libs/hwui/renderthread/RenderProxy.cpp - platform/frameworks/base - Git at Google

 /*
  * Copyright (C) 2013 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 "RenderProxy.h"

 #include "DeferredLayerUpdater.h"
 #include "DisplayList.h"
 #include "Properties.h"
 #include "Readback.h"
 #include "Rect.h"
 #include "WebViewFunctorManager.h"
 #include "pipeline/skia/SkiaOpenGLPipeline.h"
 #include "pipeline/skia/VectorDrawableAtlas.h"
 #include "renderstate/RenderState.h"
 #include "renderthread/CanvasContext.h"
 #include "renderthread/EglManager.h"
 #include "renderthread/RenderTask.h"
 #include "renderthread/RenderThread.h"
 #include "utils/Macros.h"
 #include "utils/TimeUtils.h"
 #include "utils/TraceUtils.h"

 #include <ui/GraphicBuffer.h>

 namespace android {
 namespace uirenderer {
 namespace renderthread {

 RenderProxy::RenderProxy(bool translucent, RenderNode* rootRenderNode,
                          IContextFactory* contextFactory)
         : mRenderThread(RenderThread::getInstance()), mContext(nullptr) {
     mContext = mRenderThread.queue().runSync([&]() -> CanvasContext* {
         return CanvasContext::create(mRenderThread, translucent, rootRenderNode, contextFactory);
     });
     mDrawFrameTask.setContext(&mRenderThread, mContext, rootRenderNode);
 }

 RenderProxy::~RenderProxy() {
     destroyContext();
 }

 void RenderProxy::destroyContext() {
     if (mContext) {
         mDrawFrameTask.setContext(nullptr, nullptr, nullptr);
         // This is also a fence as we need to be certain that there are no
         // outstanding mDrawFrame tasks posted before it is destroyed
         mRenderThread.queue().runSync([this]() { delete mContext; });
         mContext = nullptr;
     }
 }

 void RenderProxy::setSwapBehavior(SwapBehavior swapBehavior) {
     mRenderThread.queue().post([this, swapBehavior]() { mContext->setSwapBehavior(swapBehavior); });
 }

 bool RenderProxy::loadSystemProperties() {
     return mRenderThread.queue().runSync([this]() -> bool {
         bool needsRedraw = Properties::load();
         if (mContext->profiler().consumeProperties()) {
             needsRedraw = true;
         }
         return needsRedraw;
     });
 }

 void RenderProxy::setName(const char* name) {
     // block since name/value pointers owned by caller
     // TODO: Support move arguments
     mRenderThread.queue().runSync([this, name]() { mContext->setName(std::string(name)); });
 }

 void RenderProxy::setSurface(const sp<Surface>& surface) {
     mRenderThread.queue().post(
             [this, surf = surface]() mutable { mContext->setSurface(std::move(surf)); });
 }

 void RenderProxy::allocateBuffers() {
     mRenderThread.queue().post([=]() { mContext->allocateBuffers(); });
 }

 bool RenderProxy::pause() {
     return mRenderThread.queue().runSync([this]() -> bool { return mContext->pauseSurface(); });
 }

 void RenderProxy::setStopped(bool stopped) {
     mRenderThread.queue().runSync([this, stopped]() { mContext->setStopped(stopped); });
 }

 void RenderProxy::setLightAlpha(uint8_t ambientShadowAlpha, uint8_t spotShadowAlpha) {
     mRenderThread.queue().post(
             [=]() { mContext->setLightAlpha(ambientShadowAlpha, spotShadowAlpha); });
 }

 void RenderProxy::setLightGeometry(const Vector3& lightCenter, float lightRadius) {
     mRenderThread.queue().post([=]() { mContext->setLightGeometry(lightCenter, lightRadius); });
 }

 void RenderProxy::setOpaque(bool opaque) {
     mRenderThread.queue().post([=]() { mContext->setOpaque(opaque); });
 }

 void RenderProxy::setWideGamut(bool wideGamut) {
     mRenderThread.queue().post([=]() { mContext->setWideGamut(wideGamut); });
 }

 int64_t* RenderProxy::frameInfo() {
     return mDrawFrameTask.frameInfo();
 }

 int RenderProxy::syncAndDrawFrame() {
     return mDrawFrameTask.drawFrame();
 }

 void RenderProxy::destroy() {
     // destroyCanvasAndSurface() needs a fence as when it returns the
     // underlying BufferQueue is going to be released from under
     // the render thread.
     mRenderThread.queue().runSync([=]() { mContext->destroy(); });
 }

