/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set sw=2 ts=2 et tw=80 : */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "mozilla/layers/CompositorBridgeParent.h" #include // for fprintf, stdout #include // for uint64_t #include // for _Rb_tree_iterator, etc #include // for pair #include "LayerTransactionParent.h" // for LayerTransactionParent #include "RenderTrace.h" // for RenderTraceLayers #include "base/message_loop.h" // for MessageLoop #include "base/process.h" // for ProcessId #include "base/task.h" // for CancelableTask, etc #include "base/thread.h" // for Thread #include "gfxContext.h" // for gfxContext #include "gfxPlatform.h" // for gfxPlatform #include "TreeTraversal.h" // for ForEachNode #ifdef MOZ_WIDGET_GTK #include "gfxPlatformGtk.h" // for gfxPlatform #endif #include "gfxPrefs.h" // for gfxPrefs #include "mozilla/AutoRestore.h" // for AutoRestore #include "mozilla/ClearOnShutdown.h" // for ClearOnShutdown #include "mozilla/DebugOnly.h" // for DebugOnly #include "mozilla/dom/ContentParent.h" #include "mozilla/dom/TabParent.h" #include "mozilla/gfx/2D.h" // for DrawTarget #include "mozilla/gfx/Point.h" // for IntSize #include "mozilla/gfx/Rect.h" // for IntSize #include "VRManager.h" // for VRManager #include "mozilla/ipc/Transport.h" // for Transport #include "mozilla/layers/APZCTreeManager.h" // for APZCTreeManager #include "mozilla/layers/APZCTreeManagerParent.h" // for APZCTreeManagerParent #include "mozilla/layers/APZThreadUtils.h" // for APZCTreeManager #include "mozilla/layers/AsyncCompositionManager.h" #include "mozilla/layers/BasicCompositor.h" // for BasicCompositor #include "mozilla/layers/Compositor.h" // for Compositor #include "mozilla/layers/CompositorOGL.h" // for CompositorOGL #include "mozilla/layers/CompositorThread.h" #include "mozilla/layers/CompositorTypes.h" #include "mozilla/layers/CrossProcessCompositorBridgeParent.h" #include "mozilla/layers/FrameUniformityData.h" #include "mozilla/layers/ImageBridgeParent.h" #include "mozilla/layers/LayerManagerComposite.h" #include "mozilla/layers/LayerTreeOwnerTracker.h" #include "mozilla/layers/LayersTypes.h" #include "mozilla/layers/PLayerTransactionParent.h" #include "mozilla/layers/RemoteContentController.h" #include "mozilla/layout/RenderFrameParent.h" #include "mozilla/media/MediaSystemResourceService.h" // for MediaSystemResourceService #include "mozilla/mozalloc.h" // for operator new, etc #include "mozilla/Telemetry.h" #ifdef MOZ_WIDGET_GTK #include "basic/X11BasicCompositor.h" // for X11BasicCompositor #endif #include "nsCOMPtr.h" // for already_AddRefed #include "nsDebug.h" // for NS_ASSERTION, etc #include "nsISupportsImpl.h" // for MOZ_COUNT_CTOR, etc #include "nsIWidget.h" // for nsIWidget #include "nsTArray.h" // for nsTArray #include "nsThreadUtils.h" // for NS_IsMainThread #include "nsXULAppAPI.h" // for XRE_GetIOMessageLoop #ifdef XP_WIN #include "mozilla/layers/CompositorD3D11.h" #include "mozilla/layers/CompositorD3D9.h" #endif #include "GeckoProfiler.h" #include "mozilla/ipc/ProtocolTypes.h" #include "mozilla/Unused.h" #include "mozilla/Hal.h" #include "mozilla/HalTypes.h" #include "mozilla/StaticPtr.h" #include "mozilla/Telemetry.h" #ifdef MOZ_ENABLE_PROFILER_SPS #include "ProfilerMarkers.h" #endif #include "mozilla/VsyncDispatcher.h" #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) #include "VsyncSource.h" #endif #include "mozilla/widget/CompositorWidget.h" #ifdef MOZ_WIDGET_SUPPORTS_OOP_COMPOSITING # include "mozilla/widget/CompositorWidgetParent.h" #endif #include "LayerScope.h" namespace mozilla { namespace layers { using namespace mozilla::ipc; using namespace mozilla::gfx; using namespace std; using base::ProcessId; using base::Thread; ProcessId CompositorBridgeParentBase::GetChildProcessId() { return OtherPid(); } void CompositorBridgeParentBase::NotifyNotUsed(PTextureParent* aTexture, uint64_t aTransactionId) { RefPtr texture = TextureHost::AsTextureHost(aTexture); if (!texture) { return; } if (!(texture->GetFlags() & TextureFlags::RECYCLE)) { return; } uint64_t textureId = TextureHost::GetTextureSerial(aTexture); mPendingAsyncMessage.push_back( OpNotifyNotUsed(textureId, aTransactionId)); } void CompositorBridgeParentBase::SendAsyncMessage(const InfallibleTArray& aMessage) { Unused << SendParentAsyncMessages(aMessage); } bool CompositorBridgeParentBase::AllocShmem(size_t aSize, ipc::SharedMemory::SharedMemoryType aType, ipc::Shmem* aShmem) { return PCompositorBridgeParent::AllocShmem(aSize, aType, aShmem); } bool CompositorBridgeParentBase::AllocUnsafeShmem(size_t aSize, ipc::SharedMemory::SharedMemoryType aType, ipc::Shmem* aShmem) { return PCompositorBridgeParent::AllocUnsafeShmem(aSize, aType, aShmem); } void CompositorBridgeParentBase::DeallocShmem(ipc::Shmem& aShmem) { PCompositorBridgeParent::DeallocShmem(aShmem); } base::ProcessId