/* -*- 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 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /** * A SurfacePipe is a pipeline that consists of a series of SurfaceFilters * terminating in a SurfaceSink. Each SurfaceFilter transforms the image data in * some way before the SurfaceSink ultimately writes it to the surface. This * design allows for each transformation to be tested independently, for the * transformations to be combined as needed to meet the needs of different * situations, and for all image decoders to share the same code for these * transformations. * * Writing to the SurfacePipe is done using lambdas that act as generator * functions. Because the SurfacePipe machinery controls where the writes take * place, a bug in an image decoder cannot cause a buffer overflow of the * underlying surface. */ #ifndef mozilla_image_SurfacePipe_h #define mozilla_image_SurfacePipe_h #include <stdint.h> #include "nsDebug.h" #include "mozilla/Likely.h" #include "mozilla/Maybe.h" #include "mozilla/Move.h" #include "mozilla/UniquePtr.h" #include "mozilla/Unused.h" #include "mozilla/Variant.h" #include "mozilla/gfx/2D.h" namespace mozilla { namespace image { class Decoder; /** * An invalid rect for a surface. Results are given both in the space of the * input image (i.e., before any SurfaceFilters are applied) and in the space * of the output surface (after all SurfaceFilters). */ struct SurfaceInvalidRect { gfx::IntRect mInputSpaceRect; /// The invalid rect in pre-SurfacePipe space. gfx::IntRect mOutputSpaceRect; /// The invalid rect in post-SurfacePipe space. }; /** * An enum used to allow the lambdas passed to WritePixels() to communicate * their state to the caller. */ enum class WriteState : uint8_t { NEED_MORE_DATA, /// The lambda ran out of data. FINISHED, /// The lambda is done writing to the surface; future writes /// will fail. FAILURE /// The lambda encountered an error. The caller may recover /// if possible and continue to write. (This never indicates /// an error in the SurfacePipe machinery itself; it's only /// generated by the lambdas.) }; /** * A template alias used to make the return value of WritePixels() lambdas * (which may return either a pixel value or a WriteState) easier to specify. */ template <typename PixelType> using NextPixel = Variant<PixelType, WriteState>; /** * SurfaceFilter is the abstract superclass of SurfacePipe pipeline stages. It * implements the the code that actually writes to the surface - WritePixels() * and the other Write*() methods - which are non-virtual for efficiency. * * SurfaceFilter's API is nonpublic; only SurfacePipe and other SurfaceFilters * should use it. Non-SurfacePipe code should use the methods on SurfacePipe. * * To implement a SurfaceFilter, it's necessary to subclass SurfaceFilter and * implement, at a minimum, the pure virtual methods. It's also necessary to * define a Config struct with a Filter typedef member that identifies the * matching SurfaceFilter class, and a Configure() template method. See an * existing SurfaceFilter subclass, such as RemoveFrameRectFilter, for an * example of how the Configure() method must be implemented. It takes a list of * Config structs, passes the tail of the list to the next filter in the chain's * Configure() method, and then uses the head of the list to configure itself. A * SurfaceFilter's Configure() method must also call * SurfaceFilter::ConfigureFilter() to provide the Write*() methods with the * information they need to do their jobs. */ class SurfaceFilter { public: SurfaceFilter() : mRowPointer(nullptr) , mCol(0) , mPixelSize(0) { } virtual ~SurfaceFilter() { } /** * Reset this surface to the first row. It's legal for this filter to throw * away any previously written data at this point, as all rows must be written * to on every pass. * * @return a pointer to the buffer for the first row. */ uint8_t* ResetToFirstRow() { mCol = 0; mRowPointer = DoResetToFirstRow(); return mRowPointer; } /** * Called by WritePixels() to advance this filter to the next row. * * @return a pointer to the buffer for the next row, or nullptr to indicate * that we've finished the entire surface. */ uint8_t* AdvanceRow() { mCol = 0; mRowPointer = DoAdvanceRow(); return mRowPointer; } /// @return a pointer to the buffer for the current row. uint8_t* CurrentRowPointer() const { return mRowPointer; } /// @return true if