libs/hwui/DamageAccumulator.cpp - LeafOS-Project/android_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.
  */

 #include "DamageAccumulator.h"

 #include <log/log.h>

 #include "RenderNode.h"
 #include "utils/MathUtils.h"

 namespace android {
 namespace uirenderer {

 enum TransformType {
     TransformInvalid = 0,
     TransformRenderNode,
     TransformMatrix4,
     TransformNone,
 };

 struct DirtyStack {
     TransformType type;
     union {
         const RenderNode* renderNode;
         const Matrix4* matrix4;
     };
     // When this frame is pop'd, this rect is mapped through the above transform
     // and applied to the previous (aka parent) frame
     SkRect pendingDirty;
     DirtyStack* prev;
     DirtyStack* next;
 };

 DamageAccumulator::DamageAccumulator() {
     mHead = mAllocator.create_trivial<DirtyStack>();
     memset(mHead, 0, sizeof(DirtyStack));
     // Create a root that we will not pop off
     mHead->prev = mHead;
     mHead->type = TransformNone;
 }

 static void computeTransformImpl(const DirtyStack* currentFrame, Matrix4* outMatrix) {
     if (currentFrame->prev != currentFrame) {
         computeTransformImpl(currentFrame->prev, outMatrix);
     }
     switch (currentFrame->type) {
         case TransformRenderNode:
             currentFrame->renderNode->applyViewPropertyTransforms(*outMatrix);
             break;
         case TransformMatrix4:
             outMatrix->multiply(*currentFrame->matrix4);
             break;
         case TransformNone:
             // nothing to be done
             break;
         default:
             LOG_ALWAYS_FATAL("Tried to compute transform with an invalid type: %d",
                              currentFrame->type);
     }
 }

 void DamageAccumulator::computeCurrentTransform(Matrix4* outMatrix) const {
     outMatrix->loadIdentity();
     computeTransformImpl(mHead, outMatrix);
 }

 void DamageAccumulator::pushCommon() {
     if (!mHead->next) {
         DirtyStack* nextFrame = mAllocator.create_trivial<DirtyStack>();
         nextFrame->next = nullptr;
         nextFrame->prev = mHead;
         mHead->next = nextFrame;
     }
     mHead = mHead->next;
     mHead->pendingDirty.setEmpty();
 }

 void DamageAccumulator::pushTransform(const RenderNode* transform) {
     pushCommon();
     mHead->type = TransformRenderNode;
     mHead->renderNode = transform;
 }

 void DamageAccumulator::pushTransform(const Matrix4* transform) {
     pushCommon();
     mHead->type = TransformMatrix4;
     mHead->matrix4 = transform;
 }

 void DamageAccumulator::popTransform() {
     LOG_ALWAYS_FATAL_IF(mHead->prev == mHead, "Cannot pop the root frame!");
     DirtyStack* dirtyFrame = mHead;
     mHead = mHead->prev;
     switch (dirtyFrame->type) {
         case TransformRenderNode:
             applyRenderNodeTransform(dirtyFrame);
             break;
         case TransformMatrix4:
             applyMatrix4Transform(dirtyFrame);
             break;
         case TransformNone:
             mHead->pendingDirty.join(dirtyFrame->pendingDirty);
             break;
         default:
             LOG_ALWAYS_FATAL("Tried to pop an invalid type: %d", dirtyFrame->type);
     }
 }

 static inline void mapRect(const Matrix4* matrix, const SkRect& in, SkRect* out) {
     if (in.isEmpty()) return;
     Rect temp(in);
     if (CC_LIKELY(!matrix->isPerspective())) {
         matrix->mapRect(temp);
     } else {
         // Don't attempt to calculate damage for a perspective transform
         // as the numbers this works with can break the perspective
         // calculations. Just give up and expand to DIRTY_MIN/DIRTY_MAX
         temp.set(DIRTY_MIN, DIRTY_MIN, DIRTY_MAX, DIRTY_MAX);
     }
     out->join({RECT_ARGS(temp)});
 }

 void DamageAccumulator::applyMatrix4Transform(DirtyStack* frame) {
     mapRect(frame->matrix4, frame->pendingDirty, &mHead->pendingDirty);
 }

 static inline void applyMatrix(const SkMatrix* transform, SkRect* rect) {
     if (transform && !transform->isIdentity()) {
         if (CC_LIKELY(!transform->hasPerspective())) {
             transform->mapRect(rect);
         } else {
             // Don't attempt to calculate damage for a perspective transform
             // as the numbers this works with can break the perspective
             // calculations. Just give up and expand to DIRTY_MIN/DIRTY_MAX
             rect->setLTRB(DIRTY_MIN, DIRTY_MIN, DIRTY_MAX, DIRTY_MAX);
         }
     }
 }