CompositorBridgeParentBase::RemotePid() { return OtherPid(); } bool CompositorBridgeParentBase::StartSharingMetrics(ipc::SharedMemoryBasic::Handle aHandle, CrossProcessMutexHandle aMutexHandle, uint64_t aLayersId, uint32_t aApzcId) { return PCompositorBridgeParent::SendSharedCompositorFrameMetrics( aHandle, aMutexHandle, aLayersId, aApzcId); } bool CompositorBridgeParentBase::StopSharingMetrics(FrameMetrics::ViewID aScrollId, uint32_t aApzcId) { return PCompositorBridgeParent::SendReleaseSharedCompositorFrameMetrics( aScrollId, aApzcId); } CompositorBridgeParent::LayerTreeState::LayerTreeState() : mApzcTreeManagerParent(nullptr) , mParent(nullptr) , mLayerManager(nullptr) , mCrossProcessParent(nullptr) , mLayerTree(nullptr) , mUpdatedPluginDataAvailable(false) , mPendingCompositorUpdates(0) { } CompositorBridgeParent::LayerTreeState::~LayerTreeState() { if (mController) { mController->Destroy(); } } typedef map LayerTreeMap; static LayerTreeMap sIndirectLayerTrees; static StaticAutoPtr sIndirectLayerTreesLock; static void EnsureLayerTreeMapReady() { MOZ_ASSERT(NS_IsMainThread()); if (!sIndirectLayerTreesLock) { sIndirectLayerTreesLock = new Monitor("IndirectLayerTree"); mozilla::ClearOnShutdown(&sIndirectLayerTreesLock); } } template inline void CompositorBridgeParent::ForEachIndirectLayerTree(const Lambda& aCallback) { sIndirectLayerTreesLock->AssertCurrentThreadOwns(); for (auto it = sIndirectLayerTrees.begin(); it != sIndirectLayerTrees.end(); it++) { LayerTreeState* state = &it->second; if (state->mParent == this) { aCallback(state, it->first); } } } /** * A global map referencing each compositor by ID. * * This map is used by the ImageBridge protocol to trigger * compositions without having to keep references to the * compositor */ typedef map CompositorMap; static StaticAutoPtr sCompositorMap; void CompositorBridgeParent::Setup() { EnsureLayerTreeMapReady(); MOZ_ASSERT(!sCompositorMap); sCompositorMap = new CompositorMap; } void CompositorBridgeParent::Shutdown() { MOZ_ASSERT(sCompositorMap); MOZ_ASSERT(sCompositorMap->empty()); sCompositorMap = nullptr; } void CompositorBridgeParent::FinishShutdown() { // TODO: this should be empty by now... sIndirectLayerTrees.clear(); } static void SetThreadPriority() { hal::SetCurrentThreadPriority(hal::THREAD_PRIORITY_COMPOSITOR); } #ifdef COMPOSITOR_PERFORMANCE_WARNING static int32_t CalculateCompositionFrameRate() { // Used when layout.frame_rate is -1. Needs to be kept in sync with // DEFAULT_FRAME_RATE in nsRefreshDriver.cpp. // TODO: This should actually return the vsync rate. const int32_t defaultFrameRate = 60; int32_t compositionFrameRatePref = gfxPrefs::LayersCompositionFrameRate(); if (compositionFrameRatePref < 0) { // Use the same frame rate for composition as for layout. int32_t layoutFrameRatePref = gfxPrefs::LayoutFrameRate(); if (layoutFrameRatePref < 0) { // TODO: The main thread frame scheduling code consults the actual // monitor refresh rate in this case. We should do the same. return defaultFrameRate; } return layoutFrameRatePref; } return compositionFrameRatePref; } #endif static inline MessageLoop* CompositorLoop() { return CompositorThreadHolder::Loop(); } CompositorBridgeParent::CompositorBridgeParent(CSSToLayoutDeviceScale aScale, const TimeDuration& aVsyncRate, bool aUseExternalSurfaceSize, const gfx::IntSize& aSurfaceSize) : mWidget(nullptr) , mScale(aScale) , mVsyncRate(aVsyncRate) , mIsTesting(false) , mPendingTransaction(0) , mPaused(false) , mUseExternalSurfaceSize(aUseExternalSurfaceSize) , mEGLSurfaceSize(aSurfaceSize) , mPauseCompositionMonitor("PauseCompositionMonitor") , mResumeCompositionMonitor("ResumeCompositionMonitor") , mResetCompositorMonitor("ResetCompositorMonitor") , mRootLayerTreeID(0) , mOverrideComposeReadiness(false) , mForceCompositionTask(nullptr) , mCompositorThreadHolder(CompositorThreadHolder::GetSingleton()) , mCompositorScheduler(nullptr) , mPaintTime(TimeDuration::Forever()) #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) , mLastPluginUpdateLayerTreeId(0) , mDeferPluginWindows(false) , mPluginWindowsHidden(false) #endif { // Always run destructor on the main thread MOZ_ASSERT(NS_IsMainThread()); } void CompositorBridgeParent::InitSameProcess(widget::CompositorWidget* aWidget, const uint64_t& aLayerTreeId, bool aUseAPZ) { mWidget = aWidget; mRootLayerTreeID = aLayerTreeId; if (aUseAPZ) { mApzcTreeManager = new APZCTreeManager(); } // IPDL initialization. mSelfRef is cleared in DeferredDestroy. SetOtherProcessId(base::GetCurrentProcId()); mSelfRef = this; Initialize(); } bool CompositorBridgeParent::Bind(Endpoint&& aEndpoint) { if (!aEndpoint.Bind(this)) { return false; } mSelfRef = this; return true; } mozilla::ipc::IPCResult CompositorBridgeParent::RecvInitialize(const uint64_t& aRootLayerTreeId) { mRootLayerTreeID = aRootLayerTreeId; Initialize(); return IPC_OK(); } void CompositorBridgeParent::Initialize() { MOZ_ASSERT(CompositorThread(), "The compositor thread must be Initialized before instanciating a CompositorBridgeParent."); mCompositorID = 0; // FIXME: This holds on the the fact that right now the only thing that // can destroy this instance is initialized on the compositor thread after // this task has been processed. MOZ_ASSERT(CompositorLoop()); CompositorLoop()->PostTask(NewRunnableFunction(&AddCompositor, this, &mCompositorID)); CompositorLoop()->PostTask(NewRunnableFunction(SetThreadPriority)); { // scope lock MonitorAutoLock lock(*sIndirectLayerTreesLock); sIndirectLayerTrees[mRootLayerTreeID].mParent = this; } LayerScope::SetPixelScale(mScale.scale); mCompositorScheduler = new CompositorVsyncScheduler(this, mWidget); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvReset(nsTArray&& aBackendHints, const uint64_t& aSeqNo, bool* aResult, TextureFactoryIdentifier* aOutIdentifier) { Maybe newIdentifier; ResetCompositorTask(aBackendHints, aSeqNo, &newIdentifier); if (newIdentifier) { *aResult = true; *aOutIdentifier = newIdentifier.value(); } else { *aResult = false; } return IPC_OK(); } uint64_t CompositorBridgeParent::RootLayerTreeId() { MOZ_ASSERT(mRootLayerTreeID); return mRootLayerTreeID; } CompositorBridgeParent::~CompositorBridgeParent() { InfallibleTArray textures; ManagedPTextureParent(textures); // We expect all textures to be destroyed by now. MOZ_DIAGNOSTIC_ASSERT(textures.Length() == 0); for (unsigned int i = 0; i < textures.Length(); ++i) { RefPtr tex = TextureHost::AsTextureHost(textures[i]); tex->DeallocateDeviceData(); } } void CompositorBridgeParent::ForceIsFirstPaint() { mCompositionManager->ForceIsFirstPaint(); } void CompositorBridgeParent::StopAndClearResources() { if (mForceCompositionTask) { mForceCompositionTask->Cancel(); mForceCompositionTask = nullptr; } mPaused = true; // Ensure that the layer manager is destroyed before CompositorBridgeChild. if (mLayerManager) { MonitorAutoLock lock(*sIndirectLayerTreesLock); ForEachIndirectLayerTree([this] (LayerTreeState* lts, uint64_t) -> void { mLayerManager->ClearCachedResources(lts->mRoot); lts->mLayerManager = nullptr; lts->mParent = nullptr; }); mLayerManager->Destroy(); mLayerManager = nullptr; mCompositionManager = nullptr; } if (mCompositor) { mCompositor->DetachWidget(); mCompositor->Destroy(); mCompositor = nullptr; } // This must be destroyed now since it accesses the widget. if (mCompositorScheduler) { mCompositorScheduler->Destroy(); mCompositorScheduler = nullptr; } // After this point, it is no longer legal to access the widget. mWidget = nullptr; } mozilla::ipc::IPCResult CompositorBridgeParent::RecvWillClose() { StopAndClearResources(); return IPC_OK(); } void CompositorBridgeParent::DeferredDestroy() { MOZ_ASSERT(!NS_IsMainThread()); MOZ_ASSERT(mCompositorThreadHolder); mCompositorThreadHolder = nullptr; mSelfRef = nullptr; } mozilla::ipc::IPCResult CompositorBridgeParent::RecvPause() { PauseComposition(); return IPC_OK(); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvResume() { ResumeComposition(); return IPC_OK(); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvMakeSnapshot(const SurfaceDescriptor& aInSnapshot, const gfx::IntRect& aRect) { RefPtr target = GetDrawTargetForDescriptor(aInSnapshot, gfx::BackendType::CAIRO); MOZ_ASSERT(target); if (!target) { // We kill the content process rather than have it continue with an invalid // snapshot, that may be too harsh and we could decide to return some sort // of error to the child process and let it deal with it... return IPC_FAIL_NO_REASON(this); } ForceComposeToTarget(target, &aRect); return IPC_OK(); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvFlushRendering() { if (mCompositorScheduler->NeedsComposite()) { CancelCurrentCompositeTask(); ForceComposeToTarget(nullptr); } return IPC_OK(); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvForcePresent() { // During the shutdown sequence mLayerManager may be null if (mLayerManager) { mLayerManager->ForcePresent(); } return IPC_OK(); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvNotifyRegionInvalidated(const nsIntRegion& aRegion) { if (mLayerManager) { mLayerManager->AddInvalidRegion(aRegion); } return IPC_OK(); } void CompositorBridgeParent::Invalidate() { if (mLayerManager && mLayerManager->GetRoot()) { mLayerManager->AddInvalidRegion( mLayerManager->GetRoot()->GetLocalVisibleRegion().ToUnknownRegion().GetBounds()); } } mozilla::ipc::IPCResult CompositorBridgeParent::RecvStartFrameTimeRecording(const int32_t& aBufferSize, uint32_t* aOutStartIndex) { if (mLayerManager) { *aOutStartIndex = mLayerManager->StartFrameTimeRecording(aBufferSize); } else { *aOutStartIndex = 0; } return IPC_OK(); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvStopFrameTimeRecording(const