libs/hwui/pipeline/skia/SkiaDisplayList.h - platform/frameworks/base - Git at Google

 /*
  * Copyright (C) 2016 The Android Open Source Project
  *
  * 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

 #include "RecordingCanvas.h"
 #include "RenderNodeDrawable.h"
 #include "TreeInfo.h"
 #include "hwui/AnimatedImageDrawable.h"
 #include "utils/LinearAllocator.h"
 #include "utils/Pair.h"

 #include <deque>

 namespace android {
 namespace uirenderer {

 namespace renderthread {
 class CanvasContext;
 }

 class Outline;
 struct WebViewSyncData;

 namespace VectorDrawable {
 class Tree;
 }
 typedef uirenderer::VectorDrawable::Tree VectorDrawableRoot;

 namespace skiapipeline {

 class FunctorDrawable;

 class SkiaDisplayList {
 public:
     size_t getUsedSize() { return allocator.usedSize() + mDisplayList.usedSize(); }
     size_t getAllocatedSize() { return allocator.allocatedSize() + mDisplayList.allocatedSize(); }

     ~SkiaDisplayList() {
         /* Given that we are using a LinearStdAllocator to store some of the
          * SkDrawable contents we must ensure that any other object that is
          * holding a reference to those drawables is destroyed prior to their
          * deletion.
          */
         mDisplayList.reset();
     }

     /**
      * This resets the DisplayList so that it behaves as if the object were newly
      * constructed.  The reuse avoids any overhead associated with destroying
      * the SkLiteDL as well as the deques and vectors.
      */
     void reset();

     /**
      * Use the linear allocator to create any SkDrawables needed by the display
      * list. This could be dangerous as these objects are ref-counted, so we
      * need to monitor that they don't extend beyond the lifetime of the class
      * that creates them. Allocator dtor invokes all SkDrawable dtors.
      */
     template <class T, typename... Params>
     T* allocateDrawable(Params&&... params) {
         return allocator.create<T>(std::forward<Params>(params)...);
     }

     /**
      * Returns true if the DisplayList does not have any recorded content
      */
     bool isEmpty() const { return mDisplayList.empty(); }

     /**
      * Returns true if this list directly contains a GLFunctor drawing command.
      */
     bool hasFunctor() const { return !mChildFunctors.empty(); }

     /**
      * Returns true if this list directly contains a VectorDrawable drawing command.
      */
     bool hasVectorDrawables() const { return !mVectorDrawables.empty(); }

     bool hasText() const { return mDisplayList.hasText(); }

     /**
      * Attempts to reset and reuse this DisplayList.
      *
      * @return true if the displayList will be reused and therefore should not be deleted
      */
     bool reuseDisplayList(RenderNode* node, renderthread::CanvasContext* context);

     /**
      * ONLY to be called by RenderNode::syncDisplayList so that we can notify any
      * contained VectorDrawables or GLFunctors to sync their state.
      *
      * NOTE: This function can be folded into RenderNode when we no longer need
      *       to subclass from DisplayList
      */
     void syncContents(const WebViewSyncData& data);

     /**
      * ONLY to be called by RenderNode::prepareTree in order to prepare this
      * list while the UI thread is blocked.  Here we can upload mutable bitmaps
      * and notify our parent if any of our content has been invalidated and in
      * need of a redraw.  If the renderNode has any children then they are also
      * call in order to prepare them.
      *
      * @return true if any content change requires the node to be invalidated
      *
      * NOTE: This function can be folded into RenderNode when we no longer need
      *       to subclass from DisplayList
      */

     bool prepareListAndChildren(
             TreeObserver& observer, TreeInfo& info, bool functorsNeedLayer,
             std::function<void(RenderNode*, TreeObserver&, TreeInfo&, bool)> childFn);

     /**
      *  Calls the provided function once for each child of this DisplayList
      */
     void updateChildren(std::function<void(RenderNode*)> updateFn);

     /**
      *  Returns true if there is a child render node that is a projection receiver.
      */
     inline bool containsProjectionReceiver() const { return mProjectionReceiver; }

     void attachRecorder(RecordingCanvas* recorder, const SkIRect& bounds) {
         recorder->reset(&mDisplayList, bounds);
     }

     void draw(SkCanvas* canvas) { mDisplayList.draw(canvas); }

     void output(std::ostream& output, uint32_t level);

