val >> 16U); pBytes[3] = (uint8_t)(val >> 24U); } // Always little endian 1-8 byte unsigned int template struct packed_uint { uint8_t m_bytes[NumBytes]; inline packed_uint() { static_assert(NumBytes <= sizeof(uint64_t), "Invalid NumBytes"); } inline packed_uint(uint64_t v) { *this = v; } inline packed_uint(const packed_uint& other) { *this = other; } inline packed_uint& operator= (uint64_t v) { // TODO: Add assert on truncation? for (uint32_t i = 0; i < NumBytes; i++) m_bytes[i] = static_cast(v >> (i * 8)); return *this; } inline packed_uint& operator= (const packed_uint& rhs) { memcpy(m_bytes, rhs.m_bytes, sizeof(m_bytes)); return *this; } inline uint64_t get_uint64() const { // Some compilers may warn about this code. It clearly cannot access beyond the end of the m_bytes struct here. if constexpr (NumBytes == 1) { return m_bytes[0]; } else if constexpr (NumBytes == 2) { return (m_bytes[1] << 8U) | m_bytes[0]; } else if constexpr (NumBytes == 3) { return (m_bytes[2] << 16U) | (m_bytes[1] << 8U) | m_bytes[0]; } else if constexpr (NumBytes == 4) { return read_le_dword(m_bytes); } else if constexpr (NumBytes == 5) { uint32_t l = read_le_dword(m_bytes); uint32_t h = m_bytes[4]; return static_cast(l) | (static_cast(h) << 32U); } else if constexpr (NumBytes == 6) { uint32_t l = read_le_dword(m_bytes); uint32_t h = (m_bytes[5] << 8U) | m_bytes[4]; return static_cast(l) | (static_cast(h) << 32U); } else if constexpr (NumBytes == 7) { uint32_t l = read_le_dword(m_bytes); uint32_t h = (m_bytes[6] << 16U) | (m_bytes[5] << 8U) | m_bytes[4]; return static_cast(l) | (static_cast(h) << 32U); } else if constexpr (NumBytes == 8) { uint32_t l = read_le_dword(m_bytes); uint32_t h = read_le_dword(m_bytes + 4); return static_cast(l) | (static_cast(h) << 32U); } else { static_assert(NumBytes <= 8, "Invalid NumBytes"); return 0; } } inline uint32_t get_uint32() const { static_assert(NumBytes <= sizeof(uint32_t), "packed_uint too large to use get_uint32"); return static_cast(get_uint64()); } inline operator uint32_t() const { static_assert(NumBytes <= sizeof(uint32_t), "packed_uint too large to use operator uint32_t"); return static_cast(get_uint64()); } }; enum eZero { cZero }; enum eNoClamp { cNoClamp }; // Rice/Huffman entropy coding // This is basically Deflate-style canonical Huffman, except we allow for a lot more symbols. enum { cHuffmanMaxSupportedCodeSize = 16, cHuffmanMaxSupportedInternalCodeSize = 31, cHuffmanFastLookupBits = 10, cHuffmanMaxSymsLog2 = 14, cHuffmanMaxSyms = 1 << cHuffmanMaxSymsLog2, // Small zero runs cHuffmanSmallZeroRunSizeMin = 3, cHuffmanSmallZeroRunSizeMax = 10, cHuffmanSmallZeroRunExtraBits = 3, // Big zero run cHuffmanBigZeroRunSizeMin = 11, cHuffmanBigZeroRunSizeMax = 138, cHuffmanBigZeroRunExtraBits = 7, // Small non-zero run cHuffmanSmallRepeatSizeMin = 3, cHuffmanSmallRepeatSizeMax = 6, cHuffmanSmallRepeatExtraBits = 2, // Big non-zero run cHuffmanBigRepeatSizeMin = 