uint32_t& aStartIndex, InfallibleTArray* intervals) { if (mLayerManager) { mLayerManager->StopFrameTimeRecording(aStartIndex, *intervals); } return IPC_OK(); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvClearApproximatelyVisibleRegions(const uint64_t& aLayersId, const uint32_t& aPresShellId) { ClearApproximatelyVisibleRegions(aLayersId, Some(aPresShellId)); return IPC_OK(); } void CompositorBridgeParent::ClearApproximatelyVisibleRegions(const uint64_t& aLayersId, const Maybe& aPresShellId) { if (mLayerManager) { mLayerManager->ClearApproximatelyVisibleRegions(aLayersId, aPresShellId); // We need to recomposite to update the minimap. ScheduleComposition(); } } mozilla::ipc::IPCResult CompositorBridgeParent::RecvNotifyApproximatelyVisibleRegion(const ScrollableLayerGuid& aGuid, const CSSIntRegion& aRegion) { if (mLayerManager) { mLayerManager->UpdateApproximatelyVisibleRegion(aGuid, aRegion); // We need to recomposite to update the minimap. ScheduleComposition(); } return IPC_OK(); } void CompositorBridgeParent::ActorDestroy(ActorDestroyReason why) { StopAndClearResources(); RemoveCompositor(mCompositorID); mCompositionManager = nullptr; if (mApzcTreeManager) { mApzcTreeManager->ClearTree(); mApzcTreeManager = nullptr; } { // scope lock MonitorAutoLock lock(*sIndirectLayerTreesLock); sIndirectLayerTrees.erase(mRootLayerTreeID); } // There are chances that the ref count reaches zero on the main thread shortly // after this function returns while some ipdl code still needs to run on // this thread. // We must keep the compositor parent alive untill the code handling message // reception is finished on this thread. mSelfRef = this; MessageLoop::current()->PostTask(NewRunnableMethod(this, &CompositorBridgeParent::DeferredDestroy)); } void CompositorBridgeParent::ScheduleRenderOnCompositorThread() { MOZ_ASSERT(CompositorLoop()); CompositorLoop()->PostTask(NewRunnableMethod(this, &CompositorBridgeParent::ScheduleComposition)); } void CompositorBridgeParent::InvalidateOnCompositorThread() { MOZ_ASSERT(CompositorLoop()); CompositorLoop()->PostTask(NewRunnableMethod(this, &CompositorBridgeParent::Invalidate)); } void CompositorBridgeParent::PauseComposition() { MOZ_ASSERT(CompositorThreadHolder::IsInCompositorThread(), "PauseComposition() can only be called on the compositor thread"); MonitorAutoLock lock(mPauseCompositionMonitor); if (!mPaused) { mPaused = true; mCompositor->Pause(); TimeStamp now = TimeStamp::Now(); DidComposite(now, now); } // if anyone's waiting to make sure that composition really got paused, tell them lock.NotifyAll(); } void CompositorBridgeParent::ResumeComposition() { MOZ_ASSERT(CompositorThreadHolder::IsInCompositorThread(), "ResumeComposition() can only be called on the compositor thread"); MonitorAutoLock lock(mResumeCompositionMonitor); if (!mCompositor->Resume()) { #ifdef MOZ_WIDGET_ANDROID // We can't get a surface. This could be because the activity changed between // the time resume was scheduled and now. __android_log_print(ANDROID_LOG_INFO, "CompositorBridgeParent", "Unable to renew compositor surface; remaining in paused state"); #endif lock.NotifyAll(); return; } mPaused = false; Invalidate(); mCompositorScheduler->ResumeComposition(); // if anyone's waiting to make sure that composition really got resumed, tell them lock.NotifyAll(); } void CompositorBridgeParent::ForceComposition() { // Cancel the orientation changed state to force composition mForceCompositionTask = nullptr; ScheduleRenderOnCompositorThread(); } void CompositorBridgeParent::CancelCurrentCompositeTask() { mCompositorScheduler->CancelCurrentCompositeTask(); } void CompositorBridgeParent::SetEGLSurfaceSize(int width, int height) { NS_ASSERTION(mUseExternalSurfaceSize, "Compositor created without UseExternalSurfaceSize provided"); mEGLSurfaceSize.SizeTo(width, height); if (mCompositor) { mCompositor->SetDestinationSurfaceSize(gfx::IntSize(mEGLSurfaceSize.width, mEGLSurfaceSize.height)); } } void CompositorBridgeParent::ResumeCompositionAndResize(int width, int height) { SetEGLSurfaceSize(width, height); ResumeComposition(); } /* * This will execute a pause synchronously, waiting to make sure that the compositor * really is paused. */ void CompositorBridgeParent::SchedulePauseOnCompositorThread() { MonitorAutoLock lock(mPauseCompositionMonitor); MOZ_ASSERT(CompositorLoop()); CompositorLoop()->PostTask(NewRunnableMethod(this, &CompositorBridgeParent::PauseComposition)); // Wait until the pause has actually been processed by the compositor thread lock.Wait(); } bool CompositorBridgeParent::ScheduleResumeOnCompositorThread() { MonitorAutoLock lock(mResumeCompositionMonitor); MOZ_ASSERT(CompositorLoop()); CompositorLoop()->PostTask(NewRunnableMethod(this, &CompositorBridgeParent::ResumeComposition)); // Wait until the resume has