     LinearAllocator allocator;

     /**
      * We use std::deque here because (1) we need to iterate through these
      * elements and (2) mDisplayList holds pointers to the elements, so they
      * cannot relocate.
      */
     std::deque<RenderNodeDrawable> mChildNodes;
     std::deque<FunctorDrawable*> mChildFunctors;
     std::vector<SkImage*> mMutableImages;
 private:
     std::vector<Pair<VectorDrawableRoot*, SkMatrix>> mVectorDrawables;
 public:
     void appendVD(VectorDrawableRoot* r) {
         appendVD(r, SkMatrix::I());
     }

     void appendVD(VectorDrawableRoot* r, const SkMatrix& mat) {
         mVectorDrawables.push_back(Pair<VectorDrawableRoot*, SkMatrix>(r, mat));
     }

     std::vector<AnimatedImageDrawable*> mAnimatedImages;
     DisplayListData mDisplayList;

     // mProjectionReceiver points to a child node (stored in mChildNodes) that is as a projection
     // receiver. It is set at record time and used at both prepare and draw tree traversals to
     // make sure backward projected nodes are found and drawn immediately after mProjectionReceiver.
     RenderNodeDrawable* mProjectionReceiver = nullptr;

     // mProjectedOutline is valid only when render node tree is traversed during the draw pass.
     // Render nodes that have a child receiver node, will store a pointer to their outline in
     // mProjectedOutline. Child receiver node will apply the clip before any backward projected
     // node is drawn.
     const Outline* mProjectedOutline = nullptr;

     // mParentMatrix is set and valid when render node tree is traversed during the draw
     // pass. Render nodes, which draw in a order different than recording order (e.g. nodes with a
     // child receiver node or Z elevation), can use mParentMatrix to calculate the final transform
     // without replaying the matrix transform OPs from the display list.
     // Child receiver node will set the matrix and then clip with the outline of their parent.
     SkMatrix mParentMatrix;
 };

 }  // namespace skiapipeline
 }  // namespace uirenderer
 }  // namespace android
	/*
	* Copyright (C) 2016 The Android Open Source Project
	*
	* 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

	#include "RecordingCanvas.h"
	#include "RenderNodeDrawable.h"
	#include "TreeInfo.h"
	#include "hwui/AnimatedImageDrawable.h"
	#include "utils/LinearAllocator.h"
	#include "utils/Pair.h"

	#include <deque>

	namespace android {
	namespace uirenderer {

	namespace renderthread {
	class CanvasContext;
	}

	class Outline;
	struct WebViewSyncData;

	namespace VectorDrawable {
	class Tree;
	}
	typedef uirenderer::VectorDrawable::Tree VectorDrawableRoot;

	namespace skiapipeline {

	class FunctorDrawable;

	class SkiaDisplayList {
	public:
	size_t getUsedSize() { return allocator.usedSize() + mDisplayList.usedSize(); }
	size_t getAllocatedSize() { return allocator.allocatedSize() + mDisplayList.allocatedSize(); }

	~SkiaDisplayList() {
	/* Given that we are using a LinearStdAllocator to store some of the
	* SkDrawable contents we must ensure that any other object that is
	* holding a reference to those drawables is destroyed prior to their
	* deletion.
	*/
	mDisplayList.reset();
	}

	/**
	* This resets the DisplayList so that it behaves as if the object were newly
	* constructed. The reuse avoids any overhead associated with destroying
	* the SkLiteDL as well as the deques and vectors.
	*/
	void reset();

	/**
	* Use the linear allocator to create any SkDrawables needed by the display
	* list. This could be dangerous as these objects are ref-counted, so we
	* need to monitor that they don't extend beyond the lifetime of the class
	* that creates them. Allocator dtor invokes all SkDrawable dtors.
	*/
	template <class T, typename... Params>
	T* allocateDrawable(Params&&... params) {
	return allocator.create<T>(std::forward<Params>(params)...);
	}

	/**
	* Returns true if the DisplayList does not have any recorded content
	*/
	bool isEmpty() const { return mDisplayList.empty(); }

