/* KWin - the KDE window manager This file is part of the KDE project. SPDX-FileCopyrightText: 2006 Lubos Lunak SPDX-License-Identifier: GPL-2.0-or-later */ #ifndef KWIN_SCENE_H #define KWIN_SCENE_H #include "toplevel.h" #include "utils.h" #include "kwineffects.h" #include #include class QOpenGLFramebufferObject; namespace KWaylandServer { class BufferInterface; class SubSurfaceInterface; } namespace KWin { namespace Decoration { class DecoratedClientImpl; class Renderer; } class AbstractThumbnailItem; class Deleted; class EffectFrameImpl; class EffectWindowImpl; class OverlayWindow; class Shadow; class WindowPixmap; class GLTexture; class AbstractOutput; class SubSurfaceMonitor; // The base class for compositing backends. class KWIN_EXPORT Scene : public QObject { Q_OBJECT public: explicit Scene(QObject *parent = nullptr); ~Scene() override = 0; class EffectFrame; class Window; /** * Schedules a repaint for the specified @a region. */ void addRepaint(const QRegion ®ion); /** * Returns the repaints region for output with the specified @a screenId. */ QRegion repaints(int screenId) const; void resetRepaints(int screenId); // Returns true if the ctor failed to properly initialize. virtual bool initFailed() const = 0; virtual CompositingType compositingType() const = 0; // Repaints the given screen areas, windows provides the stacking order. // The entry point for the main part of the painting pass. // returns the time since the last vblank signal - if there's one // ie. "what of this frame is lost to painting" virtual void paint(int screenId, const QRegion &damage, const QList &windows, std::chrono::milliseconds presentTime) = 0; /** * Adds the Toplevel to the Scene. * * If the toplevel gets deleted, then the scene will try automatically * to re-bind an underlying scene window to the corresponding Deleted. * * @param toplevel The window to be added. * @note You can add a toplevel to scene only once. */ void addToplevel(Toplevel *toplevel); /** * Removes the Toplevel from the Scene. * * @param toplevel The window to be removed. * @note You can remove a toplevel from the scene only once. */ void removeToplevel(Toplevel *toplevel); /** * @brief Creates the Scene backend of an EffectFrame. * * @param frame The EffectFrame this Scene::EffectFrame belongs to. */ virtual Scene::EffectFrame *createEffectFrame(EffectFrameImpl *frame) = 0; /** * @brief Creates the Scene specific Shadow subclass. * * An implementing class has to create a proper instance. It is not allowed to * return @c null. * * @param toplevel The Toplevel for which the Shadow needs to be created. */ virtual Shadow *createShadow(Toplevel *toplevel) = 0; /** * Method invoked when the screen geometry is changed. * Reimplementing classes should also invoke the parent method * as it takes care of resizing the overlay window. * @param size The new screen geometry size */ virtual void screenGeometryChanged(const QSize &size); // Flags controlling how painting is done. enum { // Window (or at least part of it) will be painted opaque. PAINT_WINDOW_OPAQUE = 1 << 0, // Window (or at least part of it) will be painted translucent. PAINT_WINDOW_TRANSLUCENT = 1 << 1, // Window will be painted with transformed geometry. PAINT_WINDOW_TRANSFORMED = 1 << 2, // Paint only a region of the screen (can be optimized, cannot // be used together with TRANSFORMED flags). PAINT_SCREEN_REGION = 1 << 3, // Whole screen will be painted with transformed geometry. PAINT_SCREEN_TRANSFORMED = 1 << 4, // At least one window will be painted with transformed geometry. PAINT_SCREEN_WITH_TRANSFORMED_WINDOWS = 1 << 5, // Clear whole background as the very first step, without optimizing it PAINT_SCREEN_BACKGROUND_FIRST = 1 << 6, // PAINT_DECORATION_ONLY = 1 << 7 has been removed // Window will be painted with a lanczos filter. PAINT_WINDOW_LANCZOS = 1 << 8 // PAINT_SCREEN_WITH_TRANSFORMED_WINDOWS_WITHOUT_FULL_REPAINTS = 1 << 9 has been removed }; // types of filtering available enum ImageFilterType { ImageFilterFast, ImageFilterGood }; virtual OverlayWindow* overlayWindow() const = 0; virtual bool makeOpenGLContextCurrent(); virtual void doneOpenGLContextCurrent(); virtual bool supportsSurfacelessContext() const; virtual bool supportsNativeFence() const; virtual QMatrix4x4 screenProjectionMatrix() const; virtual void triggerFence(); virtual Decoration::Renderer *createDecorationRenderer(Decoration::DecoratedClientImpl *) = 0; /** * Whether