we've finished writing to the surface. bool IsSurfaceFinished() const { return mRowPointer == nullptr; } /// @return the input size this filter expects. gfx::IntSize InputSize() const { return mInputSize; } /** * Write pixels to the surface one at a time by repeatedly calling a lambda * that yields pixels. WritePixels() is completely memory safe. * * Writing continues until every pixel in the surface has been written to * (i.e., IsSurfaceFinished() returns true) or the lambda returns a WriteState * which WritePixels() will return to the caller. * * The template parameter PixelType must be uint8_t (for paletted surfaces) or * uint32_t (for BGRA/BGRX surfaces) and must be in agreement with the pixel * size passed to ConfigureFilter(). * * XXX(seth): We'll remove all support for paletted surfaces in bug 1247520, * which means we can remove the PixelType template parameter from this * method. * * @param aFunc A lambda that functions as a generator, yielding the next * pixel in the surface each time it's called. The lambda must * return a NextPixel<PixelType> value. * * @return A WriteState value indicating the lambda generator's state. * WritePixels() itself will return WriteState::FINISHED if writing * has finished, regardless of the lambda's internal state. */ template <typename PixelType, typename Func> WriteState WritePixels(Func aFunc) { Maybe<WriteState> result; while (!(result = DoWritePixelsToRow<PixelType>(Forward<Func>(aFunc)))) { } return *result; } /** * A variant of WritePixels() that writes a single row of pixels to the * surface one at a time by repeatedly calling a lambda that yields pixels. * WritePixelsToRow() is completely memory safe. * * Writing continues until every pixel in the row has been written to. If the * surface is complete at that pointer, WriteState::FINISHED is returned; * otherwise, WritePixelsToRow() returns WriteState::NEED_MORE_DATA. The * lambda can terminate writing early by returning a WriteState itself, which * WritePixelsToRow() will return to the caller. * * The template parameter PixelType must be uint8_t (for paletted surfaces) or * uint32_t (for BGRA/BGRX surfaces) and must be in agreement with the pixel * size passed to ConfigureFilter(). * * XXX(seth): We'll remove all support for paletted surfaces in bug 1247520, * which means we can remove the PixelType template parameter from this * method. * * @param aFunc A lambda that functions as a generator, yielding the next * pixel in the surface each time it's called. The lambda must * return a NextPixel<PixelType> value. * * @return A WriteState value indicating the lambda generator's state. * WritePixels() itself will return WriteState::FINISHED if writing * the entire surface has finished, or WriteState::NEED_MORE_DATA if * writing the row has finished, regardless of the lambda's internal * state. */ template <typename PixelType, typename Func> WriteState WritePixelsToRow(Func aFunc) { return DoWritePixelsToRow<PixelType>(Forward<Func>(aFunc)) .valueOr(WriteState::NEED_MORE_DATA); } /** * Write a row to the surface by copying from a buffer. This is bounds checked * and memory safe with respect to the surface, but care must still be taken * by the caller not to overread the source buffer. This variant of * WriteBuffer() requires a source buffer which contains |mInputSize.width| * pixels. * * The template parameter PixelType must be uint8_t (for paletted surfaces) or * uint32_t (for BGRA/BGRX surfaces) and must be in agreement with the pixel * size passed to ConfigureFilter(). * * XXX(seth): We'll remove all support for paletted surfaces in bug 1247520, * which means we can remove the PixelType template parameter from this * method. * * @param aSource A buffer to copy from. This buffer must be * |mInputSize.width| pixels wide, which means * |mInputSize.width * sizeof(PixelType)| bytes. May not be * null. * * @return WriteState::FINISHED if the entire surface has been written to. * Otherwise, returns WriteState::NEED_MORE_DATA. If a null |aSource| * value is passed, returns WriteState::FAILURE. */ template <typename PixelType> WriteState WriteBuffer(const PixelType* aSource) { return WriteBuffer(aSource, 0, mInputSize.width); } /** * Write a row to the surface by copying from a buffer. This is bounds checked * and memory safe with respect to the surface, but care must still be taken * by the caller not to overread the source