7, cHuffmanBigRepeatSizeMax = 134, cHuffmanBigRepeatExtraBits = 7, cHuffmanTotalCodelengthCodes = 21, cHuffmanSmallZeroRunCode = 17, cHuffmanBigZeroRunCode = 18, cHuffmanSmallRepeatCode = 19, cHuffmanBigRepeatCode = 20 }; static const uint8_t g_huffman_sorted_codelength_codes[] = { cHuffmanSmallZeroRunCode, cHuffmanBigZeroRunCode, cHuffmanSmallRepeatCode, cHuffmanBigRepeatCode, 0, 8, 7, 9, 6, 0xA, 5, 0xB, 4, 0xC, 3, 0xD, 2, 0xE, 1, 0xF, 0x10 }; const uint32_t cHuffmanTotalSortedCodelengthCodes = sizeof(g_huffman_sorted_codelength_codes) / sizeof(g_huffman_sorted_codelength_codes[0]); // GPU texture formats and various uncompressed texture formats. enum class texture_format { cInvalidTextureFormat = -1, // Block-based formats cETC1, // ETC1 cETC1S, // ETC1 (subset: diff colors only, no subblocks) cETC2_RGB, // ETC2 color block (basisu doesn't support ETC2 planar/T/H modes - just basic ETC1) cETC2_RGBA, // ETC2 EAC alpha block followed by ETC2 color block cETC2_ALPHA, // ETC2 EAC alpha block cBC1, // DXT1 cBC3, // DXT5 (BC4/DXT5A block followed by a BC1/DXT1 block) cBC4, // DXT5A cBC5, // 3DC/DXN (two BC4/DXT5A blocks) cBC6HSigned, // HDR cBC6HUnsigned, // HDR cBC7, cASTC_LDR_4x4, // ASTC 4x4 LDR only cASTC_HDR_4x4, // ASTC 4x4 HDR only (but may use LDR ASTC blocks internally, although our encoders don't do this) cASTC_HDR_6x6, // ASTC 6x6 HDR only (but may use LDR ASTC blocks internally, although our encoders don't do this) cPVRTC1_4_RGB, cPVRTC1_4_RGBA, cATC_RGB, cATC_RGBA_INTERPOLATED_ALPHA, cFXT1_RGB, cPVRTC2_4_RGBA, cETC2_R11_EAC, cETC2_RG11_EAC, cUASTC4x4, cUASTC_HDR_4x4, cBC1_NV, cBC1_AMD, // Uncompressed/raw pixels cRGBA32, cRGB565, cBGR565, cRGBA4444, cABGR4444, cRGBA_HALF, cRGB_HALF, cRGB_9E5, // All remaining ASTC LDR block size variants (other than 4x4 which is above). There are 14 total ASTC block sizes, including 4x4. cASTC_LDR_5x4, cASTC_LDR_5x5, cASTC_LDR_6x5, cASTC_LDR_6x6, cASTC_LDR_8x5, cASTC_LDR_8x6, cASTC_LDR_10x5, cASTC_LDR_10x6, cASTC_LDR_8x8, cASTC_LDR_10x8, cASTC_LDR_10x10, cASTC_LDR_12x10, cASTC_LDR_12x12 }; inline bool is_astc(texture_format fmt) { switch (fmt) { case texture_format::cASTC_HDR_4x4: case texture_format::cASTC_HDR_6x6: case texture_format::cASTC_LDR_4x4: case texture_format::cASTC_LDR_5x4: case texture_format::cASTC_LDR_5x5: case texture_format::cASTC_LDR_6x5: case texture_format::cASTC_LDR_6x6: case texture_format::cASTC_LDR_8x5: case texture_format::cASTC_LDR_8x6: case texture_format::cASTC_LDR_10x5: case texture_format::cASTC_LDR_10x6: case texture_format::cASTC_LDR_8x8: case texture_format::cASTC_LDR_10x8: case texture_format::cASTC_LDR_10x10: case texture_format::cASTC_LDR_12x10: case texture_format::cASTC_LDR_12x12: return true; default: break; } return false; } inline bool is_hdr_astc(texture_format fmt) { switch (fmt) { case texture_format::cASTC_HDR_4x4: case texture_format::cASTC_HDR_6x6: return true; default: break; } return false; } inline bool