the Scene is able to drive animations. * This is used as a hint to the effects system which effects can be supported. * If the Scene performs software rendering it is supposed to return @c false, * if rendering is hardware accelerated it should return @c true. */ virtual bool animationsSupported() const = 0; /** * The render buffer used by an XRender based compositor scene. * Default implementation returns XCB_RENDER_PICTURE_NONE */ virtual xcb_render_picture_t xrenderBufferPicture() const; /** * The QPainter used by a QPainter based compositor scene. * Default implementation returns @c nullptr; */ virtual QPainter *scenePainter() const; /** * The render buffer used by a QPainter based compositor. * Default implementation returns @c nullptr. */ virtual QImage *qpainterRenderBuffer(int screenId) const; /** * The backend specific extensions (e.g. EGL/GLX extensions). * * Not the OpenGL (ES) extension! * * Default implementation returns empty list */ virtual QVector openGLPlatformInterfaceExtensions() const; virtual QSharedPointer textureForOutput(AbstractOutput *output) const { Q_UNUSED(output); return {}; } Q_SIGNALS: void frameRendered(); void resetCompositing(); public Q_SLOTS: // a window has been closed void windowClosed(KWin::Toplevel* c, KWin::Deleted* deleted); protected: virtual Window *createWindow(Toplevel *toplevel) = 0; void createStackingOrder(const QList &toplevels); void clearStackingOrder(); // shared implementation, starts painting the screen void paintScreen(int *mask, const QRegion &damage, const QRegion &repaint, QRegion *updateRegion, QRegion *validRegion, std::chrono::milliseconds presentTime, const QMatrix4x4 &projection = QMatrix4x4(), const QRect &outputGeometry = QRect(), qreal screenScale = 1.0); // Render cursor texture in case hardware cursor is disabled/non-applicable virtual void paintCursor(const QRegion ®ion) = 0; friend class EffectsHandlerImpl; // called after all effects had their paintScreen() called void finalPaintScreen(int mask, const QRegion ®ion, ScreenPaintData& data); // shared implementation of painting the screen in the generic // (unoptimized) way virtual void paintGenericScreen(int mask, const ScreenPaintData &data); // shared implementation of painting the screen in an optimized way virtual void paintSimpleScreen(int mask, const QRegion ®ion); // paint the background (not the desktop background - the whole background) virtual void paintBackground(const QRegion ®ion) = 0; /** * Notifies about starting to paint. * * @p damage contains the reported damage as suggested by windows and effects on prepaint calls. */ virtual void aboutToStartPainting(int screenId, const QRegion &damage); // called after all effects had their paintWindow() called void finalPaintWindow(EffectWindowImpl* w, int mask, const QRegion ®ion, WindowPaintData& data); // shared implementation, starts painting the window virtual void paintWindow(Window* w, int mask, const QRegion ®ion, const WindowQuadList &quads); // called after all effects had their drawWindow() called virtual void finalDrawWindow(EffectWindowImpl* w, int mask, const QRegion ®ion, WindowPaintData& data); // let the scene decide whether it's better to paint more of the screen, eg. in order to allow a buffer swap // the default is NOOP virtual void extendPaintRegion(QRegion ®ion, bool opaqueFullscreen); virtual void paintDesktop(int desktop, int mask, const QRegion ®ion, ScreenPaintData &data); virtual void paintEffectQuickView(EffectQuickView *w) = 0; // saved data for 2nd pass of optimized screen painting struct Phase2Data { Window *window = nullptr; QRegion region; QRegion clip; int mask = 0; WindowQuadList quads; }; // The region which actually has been painted by paintScreen() and should be // copied from the buffer to the screen. I.e. the region returned from Scene::paintScreen(). // Since prePaintWindow() can extend areas to paint, these changes would have to propagate // up all the way from paintSimpleScreen() up to paintScreen(), so save them here rather // than propagate them up in arguments. QRegion painted_region; // Additional damage that needs to be repaired to bring a reused back buffer up to date QRegion repaint_region; // The dirty region before it was unioned with repaint_region QRegion damaged_region; // The screen that is being currently painted int painted_screen = -1; private: void paintWindowThumbnails(Scene::Window *w, const QRegion ®ion, qreal opacity, qreal brightness, qreal saturation); void paintDesktopThumbnails(Scene::Window *w); std::chrono::milliseconds m_expectedPresentTimestamp = std::chrono::milliseconds::zero(); void reallocRepaints(); QHash< Toplevel*, Window* > m_windows; // windows in their stacking order QVector< Window* > stacking_order; QVector m_repaints; // how many times finalPaintScreen() has been called int m_paintScreenCount = 0; }; /** * Factory class to create a Scene. Needs to be implemented by the plugins. */ class KWIN_EXPORT SceneFactory : public QObject { Q_OBJECT public: ~SceneFactory() override; /** * @returns The created Scene, may be @c nullptr. */ virtual Scene *create(QObject *parent = nullptr) const = 0; protected: explicit SceneFactory(QObject *parent); }; // The base class for windows representations in composite backends class Scene::Window : public QObject { Q_OBJECT public: explicit Window(Toplevel *client, QObject *parent = nullptr); ~Window() override; // perform the actual painting of the window virtual void performPaint(int mask, const QRegion ®ion, const WindowPaintData &data) = 0; // do any cleanup needed when the window's composite pixmap is discarded void discardPixmap(); void updatePixmap(); int x() const; int y() const; int width() const; int height() const; QRect geometry() const; QPoint pos() const; QSize size() const; QRect rect() const; // access to the internal window class // TODO eventually get rid of this Toplevel* window() const; // should the window be painted bool isPaintingEnabled() const; void resetPaintingEnabled(); // Flags explaining why painting should be disabled enum { // Window will not be painted PAINT_DISABLED = 1 << 0, // Window will not be painted because it is deleted PAINT_DISABLED_BY_DELETE = 1 << 1, // Window will not be painted because of which desktop it's on PAINT_DISABLED_BY_DESKTOP = 1 << 2, // Window will not be painted because it is minimized PAINT_DISABLED_BY_MINIMIZE = 1 << 3, // Window will not be painted because it's not on the current activity PAINT_DISABLED_BY_ACTIVITY = 1 << 5 }; void enablePainting(int reason); void disablePainting(int reason); // is the window visible at all bool isVisible() const; // is the window fully opaque bool isOpaque() const; // is the window shaded bool isShaded() const; // shape of the window QRegion bufferShape() const; QRegion clientShape() const; QRegion decorationShape() const; QPoint bufferOffset() const; void discardShape(); void updateToplevel(Deleted *deleted); // creates initial quad list for the window virtual WindowQuadList buildQuads(bool force = false) const; void updateShadow(Shadow* shadow); const Shadow* shadow() const; Shadow* shadow(); void referencePreviousPixmap(); void unreferencePreviousPixmap(); void discardQuads(); void preprocess(); void addLayerRepaint(const QRegion ®ion); QRegion repaints(int screen) const; void resetRepaints(int screen); virtual QSharedPointer windowTexture() { return {}; } /** * @brief Returns the WindowPixmap for this Window. * * If the WindowPixmap does not yet exist, this method will invoke createWindowPixmap. * If the WindowPixmap is not valid it tries to create it, in case this succeeds the WindowPixmap is * returned. In case it fails, the previous (and still valid) WindowPixmap is returned. * * @note This method can return @c NULL as there might neither be a valid previous nor current WindowPixmap * around. * * The WindowPixmap gets casted to the type passed in as a template parameter. That way this class does not * need to know the actual WindowPixmap subclass used by the concrete Scene implementations. * * @return The WindowPixmap casted to T* or @c NULL if there is no valid window pixmap. */ template T *windowPixmap() const; template T *previousWindowPixmap() const; protected: WindowQuadList makeDecorationQuads(const QRect *rects, const QRegion ®ion) const; WindowQuadList makeContentsQuads() const; /** * @brief Factory method to create a WindowPixmap. * * The inheriting classes need to implement this method to create a new instance of their WindowPixmap subclass. * @note Do not use WindowPixmap::create on the created instance. The Scene will take care of that. */ virtual WindowPixmap *createWindowPixmap() = 0; Toplevel* toplevel; ImageFilterType filter; Shadow *m_shadow; private: void reallocRepaints(); QScopedPointer m_currentPixmap; QScopedPointer m_previousPixmap; QVector m_repaints; SubSurfaceMonitor *m_subsurfaceMonitor = nullptr; int m_referencePixmapCounter; int disable_painting; mutable QRegion m_bufferShape; mutable bool m_bufferShapeIsValid = false; mutable QScopedPointer cached_quad_list; Q_DISABLE_COPY(Window) }; /** * @brief Wrapper for a pixmap of the Scene::Window. * * This class encapsulates the functionality to get the pixmap for a window. When initialized the pixmap is not yet * mapped to the window and isValid will return @c false. The pixmap mapping to the window can be established * through @ref create. If it succeeds isValid will return @c true, otherwise it will keep in the non valid * state and it can be tried to create the pixmap mapping again (e.g. in the next frame). * * This class is not intended to be updated when the pixmap is no longer valid due to e.g. resizing the window. * Instead a new instance of this class should be instantiated. The idea behind this is that a valid pixmap does not * get destroyed, but can continue to be used. To indicate that a newer pixmap should in generally be around, one can * use markAsDiscarded. * * This class is intended to be inherited for the needs of the compositor backends which need further mapping from * the native pixmap to the respective rendering format. */ class KWIN_EXPORT WindowPixmap : public QObject { Q_OBJECT public: virtual ~WindowPixmap(); /** * @brief Tries to create the mapping between the Window and the pixmap. * * In case this method succeeds in creating the pixmap for the window, isValid will return @c true otherwise * @c false. * * Inheriting classes should re-implement this method in case they need to add further functionality for mapping the * native pixmap to the rendering format. */ virtual void create(); /** * @brief Recursively updates the mapping between the WindowPixmap and the buffer. */ virtual void update(); /** * @return @c true if the pixmap has been created and is valid, @c false otherwise */ virtual bool isValid() const; /** * Returns @c true if this is the root window pixmap; otherwise returns @c false. */ bool isRoot() const; /** * @return The native X11 pixmap handle */ xcb_pixmap_t pixmap() const; /** * @return The Wayland BufferInterface for this WindowPixmap. */ KWaylandServer::BufferInterface *buffer() const; const QSharedPointer &fbo() const; QImage internalImage() const; /** * @brief Whether this WindowPixmap is considered as discarded. This means the window has changed in a way that a new * WindowPixmap should have been created already. * * @return @c true if this WindowPixmap is considered as discarded, @c false otherwise. * @see markAsDiscarded */ bool isDiscarded() const; /** * @brief Marks this WindowPixmap as discarded. From now on isDiscarded will return @c true. This method should * only be used by the Window when it changes in a way that a new pixmap is required. * * @see isDiscarded */ void markAsDiscarded(); /** * Returns the position of the WindowPixmap relative to the upper left corner of the parent. * * This method returns the position of the WindowPixmap relative to the upper left corner * of the window pixmap if parent() is @c null. * * The upper left corner of the parent window pixmap corresponds to (0, 0). */ QPoint position() const; /** * Returns the position of the WindowPixmap relative to the upper left corner of the window * frame. Note that position() returns the position relative to the parent WindowPixmap. * * The upper left corner of the window frame corresponds to (0, 0). */ QPoint framePosition() const; /** * The size of the pixmap. */ const QSize &size() const; /** * Returns the device pixel ratio for the attached buffer. This is the ratio between device * pixels and logical pixels. */ qreal scale() const; /** * Returns the region that specifies the area inside the attached buffer with the actual * client's contents. * * The upper left corner of the attached buffer corresponds to (0, 0). */ QRegion shape() const; /** * Returns the region that specifies the opaque area inside the attached buffer. * * The upper left corner of the attached buffer corresponds to (0, 0). */ QRegion opaque() const; /** * The geometry of the Client's content inside the pixmap. In case of a decorated Client the * pixmap also contains the decoration which is not rendered into this pixmap, though. This * contentsRect tells where inside the complete pixmap the real content is. */ const QRect &contentsRect() const; /** * @brief Returns the