libs/hwui/RenderNode.h - platform/frameworks/base - Gitiles

 /*
  * Copyright (C) 2014 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.
  */
 #ifndef RENDERNODE_H
 #define RENDERNODE_H

 #include <SkCamera.h>
 #include <SkMatrix.h>

 #include <utils/LinearAllocator.h>
 #include <utils/RefBase.h>
 #include <utils/String8.h>

 #include <cutils/compiler.h>

 #include <androidfw/ResourceTypes.h>

 #include "AnimatorManager.h"
 #include "Debug.h"
 #include "DisplayList.h"
 #include "Matrix.h"
 #include "RenderProperties.h"

 #include <vector>

 class SkBitmap;
 class SkPaint;
 class SkPath;
 class SkRegion;

 namespace android {
 namespace uirenderer {

 class CanvasState;
 class DisplayListCanvas;
 class DisplayListOp;
 class OpenGLRenderer;
 class Rect;
 class SkiaShader;

 #if HWUI_NEW_OPS
 class FrameBuilder;
 class OffscreenBuffer;
 struct RenderNodeOp;
 typedef OffscreenBuffer layer_t;
 typedef RenderNodeOp renderNodeOp_t;
 #else
 class Layer;
 typedef Layer layer_t;
 typedef DrawRenderNodeOp renderNodeOp_t;
 #endif

 class ClipRectOp;
 class DrawRenderNodeOp;
 class SaveLayerOp;
 class SaveOp;
 class RestoreToCountOp;
 class TreeInfo;
 class TreeObserver;

 namespace proto {
 class RenderNode;
 }

 /**
  * Primary class for storing recorded canvas commands, as well as per-View/ViewGroup display properties.
  *
  * Recording of canvas commands is somewhat similar to SkPicture, except the canvas-recording
  * functionality is split between DisplayListCanvas (which manages the recording), DisplayList
  * (which holds the actual data), and DisplayList (which holds properties and performs playback onto
  * a renderer).
  *
  * Note that DisplayList is swapped out from beneath an individual RenderNode when a view's
  * recorded stream of canvas operations is refreshed. The RenderNode (and its properties) stay
  * attached.
  */
 class RenderNode : public VirtualLightRefBase {
 friend class TestUtils; // allow TestUtils to access syncDisplayList / syncProperties
 friend class FrameBuilder;
 public:
     enum DirtyPropertyMask {
         GENERIC         = 1 << 1,
         TRANSLATION_X   = 1 << 2,
         TRANSLATION_Y   = 1 << 3,
         TRANSLATION_Z   = 1 << 4,
         SCALE_X         = 1 << 5,
         SCALE_Y         = 1 << 6,
         ROTATION        = 1 << 7,
         ROTATION_X      = 1 << 8,
         ROTATION_Y      = 1 << 9,
         X               = 1 << 10,
         Y               = 1 << 11,
         Z               = 1 << 12,
         ALPHA           = 1 << 13,
         DISPLAY_LIST    = 1 << 14,
     };

     ANDROID_API RenderNode();
     ANDROID_API virtual ~RenderNode();

     // See flags defined in DisplayList.java
     enum ReplayFlag {
         kReplayFlag_ClipChildren = 0x1
     };

     void debugDumpLayers(const char* prefix);

     ANDROID_API void setStagingDisplayList(DisplayList* newData, TreeObserver* observer);

     void computeOrdering();

     void defer(DeferStateStruct& deferStruct, const int level);
     void replay(ReplayStateStruct& replayStruct, const int level);