buffer. This variant of * WriteBuffer() reads at most @aLength pixels from the buffer and writes them * to the row starting at @aStartColumn. Any pixels in columns before * @aStartColumn or after the pixels copied from the buffer are cleared. * * Bounds checking failures produce warnings in debug builds because although * the bounds checking maintains safety, this kind of failure could indicate a * bug in the calling code. * * The template parameter PixelType must be uint8_t (for paletted surfaces) or * uint32_t (for BGRA/BGRX surfaces) and must be in agreement with the pixel * size passed to ConfigureFilter(). * * XXX(seth): We'll remove all support for paletted surfaces in bug 1247520, * which means we can remove the PixelType template parameter from this * method. * * @param aSource A buffer to copy from. This buffer must be @aLength pixels * wide, which means |aLength * sizeof(PixelType)| bytes. May * not be null. * @param aStartColumn The column to start writing to in the row. Columns * before this are cleared. * @param aLength The number of bytes, at most, which may be copied from * @aSource. Fewer bytes may be copied in practice due to * bounds checking. * * @return WriteState::FINISHED if the entire surface has been written to. * Otherwise, returns WriteState::NEED_MORE_DATA. If a null |aSource| * value is passed, returns WriteState::FAILURE. */ template <typename PixelType> WriteState WriteBuffer(const PixelType* aSource, const size_t aStartColumn, const size_t aLength) { MOZ_ASSERT(mPixelSize == 1 || mPixelSize == 4); MOZ_ASSERT_IF(mPixelSize == 1, sizeof(PixelType) == sizeof(uint8_t)); MOZ_ASSERT_IF(mPixelSize == 4, sizeof(PixelType) == sizeof(uint32_t)); if (IsSurfaceFinished()) { return WriteState::FINISHED; // Already done. } if (MOZ_UNLIKELY(!aSource)) { NS_WARNING("Passed a null pointer to WriteBuffer"); return WriteState::FAILURE; } PixelType* dest = reinterpret_cast<PixelType*>(mRowPointer); // Clear the area before |aStartColumn|. const size_t prefixLength = std::min<size_t>(mInputSize.width, aStartColumn); if (MOZ_UNLIKELY(prefixLength != aStartColumn)) { NS_WARNING("Provided starting column is out-of-bounds in WriteBuffer"); } memset(dest, 0, mInputSize.width * sizeof(PixelType)); dest += prefixLength; // Write |aLength| pixels from |aSource| into the row, with bounds checking. const size_t bufferLength = std::min<size_t>(mInputSize.width - prefixLength, aLength); if (MOZ_UNLIKELY(bufferLength != aLength)) { NS_WARNING("Provided buffer length is out-of-bounds in WriteBuffer"); } memcpy(dest, aSource, bufferLength * sizeof(PixelType)); dest += bufferLength; // Clear the rest of the row. const size_t suffixLength = mInputSize.width - (prefixLength + bufferLength); memset(dest, 0, suffixLength * sizeof(PixelType)); AdvanceRow(); return IsSurfaceFinished() ? WriteState::FINISHED : WriteState::NEED_MORE_DATA; } /** * Write an empty row to the surface. If some pixels have already been written * to this row, they'll be discarded. * * @return WriteState::FINISHED if the entire surface has been written to. * Otherwise, returns WriteState::NEED_MORE_DATA. */ WriteState WriteEmptyRow() { if (IsSurfaceFinished()) { return WriteState::FINISHED; // Already done. } memset(mRowPointer, 0, mInputSize.width * mPixelSize); AdvanceRow(); return IsSurfaceFinished() ? WriteState::FINISHED : WriteState::NEED_MORE_DATA; } /** * Write a row to the surface by calling a lambda that uses a pointer to * directly write to the row. This is unsafe because SurfaceFilter can't * provide any bounds checking; that's up to the lambda itself. For this * reason, the other Write*() methods should be preferred whenever it's * possible to use them; WriteUnsafeComputedRow() should be used only when * it's absolutely necessary to avoid extra copies or other performance * penalties. * * This method should never be exposed to SurfacePipe consumers; it's strictly * for use in SurfaceFilters. If external code needs this method, it should * probably be turned into a SurfaceFilter. * * The template parameter PixelType must be uint8_t (for paletted surfaces) or * uint32_t (for BGRA/BGRX surfaces) and must be in agreement with the pixel * size passed to ConfigureFilter(). * * XXX(seth): We'll remove all support for paletted surfaces in bug 1247520, * which means we can remove the PixelType template parameter from this * method. * * @param aFunc A lambda