Toplevel this WindowPixmap belongs to. * Note: the Toplevel can change over the lifetime of the WindowPixmap in case the Toplevel is copied to Deleted. */ Toplevel *toplevel() const; /** * Returns @c true if the attached buffer has an alpha channel; otherwise returns @c false. */ bool hasAlphaChannel() const; /** * Maps the specified @a point from the window pixmap coordinates to the window local coordinates. */ QPointF mapToWindow(const QPointF &point) const; /** * Maps the specified @a point from the window pixmap coordinates to the buffer pixel coordinates. */ QPointF mapToBuffer(const QPointF &point) const; /** * Maps the specified @a region from the window pixmap coordinates to the global screen coordinates. */ QRegion mapToGlobal(const QRegion ®ion) const; /** * @returns the parent WindowPixmap in the sub-surface tree */ WindowPixmap *parent() const { return m_parent; } /** * @returns the current sub-surface tree */ QVector children() const { return m_children; } /** * @returns the subsurface this WindowPixmap is for if it is not for a root window */ KWaylandServer::SubSurfaceInterface *subSurface() const; /** * @returns the surface this WindowPixmap references, might be @c null. */ KWaylandServer::SurfaceInterface *surface() const; protected: explicit WindowPixmap(Scene::Window *window); explicit WindowPixmap(KWaylandServer::SubSurfaceInterface *subSurface, WindowPixmap *parent); virtual WindowPixmap *createChild(KWaylandServer::SubSurfaceInterface *subSurface); /** * @return The Window this WindowPixmap belongs to */ Scene::Window *window(); /** * Sets the sub-surface tree to @p children. */ void setChildren(const QVector &children) { m_children = children; } private: void setBuffer(KWaylandServer::BufferInterface *buffer); void clear(); Scene::Window *m_window; xcb_pixmap_t m_pixmap; QSize m_pixmapSize; bool m_discarded; QRect m_contentsRect; KWaylandServer::BufferInterface *m_buffer = nullptr; QSharedPointer m_fbo; QImage m_internalImage; WindowPixmap *m_parent = nullptr; QVector m_children; QPointer m_subSurface; }; class Scene::EffectFrame { public: EffectFrame(EffectFrameImpl* frame); virtual ~EffectFrame(); virtual void render(const QRegion ®ion, double opacity, double frameOpacity) = 0; virtual void free() = 0; virtual void freeIconFrame() = 0; virtual void freeTextFrame() = 0; virtual void freeSelection() = 0; virtual void crossFadeIcon() = 0; virtual void crossFadeText() = 0; protected: EffectFrameImpl* m_effectFrame; }; inline int Scene::Window::x() const { return toplevel->x(); } inline int Scene::Window::y() const { return toplevel->y(); } inline int Scene::Window::width() const { return toplevel->width(); } inline int Scene::Window::height() const { return toplevel->height(); } inline QRect Scene::Window::geometry() const { return toplevel->frameGeometry(); } inline QSize Scene::Window::size() const { return toplevel->size(); } inline QPoint Scene::Window::pos() const { return toplevel->pos(); } inline QRect Scene::Window::rect() const { return toplevel->rect(); } inline Toplevel* Scene::Window::window() const { return toplevel; } inline const Shadow* Scene::Window::shadow() const { return m_shadow; } inline Shadow* Scene::Window::shadow() { return m_shadow; } inline KWaylandServer::BufferInterface *WindowPixmap::buffer() const { return m_buffer; } inline const QSharedPointer &WindowPixmap::fbo() const { return m_fbo; } inline QImage WindowPixmap::internalImage() const { return m_internalImage; } template inline T *Scene::Window::windowPixmap() const { if (m_currentPixmap && m_currentPixmap->isValid()) { return static_cast(m_currentPixmap.data()); } if (m_previousPixmap && m_previousPixmap->isValid()) { return static_cast(m_previousPixmap.data()); } return nullptr; } template inline T *Scene::Window::previousWindowPixmap() const { return static_cast(m_previousPixmap.data()); } inline Toplevel* WindowPixmap::toplevel() const { return m_window->window(); } inline xcb_pixmap_t WindowPixmap::pixmap() const { return m_pixmap; } inline bool WindowPixmap::isDiscarded() const { return m_discarded; } inline void WindowPixmap::markAsDiscarded() { m_discarded = true; m_window->referencePreviousPixmap(); } inline const QRect &WindowPixmap::contentsRect() const { return m_contentsRect; } inline const QSize &WindowPixmap::size() const { return m_pixmapSize; } } // namespace Q_DECLARE_INTERFACE(KWin::SceneFactory, "org.kde.kwin.Scene") #endif