 #if HWUI_NEW_OPS
     ANDROID_API void output(uint32_t level = 0, const char* label = "Root");
 #else
     ANDROID_API void output(uint32_t level = 1);
 #endif
     ANDROID_API int getDebugSize();
     void copyTo(proto::RenderNode* node);

     bool isRenderable() const {
         return mDisplayList && !mDisplayList->isEmpty();
     }

     bool hasProjectionReceiver() const {
         return mDisplayList && mDisplayList->projectionReceiveIndex >= 0;
     }

     const char* getName() const {
         return mName.string();
     }

     void setName(const char* name) {
         if (name) {
             const char* lastPeriod = strrchr(name, '.');
             if (lastPeriod) {
                 mName.setTo(lastPeriod + 1);
             } else {
                 mName.setTo(name);
             }
         }
     }

     VirtualLightRefBase* getUserContext() const {
         return mUserContext.get();
     }

     void setUserContext(VirtualLightRefBase* context) {
         mUserContext = context;
     }

     bool isPropertyFieldDirty(DirtyPropertyMask field) const {
         return mDirtyPropertyFields & field;
     }

     void setPropertyFieldsDirty(uint32_t fields) {
         mDirtyPropertyFields |= fields;
     }

     const RenderProperties& properties() const {
         return mProperties;
     }

     RenderProperties& animatorProperties() {
         return mProperties;
     }

     const RenderProperties& stagingProperties() {
         return mStagingProperties;
     }

     RenderProperties& mutateStagingProperties() {
         return mStagingProperties;
     }

     int getWidth() const {
         return properties().getWidth();
     }

     int getHeight() const {
         return properties().getHeight();
     }

     ANDROID_API virtual void prepareTree(TreeInfo& info);
     void destroyHardwareResources(TreeObserver* observer, TreeInfo* info = nullptr);

     // UI thread only!
     ANDROID_API void addAnimator(const sp<BaseRenderNodeAnimator>& animator);
     void removeAnimator(const sp<BaseRenderNodeAnimator>& animator);

     // This can only happen during pushStaging()
     void onAnimatorTargetChanged(BaseRenderNodeAnimator* animator) {
         mAnimatorManager.onAnimatorTargetChanged(animator);
     }

     AnimatorManager& animators() { return mAnimatorManager; }

     void applyViewPropertyTransforms(mat4& matrix, bool true3dTransform = false) const;

     bool nothingToDraw() const {
         const Outline& outline = properties().getOutline();
         return mDisplayList == nullptr
                 || properties().getAlpha() <= 0
                 || (outline.getShouldClip() && outline.isEmpty())
                 || properties().getScaleX() == 0
                 || properties().getScaleY() == 0;
     }

     const DisplayList* getDisplayList() const {
         return mDisplayList;
     }
 #if HWUI_NEW_OPS
     OffscreenBuffer* getLayer() const { return mLayer; }
     OffscreenBuffer** getLayerHandle() { return &mLayer; } // ugh...
 #endif

     // Note: The position callbacks are relying on the listener using
     // the frameNumber to appropriately batch/synchronize these transactions.
     // There is no other filtering/batching to ensure that only the "final"
     // state called once per frame.
     class ANDROID_API PositionListener : public VirtualLightRefBase {
     public:
         virtual ~PositionListener() {}
         // Called when the RenderNode's position changes
         virtual void onPositionUpdated(RenderNode& node, const TreeInfo& info) = 0;
         // Called when the RenderNode no longer has a position. As in, it's
         // no longer being drawn.
         // Note, tree info might be null
         virtual void onPositionLost(RenderNode& node, const TreeInfo* info) = 0;
     };

     // Note this is not thread safe, this needs to be called
     // before the RenderNode is used for drawing.
     // RenderNode takes ownership of the pointer
     ANDROID_API void setPositionListener(PositionListener* listener) {
         mPositionListener = listener;
     }