 static inline void applyMatrix(const SkMatrix& transform, SkRect* rect) {
     return applyMatrix(&transform, rect);
 }

 static inline void mapRect(const RenderProperties& props, const SkRect& in, SkRect* out) {
     if (in.isEmpty()) return;
     SkRect temp(in);
     if (Properties::getStretchEffectBehavior() == StretchEffectBehavior::UniformScale) {
         const StretchEffect& stretch = props.layerProperties().getStretchEffect();
         if (!stretch.isEmpty()) {
             applyMatrix(stretch.makeLinearStretch(props.getWidth(), props.getHeight()), &temp);
         }
     }
     applyMatrix(props.getTransformMatrix(), &temp);
     if (props.getStaticMatrix()) {
         applyMatrix(props.getStaticMatrix(), &temp);
     } else if (props.getAnimationMatrix()) {
         applyMatrix(props.getAnimationMatrix(), &temp);
     }
     temp.offset(props.getLeft(), props.getTop());
     out->join(temp);
 }

 static DirtyStack* findParentRenderNode(DirtyStack* frame) {
     while (frame->prev != frame) {
         frame = frame->prev;
         if (frame->type == TransformRenderNode) {
             return frame;
         }
     }
     return nullptr;
 }

 static DirtyStack* findProjectionReceiver(DirtyStack* frame) {
     if (frame) {
         while (frame->prev != frame) {
             frame = frame->prev;
             if (frame->type == TransformRenderNode && frame->renderNode->hasProjectionReceiver()) {
                 return frame;
             }
         }
     }
     return nullptr;
 }

 static void applyTransforms(DirtyStack* frame, DirtyStack* end) {
     SkRect* rect = &frame->pendingDirty;
     while (frame != end) {
         if (frame->type == TransformRenderNode) {
             mapRect(frame->renderNode->properties(), *rect, rect);
         } else {
             mapRect(frame->matrix4, *rect, rect);
         }
         frame = frame->prev;
     }
 }

 void DamageAccumulator::applyRenderNodeTransform(DirtyStack* frame) {
     if (frame->pendingDirty.isEmpty()) {
         return;
     }

     const RenderProperties& props = frame->renderNode->properties();
     if (props.getAlpha() <= 0) {
         return;
     }

     // Perform clipping
     if (props.getClipDamageToBounds() && !frame->pendingDirty.isEmpty()) {
         if (!frame->pendingDirty.intersect(SkRect::MakeIWH(props.getWidth(), props.getHeight()))) {
             frame->pendingDirty.setEmpty();
         }
     }

     // apply all transforms
     mapRect(props, frame->pendingDirty, &mHead->pendingDirty);

     // project backwards if necessary
     if (props.getProjectBackwards() && !frame->pendingDirty.isEmpty()) {
         // First, find our parent RenderNode:
         DirtyStack* parentNode = findParentRenderNode(frame);
         // Find our parent's projection receiver, which is what we project onto
         DirtyStack* projectionReceiver = findProjectionReceiver(parentNode);
         if (projectionReceiver) {
             applyTransforms(frame, projectionReceiver);
             projectionReceiver->pendingDirty.join(frame->pendingDirty);
         }

         frame->pendingDirty.setEmpty();
     }
 }

 SkRect DamageAccumulator::computeClipAndTransform(const SkRect& bounds, Matrix4* outMatrix) const {
     const DirtyStack* frame = mHead;
     Matrix4 transform;
     SkRect pretransformResult = bounds;
     while (true) {
         SkRect currentBounds = pretransformResult;
         pretransformResult.setEmpty();
         switch (frame->type) {
             case TransformRenderNode: {
                 const RenderProperties& props = frame->renderNode->properties();
                 // Perform clipping
                 if (props.getClipDamageToBounds() && !currentBounds.isEmpty()) {
                     if (!currentBounds.intersect(
                                 SkRect::MakeIWH(props.getWidth(), props.getHeight()))) {
                         currentBounds.setEmpty();
                     }
                 }

