/* * 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. */ #include "SkiaDisplayList.h" #include "DumpOpsCanvas.h" #include "SkiaPipeline.h" #include "VectorDrawable.h" #include "renderthread/CanvasContext.h" #include #include namespace android { namespace uirenderer { namespace skiapipeline { void SkiaDisplayList::syncContents(const WebViewSyncData& data) { for (auto& functor : mChildFunctors) { functor->syncFunctor(data); } for (auto& animatedImage : mAnimatedImages) { animatedImage->syncProperties(); } for (auto& vectorDrawable : mVectorDrawables) { vectorDrawable.first->syncProperties(); } } bool SkiaDisplayList::reuseDisplayList(RenderNode* node, renderthread::CanvasContext* context) { reset(); node->attachAvailableList(this); return true; } void SkiaDisplayList::updateChildren(std::function updateFn) { for (auto& child : mChildNodes) { updateFn(child.getRenderNode()); } } static bool intersects(const SkISize screenSize, const Matrix4& mat, const SkRect& bounds) { Vector3 points[] = { Vector3 {bounds.fLeft, bounds.fTop, 0}, Vector3 {bounds.fRight, bounds.fTop, 0}, Vector3 {bounds.fRight, bounds.fBottom, 0}, Vector3 {bounds.fLeft, bounds.fBottom, 0}}; float minX, minY, maxX, maxY; bool first = true; for (auto& point : points) { mat.mapPoint3d(point); if (first) { minX = maxX = point.x; minY = maxY = point.y; first = false; } else { minX = std::min(minX, point.x); minY = std::min(minY, point.y); maxX = std::max(maxX, point.x); maxY = std::max(maxY, point.y); } } return SkRect::Make(screenSize).intersects(SkRect::MakeLTRB(minX, minY, maxX, maxY)); } bool SkiaDisplayList::prepareListAndChildren( TreeObserver& observer, TreeInfo& info, bool functorsNeedLayer, std::function childFn) { // If the prepare tree is triggered by the UI thread and no previous call to // pinImages has failed then we must pin all mutable images in the GPU cache // until the next UI thread draw. if (info.prepareTextures && !info.canvasContext.pinImages(mMutableImages)) { // In the event that pinning failed we prevent future pinImage calls for the // remainder of this tree traversal and also unpin any currently pinned images // to free up GPU resources. info.prepareTextures = false; info.canvasContext.unpinImages(); } bool hasBackwardProjectedNodesHere = false; bool hasBackwardProjectedNodesSubtree = false; for (auto& child : mChildNodes) { hasBackwardProjectedNodesHere |= child.getNodeProperties().getProjectBackwards(); RenderNode* childNode = child.getRenderNode(); Matrix4 mat4(child.getRecordedMatrix()); info.damageAccumulator->pushTransform(&mat4); info.hasBackwardProjectedNodes = false; childFn(childNode, observer, info, functorsNeedLayer); hasBackwardProjectedNodesSubtree |= info.hasBackwardProjectedNodes; info.damageAccumulator->popTransform(); } // The purpose of next block of code is to reset projected display list if there are no // backward projected nodes. This speeds up drawing, by avoiding an extra walk of the tree if (mProjectionReceiver) { mProjectionReceiver->setProjectedDisplayList(hasBackwardProjectedNodesSubtree ? this : nullptr); info.hasBackwardProjectedNodes = hasBackwardProjectedNodesHere; } else { info.hasBackwardProjectedNodes = hasBackwardProjectedNodesSubtree || hasBackwardProjectedNodesHere; } bool isDirty = false; for (auto& animatedImage : mAnimatedImages) { nsecs_t timeTilNextFrame = TreeInfo::Out::kNoAnimatedImageDelay; // If any animated image in the display list needs updated, then damage the node. if (animatedImage->isDirty(&timeTilNextFrame)) { isDirty = true; } if (animatedImage->isRunning() && timeTilNextFrame != TreeInfo::Out::kNoAnimatedImageDelay) { auto& delay = info.out.animatedImageDelay; if (delay == TreeInfo::Out::kNoAnimatedImageDelay || timeTilNextFrame < delay) { delay = timeTilNextFrame; } } } for (auto& vectorDrawablePair : mVectorDrawables) { // If any vector drawable in the display list needs update, damage the node. auto& vectorDrawable = vectorDrawablePair.first; if (vectorDrawable->isDirty()) { Matrix4 totalMatrix; info.damageAccumulator->computeCurrentTransform(&totalMatrix); Matrix4 canvasMatrix(vectorDrawablePair.second); totalMatrix.multiply(canvasMatrix); const SkRect& bounds = vectorDrawable->properties().getBounds(); if (intersects(info.screenSize, totalMatrix, bounds)) { isDirty = true; static_cast(info.canvasContext.getRenderPipeline()) ->getVectorDrawables() ->push_back(vectorDrawable); vectorDrawable->setPropertyChangeWillBeConsumed(true); } } } return isDirty; } void SkiaDisplayList::reset() { mProjectionReceiver = nullptr; mDisplayList.reset(); mMutableImages.clear(); mVectorDrawables.clear(); mAnimatedImages.clear(); mChildFunctors.clear(); mChildNodes.clear(); allocator.~LinearAllocator(); new (&allocator) LinearAllocator(); } void SkiaDisplayList::output(std::ostream& output, uint32_t level) { DumpOpsCanvas canvas(output, level, *this); mDisplayList.draw(&canvas); } } // namespace skiapipeline } // namespace uirenderer } // namespace android