     // This is only modified in MODE_FULL, so it can be safely accessed
     // on the UI thread.
     ANDROID_API bool hasParents() {
         return mParentCount;
     }

 private:
     typedef key_value_pair_t<float, DrawRenderNodeOp*> ZDrawRenderNodeOpPair;

     static size_t findNonNegativeIndex(const std::vector<ZDrawRenderNodeOpPair>& nodes) {
         for (size_t i = 0; i < nodes.size(); i++) {
             if (nodes[i].key >= 0.0f) return i;
         }
         return nodes.size();
     }

     enum class ChildrenSelectMode {
         NegativeZChildren,
         PositiveZChildren
     };

     void computeOrderingImpl(renderNodeOp_t* opState,
             std::vector<renderNodeOp_t*>* compositedChildrenOfProjectionSurface,
             const mat4* transformFromProjectionSurface);

     template <class T>
     inline void setViewProperties(OpenGLRenderer& renderer, T& handler);

     void buildZSortedChildList(const DisplayList::Chunk& chunk,
             std::vector<ZDrawRenderNodeOpPair>& zTranslatedNodes);

     template<class T>
     inline void issueDrawShadowOperation(const Matrix4& transformFromParent, T& handler);

     template <class T>
     inline void issueOperationsOf3dChildren(ChildrenSelectMode mode,
             const Matrix4& initialTransform, const std::vector<ZDrawRenderNodeOpPair>& zTranslatedNodes,
             OpenGLRenderer& renderer, T& handler);

     template <class T>
     inline void issueOperationsOfProjectedChildren(OpenGLRenderer& renderer, T& handler);

     /**
      * Issue the RenderNode's operations into a handler, recursing for subtrees through
      * DrawRenderNodeOp's defer() or replay() methods
      */
     template <class T>
     inline void issueOperations(OpenGLRenderer& renderer, T& handler);

     class TextContainer {
     public:
         size_t length() const {
             return mByteLength;
         }

         const char* text() const {
             return (const char*) mText;
         }

         size_t mByteLength;
         const char* mText;
     };


     void syncProperties();
     void syncDisplayList(TreeInfo* info);

     void prepareTreeImpl(TreeInfo& info, bool functorsNeedLayer);
     void pushStagingPropertiesChanges(TreeInfo& info);
     void pushStagingDisplayListChanges(TreeInfo& info);
     void prepareSubTree(TreeInfo& info, bool functorsNeedLayer, DisplayList* subtree);
 #if !HWUI_NEW_OPS
     void applyLayerPropertiesToLayer(TreeInfo& info);
 #endif
     void prepareLayer(TreeInfo& info, uint32_t dirtyMask);
     void pushLayerUpdate(TreeInfo& info);
     void deleteDisplayList(TreeObserver* observer, TreeInfo* info = nullptr);
     void damageSelf(TreeInfo& info);

     void incParentRefCount() { mParentCount++; }
     void decParentRefCount(TreeObserver* observer, TreeInfo* info = nullptr);

     String8 mName;
     sp<VirtualLightRefBase> mUserContext;

     uint32_t mDirtyPropertyFields;
     RenderProperties mProperties;
     RenderProperties mStagingProperties;

     bool mNeedsDisplayListSync;
     // WARNING: Do not delete this directly, you must go through deleteDisplayList()!
     DisplayList* mDisplayList;
     DisplayList* mStagingDisplayList;

     friend class AnimatorManager;
     AnimatorManager mAnimatorManager;

     // Owned by RT. Lifecycle is managed by prepareTree(), with the exception
     // being in ~RenderNode() which may happen on any thread.
     layer_t* mLayer = nullptr;

     /**
      * Draw time state - these properties are only set and used during rendering
      */

     // for projection surfaces, contains a list of all children items
     std::vector<renderNodeOp_t*> mProjectedNodes;

     // How many references our parent(s) have to us. Typically this should alternate
     // between 2 and 1 (when a staging push happens we inc first then dec)
     // When this hits 0 we are no longer in the tree, so any hardware resources
     // (specifically Layers) should be released.
     // This is *NOT* thread-safe, and should therefore only be tracking
     // mDisplayList, not mStagingDisplayList.
     uint32_t mParentCount;

     sp<PositionListener> mPositionListener;
 }; // class RenderNode

 } /* namespace uirenderer */
 } /* namespace android */

 #endif /* RENDERNODE_H */
	/*
	* Copyright (C) 2014 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.
	*/
	#ifndef RENDERNODE_H
	#define RENDERNODE_H