                 // apply all transforms
                 mapRect(props, currentBounds, &pretransformResult);
                 frame->renderNode->applyViewPropertyTransforms(transform);
             } break;
             case TransformMatrix4:
                 mapRect(frame->matrix4, currentBounds, &pretransformResult);
                 transform.multiply(*frame->matrix4);
                 break;
             default:
                 pretransformResult = currentBounds;
                 break;
         }
         if (frame->prev == frame) break;
         frame = frame->prev;
     }
     SkRect result;
     Matrix4 globalToLocal;
     globalToLocal.loadInverse(transform);
     mapRect(&globalToLocal, pretransformResult, &result);
     *outMatrix = transform;
     return result;
 }

 void DamageAccumulator::dirty(float left, float top, float right, float bottom) {
     mHead->pendingDirty.join({left, top, right, bottom});
 }

 void DamageAccumulator::peekAtDirty(SkRect* dest) const {
     *dest = mHead->pendingDirty;
 }

 void DamageAccumulator::finish(SkRect* totalDirty) {
     LOG_ALWAYS_FATAL_IF(mHead->prev != mHead, "Cannot finish, mismatched push/pop calls! %p vs. %p",
                         mHead->prev, mHead);
     // Root node never has a transform, so this is the fully mapped dirty rect
     *totalDirty = mHead->pendingDirty;
     totalDirty->roundOut(totalDirty);
     mHead->pendingDirty.setEmpty();
 }

 DamageAccumulator::StretchResult DamageAccumulator::findNearestStretchEffect() const {
     DirtyStack* frame = mHead;
     while (frame->prev != frame) {
         if (frame->type == TransformRenderNode) {
             const auto& renderNode = frame->renderNode;
             const auto& frameRenderNodeProperties = renderNode->properties();
             const auto& effect =
                     frameRenderNodeProperties.layerProperties().getStretchEffect();
             const float width = (float) frameRenderNodeProperties.getWidth();
             const float height = (float) frameRenderNodeProperties.getHeight();
             if (!effect.isEmpty()) {
                 Matrix4 stretchMatrix;
                 computeTransformImpl(frame, &stretchMatrix);
                 Rect stretchRect = Rect(0.f, 0.f, width, height);
                 stretchMatrix.mapRect(stretchRect);

                 return StretchResult{
                         .stretchEffect = &effect,
                         .parentBounds = SkRect::MakeLTRB(stretchRect.left, stretchRect.top,
                                                          stretchRect.right, stretchRect.bottom),
                         .width = width,
                         .height = height};
             }
         }
         frame = frame->prev;
     }
     return StretchResult{};
 }

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

	#include "DamageAccumulator.h"

	#include <log/log.h>

	#include "RenderNode.h"
	#include "utils/MathUtils.h"

	namespace android {
	namespace uirenderer {

	enum TransformType {
	TransformInvalid = 0,
	TransformRenderNode,
	TransformMatrix4,
	TransformNone,
	};

	struct DirtyStack {
	TransformType type;
	union {
	const RenderNode* renderNode;
	const Matrix4* matrix4;
	};
	// When this frame is pop'd, this rect is mapped through the above transform
	// and applied to the previous (aka parent) frame
	SkRect pendingDirty;
	DirtyStack* prev;
	DirtyStack* next;
	};

	DamageAccumulator::DamageAccumulator() {
	mHead = mAllocator.create_trivial<DirtyStack>();
	memset(mHead, 0, sizeof(DirtyStack));
	// Create a root that we will not pop off
	mHead->prev = mHead;
	mHead->type = TransformNone;
	}

	static void computeTransformImpl(const DirtyStack* currentFrame, Matrix4* outMatrix) {
	if (currentFrame->prev != currentFrame) {
	computeTransformImpl(currentFrame->prev, outMatrix);
	}
	switch (currentFrame->type) {
	case TransformRenderNode:
	currentFrame->renderNode->applyViewPropertyTransforms(*outMatrix);
	break;
	case TransformMatrix4:
	outMatrix->multiply(*currentFrame->matrix4);
	break;
	case TransformNone:
	// nothing to be done
	break;
	default:
	LOG_ALWAYS_FATAL("Tried to compute transform with an invalid type: %d",
	currentFrame->type);
	}
	}

	void DamageAccumulator::computeCurrentTransform(Matrix4* outMatrix) const {
	outMatrix->loadIdentity();
	computeTransformImpl(mHead, outMatrix);
	}

	void DamageAccumulator::pushCommon() {
	if (!mHead->next) {
	DirtyStack* nextFrame = mAllocator.create_trivial<DirtyStack>();
	nextFrame->next = nullptr;
	nextFrame->prev = mHead;
	mHead->next = nextFrame;
	}
	mHead = mHead->next;
	mHead->pendingDirty.setEmpty();
	}

