/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- * * 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/. */ #ifndef mozilla_image_imgFrame_h #define mozilla_image_imgFrame_h #include "mozilla/Maybe.h" #include "mozilla/MemoryReporting.h" #include "mozilla/Monitor.h" #include "mozilla/Move.h" #include "FrameTimeout.h" #include "gfxDrawable.h" #include "imgIContainer.h" #include "MainThreadUtils.h" #include "nsAutoPtr.h" namespace mozilla { namespace image { class ImageRegion; class DrawableFrameRef; class RawAccessFrameRef; enum class BlendMethod : int8_t { // All color components of the frame, including alpha, overwrite the current // contents of the frame's output buffer region. SOURCE, // The frame should be composited onto the output buffer based on its alpha, // using a simple OVER operation. OVER }; enum class DisposalMethod : int8_t { CLEAR_ALL = -1, // Clear the whole image, revealing what's underneath. NOT_SPECIFIED, // Leave the frame and let the new frame draw on top. KEEP, // Leave the frame and let the new frame draw on top. CLEAR, // Clear the frame's area, revealing what's underneath. RESTORE_PREVIOUS // Restore the previous (composited) frame. }; enum class Opacity : uint8_t { FULLY_OPAQUE, SOME_TRANSPARENCY }; /** * AnimationData contains all of the information necessary for using an imgFrame * as part of an animation. * * It includes pointers to the raw image data of the underlying imgFrame, but * does not own that data. A RawAccessFrameRef for the underlying imgFrame must * outlive the AnimationData for it to remain valid. */ struct AnimationData { AnimationData(uint8_t* aRawData, uint32_t aPaletteDataLength, FrameTimeout aTimeout, const nsIntRect& aRect, BlendMethod aBlendMethod, const Maybe& aBlendRect, DisposalMethod aDisposalMethod, bool aHasAlpha) : mRawData(aRawData) , mPaletteDataLength(aPaletteDataLength) , mTimeout(aTimeout) , mRect(aRect) , mBlendMethod(aBlendMethod) , mBlendRect(aBlendRect) , mDisposalMethod(aDisposalMethod) , mHasAlpha(aHasAlpha) { } uint8_t* mRawData; uint32_t mPaletteDataLength; FrameTimeout mTimeout; nsIntRect mRect; BlendMethod mBlendMethod; Maybe mBlendRect; DisposalMethod mDisposalMethod; bool mHasAlpha; }; class imgFrame { typedef gfx::Color Color; typedef gfx::DataSourceSurface DataSourceSurface; typedef gfx::DrawTarget DrawTarget; typedef gfx::SamplingFilter SamplingFilter; typedef gfx::IntPoint IntPoint; typedef gfx::IntRect IntRect; typedef gfx::IntSize IntSize; typedef gfx::SourceSurface SourceSurface; typedef gfx::SurfaceFormat SurfaceFormat; public: MOZ_DECLARE_REFCOUNTED_TYPENAME(imgFrame) NS_INLINE_DECL_THREADSAFE_REFCOUNTING(imgFrame) imgFrame(); /** * Initialize this imgFrame with an empty surface and prepare it for being * written to by a decoder. * * This is appropriate for use with decoded images, but it should not be used * when drawing content into an imgFrame, as it may use a different graphics * backend than normal content drawing. */ nsresult InitForDecoder(const nsIntSize& aImageSize, const nsIntRect& aRect, SurfaceFormat aFormat, uint8_t aPaletteDepth = 0, bool aNonPremult = false, bool aIsAnimated = false); nsresult InitForAnimator(const nsIntSize& aSize, SurfaceFormat aFormat) { return InitForDecoder(aSize, nsIntRect(0, 0, aSize.width, aSize.height), aFormat, 0, false, true); } /** * Initialize this imgFrame with a new surface and draw the provided * gfxDrawable into it. * * This is appropriate to use when drawing content into an imgFrame, as it * uses the same graphics backend as normal content drawing. The downside is * that the underlying surface may not be stored in a volatile buffer on all * platforms, and raw access to the surface (using RawAccessRef()) may be much * more expensive than in the InitForDecoder() case. * * aBackend specifies the DrawTarget backend type this imgFrame is supposed * to be drawn to. */ nsresult InitWithDrawable(gfxDrawable* aDrawable, const nsIntSize& aSize, const SurfaceFormat aFormat, SamplingFilter aSamplingFilter, uint32_t aImageFlags, gfx::BackendType aBackend); DrawableFrameRef DrawableRef(); RawAccessFrameRef RawAccessRef(); /** * Make this imgFrame permanently available for raw access. * * This is irrevocable, and should be avoided whenever possible, since it * prevents this imgFrame from being optimized and makes it impossible for its * volatile buffer to be freed. * * It is an error to call this without already holding a RawAccessFrameRef to * this imgFrame. */ void SetRawAccessOnly(); bool Draw(gfxContext* aContext, const ImageRegion& aRegion, SamplingFilter aSamplingFilter, uint32_t aImageFlags, float aOpacity); nsresult ImageUpdated(const nsIntRect& aUpdateRect); /** * Mark this imgFrame as completely decoded, and set final