 void RenderProxy::invokeFunctor(Functor* functor, bool waitForCompletion) {
     ATRACE_CALL();
     RenderThread& thread = RenderThread::getInstance();
     auto invoke = [&thread, functor]() { CanvasContext::invokeFunctor(thread, functor); };
     if (waitForCompletion) {
         // waitForCompletion = true is expected to be fairly rare and only
         // happen in destruction. Thus it should be fine to temporarily
         // create a Mutex
         thread.queue().runSync(std::move(invoke));
     } else {
         thread.queue().post(std::move(invoke));
     }
 }

 void RenderProxy::destroyFunctor(int functor) {
     ATRACE_CALL();
     RenderThread& thread = RenderThread::getInstance();
     thread.queue().post([=]() { WebViewFunctorManager::instance().destroyFunctor(functor); });
 }

 DeferredLayerUpdater* RenderProxy::createTextureLayer() {
     return mRenderThread.queue().runSync([this]() -> auto {
         return mContext->createTextureLayer();
     });
 }

 void RenderProxy::buildLayer(RenderNode* node) {
     mRenderThread.queue().runSync([&]() { mContext->buildLayer(node); });
 }

 bool RenderProxy::copyLayerInto(DeferredLayerUpdater* layer, SkBitmap& bitmap) {
     ATRACE_NAME("TextureView#getBitmap");
     auto& thread = RenderThread::getInstance();
     return thread.queue().runSync([&]() -> bool {
         return thread.readback().copyLayerInto(layer, &bitmap) == CopyResult::Success;
     });
 }

 void RenderProxy::pushLayerUpdate(DeferredLayerUpdater* layer) {
     mDrawFrameTask.pushLayerUpdate(layer);
 }

 void RenderProxy::cancelLayerUpdate(DeferredLayerUpdater* layer) {
     mDrawFrameTask.removeLayerUpdate(layer);
 }

 void RenderProxy::detachSurfaceTexture(DeferredLayerUpdater* layer) {
     return mRenderThread.queue().runSync([&]() { layer->detachSurfaceTexture(); });
 }

 void RenderProxy::destroyHardwareResources() {
     return mRenderThread.queue().runSync([&]() { mContext->destroyHardwareResources(); });
 }

 void RenderProxy::trimMemory(int level) {
     // Avoid creating a RenderThread to do a trimMemory.
     if (RenderThread::hasInstance()) {
         RenderThread& thread = RenderThread::getInstance();
         thread.queue().post([&thread, level]() { CanvasContext::trimMemory(thread, level); });
     }
 }

 void RenderProxy::overrideProperty(const char* name, const char* value) {
     // expensive, but block here since name/value pointers owned by caller
     RenderThread::getInstance().queue().runSync(
             [&]() { Properties::overrideProperty(name, value); });
 }

 void RenderProxy::fence() {
     mRenderThread.queue().runSync([]() {});
 }

 int RenderProxy::maxTextureSize() {
     static int maxTextureSize = RenderThread::getInstance().queue().runSync(
             []() { return DeviceInfo::get()->maxTextureSize(); });
     return maxTextureSize;
 }

 void RenderProxy::stopDrawing() {
     mRenderThread.queue().runSync([this]() { mContext->stopDrawing(); });
 }

 void RenderProxy::notifyFramePending() {
     mRenderThread.queue().post([this]() { mContext->notifyFramePending(); });
 }

 void RenderProxy::dumpProfileInfo(int fd, int dumpFlags) {
     mRenderThread.queue().runSync([&]() {
         mContext->profiler().dumpData(fd);
         if (dumpFlags & DumpFlags::FrameStats) {
             mContext->dumpFrames(fd);
         }
         if (dumpFlags & DumpFlags::JankStats) {
             mRenderThread.globalProfileData()->dump(fd);
         }
         if (dumpFlags & DumpFlags::Reset) {
             mContext->resetFrameStats();
         }
     });
 }

 void RenderProxy::resetProfileInfo() {
     mRenderThread.queue().runSync([=]() { mContext->resetFrameStats(); });
 }

 uint32_t RenderProxy::frameTimePercentile(int percentile) {
     return mRenderThread.queue().runSync([&]() -> auto {
         return mRenderThread.globalProfileData()->findPercentile(percentile);
     });
 }