	#include <SkCamera.h>
	#include <SkMatrix.h>

	#include <utils/LinearAllocator.h>
	#include <utils/RefBase.h>
	#include <utils/String8.h>

	#include <cutils/compiler.h>

	#include <androidfw/ResourceTypes.h>

	#include "AnimatorManager.h"
	#include "Debug.h"
	#include "DisplayList.h"
	#include "Matrix.h"
	#include "RenderProperties.h"

	#include <vector>

	class SkBitmap;
	class SkPaint;
	class SkPath;
	class SkRegion;

	namespace android {
	namespace uirenderer {

	class CanvasState;
	class DisplayListCanvas;
	class DisplayListOp;
	class OpenGLRenderer;
	class Rect;
	class SkiaShader;

	#if HWUI_NEW_OPS
	class FrameBuilder;
	class OffscreenBuffer;
	struct RenderNodeOp;
	typedef OffscreenBuffer layer_t;
	typedef RenderNodeOp renderNodeOp_t;
	#else
	class Layer;
	typedef Layer layer_t;
	typedef DrawRenderNodeOp renderNodeOp_t;
	#endif

	class ClipRectOp;
	class DrawRenderNodeOp;
	class SaveLayerOp;
	class SaveOp;
	class RestoreToCountOp;
	class TreeInfo;
	class TreeObserver;

	namespace proto {
	class RenderNode;
	}

	/**
	* Primary class for storing recorded canvas commands, as well as per-View/ViewGroup display properties.
	*
	* Recording of canvas commands is somewhat similar to SkPicture, except the canvas-recording
	* functionality is split between DisplayListCanvas (which manages the recording), DisplayList
	* (which holds the actual data), and DisplayList (which holds properties and performs playback onto
	* a renderer).
	*
	* Note that DisplayList is swapped out from beneath an individual RenderNode when a view's
	* recorded stream of canvas operations is refreshed. The RenderNode (and its properties) stay
	* attached.
	*/
	class RenderNode : public VirtualLightRefBase {
	friend class TestUtils; // allow TestUtils to access syncDisplayList / syncProperties
	friend class FrameBuilder;
	public:
	enum DirtyPropertyMask {
	GENERIC = 1 << 1,
	TRANSLATION_X = 1 << 2,
	TRANSLATION_Y = 1 << 3,
	TRANSLATION_Z = 1 << 4,
	SCALE_X = 1 << 5,
	SCALE_Y = 1 << 6,
	ROTATION = 1 << 7,
	ROTATION_X = 1 << 8,
	ROTATION_Y = 1 << 9,
	X = 1 << 10,
	Y = 1 << 11,
	Z = 1 << 12,
	ALPHA = 1 << 13,
	DISPLAY_LIST = 1 << 14,
	};

	ANDROID_API RenderNode();
	ANDROID_API virtual ~RenderNode();

	// See flags defined in DisplayList.java
	enum ReplayFlag {
	kReplayFlag_ClipChildren = 0x1
	};

	void debugDumpLayers(const char* prefix);

	ANDROID_API void setStagingDisplayList(DisplayList* newData, TreeObserver* observer);

	void computeOrdering();

	void defer(DeferStateStruct& deferStruct, const int level);
	void replay(ReplayStateStruct& replayStruct, const int level);

	#if HWUI_NEW_OPS
	ANDROID_API void output(uint32_t level = 0, const char* label = "Root");
	#else
	ANDROID_API void output(uint32_t level = 1);
	#endif
	ANDROID_API int getDebugSize();
	void copyTo(proto::RenderNode* node);

	bool isRenderable() const {
	return mDisplayList && !mDisplayList->isEmpty();
	}

	bool hasProjectionReceiver() const {
	return mDisplayList && mDisplayList->projectionReceiveIndex >= 0;
	}

	const char* getName() const {
	return mName.string();
	}

	void setName(const char* name) {
	if (name) {
	const char* lastPeriod = strrchr(name, '.');
	if (lastPeriod) {
	mName.setTo(lastPeriod + 1);
	} else {
	mName.setTo(name);
	}
	}
	}