	/**
	* Returns true if this list directly contains a GLFunctor drawing command.
	*/
	bool hasFunctor() const { return !mChildFunctors.empty(); }

	/**
	* Returns true if this list directly contains a VectorDrawable drawing command.
	*/
	bool hasVectorDrawables() const { return !mVectorDrawables.empty(); }

	bool hasText() const { return mDisplayList.hasText(); }

	/**
	* Attempts to reset and reuse this DisplayList.
	*
	* @return true if the displayList will be reused and therefore should not be deleted
	*/
	bool reuseDisplayList(RenderNode* node, renderthread::CanvasContext* context);

	/**
	* ONLY to be called by RenderNode::syncDisplayList so that we can notify any
	* contained VectorDrawables or GLFunctors to sync their state.
	*
	* NOTE: This function can be folded into RenderNode when we no longer need
	* to subclass from DisplayList
	*/
	void syncContents(const WebViewSyncData& data);

	/**
	* ONLY to be called by RenderNode::prepareTree in order to prepare this
	* list while the UI thread is blocked. Here we can upload mutable bitmaps
	* and notify our parent if any of our content has been invalidated and in
	* need of a redraw. If the renderNode has any children then they are also
	* call in order to prepare them.
	*
	* @return true if any content change requires the node to be invalidated
	*
	* NOTE: This function can be folded into RenderNode when we no longer need
	* to subclass from DisplayList
	*/

	bool prepareListAndChildren(
	TreeObserver& observer, TreeInfo& info, bool functorsNeedLayer,
	std::function<void(RenderNode*, TreeObserver&, TreeInfo&, bool)> childFn);

	/**
	* Calls the provided function once for each child of this DisplayList
	*/
	void updateChildren(std::function<void(RenderNode*)> updateFn);

	/**
	* Returns true if there is a child render node that is a projection receiver.
	*/
	inline bool containsProjectionReceiver() const { return mProjectionReceiver; }

	void attachRecorder(RecordingCanvas* recorder, const SkIRect& bounds) {
	recorder->reset(&mDisplayList, bounds);
	}

	void draw(SkCanvas* canvas) { mDisplayList.draw(canvas); }

	void output(std::ostream& output, uint32_t level);

	LinearAllocator allocator;

	/**
	* We use std::deque here because (1) we need to iterate through these
	* elements and (2) mDisplayList holds pointers to the elements, so they
	* cannot relocate.
	*/
	std::deque<RenderNodeDrawable> mChildNodes;
	std::deque<FunctorDrawable*> mChildFunctors;
	std::vector<SkImage*> mMutableImages;
	private:
	std::vector<Pair<VectorDrawableRoot*, SkMatrix>> mVectorDrawables;
	public:
	void appendVD(VectorDrawableRoot* r) {
	appendVD(r, SkMatrix::I());
	}

	void appendVD(VectorDrawableRoot* r, const SkMatrix& mat) {
	mVectorDrawables.push_back(Pair<VectorDrawableRoot*, SkMatrix>(r, mat));
	}

	std::vector<AnimatedImageDrawable*> mAnimatedImages;
	DisplayListData mDisplayList;

	// mProjectionReceiver points to a child node (stored in mChildNodes) that is as a projection
	// receiver. It is set at record time and used at both prepare and draw tree traversals to
	// make sure backward projected nodes are found and drawn immediately after mProjectionReceiver.
	RenderNodeDrawable* mProjectionReceiver = nullptr;

	// mProjectedOutline is valid only when render node tree is traversed during the draw pass.
	// Render nodes that have a child receiver node, will store a pointer to their outline in
	// mProjectedOutline. Child receiver node will apply the clip before any backward projected
	// node is drawn.
	const Outline* mProjectedOutline = nullptr;

	// mParentMatrix is set and valid when render node tree is traversed during the draw
	// pass. Render nodes, which draw in a order different than recording order (e.g. nodes with a
	// child receiver node or Z elevation), can use mParentMatrix to calculate the final transform
	// without replaying the matrix transform OPs from the display list.
	// Child receiver node will set the matrix and then clip with the outline of their parent.
	SkMatrix mParentMatrix;
	};

	} // namespace skiapipeline
	} // namespace uirenderer
	} // namespace android