 void RenderProxy::dumpGraphicsMemory(int fd) {
     if (RenderThread::hasInstance()) {
         auto& thread = RenderThread::getInstance();
         thread.queue().runSync([&]() { thread.dumpGraphicsMemory(fd); });
     }
 }

 void RenderProxy::setProcessStatsBuffer(int fd) {
     auto& rt = RenderThread::getInstance();
     rt.queue().post([&rt, fd = dup(fd)]() {
         rt.globalProfileData().switchStorageToAshmem(fd);
         close(fd);
     });
 }

 void RenderProxy::rotateProcessStatsBuffer() {
     auto& rt = RenderThread::getInstance();
     rt.queue().post([&rt]() { rt.globalProfileData().rotateStorage(); });
 }

 int RenderProxy::getRenderThreadTid() {
     return mRenderThread.getTid();
 }

 void RenderProxy::addRenderNode(RenderNode* node, bool placeFront) {
     mRenderThread.queue().post([=]() { mContext->addRenderNode(node, placeFront); });
 }

 void RenderProxy::removeRenderNode(RenderNode* node) {
     mRenderThread.queue().post([=]() { mContext->removeRenderNode(node); });
 }

 void RenderProxy::drawRenderNode(RenderNode* node) {
     mRenderThread.queue().runSync([=]() { mContext->prepareAndDraw(node); });
 }

 void RenderProxy::setContentDrawBounds(int left, int top, int right, int bottom) {
     mDrawFrameTask.setContentDrawBounds(left, top, right, bottom);
 }

 void RenderProxy::setPictureCapturedCallback(
         const std::function<void(sk_sp<SkPicture>&&)>& callback) {
     mRenderThread.queue().post(
             [this, cb = callback]() { mContext->setPictureCapturedCallback(cb); });
 }

 void RenderProxy::setFrameCallback(std::function<void(int64_t)>&& callback) {
     mDrawFrameTask.setFrameCallback(std::move(callback));
 }

 void RenderProxy::setFrameCompleteCallback(std::function<void(int64_t)>&& callback) {
     mDrawFrameTask.setFrameCompleteCallback(std::move(callback));
 }

 void RenderProxy::addFrameMetricsObserver(FrameMetricsObserver* observerPtr) {
     mRenderThread.queue().post([this, observer = sp{observerPtr}]() {
         mContext->addFrameMetricsObserver(observer.get());
     });
 }

 void RenderProxy::removeFrameMetricsObserver(FrameMetricsObserver* observerPtr) {
     mRenderThread.queue().post([this, observer = sp{observerPtr}]() {
         mContext->removeFrameMetricsObserver(observer.get());
     });
 }

 void RenderProxy::setForceDark(bool enable) {
     mRenderThread.queue().post([this, enable]() { mContext->setForceDark(enable); });
 }

 void RenderProxy::setRenderAheadDepth(int renderAhead) {
     mRenderThread.queue().post(
             [context = mContext, renderAhead] { context->setRenderAheadDepth(renderAhead); });
 }

 int RenderProxy::copySurfaceInto(sp<Surface>& surface, int left, int top, int right, int bottom,
                                  SkBitmap* bitmap) {
     auto& thread = RenderThread::getInstance();
     return static_cast<int>(thread.queue().runSync([&]() -> auto {
         return thread.readback().copySurfaceInto(*surface, Rect(left, top, right, bottom), bitmap);
     }));
 }

 void RenderProxy::prepareToDraw(Bitmap& bitmap) {
     // If we haven't spun up a hardware accelerated window yet, there's no
     // point in precaching these bitmaps as it can't impact jank.
     // We also don't know if we even will spin up a hardware-accelerated
     // window or not.
     if (!RenderThread::hasInstance()) return;
     RenderThread* renderThread = &RenderThread::getInstance();
     bitmap.ref();
     auto task = [renderThread, &bitmap]() {
         CanvasContext::prepareToDraw(*renderThread, &bitmap);
         bitmap.unref();
     };
     nsecs_t lastVsync = renderThread->timeLord().latestVsync();
     nsecs_t estimatedNextVsync = lastVsync + renderThread->timeLord().frameIntervalNanos();
     nsecs_t timeToNextVsync = estimatedNextVsync - systemTime(CLOCK_MONOTONIC);
     // We expect the UI thread to take 4ms and for RT to be active from VSYNC+4ms to
     // VSYNC+12ms or so, so aim for the gap during which RT is expected to
     // be idle
     // TODO: Make this concept a first-class supported thing? RT could use
     // knowledge of pending draws to better schedule this task
     if (timeToNextVsync > -6_ms && timeToNextVsync < 1_ms) {
         renderThread->queue().postAt(estimatedNextVsync + 8_ms, task);
     } else {
         renderThread->queue().post(task);
     }
 }