options. * * You must always call either Finish() or Abort() before releasing the last * RawAccessFrameRef pointing to an imgFrame. * * @param aFrameOpacity Whether this imgFrame is opaque. * @param aDisposalMethod For animation frames, how this imgFrame is cleared * from the compositing frame before the next frame is * displayed. * @param aTimeout For animation frames, the timeout before the next * frame is displayed. * @param aBlendMethod For animation frames, a blending method to be used * when compositing this frame. * @param aBlendRect For animation frames, if present, the subrect in * which @aBlendMethod applies. Outside of this * subrect, BlendMethod::OVER is always used. * @param aFinalize Finalize the underlying surface (e.g. so that it * may be marked as read only if possible). */ void Finish(Opacity aFrameOpacity = Opacity::SOME_TRANSPARENCY, DisposalMethod aDisposalMethod = DisposalMethod::KEEP, FrameTimeout aTimeout = FrameTimeout::FromRawMilliseconds(0), BlendMethod aBlendMethod = BlendMethod::OVER, const Maybe& aBlendRect = Nothing(), bool aFinalize = true); /** * Mark this imgFrame as aborted. This informs the imgFrame that if it isn't * completely decoded now, it never will be. * * You must always call either Finish() or Abort() before releasing the last * RawAccessFrameRef pointing to an imgFrame. */ void Abort(); /** * Returns true if this imgFrame has been aborted. */ bool IsAborted() const; /** * Returns true if this imgFrame is completely decoded. */ bool IsFinished() const; /** * Blocks until this imgFrame is either completely decoded, or is marked as * aborted. * * Note that calling this on the main thread _blocks the main thread_. Be very * careful in your use of this method to avoid excessive main thread jank or * deadlock. */ void WaitUntilFinished() const; /** * Returns the number of bytes per pixel this imgFrame requires. This is a * worst-case value that does not take into account the effects of format * changes caused by Optimize(), since an imgFrame is not optimized throughout * its lifetime. */ uint32_t GetBytesPerPixel() const { return GetIsPaletted() ? 1 : 4; } IntSize GetImageSize() const { return mImageSize; } IntRect GetRect() const { return mFrameRect; } IntSize GetSize() const { return mFrameRect.Size(); } void GetImageData(uint8_t** aData, uint32_t* length) const; uint8_t* GetImageData() const; bool GetIsPaletted() const; void GetPaletteData(uint32_t** aPalette, uint32_t* length) const; uint32_t* GetPaletteData() const; uint8_t GetPaletteDepth() const { return mPaletteDepth; } AnimationData GetAnimationData() const; bool GetCompositingFailed() const; void SetCompositingFailed(bool val); void SetOptimizable(); void FinalizeSurface(); already_AddRefed GetSourceSurface(); void AddSizeOfExcludingThis(MallocSizeOf aMallocSizeOf, size_t& aHeapSizeOut, size_t& aNonHeapSizeOut, size_t& aExtHandlesOut) const; private: // methods ~imgFrame(); nsresult LockImageData(); nsresult UnlockImageData(); nsresult Optimize(gfx::DrawTarget* aTarget); void AssertImageDataLocked() const; bool AreAllPixelsWritten() const; nsresult ImageUpdatedInternal(const nsIntRect& aUpdateRect); void GetImageDataInternal(uint8_t** aData, uint32_t* length) const; uint32_t GetImageBytesPerRow() const; uint32_t GetImageDataLength() const; void FinalizeSurfaceInternal(); already_AddRefed GetSourceSurfaceInternal(); uint32_t PaletteDataLength() const { return mPaletteDepth ? (size_t(1) << mPaletteDepth) * sizeof(uint32_t) : 0; } struct SurfaceWithFormat { RefPtr mDrawable; SurfaceFormat mFormat; SurfaceWithFormat() { } SurfaceWithFormat(gfxDrawable* aDrawable, SurfaceFormat aFormat) : mDrawable(aDrawable), mFormat(aFormat) { } bool IsValid() { return !!mDrawable; } }; SurfaceWithFormat SurfaceForDrawing(bool aDoPartialDecode, bool aDoTile, ImageRegion& aRegion, SourceSurface* aSurface); private: // data friend class DrawableFrameRef; friend class RawAccessFrameRef; friend class UnlockImageDataRunnable; ////////////////////////////////////////////////////////////////////////////// // Thread-safe mutable data, protected by mMonitor. ////////////////////////////////////////////////////////////////////////////// mutable Monitor mMonitor; /** * Surface which contains either a weak or a strong reference to its * underlying data buffer. If it is a weak reference, and there are no strong * references, the buffer may be released due to events such as low memory. */ RefPtr mRawSurface; /** * Refers to the same data as mRawSurface, but when set, it guarantees that * we hold a strong reference to the underlying data buffer. */ RefPtr mLockedSurface; /** * Optimized copy of mRawSurface for the DrawTarget that will render it. This * is unused if the DrawTarget is able to render