that writes directly to the row. * * @return WriteState::FINISHED if the entire surface has been written to. * Otherwise, returns WriteState::NEED_MORE_DATA. */ template <typename PixelType, typename Func> WriteState WriteUnsafeComputedRow(Func aFunc) { MOZ_ASSERT(mPixelSize == 1 || mPixelSize == 4); MOZ_ASSERT_IF(mPixelSize == 1, sizeof(PixelType) == sizeof(uint8_t)); MOZ_ASSERT_IF(mPixelSize == 4, sizeof(PixelType) == sizeof(uint32_t)); if (IsSurfaceFinished()) { return WriteState::FINISHED; // Already done. } // Call the provided lambda with a pointer to the buffer for the current // row. This is unsafe because we can't do any bounds checking; the lambda // itself has to be responsible for that. PixelType* rowPtr = reinterpret_cast<PixelType*>(mRowPointer); aFunc(rowPtr, mInputSize.width); AdvanceRow(); return IsSurfaceFinished() ? WriteState::FINISHED : WriteState::NEED_MORE_DATA; } ////////////////////////////////////////////////////////////////////////////// // Methods Subclasses Should Override ////////////////////////////////////////////////////////////////////////////// /// @return true if this SurfaceFilter can be used with paletted surfaces. virtual bool IsValidPalettedPipe() const { return false; } /** * @return a SurfaceInvalidRect representing the region of the surface that * has been written to since the last time TakeInvalidRect() was * called, or Nothing() if the region is empty (i.e. nothing has been * written). */ virtual Maybe<SurfaceInvalidRect> TakeInvalidRect() = 0; protected: /** * Called by ResetToFirstRow() to actually perform the reset. It's legal to * throw away any previously written data at this point, as all rows must be * written to on every pass. */ virtual uint8_t* DoResetToFirstRow() = 0; /** * Called by AdvanceRow() to actually advance this filter to the next row. * * @return a pointer to the buffer for the next row, or nullptr to indicate * that we've finished the entire surface. */ virtual uint8_t* DoAdvanceRow() = 0; ////////////////////////////////////////////////////////////////////////////// // Methods For Internal Use By Subclasses ////////////////////////////////////////////////////////////////////////////// /** * Called by subclasses' Configure() methods to initialize the configuration * of this filter. After the filter is configured, calls ResetToFirstRow(). * * @param aInputSize The input size of this filter, in pixels. The previous * filter in the chain will expect to write into rows * |aInputSize.width| pixels wide. * @param aPixelSize How large, in bytes, each pixel in the surface is. This * should be either 1 for paletted images or 4 for BGRA/BGRX * images. */ void ConfigureFilter(gfx::IntSize aInputSize, uint8_t aPixelSize) { mInputSize = aInputSize; mPixelSize = aPixelSize; ResetToFirstRow(); } private: /** * An internal method used to implement both WritePixels() and * WritePixelsToRow(). Those methods differ only in their behavior after a row * is successfully written - WritePixels() continues to write another row, * while WritePixelsToRow() returns to the caller. This method writes a single * row and returns Some() if we either finished the entire surface or the * lambda returned a WriteState indicating that we should return to the * caller. If the row was successfully written without either of those things * happening, it returns Nothing(), allowing WritePixels() and * WritePixelsToRow() to implement their respective behaviors. */ template <typename PixelType, typename Func> Maybe<WriteState> DoWritePixelsToRow(Func aFunc) { MOZ_ASSERT(mPixelSize == 1 || mPixelSize == 4); MOZ_ASSERT_IF(mPixelSize == 1, sizeof(PixelType) == sizeof(uint8_t)); MOZ_ASSERT_IF(mPixelSize == 4, sizeof(PixelType) == sizeof(uint32_t)); if (IsSurfaceFinished()) { return Some(WriteState::FINISHED); // We're already done. } PixelType* rowPtr = reinterpret_cast<PixelType*>(mRowPointer); for (; mCol < mInputSize.width; ++mCol) { NextPixel<PixelType> result = aFunc(); if (result.template is<PixelType>()) { rowPtr[mCol] = result.template as<PixelType>(); continue; } switch (result.template as<WriteState>()) { case WriteState::NEED_MORE_DATA: return Some(WriteState::NEED_MORE_DATA); case WriteState::FINISHED: ZeroOutRestOfSurface<PixelType>(); return Some(WriteState::FINISHED); case WriteState::FAILURE: // Note that we don't need to record this anywhere, because this // indicates an error in