 int RenderProxy::copyHWBitmapInto(Bitmap* hwBitmap, SkBitmap* bitmap) {
     ATRACE_NAME("HardwareBitmap readback");
     RenderThread& thread = RenderThread::getInstance();
     if (gettid() == thread.getTid()) {
         // TODO: fix everything that hits this. We should never be triggering a readback ourselves.
         return (int)thread.readback().copyHWBitmapInto(hwBitmap, bitmap);
     } else {
         return thread.queue().runSync(
                 [&]() -> int { return (int)thread.readback().copyHWBitmapInto(hwBitmap, bitmap); });
     }
 }

 void RenderProxy::disableVsync() {
     Properties::disableVsync = true;
 }

 void RenderProxy::repackVectorDrawableAtlas() {
     RenderThread& thread = RenderThread::getInstance();
     thread.queue().post([&thread]() {
         // The context may be null if trimMemory executed, but then the atlas was deleted too.
         if (thread.getGrContext() != nullptr) {
             thread.cacheManager().acquireVectorDrawableAtlas()->repackIfNeeded(
                     thread.getGrContext());
         }
     });
 }

 void RenderProxy::releaseVDAtlasEntries() {
     RenderThread& thread = RenderThread::getInstance();
     thread.queue().post([&thread]() {
         // The context may be null if trimMemory executed, but then the atlas was deleted too.
         if (thread.getGrContext() != nullptr) {
             thread.cacheManager().acquireVectorDrawableAtlas()->delayedReleaseEntries();
         }
     });
 }

 void RenderProxy::preload() {
     // Create RenderThread object and start the thread. Then preload Vulkan/EGL driver.
     auto& thread = RenderThread::getInstance();
     thread.queue().post([&thread]() { thread.preload(); });
 }

 } /* namespace renderthread */
 } /* namespace uirenderer */
 } /* namespace android */
	/*
	* Copyright (C) 2013 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 "RenderProxy.h"

	#include "DeferredLayerUpdater.h"
	#include "DisplayList.h"
	#include "Properties.h"
	#include "Readback.h"
	#include "Rect.h"
	#include "WebViewFunctorManager.h"
	#include "pipeline/skia/SkiaOpenGLPipeline.h"
	#include "pipeline/skia/VectorDrawableAtlas.h"
	#include "renderstate/RenderState.h"
	#include "renderthread/CanvasContext.h"
	#include "renderthread/EglManager.h"
	#include "renderthread/RenderTask.h"
	#include "renderthread/RenderThread.h"
	#include "utils/Macros.h"
	#include "utils/TimeUtils.h"
	#include "utils/TraceUtils.h"

	#include <ui/GraphicBuffer.h>

	namespace android {
	namespace uirenderer {
	namespace renderthread {

	RenderProxy::RenderProxy(bool translucent, RenderNode* rootRenderNode,
	IContextFactory* contextFactory)
	: mRenderThread(RenderThread::getInstance()), mContext(nullptr) {
	mContext = mRenderThread.queue().runSync([&]() -> CanvasContext* {
	return CanvasContext::create(mRenderThread, translucent, rootRenderNode, contextFactory);
	});
	mDrawFrameTask.setContext(&mRenderThread, mContext, rootRenderNode);
	}

	RenderProxy::~RenderProxy() {
	destroyContext();
	}

	void RenderProxy::destroyContext() {
	if (mContext) {
	mDrawFrameTask.setContext(nullptr, nullptr, nullptr);
	// This is also a fence as we need to be certain that there are no
	// outstanding mDrawFrame tasks posted before it is destroyed
	mRenderThread.queue().runSync([this]() { delete mContext; });
	mContext = nullptr;
	}
	}

	void RenderProxy::setSwapBehavior(SwapBehavior swapBehavior) {
	mRenderThread.queue().post([this, swapBehavior]() { mContext->setSwapBehavior(swapBehavior); });
	}