actually been processed by the compositor thread lock.Wait(); return !mPaused; } bool CompositorBridgeParent::ScheduleResumeOnCompositorThread(int width, int height) { MonitorAutoLock lock(mResumeCompositionMonitor); MOZ_ASSERT(CompositorLoop()); CompositorLoop()->PostTask(NewRunnableMethod (this, &CompositorBridgeParent::ResumeCompositionAndResize, width, height)); // Wait until the resume has actually been processed by the compositor thread lock.Wait(); return !mPaused; } void CompositorBridgeParent::ScheduleTask(already_AddRefed task, int time) { if (time == 0) { MessageLoop::current()->PostTask(Move(task)); } else { MessageLoop::current()->PostDelayedTask(Move(task), time); } } void CompositorBridgeParent::UpdatePaintTime(LayerTransactionParent* aLayerTree, const TimeDuration& aPaintTime) { // We get a lot of paint timings for things with empty transactions. if (!mLayerManager || aPaintTime.ToMilliseconds() < 1.0) { return; } mLayerManager->SetPaintTime(aPaintTime); } void CompositorBridgeParent::NotifyShadowTreeTransaction(uint64_t aId, bool aIsFirstPaint, bool aScheduleComposite, uint32_t aPaintSequenceNumber, bool aIsRepeatTransaction, bool aHitTestUpdate) { if (!aIsRepeatTransaction && mLayerManager && mLayerManager->GetRoot()) { // Process plugin data here to give time for them to update before the next // composition. bool pluginsUpdatedFlag = true; AutoResolveRefLayers resolve(mCompositionManager, this, nullptr, &pluginsUpdatedFlag); #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) // If plugins haven't been updated, stop waiting. if (!pluginsUpdatedFlag) { mWaitForPluginsUntil = TimeStamp(); mHaveBlockedForPlugins = false; } #endif if (mApzcTreeManager && aHitTestUpdate) { mApzcTreeManager->UpdateHitTestingTree(mRootLayerTreeID, mLayerManager->GetRoot(), aIsFirstPaint, aId, aPaintSequenceNumber); } mLayerManager->NotifyShadowTreeTransaction(); } if (aScheduleComposite) { ScheduleComposition(); } } void CompositorBridgeParent::ScheduleComposition() { MOZ_ASSERT(CompositorThreadHolder::IsInCompositorThread()); if (mPaused) { return; } mCompositorScheduler->ScheduleComposition(); } // Go down the composite layer tree, setting properties to match their // content-side counterparts. /* static */ void CompositorBridgeParent::SetShadowProperties(Layer* aLayer) { ForEachNode( aLayer, [] (Layer *layer) { if (Layer* maskLayer = layer->GetMaskLayer()) { SetShadowProperties(maskLayer); } for (size_t i = 0; i < layer->GetAncestorMaskLayerCount(); i++) { SetShadowProperties(layer->GetAncestorMaskLayerAt(i)); } // FIXME: Bug 717688 -- Do these updates in LayerTransactionParent::RecvUpdate. LayerComposite* layerComposite = layer->AsLayerComposite(); // Set the layerComposite's base transform to the layer's base transform. layerComposite->SetShadowBaseTransform(layer->GetBaseTransform()); layerComposite->SetShadowTransformSetByAnimation(false); layerComposite->SetShadowVisibleRegion(layer->GetVisibleRegion()); layerComposite->SetShadowClipRect(layer->GetClipRect()); layerComposite->SetShadowOpacity(layer->GetOpacity()); layerComposite->SetShadowOpacitySetByAnimation(false); } ); } void CompositorBridgeParent::CompositeToTarget(DrawTarget* aTarget, const gfx::IntRect* aRect) { profiler_tracing("Paint", "Composite", TRACING_INTERVAL_START); PROFILER_LABEL("CompositorBridgeParent", "Composite", js::ProfileEntry::Category::GRAPHICS); MOZ_ASSERT(CompositorThreadHolder::IsInCompositorThread(), "Composite can only be called on the compositor thread"); TimeStamp start = TimeStamp::Now(); #ifdef COMPOSITOR_PERFORMANCE_WARNING TimeDuration scheduleDelta = TimeStamp::Now() - mCompositorScheduler->GetExpectedComposeStartTime(); if (scheduleDelta > TimeDuration::FromMilliseconds(2) || scheduleDelta < TimeDuration::FromMilliseconds(-2)) { printf_stderr("Compositor: Compose starting off schedule by %4.1f ms\n", scheduleDelta.ToMilliseconds()); } #endif if (!CanComposite()) { TimeStamp end = TimeStamp::Now(); DidComposite(start, end); return; } #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) if (!mWaitForPluginsUntil.IsNull() && mWaitForPluginsUntil > start) { mHaveBlockedForPlugins = true; ScheduleComposition(); return; } #endif /* * AutoResolveRefLayers handles two tasks related to Windows and Linux * plugin window management: * 1) calculating if we have remote content in the view. If we do not have * remote content, all plugin windows for this CompositorBridgeParent (window) * can be hidden since we do not support plugins in chrome when running * under e10s. * 2) Updating plugin position, size, and clip. We do this here while the * remote layer tree is hooked up to to chrome layer tree. This is needed * since plugin clipping can depend on chrome (for example, due to tab modal * prompts). Updates in step 2 are applied via an async ipc message sent * to the