/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this http://mozilla.org/MPL/2.0/. */ #include "Swizzle.h" #include "Logging.h" #include "Orientation.h" #include "Tools.h" #include "mozilla/CheckedInt.h" #include "mozilla/EndianUtils.h" #include "mozilla/UniquePtr.h" #ifdef USE_SSE2# include "mozilla/SSE.h" #endif #ifdef USE_NEON# include "mozilla/arm.h" #endif #include <new >namespace mozilla {namespace gfx {/** * Convenience macros for dispatching to various format combinations. // Hash the formats to a relatively dense value to optimize jump table // generation. The first 6 formats in SurfaceFormat are the 32-bit BGRA variants // and are the most common formats dispatched here. Room is reserved in the // lowish bits for up to these 6 destination formats. If a destination format is // >= 6, the 6th bit is set to avoid collisions. #define FORMAT_KEY(aSrcFormat, aDstFormat) \int (aSrcFormat) * 6 + int (aDstFormat) + (int (int (aDstFormat) >= 6) << 6))#define FORMAT_CASE_EXPR(aSrcFormat, aDstFormat, ...) \case FORMAT_KEY(aSrcFormat, aDstFormat): \return true ;#define FORMAT_CASE(aSrcFormat, aDstFormat, ...) \#define FORMAT_CASE_ROW(aSrcFormat, aDstFormat, ...) \case FORMAT_KEY(aSrcFormat, aDstFormat): \return &__VA_ARGS__;/** * Constexpr functions for analyzing format attributes in templates. // Whether B comes before R in pixel memory layout. static constexpr bool IsBGRFormat(SurfaceFormat aFormat) {return aFormat == SurfaceFormat::B8G8R8A8 ||#if MOZ_LITTLE_ENDIAN()#endif // Whether the order of B and R need to be swapped to map from src to dst. static constexpr bool ShouldSwapRB(SurfaceFormat aSrcFormat,return IsBGRFormat(aSrcFormat) != IsBGRFormat(aDstFormat);// The starting byte of the RGB components in pixel memory. static constexpr uint32_t RGBByteIndex(SurfaceFormat aFormat) {return aFormat == SurfaceFormat::A8R8G8B8 ||// The byte of the alpha component, which just comes after RGB. static constexpr uint32_t AlphaByteIndex(SurfaceFormat aFormat) {return (RGBByteIndex(aFormat) + 3) % 4;// The endian-dependent bit shift to access RGB of a UINT32 pixel. static constexpr uint32_t RGBBitShift(SurfaceFormat aFormat) {#if MOZ_LITTLE_ENDIAN()return 8 * RGBByteIndex(aFormat);#else return 8 - 8 * RGBByteIndex(aFormat);#endif // The endian-dependent bit shift to access alpha of a UINT32 pixel. static constexpr uint32_t AlphaBitShift(SurfaceFormat aFormat) {return (RGBBitShift(aFormat) + 24) % 32;// Whether the pixel format should ignore the value of the alpha channel and // treat it as opaque. static constexpr bool IgnoreAlpha(SurfaceFormat aFormat) {return aFormat == SurfaceFormat::B8G8R8X8 ||// Whether to force alpha to opaque to map from src to dst. static constexpr bool ShouldForceOpaque(SurfaceFormat aSrcFormat,return IgnoreAlpha(aSrcFormat) != IgnoreAlpha(aDstFormat);#ifdef USE_SSE2/** * SSE2 optimizations template <bool aSwapRB, bool aOpaqueAlpha>void Premultiply_SSE2(const uint8_t*, int32_t, uint8_t*, int32_t, IntSize);# define PREMULTIPLY_SSE2(aSrcFormat, aDstFormat) \template <bool aSwapRB, bool aOpaqueAlpha>void PremultiplyRow_SSE2(const uint8_t*, uint8_t*, int32_t);# define PREMULTIPLY_ROW_SSE2(aSrcFormat, aDstFormat) \template <bool aSwapRB>void Unpremultiply_SSE2(const uint8_t*, int32_t, uint8_t*, int32_t, IntSize);# define UNPREMULTIPLY_SSE2(aSrcFormat, aDstFormat) \template <bool aSwapRB>void UnpremultiplyRow_SSE2(const uint8_t*, uint8_t*, int32_t);# define UNPREMULTIPLY_ROW_SSE2(aSrcFormat, aDstFormat) \template <bool aSwapRB, bool aOpaqueAlpha>void Swizzle_SSE2(const uint8_t*, int32_t, uint8_t*, int32_t, IntSize);# define SWIZZLE_SSE2(aSrcFormat, aDstFormat) \template <bool aSwapRB, bool aOpaqueAlpha>void SwizzleRow_SSE2(const uint8_t*, uint8_t*, int32_t);# define SWIZZLE_ROW_SSE2(aSrcFormat, aDstFormat) \template <bool aSwapRB>void UnpackRowRGB24_SSSE3(const uint8_t*, uint8_t*, int32_t);# define UNPACK_ROW_RGB_SSSE3(aDstFormat) \template <bool aSwapRB>void UnpackRowRGB24_AVX2(const uint8_t*, uint8_t*, int32_t);# define UNPACK_ROW_RGB_AVX2(aDstFormat) \#endif #ifdef USE_NEON/** * ARM NEON optimizations template <bool aSwapRB, bool aOpaqueAlpha>void Premultiply_NEON(const uint8_t*, int32_t, uint8_t*, int32_t, IntSize);# define PREMULTIPLY_NEON(aSrcFormat, aDstFormat) \template <bool aSwapRB, bool aOpaqueAlpha>void PremultiplyRow_NEON(const uint8_t*, uint8_t*, int32_t);# define PREMULTIPLY_ROW_NEON(aSrcFormat, aDstFormat) \template <bool aSwapRB>void Unpremultiply_NEON(const uint8_t*, int32_t, uint8_t*, int32_t, IntSize);# define UNPREMULTIPLY_NEON(aSrcFormat, aDstFormat) \template <bool aSwapRB>void UnpremultiplyRow_NEON(const uint8_t*, uint8_t*, int32_t);# define UNPREMULTIPLY_ROW_NEON(aSrcFormat, aDstFormat) \template <bool aSwapRB, bool aOpaqueAlpha>void Swizzle_NEON(const uint8_t*, int32_t, uint8_t*, int32_t, IntSize);# define SWIZZLE_NEON(aSrcFormat, aDstFormat) \template <bool aSwapRB, bool aOpaqueAlpha>void SwizzleRow_NEON(const uint8_t*, uint8_t*, int32_t);# define SWIZZLE_ROW_NEON(aSrcFormat, aDstFormat) \template <bool aSwapRB>void UnpackRowRGB24_NEON(const uint8_t*, uint8_t*, int32_t);# define UNPACK_ROW_RGB_NEON(aDstFormat) \#endif /** * Premultiplying // Fallback premultiply implementation that uses splayed pixel math to reduce // the multiplications used. That is, the R and B components are isolated from // the G and A components, which then can be multiplied as if they were two // 2-component vectors. Otherwise, an approximation if divide-by-255 is used // which is faster than an actual division. These optimizations are also used // for the SSE2 and NEON implementations. template <bool aSwapRB, bool aOpaqueAlpha, uint32_t aSrcRGBShift,static void PremultiplyChunkFallback(const uint8_t*& aSrc, uint8_t*& aDst,const uint8_t* end = aSrc + 4 * aLength;do {// Load and process 1 entire pixel at a time. reinterpret_cast <const uint32_t*>(aSrc);// Isolate the R and B components. // Swap the order of R and B if necessary. if (aSwapRB) {// Approximate the multiply by alpha and divide by 255 which is // essentially: // c = c*a + 255; c = (c + (c >> 8)) >> 8; // However, we omit the final >> 8 to fold it with the final shift into // place depending on desired output format. // Use same approximation as above, but G is shifted 8 bits left. // Alpha is left out and handled separately. // The above math leaves RGB shifted left by 8 bits. // Shift them right if required for the output format. // then combine them back together to produce output pixel. // Add the alpha back on if the output format is not opaque. reinterpret_cast <uint32_t*>(aDst) =while (aSrc < end);template <bool aSwapRB, bool aOpaqueAlpha, uint32_t aSrcRGBShift,static void PremultiplyRowFallback(const uint8_t* aSrc, uint8_t* aDst,template <bool aSwapRB, bool aOpaqueAlpha, uint32_t aSrcRGBShift,static void PremultiplyFallback(const uint8_t* aSrc, int32_t aSrcGap,for (int32_t height = aSize.height; height > 0; height--) {#define