	bool RenderProxy::loadSystemProperties() {
	return mRenderThread.queue().runSync([this]() -> bool {
	bool needsRedraw = Properties::load();
	if (mContext->profiler().consumeProperties()) {
	needsRedraw = true;
	}
	return needsRedraw;
	});
	}

	void RenderProxy::setName(const char* name) {
	// block since name/value pointers owned by caller
	// TODO: Support move arguments
	mRenderThread.queue().runSync([this, name]() { mContext->setName(std::string(name)); });
	}

	void RenderProxy::setSurface(const sp<Surface>& surface) {
	mRenderThread.queue().post(
	[this, surf = surface]() mutable { mContext->setSurface(std::move(surf)); });
	}

	void RenderProxy::allocateBuffers() {
	mRenderThread.queue().post([=]() { mContext->allocateBuffers(); });
	}

	bool RenderProxy::pause() {
	return mRenderThread.queue().runSync([this]() -> bool { return mContext->pauseSurface(); });
	}

	void RenderProxy::setStopped(bool stopped) {
	mRenderThread.queue().runSync([this, stopped]() { mContext->setStopped(stopped); });
	}

	void RenderProxy::setLightAlpha(uint8_t ambientShadowAlpha, uint8_t spotShadowAlpha) {
	mRenderThread.queue().post(
	[=]() { mContext->setLightAlpha(ambientShadowAlpha, spotShadowAlpha); });
	}

	void RenderProxy::setLightGeometry(const Vector3& lightCenter, float lightRadius) {
	mRenderThread.queue().post([=]() { mContext->setLightGeometry(lightCenter, lightRadius); });
	}

	void RenderProxy::setOpaque(bool opaque) {
	mRenderThread.queue().post([=]() { mContext->setOpaque(opaque); });
	}

	void RenderProxy::setWideGamut(bool wideGamut) {
	mRenderThread.queue().post([=]() { mContext->setWideGamut(wideGamut); });
	}

	int64_t* RenderProxy::frameInfo() {
	return mDrawFrameTask.frameInfo();
	}

	int RenderProxy::syncAndDrawFrame() {
	return mDrawFrameTask.drawFrame();
	}

	void RenderProxy::destroy() {
	// destroyCanvasAndSurface() needs a fence as when it returns the
	// underlying BufferQueue is going to be released from under
	// the render thread.
	mRenderThread.queue().runSync([=]() { mContext->destroy(); });
	}

	void RenderProxy::invokeFunctor(Functor* functor, bool waitForCompletion) {
	ATRACE_CALL();
	RenderThread& thread = RenderThread::getInstance();
	auto invoke = [&thread, functor]() { CanvasContext::invokeFunctor(thread, functor); };
	if (waitForCompletion) {
	// waitForCompletion = true is expected to be fairly rare and only
	// happen in destruction. Thus it should be fine to temporarily
	// create a Mutex
	thread.queue().runSync(std::move(invoke));
	} else {
	thread.queue().post(std::move(invoke));
	}
	}

	void RenderProxy::destroyFunctor(int functor) {
	ATRACE_CALL();
	RenderThread& thread = RenderThread::getInstance();
	thread.queue().post([=]() { WebViewFunctorManager::instance().destroyFunctor(functor); });
	}

	DeferredLayerUpdater* RenderProxy::createTextureLayer() {
	return mRenderThread.queue().runSync([this]() -> auto {
	return mContext->createTextureLayer();
	});
	}

	void RenderProxy::buildLayer(RenderNode* node) {
	mRenderThread.queue().runSync([&]() { mContext->buildLayer(node); });
	}

	bool RenderProxy::copyLayerInto(DeferredLayerUpdater* layer, SkBitmap& bitmap) {
	ATRACE_NAME("TextureView#getBitmap");
	auto& thread = RenderThread::getInstance();
	return thread.queue().runSync([&]() -> bool {
	return thread.readback().copyLayerInto(layer, &bitmap) == CopyResult::Success;
	});
	}

	void RenderProxy::pushLayerUpdate(DeferredLayerUpdater* layer) {
	mDrawFrameTask.pushLayerUpdate(layer);
	}

	void RenderProxy::cancelLayerUpdate(DeferredLayerUpdater* layer) {
	mDrawFrameTask.removeLayerUpdate(layer);
	}

	void RenderProxy::detachSurfaceTexture(DeferredLayerUpdater* layer) {
	return mRenderThread.queue().runSync([&]() { layer->detachSurfaceTexture(); });
	}