is_ldr_astc(texture_format fmt) { switch (fmt) { case texture_format::cASTC_LDR_4x4: case texture_format::cASTC_LDR_5x4: case texture_format::cASTC_LDR_5x5: case texture_format::cASTC_LDR_6x5: case texture_format::cASTC_LDR_6x6: case texture_format::cASTC_LDR_8x5: case texture_format::cASTC_LDR_8x6: case texture_format::cASTC_LDR_10x5: case texture_format::cASTC_LDR_10x6: case texture_format::cASTC_LDR_8x8: case texture_format::cASTC_LDR_10x8: case texture_format::cASTC_LDR_10x10: case texture_format::cASTC_LDR_12x10: case texture_format::cASTC_LDR_12x12: return true; default: break; } return false; } inline bool is_uncompressed_texture_format(texture_format fmt) { switch (fmt) { case texture_format::cRGBA32: case texture_format::cRGB565: case texture_format::cBGR565: case texture_format::cRGBA4444: case texture_format::cABGR4444: case texture_format::cRGBA_HALF: case texture_format::cRGB_HALF: case texture_format::cRGB_9E5: return true; default: break; } return false; } inline bool is_block_based_texture_format(texture_format fmt) { return !is_uncompressed_texture_format(fmt); } // This is bytes per block for GPU formats, or bytes per texel for uncompressed formats. inline uint32_t get_bytes_per_block_or_pixel(texture_format fmt) { switch (fmt) { case texture_format::cETC1: case texture_format::cETC1S: case texture_format::cETC2_RGB: case texture_format::cETC2_ALPHA: case texture_format::cBC1: case texture_format::cBC1_NV: case texture_format::cBC1_AMD: case texture_format::cBC4: case texture_format::cPVRTC1_4_RGB: case texture_format::cPVRTC1_4_RGBA: case texture_format::cATC_RGB: case texture_format::cPVRTC2_4_RGBA: case texture_format::cETC2_R11_EAC: return 8; case texture_format::cRGBA32: case texture_format::cRGB_9E5: return sizeof(uint32_t); case texture_format::cRGB_HALF: return sizeof(uint16_t) * 3; case texture_format::cRGBA_HALF: return sizeof(uint16_t) * 4; case texture_format::cRGB565: case texture_format::cBGR565: case texture_format::cRGBA4444: case texture_format::cABGR4444: return sizeof(uint16_t); default: break; } // Everything else is 16 bytes/block. return 16; } // This is qwords per block for GPU formats, or not valid for uncompressed formats. inline uint32_t get_qwords_per_block(texture_format fmt) { assert(is_block_based_texture_format(fmt)); const uint32_t bytes_per_block = get_bytes_per_block_or_pixel(fmt); return bytes_per_block >> 3; } inline uint32_t get_block_width(texture_format fmt) { assert(is_block_based_texture_format(fmt)); switch (fmt) { case texture_format::cFXT1_RGB: return 8; case texture_format::cASTC_HDR_6x6: return 6; case texture_format::cASTC_LDR_5x4: return 5; case texture_format::cASTC_LDR_5x5: return 5; case texture_format::cASTC_LDR_6x5: return 6; case texture_format::cASTC_LDR_6x6: return 6; case texture_format::cASTC_LDR_8x5: return 8; case texture_format::cASTC_LDR_8x6: return 8; case texture_format::cASTC_LDR_10x5: return 10; case