aFunc, and there's nothing wrong with our // machinery. The caller can recover as needed and continue writing to // the row. return Some(WriteState::FAILURE); } } AdvanceRow(); // We've finished the row. return IsSurfaceFinished() ? Some(WriteState::FINISHED) : Nothing(); } template <typename PixelType> void ZeroOutRestOfSurface() { WritePixels<PixelType>([]{ return AsVariant(PixelType(0)); }); } gfx::IntSize mInputSize; /// The size of the input this filter expects. uint8_t* mRowPointer; /// Pointer to the current row or null if finished. int32_t mCol; /// The current column we're writing to. (0-indexed) uint8_t mPixelSize; /// How large each pixel in the surface is, in bytes. }; class NullSurfaceSink; /// A trivial configuration struct for NullSurfaceSink. struct NullSurfaceConfig { using Filter = NullSurfaceSink; }; /** * NullSurfaceSink is a trivial SurfaceFilter implementation that behaves as if * it were a zero-size SurfaceSink. It's used as the default filter chain for an * uninitialized SurfacePipe. * * To avoid unnecessary allocations when creating SurfacePipe objects, * NullSurfaceSink is a singleton. (This implies that the implementation must be * stateless.) */ class NullSurfaceSink final : public SurfaceFilter { public: /// Returns the singleton instance of NullSurfaceSink. static NullSurfaceSink* Singleton(); virtual ~NullSurfaceSink() { } nsresult Configure(const NullSurfaceConfig& aConfig); Maybe<SurfaceInvalidRect> TakeInvalidRect() override { return Nothing(); } protected: uint8_t* DoResetToFirstRow() override { return nullptr; } uint8_t* DoAdvanceRow() override { return nullptr; } private: static UniquePtr<NullSurfaceSink> sSingleton; /// The singleton instance. }; /** * SurfacePipe is the public API that decoders should use to interact with a * SurfaceFilter pipeline. */ class SurfacePipe { public: /// Initialize global state used by all SurfacePipes. static void Initialize() { NullSurfaceSink::Singleton(); } SurfacePipe() : mHead(NullSurfaceSink::Singleton()) { } SurfacePipe(SurfacePipe&& aOther) : mHead(Move(aOther.mHead)) { } ~SurfacePipe() { // Ensure that we don't free the NullSurfaceSink singleton. if (mHead.get() == NullSurfaceSink::Singleton()) { Unused << mHead.release(); } } SurfacePipe& operator=(SurfacePipe&& aOther) { MOZ_ASSERT(this != &aOther); // Ensure that we don't free the NullSurfaceSink singleton. if (mHead.get() == NullSurfaceSink::Singleton()) { Unused << mHead.release(); } mHead = Move(aOther.mHead); return *this; } /// Begins a new pass, seeking to the first row of the surface. void ResetToFirstRow() { mHead->ResetToFirstRow(); } /** * Write pixels to the surface one at a time by repeatedly calling a lambda * that yields pixels. WritePixels() is completely memory safe. * * @see SurfaceFilter::WritePixels() for the canonical documentation. */ template <typename PixelType, typename Func> WriteState WritePixels(Func aFunc) { return mHead->WritePixels<PixelType>(Forward<Func>(aFunc)); } /** * A variant of WritePixels() that writes a single row of pixels to the * surface one at a time by repeatedly calling a lambda that yields pixels. * WritePixelsToRow() is completely memory safe. * * @see SurfaceFilter::WritePixelsToRow() for the canonical documentation. */ template <typename PixelType, typename Func> WriteState WritePixelsToRow(Func aFunc) { return mHead->WritePixelsToRow<PixelType>(Forward<Func>(aFunc)); } /** * Write a row to the surface by copying from a buffer. This is bounds checked * and memory safe with respect to the surface, but care must still be taken * by the caller not to overread the source buffer. This variant of * WriteBuffer() requires a source buffer which contains |mInputSize.width| * pixels. * * @see SurfaceFilter::WriteBuffer() for the canonical documentation. */ template <typename PixelType> WriteState WriteBuffer(const PixelType* aSource) { return mHead->WriteBuffer<PixelType>(aSource); } /** * Write a row to the surface by copying from a buffer. This is bounds checked * and memory safe with respect to the surface, but care must still be taken * by the caller not to overread the source buffer. This variant of * WriteBuffer() reads at most @aLength pixels from the buffer and writes them * to the row starting at @aStartColumn. Any pixels in columns before * @aStartColumn or after the pixels copied from the buffer are cleared. * * @see SurfaceFilter::WriteBuffer() for