PREMULTIPLY_FALLBACK_CASE(aSrcFormat, aDstFormat) \#define PREMULTIPLY_FALLBACK(aSrcFormat) \#define PREMULTIPLY_ROW_FALLBACK_CASE(aSrcFormat, aDstFormat) \#define PREMULTIPLY_ROW_FALLBACK(aSrcFormat) \// If rows are tightly packed, and the size of the total area will fit within // the precision range of a single row, then process all the data as if it was // a single row. static inline IntSize CollapseSize(const IntSize& aSize, int32_t aSrcStride,if (aSrcStride == aDstStride && (aSrcStride & 3) == 0 &&if (area.isValid()) {return IntSize(area.value(), 1);return aSize;static inline int32_t GetStrideGap(int32_t aWidth, SurfaceFormat aFormat,if (!used.isValid() || used.value() < 0) {return -1;return aStride - used.value();bool PremultiplyData(const uint8_t* aSrc, int32_t aSrcStride,const IntSize& aSize) {if (aSize.IsEmpty()) {return true ;// Find gap from end of row to the start of the next row. if (srcGap < 0 || dstGap < 0) {return false ;#define FORMAT_CASE_CALL(...) __VA_ARGS__(aSrc, srcGap, aDst, dstGap, size)#ifdef USE_SSE2if (mozilla::supports_sse2()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif #ifdef USE_NEONif (mozilla::supports_neon()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#undef FORMAT_CASE_CALLfalse , "Unsupported premultiply formats" );return false ;#ifdef USE_SSE2if (mozilla::supports_sse2()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif #ifdef USE_NEONif (mozilla::supports_neon()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;"Unsupported premultiply formats" );return nullptr;/** * Unpremultiplying // Generate a table of 8.16 fixed-point reciprocals representing 1/alpha. #define UNPREMULQ(x) (0xFF00FFU / (x))#define UNPREMULQ_2(x) UNPREMULQ(x), UNPREMULQ((x) + 1)#define UNPREMULQ_4(x) UNPREMULQ_2(x), UNPREMULQ_2((x) + 2)#define UNPREMULQ_8(x) UNPREMULQ_4(x), UNPREMULQ_4((x) + 4)#define UNPREMULQ_16(x) UNPREMULQ_8(x), UNPREMULQ_8((x) + 8)#define UNPREMULQ_32(x) UNPREMULQ_16(x), UNPREMULQ_16((x) + 16)static const uint32_t sUnpremultiplyTable[256] = {0,// Fallback unpremultiply implementation that uses 8.16 fixed-point reciprocal // math to eliminate any division by the alpha component. This optimization is // used for the SSE2 and NEON implementations, with some adaptations. This // implementation also accesses color components using individual byte accesses // as this profiles faster than accessing the pixel as a uint32_t and // shifting/masking to access components. template <bool aSwapRB, uint32_t aSrcRGBIndex, uint32_t aSrcAIndex,static void UnpremultiplyChunkFallback(const uint8_t*& aSrc, uint8_t*& aDst,const uint8_t* end = aSrc + 4 * aLength;do {// Access the 8.16 reciprocal from the table based on alpha. Multiply by // the reciprocal and shift off the fraction bits to approximate the // division by alpha. while (aSrc < end);template <bool aSwapRB, uint32_t aSrcRGBIndex, uint32_t aSrcAIndex,static void UnpremultiplyRowFallback(const uint8_t* aSrc, uint8_t* aDst,template <bool aSwapRB, uint32_t aSrcRGBIndex, uint32_t aSrcAIndex,static void UnpremultiplyFallback(const uint8_t* aSrc, int32_t aSrcGap,for (int32_t height = aSize.height; height > 0; height--) {#define UNPREMULTIPLY_FALLBACK_CASE(aSrcFormat, aDstFormat) \#define UNPREMULTIPLY_FALLBACK(aSrcFormat) \#define UNPREMULTIPLY_ROW_FALLBACK_CASE(aSrcFormat, aDstFormat) \#define UNPREMULTIPLY_ROW_FALLBACK(aSrcFormat) \bool UnpremultiplyData(const uint8_t* aSrc, int32_t aSrcStride,const IntSize& aSize) {if (aSize.IsEmpty()) {return true ;// Find