main thread. */ bool hasRemoteContent = false; bool updatePluginsFlag = true; AutoResolveRefLayers resolve(mCompositionManager, this, &hasRemoteContent, &updatePluginsFlag); #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) // We do not support plugins in local content. When switching tabs // to local pages, hide every plugin associated with the window. if (!hasRemoteContent && gfxVars::BrowserTabsRemoteAutostart() && mCachedPluginData.Length()) { Unused << SendHideAllPlugins(GetWidget()->GetWidgetKey()); mCachedPluginData.Clear(); } #endif if (aTarget) { mLayerManager->BeginTransactionWithDrawTarget(aTarget, *aRect); } else { mLayerManager->BeginTransaction(); } SetShadowProperties(mLayerManager->GetRoot()); if (mForceCompositionTask && !mOverrideComposeReadiness) { if (mCompositionManager->ReadyForCompose()) { mForceCompositionTask->Cancel(); mForceCompositionTask = nullptr; } else { return; } } mCompositionManager->ComputeRotation(); TimeStamp time = mIsTesting ? mTestTime : mCompositorScheduler->GetLastComposeTime(); bool requestNextFrame = mCompositionManager->TransformShadowTree(time, mVsyncRate); if (requestNextFrame) { ScheduleComposition(); #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) // If we have visible windowed plugins then we need to wait for content (and // then the plugins) to have been updated by the active animation. if (!mPluginWindowsHidden && mCachedPluginData.Length()) { mWaitForPluginsUntil = mCompositorScheduler->GetLastComposeTime() + (mVsyncRate * 2); } #endif } RenderTraceLayers(mLayerManager->GetRoot(), "0000"); #ifdef MOZ_DUMP_PAINTING if (gfxPrefs::DumpHostLayers()) { printf_stderr("Painting --- compositing layer tree:\n"); mLayerManager->Dump(/* aSorted = */ true); } #endif mLayerManager->SetDebugOverlayWantsNextFrame(false); mLayerManager->EndTransaction(time); if (!aTarget) { TimeStamp end = TimeStamp::Now(); DidComposite(start, end); } // We're not really taking advantage of the stored composite-again-time here. // We might be able to skip the next few composites altogether. However, // that's a bit complex to implement and we'll get most of the advantage // by skipping compositing when we detect there's nothing invalid. This is why // we do "composite until" rather than "composite again at". if (!mCompositor->GetCompositeUntilTime().IsNull() || mLayerManager->DebugOverlayWantsNextFrame()) { ScheduleComposition(); } #ifdef COMPOSITOR_PERFORMANCE_WARNING TimeDuration executionTime = TimeStamp::Now() - mCompositorScheduler->GetLastComposeTime(); TimeDuration frameBudget = TimeDuration::FromMilliseconds(15); int32_t frameRate = CalculateCompositionFrameRate(); if (frameRate > 0) { frameBudget = TimeDuration::FromSeconds(1.0 / frameRate); } if (executionTime > frameBudget) { printf_stderr("Compositor: Composite execution took %4.1f ms\n", executionTime.ToMilliseconds()); } #endif // 0 -> Full-tilt composite if (gfxPrefs::LayersCompositionFrameRate() == 0 || mLayerManager->GetCompositor()->GetDiagnosticTypes() & DiagnosticTypes::FLASH_BORDERS) { // Special full-tilt composite mode for performance testing ScheduleComposition(); } mCompositor->SetCompositionTime(TimeStamp()); mozilla::Telemetry::AccumulateTimeDelta(mozilla::Telemetry::COMPOSITE_TIME, start); profiler_tracing("Paint", "Composite", TRACING_INTERVAL_END); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvRemotePluginsReady() { #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) mWaitForPluginsUntil = TimeStamp(); if (mHaveBlockedForPlugins) { mHaveBlockedForPlugins = false; ForceComposeToTarget(nullptr); } else { ScheduleComposition(); } return IPC_OK(); #else NS_NOTREACHED("CompositorBridgeParent::RecvRemotePluginsReady calls " "unexpected on this platform."); return IPC_FAIL_NO_REASON(this); #endif } void CompositorBridgeParent::ForceComposeToTarget(DrawTarget* aTarget, const gfx::IntRect* aRect) { PROFILER_LABEL("CompositorBridgeParent", "ForceComposeToTarget", js::ProfileEntry::Category::GRAPHICS); AutoRestore override(mOverrideComposeReadiness); mOverrideComposeReadiness = true; mCompositorScheduler->ForceComposeToTarget(aTarget, aRect); } PAPZCTreeManagerParent* CompositorBridgeParent::AllocPAPZCTreeManagerParent(const uint64_t& aLayersId) { // The main process should pass in 0 because we assume mRootLayerTreeID MOZ_ASSERT(aLayersId == 0); // This message doubles as initialization MOZ_ASSERT(!mApzcTreeManager); mApzcTreeManager = new APZCTreeManager(); MonitorAutoLock lock(*sIndirectLayerTreesLock); CompositorBridgeParent::LayerTreeState& state = sIndirectLayerTrees[mRootLayerTreeID]; MOZ_ASSERT(state.mParent); MOZ_ASSERT(!state.mApzcTreeManagerParent); state.mApzcTreeManagerParent = new APZCTreeManagerParent(mRootLayerTreeID, state.mParent->GetAPZCTreeManager()); return state.mApzcTreeManagerParent; } bool