DataSourceSurface buffers * directly. */ RefPtr mOptSurface; nsIntRect mDecoded; //! Number of RawAccessFrameRefs currently alive for this imgFrame. int32_t mLockCount; //! The timeout for this frame. FrameTimeout mTimeout; DisposalMethod mDisposalMethod; BlendMethod mBlendMethod; Maybe mBlendRect; SurfaceFormat mFormat; bool mAborted; bool mFinished; bool mOptimizable; ////////////////////////////////////////////////////////////////////////////// // Effectively const data, only mutated in the Init methods. ////////////////////////////////////////////////////////////////////////////// IntSize mImageSize; IntRect mFrameRect; // The palette and image data for images that are paletted, since Cairo // doesn't support these images. // The paletted data comes first, then the image data itself. // Total length is PaletteDataLength() + GetImageDataLength(). uint8_t* mPalettedImageData; uint8_t mPaletteDepth; bool mNonPremult; ////////////////////////////////////////////////////////////////////////////// // Main-thread-only mutable data. ////////////////////////////////////////////////////////////////////////////// bool mCompositingFailed; }; /** * A reference to an imgFrame that holds the imgFrame's surface in memory, * allowing drawing. If you have a DrawableFrameRef |ref| and |if (ref)| returns * true, then calls to Draw() and GetSourceSurface() are guaranteed to succeed. */ class DrawableFrameRef final { typedef gfx::DataSourceSurface DataSourceSurface; public: DrawableFrameRef() { } explicit DrawableFrameRef(imgFrame* aFrame) : mFrame(aFrame) { MOZ_ASSERT(aFrame); MonitorAutoLock lock(aFrame->mMonitor); // Paletted images won't have a surface so there is no strong reference // to hold on to. Since Draw() and GetSourceSurface() calls will not work // in that case, we should be using RawAccessFrameRef exclusively instead. // See FrameAnimator::GetRawFrame for an example of this behaviour. if (aFrame->mRawSurface) { mRef = new DataSourceSurface::ScopedMap(aFrame->mRawSurface, DataSourceSurface::READ_WRITE); if (!mRef->IsMapped()) { mFrame = nullptr; mRef = nullptr; } } else { MOZ_ASSERT(aFrame->mOptSurface || aFrame->GetIsPaletted()); } } DrawableFrameRef(DrawableFrameRef&& aOther) : mFrame(aOther.mFrame.forget()) , mRef(Move(aOther.mRef)) { } DrawableFrameRef& operator=(DrawableFrameRef&& aOther) { MOZ_ASSERT(this != &aOther, "Self-moves are prohibited"); mFrame = aOther.mFrame.forget(); mRef = Move(aOther.mRef); return *this; } explicit operator bool() const { return bool(mFrame); } imgFrame* operator->() { MOZ_ASSERT(mFrame); return mFrame; } const imgFrame* operator->() const { MOZ_ASSERT(mFrame); return mFrame; } imgFrame* get() { return mFrame; } const imgFrame* get() const { return mFrame; } void reset() { mFrame = nullptr; mRef = nullptr; } private: DrawableFrameRef(const DrawableFrameRef& aOther) = delete; RefPtr mFrame; nsAutoPtr mRef; }; /** * A reference to an imgFrame that holds the imgFrame's surface in memory in a * format appropriate for access as raw data. If you have a RawAccessFrameRef * |ref| and |if (ref)| is true, then calls to GetImageData() and * GetPaletteData() are guaranteed to succeed. This guarantee is stronger than * DrawableFrameRef, so everything that a valid DrawableFrameRef guarantees is * also guaranteed by a valid RawAccessFrameRef. * * This may be considerably more expensive than is necessary just for drawing, * so only use this when you need to read or write the raw underlying image data * that the imgFrame holds. * * Once all an imgFrame's RawAccessFrameRefs go out of scope, new * RawAccessFrameRefs cannot be created. */ class RawAccessFrameRef final { public: RawAccessFrameRef() { } explicit RawAccessFrameRef(imgFrame* aFrame) : mFrame(aFrame) { MOZ_ASSERT(mFrame, "Need a frame"); if (NS_FAILED(mFrame->LockImageData())) { mFrame->UnlockImageData(); mFrame = nullptr; } } RawAccessFrameRef(RawAccessFrameRef&& aOther) : mFrame(aOther.mFrame.forget()) { } ~RawAccessFrameRef() { if (mFrame) { mFrame->UnlockImageData(); } } RawAccessFrameRef& operator=(RawAccessFrameRef&& aOther) { MOZ_ASSERT(this != &aOther, "Self-moves are prohibited"); if (mFrame) { mFrame->UnlockImageData(); } mFrame = aOther.mFrame.forget(); return *this; } explicit operator bool() const { return bool(mFrame); } imgFrame* operator->() { MOZ_ASSERT(mFrame); return mFrame.get(); } const imgFrame* operator->() const { MOZ_ASSERT(mFrame); return mFrame; } imgFrame* get() { return mFrame; } const imgFrame* get() const { return mFrame; } void reset() { if (mFrame) { mFrame->UnlockImageData(); } mFrame = nullptr; } private: RawAccessFrameRef(const RawAccessFrameRef& aOther) = delete; RefPtr mFrame; }; } // namespace image } // namespace mozilla #endif // mozilla_image_imgFrame_h