gap from end of row to the start of the next row. if (srcGap < 0 || dstGap < 0) {return false ;#define FORMAT_CASE_CALL(...) __VA_ARGS__(aSrc, srcGap, aDst, dstGap, size)#ifdef USE_SSE2if (mozilla::supports_sse2()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif #ifdef USE_NEONif (mozilla::supports_neon()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#undef FORMAT_CASE_CALLfalse , "Unsupported unpremultiply formats" );return false ;#ifdef USE_SSE2if (mozilla::supports_sse2()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif #ifdef USE_NEONif (mozilla::supports_neon()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;"Unsupported premultiply formats" );return nullptr;/** * Swizzling // Fallback swizzle implementation that uses shifting and masking to reorder // pixels. template <bool aSwapRB, bool aOpaqueAlpha, uint32_t aSrcRGBShift,static void SwizzleChunkFallback(const uint8_t*& aSrc, uint8_t*& aDst,const uint8_t* end = aSrc + 4 * aLength;do {reinterpret_cast <const uint32_t*>(aSrc);if (aSwapRB) {// Handle R and B swaps by exchanging words and masking. // If src and dst shifts differ, rotate left or right to move RGB into // place, i.e. ARGB -> RGBA or ARGB -> RGBA. if (aDstRGBShift > aSrcRGBShift) {else if (aSrcRGBShift > aDstRGBShift) {else if (aOpaqueAlpha) {reinterpret_cast <uint32_t*>(aDst) = rgba;while (aSrc < end);template <bool aSwapRB, bool aOpaqueAlpha, uint32_t aSrcRGBShift,static void SwizzleRowFallback(const uint8_t* aSrc, uint8_t* aDst,template <bool aSwapRB, bool aOpaqueAlpha, uint32_t aSrcRGBShift,static void SwizzleFallback(const uint8_t* aSrc, int32_t aSrcGap, uint8_t* aDst,for (int32_t height = aSize.height; height > 0; height--) {#define SWIZZLE_FALLBACK(aSrcFormat, aDstFormat) \#define SWIZZLE_ROW_FALLBACK(aSrcFormat, aDstFormat) \// Fast-path for matching formats. template <int32_t aBytesPerPixel>static void SwizzleRowCopy(const uint8_t* aSrc, uint8_t* aDst,if (aSrc != aDst) {// Fast-path for matching formats. static void SwizzleCopy(const uint8_t* aSrc, int32_t aSrcGap, uint8_t* aDst,if (aSrc != aDst) {for (int32_t height = aSize.height; height > 0; height--) {// Fast-path for conversions that swap all bytes. template <bool aOpaqueAlpha, uint32_t aSrcAShift, uint32_t aDstAShift>static void SwizzleChunkSwap(const uint8_t*& aSrc, uint8_t*& aDst,const uint8_t* end = aSrc + 4 * aLength;do {// Use an endian swap to move the bytes, i.e. BGRA -> ARGB. reinterpret_cast <const uint32_t*>(aSrc);#if MOZ_LITTLE_ENDIAN()#else #endif if (aOpaqueAlpha) {reinterpret_cast <uint32_t*>(aDst) = rgba;while (aSrc < end);template <bool aOpaqueAlpha, uint32_t aSrcAShift, uint32_t aDstAShift>static void SwizzleRowSwap(const uint8_t* aSrc, uint8_t* aDst,template <bool aOpaqueAlpha, uint32_t aSrcAShift, uint32_t aDstAShift>static void SwizzleSwap(const uint8_t* aSrc, int32_t aSrcGap, uint8_t* aDst,for (int32_t height = aSize.height; height > 0; height--) {#define SWIZZLE_SWAP(aSrcFormat, aDstFormat) \#define SWIZZLE_ROW_SWAP(aSrcFormat, aDstFormat) \static void SwizzleChunkSwapRGB24(const uint8_t*& aSrc, uint8_t*& aDst,const uint8_t* end = aSrc + 3 * aLength;do {while (aSrc < end);static void SwizzleRowSwapRGB24(const uint8_t* aSrc, uint8_t* aDst,static void SwizzleSwapRGB24(const uint8_t* aSrc, int32_t aSrcGap,for (int32_t height = aSize.height; height > 0; height--) {#define SWIZZLE_SWAP_RGB24(aSrcFormat, aDstFormat) \#define SWIZZLE_ROW_SWAP_RGB24(aSrcFormat, aDstFormat) \// Fast-path for conversions