	VirtualLightRefBase* getUserContext() const {
	return mUserContext.get();
	}

	void setUserContext(VirtualLightRefBase* context) {
	mUserContext = context;
	}

	bool isPropertyFieldDirty(DirtyPropertyMask field) const {
	return mDirtyPropertyFields & field;
	}

	void setPropertyFieldsDirty(uint32_t fields) {
	mDirtyPropertyFields \|= fields;
	}

	const RenderProperties& properties() const {
	return mProperties;
	}

	RenderProperties& animatorProperties() {
	return mProperties;
	}

	const RenderProperties& stagingProperties() {
	return mStagingProperties;
	}

	RenderProperties& mutateStagingProperties() {
	return mStagingProperties;
	}

	int getWidth() const {
	return properties().getWidth();
	}

	int getHeight() const {
	return properties().getHeight();
	}

	ANDROID_API virtual void prepareTree(TreeInfo& info);
	void destroyHardwareResources(TreeObserver* observer, TreeInfo* info = nullptr);

	// UI thread only!
	ANDROID_API void addAnimator(const sp<BaseRenderNodeAnimator>& animator);
	void removeAnimator(const sp<BaseRenderNodeAnimator>& animator);

	// This can only happen during pushStaging()
	void onAnimatorTargetChanged(BaseRenderNodeAnimator* animator) {
	mAnimatorManager.onAnimatorTargetChanged(animator);
	}

	AnimatorManager& animators() { return mAnimatorManager; }

	void applyViewPropertyTransforms(mat4& matrix, bool true3dTransform = false) const;

	bool nothingToDraw() const {
	const Outline& outline = properties().getOutline();
	return mDisplayList == nullptr
	\|\| properties().getAlpha() <= 0
	\|\| (outline.getShouldClip() && outline.isEmpty())
	\|\| properties().getScaleX() == 0
	\|\| properties().getScaleY() == 0;
	}

	const DisplayList* getDisplayList() const {
	return mDisplayList;
	}
	#if HWUI_NEW_OPS
	OffscreenBuffer* getLayer() const { return mLayer; }
	OffscreenBuffer** getLayerHandle() { return &mLayer; } // ugh...
	#endif

	// Note: The position callbacks are relying on the listener using
	// the frameNumber to appropriately batch/synchronize these transactions.
	// There is no other filtering/batching to ensure that only the "final"
	// state called once per frame.
	class ANDROID_API PositionListener : public VirtualLightRefBase {
	public:
	virtual ~PositionListener() {}
	// Called when the RenderNode's position changes
	virtual void onPositionUpdated(RenderNode& node, const TreeInfo& info) = 0;
	// Called when the RenderNode no longer has a position. As in, it's
	// no longer being drawn.
	// Note, tree info might be null
	virtual void onPositionLost(RenderNode& node, const TreeInfo* info) = 0;
	};

	// Note this is not thread safe, this needs to be called
	// before the RenderNode is used for drawing.
	// RenderNode takes ownership of the pointer
	ANDROID_API void setPositionListener(PositionListener* listener) {
	mPositionListener = listener;
	}