	void RenderProxy::destroyHardwareResources() {
	return mRenderThread.queue().runSync([&]() { mContext->destroyHardwareResources(); });
	}

	void RenderProxy::trimMemory(int level) {
	// Avoid creating a RenderThread to do a trimMemory.
	if (RenderThread::hasInstance()) {
	RenderThread& thread = RenderThread::getInstance();
	thread.queue().post([&thread, level]() { CanvasContext::trimMemory(thread, level); });
	}
	}

	void RenderProxy::overrideProperty(const char* name, const char* value) {
	// expensive, but block here since name/value pointers owned by caller
	RenderThread::getInstance().queue().runSync(
	[&]() { Properties::overrideProperty(name, value); });
	}

	void RenderProxy::fence() {
	mRenderThread.queue().runSync([]() {});
	}

	int RenderProxy::maxTextureSize() {
	static int maxTextureSize = RenderThread::getInstance().queue().runSync(
	[]() { return DeviceInfo::get()->maxTextureSize(); });
	return maxTextureSize;
	}

	void RenderProxy::stopDrawing() {
	mRenderThread.queue().runSync([this]() { mContext->stopDrawing(); });
	}

	void RenderProxy::notifyFramePending() {
	mRenderThread.queue().post([this]() { mContext->notifyFramePending(); });
	}

	void RenderProxy::dumpProfileInfo(int fd, int dumpFlags) {
	mRenderThread.queue().runSync([&]() {
	mContext->profiler().dumpData(fd);
	if (dumpFlags & DumpFlags::FrameStats) {
	mContext->dumpFrames(fd);
	}
	if (dumpFlags & DumpFlags::JankStats) {
	mRenderThread.globalProfileData()->dump(fd);
	}
	if (dumpFlags & DumpFlags::Reset) {
	mContext->resetFrameStats();
	}
	});
	}

	void RenderProxy::resetProfileInfo() {
	mRenderThread.queue().runSync([=]() { mContext->resetFrameStats(); });
	}

	uint32_t RenderProxy::frameTimePercentile(int percentile) {
	return mRenderThread.queue().runSync([&]() -> auto {
	return mRenderThread.globalProfileData()->findPercentile(percentile);
	});
	}

	void RenderProxy::dumpGraphicsMemory(int fd) {
	if (RenderThread::hasInstance()) {
	auto& thread = RenderThread::getInstance();
	thread.queue().runSync([&]() { thread.dumpGraphicsMemory(fd); });
	}
	}

	void RenderProxy::setProcessStatsBuffer(int fd) {
	auto& rt = RenderThread::getInstance();
	rt.queue().post([&rt, fd = dup(fd)]() {
	rt.globalProfileData().switchStorageToAshmem(fd);
	close(fd);
	});
	}

	void RenderProxy::rotateProcessStatsBuffer() {
	auto& rt = RenderThread::getInstance();
	rt.queue().post([&rt]() { rt.globalProfileData().rotateStorage(); });
	}

	int RenderProxy::getRenderThreadTid() {
	return mRenderThread.getTid();
	}

	void RenderProxy::addRenderNode(RenderNode* node, bool placeFront) {
	mRenderThread.queue().post([=]() { mContext->addRenderNode(node, placeFront); });
	}

	void RenderProxy::removeRenderNode(RenderNode* node) {
	mRenderThread.queue().post([=]() { mContext->removeRenderNode(node); });
	}

	void RenderProxy::drawRenderNode(RenderNode* node) {
	mRenderThread.queue().runSync([=]() { mContext->prepareAndDraw(node); });
	}

	void RenderProxy::setContentDrawBounds(int left, int top, int right, int bottom) {
	mDrawFrameTask.setContentDrawBounds(left, top, right, bottom);
	}

	void RenderProxy::setPictureCapturedCallback(
	const std::function<void(sk_sp<SkPicture>&&)>& callback) {
	mRenderThread.queue().post(
	[this, cb = callback]() { mContext->setPictureCapturedCallback(cb); });
	}

	void RenderProxy::setFrameCallback(std::function<void(int64_t)>&& callback) {
	mDrawFrameTask.setFrameCallback(std::move(callback));
	}

	void RenderProxy::setFrameCompleteCallback(std::function<void(int64_t)>&& callback) {
	mDrawFrameTask.setFrameCompleteCallback(std::move(callback));
	}