the canonical documentation. */ template <typename PixelType> WriteState WriteBuffer(const PixelType* aSource, const size_t aStartColumn, const size_t aLength) { return mHead->WriteBuffer<PixelType>(aSource, aStartColumn, aLength); } /** * Write an empty row to the surface. If some pixels have already been written * to this row, they'll be discarded. * * @see SurfaceFilter::WriteEmptyRow() for the canonical documentation. */ WriteState WriteEmptyRow() { return mHead->WriteEmptyRow(); } /// @return true if we've finished writing to the surface. bool IsSurfaceFinished() const { return mHead->IsSurfaceFinished(); } /// @see SurfaceFilter::TakeInvalidRect() for the canonical documentation. Maybe<SurfaceInvalidRect> TakeInvalidRect() const { return mHead->TakeInvalidRect(); } private: friend class SurfacePipeFactory; friend class TestSurfacePipeFactory; explicit SurfacePipe(UniquePtr<SurfaceFilter>&& aHead) : mHead(Move(aHead)) { } SurfacePipe(const SurfacePipe&) = delete; SurfacePipe& operator=(const SurfacePipe&) = delete; UniquePtr<SurfaceFilter> mHead; /// The first filter in the chain. }; /** * AbstractSurfaceSink contains shared implementation for both SurfaceSink and * PalettedSurfaceSink. */ class AbstractSurfaceSink : public SurfaceFilter { public: AbstractSurfaceSink() : mImageData(nullptr) , mImageDataLength(0) , mRow(0) , mFlipVertically(false) { } Maybe<SurfaceInvalidRect> TakeInvalidRect() override final; protected: uint8_t* DoResetToFirstRow() override final; uint8_t* DoAdvanceRow() override final; virtual uint8_t* GetRowPointer() const = 0; gfx::IntRect mInvalidRect; /// The region of the surface that has been written /// to since the last call to TakeInvalidRect(). uint8_t* mImageData; /// A pointer to the beginning of the surface data. uint32_t mImageDataLength; /// The length of the surface data. uint32_t mRow; /// The row to which we're writing. (0-indexed) bool mFlipVertically; /// If true, write the rows from top to bottom. }; class SurfaceSink; /// A configuration struct for SurfaceSink. struct SurfaceConfig { using Filter = SurfaceSink; Decoder* mDecoder; /// Which Decoder to use to allocate the surface. uint32_t mFrameNum; /// Which frame of animation this surface is for. gfx::IntSize mOutputSize; /// The size of the surface. gfx::SurfaceFormat mFormat; /// The surface format (BGRA or BGRX). bool mFlipVertically; /// If true, write the rows from bottom to top. }; /** * A sink for normal (i.e., non-paletted) surfaces. It handles the allocation of * the surface and protects against buffer overflow. This sink should be used * for all non-animated images and for the first frame of animated images. * * Sinks must always be at the end of the SurfaceFilter chain. */ class SurfaceSink final : public AbstractSurfaceSink { public: nsresult Configure(const SurfaceConfig& aConfig); protected: uint8_t* GetRowPointer() const override; }; class PalettedSurfaceSink; struct PalettedSurfaceConfig { using Filter = PalettedSurfaceSink; Decoder* mDecoder; /// Which Decoder to use to allocate the surface. uint32_t mFrameNum; /// Which frame of animation this surface is for. gfx::IntSize mOutputSize; /// The logical size of the surface. gfx::IntRect mFrameRect; /// The surface subrect which contains data. gfx::SurfaceFormat mFormat; /// The surface format (BGRA or BGRX). uint8_t mPaletteDepth; /// The palette depth of this surface. bool mFlipVertically; /// If true, write the rows from bottom to top. }; /** * A sink for paletted surfaces. It handles the allocation of the surface and * protects against buffer overflow. This sink can be used for frames of * animated images except the first. * * Sinks must always be at the end of the SurfaceFilter chain. * * XXX(seth): We'll remove all support for paletted surfaces in bug 1247520, * which means we can remove PalettedSurfaceSink entirely. */ class PalettedSurfaceSink final : public AbstractSurfaceSink { public: bool IsValidPalettedPipe() const override { return true; } nsresult Configure(const PalettedSurfaceConfig& aConfig); protected: uint8_t* GetRowPointer() const override; private: /** * The surface subrect which contains data. Note that the surface size we * actually allocate is the size of the frame rect, not the logical size of * the surface. */ gfx::IntRect mFrameRect; }; } // namespace image } // namespace mozilla #endif // mozilla_image_SurfacePipe_h