that force alpha to opaque. template <uint32_t aDstAShift>static void SwizzleChunkOpaqueUpdate(uint8_t*& aBuffer, int32_t aLength) {const uint8_t* end = aBuffer + 4 * aLength;do {reinterpret_cast <const uint32_t*>(aBuffer);// Just add on the alpha bits to the source. reinterpret_cast <uint32_t*>(aBuffer) = rgba;while (aBuffer < end);template <uint32_t aDstAShift>static void SwizzleChunkOpaqueCopy(const uint8_t*& aSrc, uint8_t* aDst,const uint8_t* end = aSrc + 4 * aLength;do {reinterpret_cast <const uint32_t*>(aSrc);// Just add on the alpha bits to the source. reinterpret_cast <uint32_t*>(aDst) = rgba;while (aSrc < end);template <uint32_t aDstAShift>static void SwizzleRowOpaque(const uint8_t* aSrc, uint8_t* aDst,if (aSrc == aDst) {else {template <uint32_t aDstAShift>static void SwizzleOpaque(const uint8_t* aSrc, int32_t aSrcGap, uint8_t* aDst,if (aSrc == aDst) {// Modifying in-place, so just write out the alpha. for (int32_t height = aSize.height; height > 0; height--) {else {for (int32_t height = aSize.height; height > 0; height--) {#define SWIZZLE_OPAQUE(aSrcFormat, aDstFormat) \#define SWIZZLE_ROW_OPAQUE(aSrcFormat, aDstFormat) \// Packing of 32-bit formats to RGB565. template <bool aSwapRB, uint32_t aSrcRGBShift, uint32_t aSrcRGBIndex>static void PackToRGB565(const uint8_t* aSrc, int32_t aSrcGap, uint8_t* aDst,for (int32_t height = aSize.height; height > 0; height--) {const uint8_t* end = aSrc + 4 * aSize.width;do {reinterpret_cast <const uint32_t*>(aSrc);// Isolate the R, G, and B components and shift to final endian-dependent // locations. if (aSwapRB) {else {reinterpret_cast <uint16_t*>(aDst) = rgb565;while (aSrc < end);// Packing of 32-bit formats to 24-bit formats. template <bool aSwapRB, uint32_t aSrcRGBShift, uint32_t aSrcRGBIndex>static void PackChunkToRGB24(const uint8_t*& aSrc, uint8_t*& aDst,const uint8_t* end = aSrc + 4 * aLength;do {while (aSrc < end);template <bool aSwapRB, uint32_t aSrcRGBShift, uint32_t aSrcRGBIndex>static void PackRowToRGB24(const uint8_t* aSrc, uint8_t* aDst,template <bool aSwapRB, uint32_t aSrcRGBShift, uint32_t aSrcRGBIndex>static void PackToRGB24(const uint8_t* aSrc, int32_t aSrcGap, uint8_t* aDst,for (int32_t height = aSize.height; height > 0; height--) {#define PACK_RGB_CASE(aSrcFormat, aDstFormat, aPackFunc) \#define PACK_RGB(aDstFormat, aPackFunc) \#define PACK_ROW_RGB_CASE(aSrcFormat, aDstFormat, aPackFunc) \#define PACK_ROW_RGB(aDstFormat, aPackFunc) \// Packing of 32-bit formats to A8. template <uint32_t aSrcAIndex>static void PackToA8(const uint8_t* aSrc, int32_t aSrcGap, uint8_t* aDst,for (int32_t height = aSize.height; height > 0; height--) {const uint8_t* end = aSrc + 4 * aSize.width;do {while (aSrc < end);#define PACK_ALPHA_CASE(aSrcFormat, aDstFormat, aPackFunc) \#define PACK_ALPHA(aDstFormat, aPackFunc) \template <bool aSwapRB>void UnpackRowRGB24(const uint8_t* aSrc, uint8_t* aDst, int32_t aLength) {// Because we are expanding, we can only process the data back to front in // case we are performing this in place. const uint8_t* src = aSrc + 3 * (aLength - 1);reinterpret_cast <uint32_t*>(aDst + 4 * aLength);while (src >= aSrc) {#if MOZ_LITTLE_ENDIAN()#else #endif // Force instantiation of swizzle variants here. template void UnpackRowRGB24<false >(const uint8_t*, uint8_t*, int32_t);template void UnpackRowRGB24<true >(const uint8_t*, uint8_t*, int32_t);#define UNPACK_ROW_RGB(aDstFormat) \static void UnpackRowRGB24_To_ARGB(const uint8_t* aSrc, uint8_t* aDst,// Because