	void RenderProxy::addFrameMetricsObserver(FrameMetricsObserver* observerPtr) {
	mRenderThread.queue().post([this, observer = sp{observerPtr}]() {
	mContext->addFrameMetricsObserver(observer.get());
	});
	}

	void RenderProxy::removeFrameMetricsObserver(FrameMetricsObserver* observerPtr) {
	mRenderThread.queue().post([this, observer = sp{observerPtr}]() {
	mContext->removeFrameMetricsObserver(observer.get());
	});
	}

	void RenderProxy::setForceDark(bool enable) {
	mRenderThread.queue().post([this, enable]() { mContext->setForceDark(enable); });
	}

	void RenderProxy::setRenderAheadDepth(int renderAhead) {
	mRenderThread.queue().post(
	[context = mContext, renderAhead] { context->setRenderAheadDepth(renderAhead); });
	}

	int RenderProxy::copySurfaceInto(sp<Surface>& surface, int left, int top, int right, int bottom,
	SkBitmap* bitmap) {
	auto& thread = RenderThread::getInstance();
	return static_cast<int>(thread.queue().runSync([&]() -> auto {
	return thread.readback().copySurfaceInto(*surface, Rect(left, top, right, bottom), bitmap);
	}));
	}

	void RenderProxy::prepareToDraw(Bitmap& bitmap) {
	// If we haven't spun up a hardware accelerated window yet, there's no
	// point in precaching these bitmaps as it can't impact jank.
	// We also don't know if we even will spin up a hardware-accelerated
	// window or not.
	if (!RenderThread::hasInstance()) return;
	RenderThread* renderThread = &RenderThread::getInstance();
	bitmap.ref();
	auto task = [renderThread, &bitmap]() {
	CanvasContext::prepareToDraw(*renderThread, &bitmap);
	bitmap.unref();
	};
	nsecs_t lastVsync = renderThread->timeLord().latestVsync();
	nsecs_t estimatedNextVsync = lastVsync + renderThread->timeLord().frameIntervalNanos();
	nsecs_t timeToNextVsync = estimatedNextVsync - systemTime(CLOCK_MONOTONIC);
	// We expect the UI thread to take 4ms and for RT to be active from VSYNC+4ms to
	// VSYNC+12ms or so, so aim for the gap during which RT is expected to
	// be idle
	// TODO: Make this concept a first-class supported thing? RT could use
	// knowledge of pending draws to better schedule this task
	if (timeToNextVsync > -6_ms && timeToNextVsync < 1_ms) {
	renderThread->queue().postAt(estimatedNextVsync + 8_ms, task);
	} else {
	renderThread->queue().post(task);
	}
	}

	int RenderProxy::copyHWBitmapInto(Bitmap* hwBitmap, SkBitmap* bitmap) {
	ATRACE_NAME("HardwareBitmap readback");
	RenderThread& thread = RenderThread::getInstance();
	if (gettid() == thread.getTid()) {
	// TODO: fix everything that hits this. We should never be triggering a readback ourselves.
	return (int)thread.readback().copyHWBitmapInto(hwBitmap, bitmap);
	} else {
	return thread.queue().runSync(
	[&]() -> int { return (int)thread.readback().copyHWBitmapInto(hwBitmap, bitmap); });
	}
	}

	void RenderProxy::disableVsync() {
	Properties::disableVsync = true;
	}

	void RenderProxy::repackVectorDrawableAtlas() {
	RenderThread& thread = RenderThread::getInstance();
	thread.queue().post([&thread]() {
	// The context may be null if trimMemory executed, but then the atlas was deleted too.
	if (thread.getGrContext() != nullptr) {
	thread.cacheManager().acquireVectorDrawableAtlas()->repackIfNeeded(
	thread.getGrContext());
	}
	});
	}

	void RenderProxy::releaseVDAtlasEntries() {
	RenderThread& thread = RenderThread::getInstance();
	thread.queue().post([&thread]() {
	// The context may be null if trimMemory executed, but then the atlas was deleted too.
	if (thread.getGrContext() != nullptr) {
	thread.cacheManager().acquireVectorDrawableAtlas()->delayedReleaseEntries();
	}
	});
	}

	void RenderProxy::preload() {
	// Create RenderThread object and start the thread. Then preload Vulkan/EGL driver.
	auto& thread = RenderThread::getInstance();
	thread.queue().post([&thread]() { thread.preload(); });
	}

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