texture_format::cASTC_LDR_10x6: return 10; case texture_format::cASTC_LDR_8x8: return 8; case texture_format::cASTC_LDR_10x8: return 10; case texture_format::cASTC_LDR_10x10: return 10; case texture_format::cASTC_LDR_12x10: return 12; case texture_format::cASTC_LDR_12x12: return 12; default: break; } return 4; } inline uint32_t get_block_height(texture_format fmt) { assert(is_block_based_texture_format(fmt)); switch (fmt) { case texture_format::cASTC_HDR_6x6: return 6; case texture_format::cASTC_LDR_5x5: return 5; case texture_format::cASTC_LDR_6x5: return 5; case texture_format::cASTC_LDR_6x6: return 6; case texture_format::cASTC_LDR_8x5: return 5; case texture_format::cASTC_LDR_8x6: return 6; case texture_format::cASTC_LDR_10x5: return 5; case texture_format::cASTC_LDR_10x6: return 6; case texture_format::cASTC_LDR_8x8: return 8; case texture_format::cASTC_LDR_10x8: return 8; case texture_format::cASTC_LDR_10x10: return 10; case texture_format::cASTC_LDR_12x10: return 10; case texture_format::cASTC_LDR_12x12: return 12; default: break; } return 4; } inline bool is_hdr_texture_format(texture_format fmt) { switch (fmt) { case texture_format::cASTC_HDR_4x4: case texture_format::cUASTC_HDR_4x4: case texture_format::cASTC_HDR_6x6: case texture_format::cBC6HSigned: case texture_format::cBC6HUnsigned: case texture_format::cRGBA_HALF: case texture_format::cRGB_HALF: case texture_format::cRGB_9E5: return true; default: break; } return false; } inline bool is_ldr_texture_format(texture_format fmt) { return !is_hdr_texture_format(fmt); } inline texture_format get_astc_ldr_texture_format(uint32_t width, uint32_t height) { #define BU_ASTC_LDR_MATCH_BLOCK_DIM(x, y, f) if ((width == (x)) && (height == (y))) return (f); BU_ASTC_LDR_MATCH_BLOCK_DIM(4, 4, texture_format::cASTC_LDR_4x4); BU_ASTC_LDR_MATCH_BLOCK_DIM(5, 4, texture_format::cASTC_LDR_5x4); BU_ASTC_LDR_MATCH_BLOCK_DIM(5, 5, texture_format::cASTC_LDR_5x5); BU_ASTC_LDR_MATCH_BLOCK_DIM(6, 5, texture_format::cASTC_LDR_6x5); BU_ASTC_LDR_MATCH_BLOCK_DIM(6, 6, texture_format::cASTC_LDR_6x6); BU_ASTC_LDR_MATCH_BLOCK_DIM(8, 5, texture_format::cASTC_LDR_8x5); BU_ASTC_LDR_MATCH_BLOCK_DIM(8, 6, texture_format::cASTC_LDR_8x6); BU_ASTC_LDR_MATCH_BLOCK_DIM(10, 5, texture_format::cASTC_LDR_10x5); BU_ASTC_LDR_MATCH_BLOCK_DIM(10, 6, texture_format::cASTC_LDR_10x6); BU_ASTC_LDR_MATCH_BLOCK_DIM(8, 8, texture_format::cASTC_LDR_8x8); BU_ASTC_LDR_MATCH_BLOCK_DIM(10, 8, texture_format::cASTC_LDR_10x8); BU_ASTC_LDR_MATCH_BLOCK_DIM(10, 10, texture_format::cASTC_LDR_10x10); BU_ASTC_LDR_MATCH_BLOCK_DIM(12, 10, texture_format::cASTC_LDR_12x10); BU_ASTC_LDR_MATCH_BLOCK_DIM(12, 12, texture_format::cASTC_LDR_12x12); #undef BU_ASTC_LDR_MATCH_BLOCK_DIM return texture_format::cInvalidTextureFormat; } inline bool is_valid_astc_block_size(uint32_t width, uint32_t height) { return get_astc_ldr_texture_format(width, height) != texture_format::cInvalidTextureFormat; } } // namespace basisu