we are expanding, we can only process the data back to front in // case we are performing this in place. const uint8_t* src = aSrc + 3 * (aLength - 1);reinterpret_cast <uint32_t*>(aDst + 4 * aLength);while (src >= aSrc) {#if MOZ_LITTLE_ENDIAN()#else #endif #define UNPACK_ROW_RGB_TO_ARGB(aDstFormat) \bool SwizzleData(const uint8_t* aSrc, int32_t aSrcStride,const IntSize& aSize) {if (aSize.IsEmpty()) {return true ;// Find gap from end of row to the start of the next row. if (srcGap < 0 || dstGap < 0) {return false ;#define FORMAT_CASE_CALL(...) __VA_ARGS__(aSrc, srcGap, aDst, dstGap, size)#ifdef USE_SSE2if (mozilla::supports_sse2()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif #ifdef USE_NEONif (mozilla::supports_neon()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;if (aSrcFormat == aDstFormat) {// If the formats match, just do a generic copy. return true ;#undef FORMAT_CASE_CALLfalse , "Unsupported swizzle formats" );return false ;static bool SwizzleYFlipDataInternal(const uint8_t* aSrc, int32_t aSrcStride,const IntSize& aSize,if (!aSwizzleFn) {return false ;// Guarantee our width and height are both greater than zero. if (aSize.IsEmpty()) {return true ;// Unlike SwizzleData/PremultiplyData, we don't use the stride gaps directly, // but we can use it to verify that the stride is valid for our width and // format. if (srcGap < 0 || dstGap < 0) {return false ;// Swapping/swizzling to a new buffer is trivial. if (aSrc != aDst) {const uint8_t* src = aSrc;const uint8_t* srcEnd = aSrc + aSize.height * aSrcStride;while (src < srcEnd) {return true ;if (aSrcStride != aDstStride) {return false ;// If we are swizzling in place, then we need a temporary row buffer. new (std::nothrow) uint8_t[aDstStride]);if (!rowBuffer) {return false ;// Swizzle and swap the top and bottom rows until we meet in the middle. for (int32_t row = 0; row < middleRow; ++row) {// If there is an odd numbered row, we haven't swizzled it yet. if (aSize.height % 2 == 1) {return true ;bool SwizzleYFlipData(const uint8_t* aSrc, int32_t aSrcStride,const IntSize& aSize) {return SwizzleYFlipDataInternal(aSrc, aSrcStride, aSrcFormat, aDst,bool PremultiplyYFlipData(const uint8_t* aSrc, int32_t aSrcStride,const IntSize& aSize) {return SwizzleYFlipDataInternal(aSrc, aSrcStride, aSrcFormat, aDst,#ifdef USE_SSE2if (mozilla::supports_avx2()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;if (mozilla::supports_ssse3()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;if (mozilla::supports_sse2()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif #ifdef USE_NEONif (mozilla::supports_neon()) switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;#endif switch (FORMAT_KEY(aSrcFormat, aDstFormat)) {default :break ;if (aSrcFormat == aDstFormat) {switch (BytesPerPixel(aSrcFormat)) {case 4:return &SwizzleRowCopy<4>;case 3:return &SwizzleRowCopy<3>;default :break ;"Unsupported swizzle formats" );return nullptr;static IntRect ReorientRowRotate0FlipFallback(const uint8_t* aSrc,const IntSize& aDstSize,// Reverse order of pixels in the row. const uint32_t* src = reinterpret_cast <const uint32_t*>(aSrc);const uint32_t* end = src + aDstSize.width;reinterpret_cast <uint32_t*>(aDst + aSrcRow * aDstStride) +do {while (src < end);return IntRect(0, aSrcRow, aDstSize.width, 1);static IntRect ReorientRowRotate90FlipFallback(const uint8_t* aSrc,const IntSize& aDstSize,// Copy row of pixels from top to bottom, into left to right columns. const uint32_t* src = reinterpret_cast <const uint32_t*>(aSrc);const uint32_t* end = src + aDstSize.height;reinterpret_cast <uint32_t*>(aDst) + aSrcRow;sizeof (uint32_t);do {while (src < end);return IntRect(aSrcRow, 0, 1, aDstSize.height);static IntRect ReorientRowRotate180FlipFallback(const uint8_t* aSrc,const IntSize& aDstSize,// Copy row of pixels from top to bottom, into bottom to top rows. sizeof (uint32_t));return IntRect(0, aDstSize.height - aSrcRow - 1, aDstSize.width, 1);static IntRect ReorientRowRotate270FlipFallback(const uint8_t* aSrc,const IntSize& aDstSize,// Copy row of pixels in reverse order from top to bottom, into right to left // columns. const uint32_t* src = reinterpret_cast <const uint32_t*>(aSrc);const uint32_t* end = src + aDstSize.height;reinterpret_cast <uint32_t*>(aDst + (aDstSize.height - 1) * aDstStride) +sizeof (uint32_t);do {while (src < end);return IntRect(aDstSize.width - aSrcRow - 1, 0, 1, aDstSize.height);static IntRect ReorientRowRotate0Fallback(const uint8_t* aSrc, int32_t aSrcRow,const IntSize& aDstSize,// Copy row of pixels into the destination. sizeof (uint32_t));return IntRect(0, aSrcRow, aDstSize.width, 1);static IntRect ReorientRowRotate90Fallback(const uint8_t* aSrc, int32_t aSrcRow,const IntSize& aDstSize,// Copy row of pixels from top to bottom, into right to left columns. const uint32_t* src = reinterpret_cast <const uint32_t*>(aSrc);const uint32_t* end = src + aDstSize.height;reinterpret_cast <uint32_t*>(aDst) + aDstSize.width - aSrcRow - 1;sizeof (uint32_t);do {while (src < end);return IntRect(aDstSize.width - aSrcRow - 1, 0, 1, aDstSize.height);static IntRect ReorientRowRotate180Fallback(const uint8_t* aSrc,const IntSize& aDstSize,// Copy row of pixels in reverse order from top to bottom, into bottom to top // rows. const uint32_t* src = reinterpret_cast <const uint32_t*>(aSrc);const uint32_t* end = src + aDstSize.width;reinterpret_cast <uint32_t*>(do {while (src < end);return IntRect(0, aDstSize.height - aSrcRow - 1, aDstSize.width, 1);static IntRect ReorientRowRotate270Fallback(const uint8_t* aSrc,const IntSize& aDstSize,// Copy row of pixels in reverse order from top to bottom, into left to right // column. const uint32_t* src = reinterpret_cast <const uint32_t*>(aSrc);const uint32_t* end = src + aDstSize.height;reinterpret_cast <uint32_t*>(aDst + (aDstSize.height - 1) * aDstStride) +sizeof (uint32_t);do {while (src < end);return IntRect(aSrcRow, 0, 1, aDstSize.height);const struct image::Orientation& aOrientation) {switch (aOrientation.flip) {case image::Flip::Unflipped:switch (aOrientation.rotation) {case image::Angle::D0:return &ReorientRowRotate0Fallback;case image::Angle::D90:return &ReorientRowRotate90Fallback;case image::Angle::D180:return &ReorientRowRotate180Fallback;case image::Angle::D270:return &ReorientRowRotate270Fallback;default :break ;break ;case image::Flip::Horizontal:switch (aOrientation.rotation) {case image::Angle::D0:return &ReorientRowRotate0FlipFallback;case image::Angle::D90:if (aOrientation.flipFirst) {return &ReorientRowRotate270FlipFallback;else {return &ReorientRowRotate90FlipFallback;case image::Angle::D180:return &ReorientRowRotate180FlipFallback;case image::Angle::D270:if (aOrientation.flipFirst) {return &ReorientRowRotate90FlipFallback;else {return &ReorientRowRotate270FlipFallback;default :break ;break ;default :break ;"Unhandled orientation!" );return nullptr;// namespace gfx // namespace mozilla quality 85%
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