CompositorBridgeParent::DeallocPAPZCTreeManagerParent(PAPZCTreeManagerParent* aActor) { delete aActor; return true; } PAPZParent* CompositorBridgeParent::AllocPAPZParent(const uint64_t& aLayersId) { // The main process should pass in 0 because we assume mRootLayerTreeID MOZ_ASSERT(aLayersId == 0); RemoteContentController* controller = new RemoteContentController(); // Increment the controller's refcount before we return it. This will keep the // controller alive until it is released by IPDL in DeallocPAPZParent. controller->AddRef(); MonitorAutoLock lock(*sIndirectLayerTreesLock); CompositorBridgeParent::LayerTreeState& state = sIndirectLayerTrees[mRootLayerTreeID]; MOZ_ASSERT(!state.mController); state.mController = controller; return controller; } bool CompositorBridgeParent::DeallocPAPZParent(PAPZParent* aActor) { RemoteContentController* controller = static_cast(aActor); controller->Release(); return true; } mozilla::ipc::IPCResult CompositorBridgeParent::RecvAsyncPanZoomEnabled(const uint64_t& aLayersId, bool* aHasAPZ) { // The main process should pass in 0 because we assume mRootLayerTreeID MOZ_ASSERT(aLayersId == 0); *aHasAPZ = AsyncPanZoomEnabled(); return IPC_OK(); } RefPtr CompositorBridgeParent::GetAPZCTreeManager() { return mApzcTreeManager; } bool CompositorBridgeParent::CanComposite() { return mLayerManager && mLayerManager->GetRoot() && !mPaused; } void CompositorBridgeParent::ScheduleRotationOnCompositorThread(const TargetConfig& aTargetConfig, bool aIsFirstPaint) { MOZ_ASSERT(CompositorThreadHolder::IsInCompositorThread()); if (!aIsFirstPaint && !mCompositionManager->IsFirstPaint() && mCompositionManager->RequiresReorientation(aTargetConfig.orientation())) { if (mForceCompositionTask != nullptr) { mForceCompositionTask->Cancel(); } RefPtr task = NewCancelableRunnableMethod(this, &CompositorBridgeParent::ForceComposition); mForceCompositionTask = task; ScheduleTask(task.forget(), gfxPrefs::OrientationSyncMillis()); } } void CompositorBridgeParent::ShadowLayersUpdated(LayerTransactionParent* aLayerTree, const uint64_t& aTransactionId, const TargetConfig& aTargetConfig, const InfallibleTArray& aUnused, bool aIsFirstPaint, bool aScheduleComposite, uint32_t aPaintSequenceNumber, bool aIsRepeatTransaction, int32_t aPaintSyncId, bool aHitTestUpdate) { ScheduleRotationOnCompositorThread(aTargetConfig, aIsFirstPaint); // Instruct the LayerManager to update its render bounds now. Since all the orientation // change, dimension change would be done at the stage, update the size here is free of // race condition. mLayerManager->UpdateRenderBounds(aTargetConfig.naturalBounds()); mLayerManager->SetRegionToClear(aTargetConfig.clearRegion()); mLayerManager->GetCompositor()->SetScreenRotation(aTargetConfig.rotation()); mCompositionManager->Updated(aIsFirstPaint, aTargetConfig, aPaintSyncId); Layer* root = aLayerTree->GetRoot(); mLayerManager->SetRoot(root); if (mApzcTreeManager && !aIsRepeatTransaction && aHitTestUpdate) { AutoResolveRefLayers resolve(mCompositionManager); mApzcTreeManager->UpdateHitTestingTree(mRootLayerTreeID, root, aIsFirstPaint, mRootLayerTreeID, aPaintSequenceNumber); } // The transaction ID might get reset to 1 if the page gets reloaded, see // https://bugzilla.mozilla.org/show_bug.cgi?id=1145295#c41 // Otherwise, it should be continually increasing. MOZ_ASSERT(aTransactionId == 1 || aTransactionId > mPendingTransaction); mPendingTransaction = aTransactionId; if (root) { SetShadowProperties(root); } if (aScheduleComposite) { ScheduleComposition(); if (mPaused) { TimeStamp now = TimeStamp::Now(); DidComposite(now, now); } } mLayerManager->NotifyShadowTreeTransaction(); } void CompositorBridgeParent::ForceComposite(LayerTransactionParent* aLayerTree) { ScheduleComposition(); } bool CompositorBridgeParent::SetTestSampleTime(LayerTransactionParent* aLayerTree, const TimeStamp& aTime) { if (aTime.IsNull()) { return false; } mIsTesting = true; mTestTime = aTime; bool testComposite = mCompositionManager && mCompositorScheduler->NeedsComposite(); // Update but only if we were already scheduled to animate if (testComposite) { AutoResolveRefLayers resolve(mCompositionManager); bool requestNextFrame = mCompositionManager->TransformShadowTree(aTime, mVsyncRate); if (!requestNextFrame) { CancelCurrentCompositeTask(); // Pretend we composited in case someone is wating for this event. TimeStamp now = TimeStamp::Now(); DidComposite(now, now); } } return true; } void CompositorBridgeParent::LeaveTestMode(LayerTransactionParent* aLayerTree) { mIsTesting = false; } void CompositorBridgeParent::ApplyAsyncProperties(LayerTransactionParent* aLayerTree) { // NOTE: This should only be used for testing. For example, when mIsTesting is // true or when called from test-only methods like // LayerTransactionParent::RecvGetAnimationTransform. // Synchronously update the layer tree