	// This is only modified in MODE_FULL, so it can be safely accessed
	// on the UI thread.
	ANDROID_API bool hasParents() {
	return mParentCount;
	}

	private:
	typedef key_value_pair_t<float, DrawRenderNodeOp*> ZDrawRenderNodeOpPair;

	static size_t findNonNegativeIndex(const std::vector<ZDrawRenderNodeOpPair>& nodes) {
	for (size_t i = 0; i < nodes.size(); i++) {
	if (nodes[i].key >= 0.0f) return i;
	}
	return nodes.size();
	}

	enum class ChildrenSelectMode {
	NegativeZChildren,
	PositiveZChildren
	};

	void computeOrderingImpl(renderNodeOp_t* opState,
	std::vector<renderNodeOp_t> compositedChildrenOfProjectionSurface,
	const mat4* transformFromProjectionSurface);

	template <class T>
	inline void setViewProperties(OpenGLRenderer& renderer, T& handler);

	void buildZSortedChildList(const DisplayList::Chunk& chunk,
	std::vector<ZDrawRenderNodeOpPair>& zTranslatedNodes);

	template<class T>
	inline void issueDrawShadowOperation(const Matrix4& transformFromParent, T& handler);

	template <class T>
	inline void issueOperationsOf3dChildren(ChildrenSelectMode mode,
	const Matrix4& initialTransform, const std::vector<ZDrawRenderNodeOpPair>& zTranslatedNodes,
	OpenGLRenderer& renderer, T& handler);

	template <class T>
	inline void issueOperationsOfProjectedChildren(OpenGLRenderer& renderer, T& handler);

	/**
	* Issue the RenderNode's operations into a handler, recursing for subtrees through
	* DrawRenderNodeOp's defer() or replay() methods
	*/
	template <class T>
	inline void issueOperations(OpenGLRenderer& renderer, T& handler);

	class TextContainer {
	public:
	size_t length() const {
	return mByteLength;
	}

	const char* text() const {
	return (const char*) mText;
	}

	size_t mByteLength;
	const char* mText;
	};


	void syncProperties();
	void syncDisplayList(TreeInfo* info);

	void prepareTreeImpl(TreeInfo& info, bool functorsNeedLayer);
	void pushStagingPropertiesChanges(TreeInfo& info);
	void pushStagingDisplayListChanges(TreeInfo& info);
	void prepareSubTree(TreeInfo& info, bool functorsNeedLayer, DisplayList* subtree);
	#if !HWUI_NEW_OPS
	void applyLayerPropertiesToLayer(TreeInfo& info);
	#endif
	void prepareLayer(TreeInfo& info, uint32_t dirtyMask);
	void pushLayerUpdate(TreeInfo& info);
	void deleteDisplayList(TreeObserver* observer, TreeInfo* info = nullptr);
	void damageSelf(TreeInfo& info);

	void incParentRefCount() { mParentCount++; }
	void decParentRefCount(TreeObserver* observer, TreeInfo* info = nullptr);

	String8 mName;
	sp<VirtualLightRefBase> mUserContext;

	uint32_t mDirtyPropertyFields;
	RenderProperties mProperties;
	RenderProperties mStagingProperties;

	bool mNeedsDisplayListSync;
	// WARNING: Do not delete this directly, you must go through deleteDisplayList()!
	DisplayList* mDisplayList;
	DisplayList* mStagingDisplayList;

	friend class AnimatorManager;
	AnimatorManager mAnimatorManager;

	// Owned by RT. Lifecycle is managed by prepareTree(), with the exception
	// being in ~RenderNode() which may happen on any thread.
	layer_t* mLayer = nullptr;

	/**
	* Draw time state - these properties are only set and used during rendering
	*/

	// for projection surfaces, contains a list of all children items
	std::vector<renderNodeOp_t*> mProjectedNodes;

	// How many references our parent(s) have to us. Typically this should alternate
	// between 2 and 1 (when a staging push happens we inc first then dec)
	// When this hits 0 we are no longer in the tree, so any hardware resources
	// (specifically Layers) should be released.
	// This is NOT thread-safe, and should therefore only be tracking
	// mDisplayList, not mStagingDisplayList.
	uint32_t mParentCount;

	sp<PositionListener> mPositionListener;
	}; // class RenderNode

	} /* namespace uirenderer */
	} /* namespace android */

	#endif /* RENDERNODE_H */