	void DamageAccumulator::pushTransform(const RenderNode* transform) {
	pushCommon();
	mHead->type = TransformRenderNode;
	mHead->renderNode = transform;
	}

	void DamageAccumulator::pushTransform(const Matrix4* transform) {
	pushCommon();
	mHead->type = TransformMatrix4;
	mHead->matrix4 = transform;
	}

	void DamageAccumulator::popTransform() {
	LOG_ALWAYS_FATAL_IF(mHead->prev == mHead, "Cannot pop the root frame!");
	DirtyStack* dirtyFrame = mHead;
	mHead = mHead->prev;
	switch (dirtyFrame->type) {
	case TransformRenderNode:
	applyRenderNodeTransform(dirtyFrame);
	break;
	case TransformMatrix4:
	applyMatrix4Transform(dirtyFrame);
	break;
	case TransformNone:
	mHead->pendingDirty.join(dirtyFrame->pendingDirty);
	break;
	default:
	LOG_ALWAYS_FATAL("Tried to pop an invalid type: %d", dirtyFrame->type);
	}
	}

	static inline void mapRect(const Matrix4* matrix, const SkRect& in, SkRect* out) {
	if (in.isEmpty()) return;
	Rect temp(in);
	if (CC_LIKELY(!matrix->isPerspective())) {
	matrix->mapRect(temp);
	} else {
	// Don't attempt to calculate damage for a perspective transform
	// as the numbers this works with can break the perspective
	// calculations. Just give up and expand to DIRTY_MIN/DIRTY_MAX
	temp.set(DIRTY_MIN, DIRTY_MIN, DIRTY_MAX, DIRTY_MAX);
	}
	out->join({RECT_ARGS(temp)});
	}

	void DamageAccumulator::applyMatrix4Transform(DirtyStack* frame) {
	mapRect(frame->matrix4, frame->pendingDirty, &mHead->pendingDirty);
	}

	static inline void applyMatrix(const SkMatrix* transform, SkRect* rect) {
	if (transform && !transform->isIdentity()) {
	if (CC_LIKELY(!transform->hasPerspective())) {
	transform->mapRect(rect);
	} else {
	// Don't attempt to calculate damage for a perspective transform
	// as the numbers this works with can break the perspective
	// calculations. Just give up and expand to DIRTY_MIN/DIRTY_MAX
	rect->setLTRB(DIRTY_MIN, DIRTY_MIN, DIRTY_MAX, DIRTY_MAX);
	}
	}
	}

	static inline void applyMatrix(const SkMatrix& transform, SkRect* rect) {
	return applyMatrix(&transform, rect);
	}

	static inline void mapRect(const RenderProperties& props, const SkRect& in, SkRect* out) {
	if (in.isEmpty()) return;
	SkRect temp(in);
	if (Properties::getStretchEffectBehavior() == StretchEffectBehavior::UniformScale) {
	const StretchEffect& stretch = props.layerProperties().getStretchEffect();
	if (!stretch.isEmpty()) {
	applyMatrix(stretch.makeLinearStretch(props.getWidth(), props.getHeight()), &temp);
	}
	}
	applyMatrix(props.getTransformMatrix(), &temp);
	if (props.getStaticMatrix()) {
	applyMatrix(props.getStaticMatrix(), &temp);
	} else if (props.getAnimationMatrix()) {
	applyMatrix(props.getAnimationMatrix(), &temp);
	}
	temp.offset(props.getLeft(), props.getTop());
	out->join(temp);
	}

	static DirtyStack* findParentRenderNode(DirtyStack* frame) {
	while (frame->prev != frame) {
	frame = frame->prev;
	if (frame->type == TransformRenderNode) {
	return frame;
	}
	}
	return nullptr;
	}

	static DirtyStack* findProjectionReceiver(DirtyStack* frame) {
	if (frame) {
	while (frame->prev != frame) {
	frame = frame->prev;
	if (frame->type == TransformRenderNode && frame->renderNode->hasProjectionReceiver()) {
	return frame;
	}
	}
	}
	return nullptr;
	}

	static void applyTransforms(DirtyStack* frame, DirtyStack* end) {
	SkRect* rect = &frame->pendingDirty;
	while (frame != end) {
	if (frame->type == TransformRenderNode) {
	mapRect(frame->renderNode->properties(), *rect, rect);
	} else {
	mapRect(frame->matrix4, *rect, rect);
	}
	frame = frame->prev;
	}
	}

	void DamageAccumulator::applyRenderNodeTransform(DirtyStack* frame) {
	if (frame->pendingDirty.isEmpty()) {
	return;
	}

	const RenderProperties& props = frame->renderNode->properties();
	if (props.getAlpha() <= 0) {
	return;
	}

	// Perform clipping
	if (props.getClipDamageToBounds() && !frame->pendingDirty.isEmpty()) {
	if (!frame->pendingDirty.intersect(SkRect::MakeIWH(props.getWidth(), props.getHeight()))) {
	frame->pendingDirty.setEmpty();
	}
	}

	// apply all transforms
	mapRect(props, frame->pendingDirty, &mHead->pendingDirty);

	// project backwards if necessary
	if (props.getProjectBackwards() && !frame->pendingDirty.isEmpty()) {
	// First, find our parent RenderNode:
	DirtyStack* parentNode = findParentRenderNode(frame);
	// Find our parent's projection receiver, which is what we project onto
	DirtyStack* projectionReceiver = findProjectionReceiver(parentNode);
	if (projectionReceiver) {
	applyTransforms(frame, projectionReceiver);
	projectionReceiver->pendingDirty.join(frame->pendingDirty);
	}

	frame->pendingDirty.setEmpty();
	}
	}

	SkRect DamageAccumulator::computeClipAndTransform(const SkRect& bounds, Matrix4* outMatrix) const {
	const DirtyStack* frame = mHead;
	Matrix4 transform;
	SkRect pretransformResult = bounds;
	while (true) {
	SkRect currentBounds = pretransformResult;
	pretransformResult.setEmpty();
	switch (frame->type) {
	case TransformRenderNode: {
	const RenderProperties& props = frame->renderNode->properties();
	// Perform clipping
	if (props.getClipDamageToBounds() && !currentBounds.isEmpty()) {
	if (!currentBounds.intersect(
	SkRect::MakeIWH(props.getWidth(), props.getHeight()))) {
	currentBounds.setEmpty();
	}
	}

	// apply all transforms
	mapRect(props, currentBounds, &pretransformResult);
	frame->renderNode->applyViewPropertyTransforms(transform);
	} break;
	case TransformMatrix4:
	mapRect(frame->matrix4, currentBounds, &pretransformResult);
	transform.multiply(*frame->matrix4);
	break;
	default:
	pretransformResult = currentBounds;
	break;
	}
	if (frame->prev == frame) break;
	frame = frame->prev;
	}
	SkRect result;
	Matrix4 globalToLocal;
	globalToLocal.loadInverse(transform);
	mapRect(&globalToLocal, pretransformResult, &result);
	*outMatrix = transform;
	return result;
	}

	void DamageAccumulator::dirty(float left, float top, float right, float bottom) {
	mHead->pendingDirty.join({left, top, right, bottom});
	}

	void DamageAccumulator::peekAtDirty(SkRect* dest) const {
	*dest = mHead->pendingDirty;
	}

	void DamageAccumulator::finish(SkRect* totalDirty) {
	LOG_ALWAYS_FATAL_IF(mHead->prev != mHead, "Cannot finish, mismatched push/pop calls! %p vs. %p",
	mHead->prev, mHead);
	// Root node never has a transform, so this is the fully mapped dirty rect
	*totalDirty = mHead->pendingDirty;
	totalDirty->roundOut(totalDirty);
	mHead->pendingDirty.setEmpty();
	}

	DamageAccumulator::StretchResult DamageAccumulator::findNearestStretchEffect() const {
	DirtyStack* frame = mHead;
	while (frame->prev != frame) {
	if (frame->type == TransformRenderNode) {
	const auto& renderNode = frame->renderNode;
	const auto& frameRenderNodeProperties = renderNode->properties();
	const auto& effect =
	frameRenderNodeProperties.layerProperties().getStretchEffect();
	const float width = (float) frameRenderNodeProperties.getWidth();
	const float height = (float) frameRenderNodeProperties.getHeight();
	if (!effect.isEmpty()) {
	Matrix4 stretchMatrix;
	computeTransformImpl(frame, &stretchMatrix);
	Rect stretchRect = Rect(0.f, 0.f, width, height);
	stretchMatrix.mapRect(stretchRect);

	return StretchResult{
	.stretchEffect = &effect,
	.parentBounds = SkRect::MakeLTRB(stretchRect.left, stretchRect.top,
	stretchRect.right, stretchRect.bottom),
	.width = width,
	.height = height};
	}
	}
	frame = frame->prev;
	}
	return StretchResult{};
	}

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