if (aLayerTree->GetRoot()) { AutoResolveRefLayers resolve(mCompositionManager); SetShadowProperties(mLayerManager->GetRoot()); TimeStamp time = mIsTesting ? mTestTime : mCompositorScheduler->GetLastComposeTime(); bool requestNextFrame = mCompositionManager->TransformShadowTree(time, mVsyncRate, AsyncCompositionManager::TransformsToSkip::APZ); if (!requestNextFrame) { CancelCurrentCompositeTask(); // Pretend we composited in case someone is waiting for this event. TimeStamp now = TimeStamp::Now(); DidComposite(now, now); } } } mozilla::ipc::IPCResult CompositorBridgeParent::RecvGetFrameUniformity(FrameUniformityData* aOutData) { mCompositionManager->GetFrameUniformity(aOutData); return IPC_OK(); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvRequestOverfill() { uint32_t overfillRatio = mCompositor->GetFillRatio(); Unused << SendOverfill(overfillRatio); return IPC_OK(); } void CompositorBridgeParent::FlushApzRepaints(const LayerTransactionParent* aLayerTree) { MOZ_ASSERT(mApzcTreeManager); uint64_t layersId = aLayerTree->GetId(); if (layersId == 0) { // The request is coming from the parent-process layer tree, so we should // use the compositor's root layer tree id. layersId = mRootLayerTreeID; } APZThreadUtils::RunOnControllerThread(NS_NewRunnableFunction([=] () { mApzcTreeManager->FlushApzRepaints(layersId); })); } void CompositorBridgeParent::GetAPZTestData(const LayerTransactionParent* aLayerTree, APZTestData* aOutData) { MonitorAutoLock lock(*sIndirectLayerTreesLock); *aOutData = sIndirectLayerTrees[mRootLayerTreeID].mApzTestData; } void CompositorBridgeParent::SetConfirmedTargetAPZC(const LayerTransactionParent* aLayerTree, const uint64_t& aInputBlockId, const nsTArray& aTargets) { if (!mApzcTreeManager) { return; } // Need to specifically bind this since it's overloaded. void (APZCTreeManager::*setTargetApzcFunc) (uint64_t, const nsTArray&) = &APZCTreeManager::SetTargetAPZC; RefPtr task = NewRunnableMethod >> (mApzcTreeManager.get(), setTargetApzcFunc, aInputBlockId, aTargets); APZThreadUtils::RunOnControllerThread(task.forget()); } void CompositorBridgeParent::InitializeLayerManager(const nsTArray& aBackendHints) { NS_ASSERTION(!mLayerManager, "Already initialised mLayerManager"); NS_ASSERTION(!mCompositor, "Already initialised mCompositor"); mCompositor = NewCompositor(aBackendHints); if (!mCompositor) { return; } mLayerManager = new LayerManagerComposite(mCompositor); MonitorAutoLock lock(*sIndirectLayerTreesLock); sIndirectLayerTrees[mRootLayerTreeID].mLayerManager = mLayerManager; } RefPtr CompositorBridgeParent::NewCompositor(const nsTArray& aBackendHints) { for (size_t i = 0; i < aBackendHints.Length(); ++i) { RefPtr compositor; if (aBackendHints[i] == LayersBackend::LAYERS_OPENGL) { compositor = new CompositorOGL(this, mWidget, mEGLSurfaceSize.width, mEGLSurfaceSize.height, mUseExternalSurfaceSize); } else if (aBackendHints[i] == LayersBackend::LAYERS_BASIC) { #ifdef MOZ_WIDGET_GTK if (gfxVars::UseXRender()) { compositor = new X11BasicCompositor(this, mWidget); } else #endif { compositor = new BasicCompositor(this, mWidget); } #ifdef XP_WIN } else if (aBackendHints[i] == LayersBackend::LAYERS_D3D11) { compositor = new CompositorD3D11(this, mWidget); } else if (aBackendHints[i] == LayersBackend::LAYERS_D3D9) { compositor = new CompositorD3D9(this, mWidget); #endif } nsCString failureReason; if (compositor && compositor->Initialize(&failureReason)) { if (failureReason.IsEmpty()){ failureReason = "SUCCESS"; } // should only report success here if (aBackendHints[i] == LayersBackend::LAYERS_OPENGL){ Telemetry::Accumulate(Telemetry::OPENGL_COMPOSITING_FAILURE_ID, failureReason); } #ifdef XP_WIN else if (aBackendHints[i] == LayersBackend::LAYERS_D3D9){ Telemetry::Accumulate(Telemetry::D3D9_COMPOSITING_FAILURE_ID, failureReason); } else if (aBackendHints[i] == LayersBackend::LAYERS_D3D11){ Telemetry::Accumulate(Telemetry::D3D11_COMPOSITING_FAILURE_ID, failureReason); } #endif compositor->SetCompositorID(mCompositorID); return compositor; } // report any failure reasons here if (aBackendHints[i] == LayersBackend::LAYERS_OPENGL){ gfxCriticalNote << "[OPENGL] Failed to init compositor with reason: " << failureReason.get(); Telemetry::Accumulate(Telemetry::OPENGL_COMPOSITING_FAILURE_ID, failureReason); } #ifdef XP_WIN else if (aBackendHints[i] == LayersBackend::LAYERS_D3D9){ gfxCriticalNote << "[D3D9] Failed to init compositor with reason: " << failureReason.get(); Telemetry::Accumulate(Telemetry::D3D9_COMPOSITING_FAILURE_ID, failureReason); } else if (aBackendHints[i] == LayersBackend::LAYERS_D3D11){ gfxCriticalNote << "[D3D11] Failed to init compositor with reason: " << failureReason.get(); Telemetry::Accumulate(Telemetry::D3D11_COMPOSITING_FAILURE_ID, failureReason); } #endif } return nullptr; } PLayerTransactionParent* CompositorBridgeParent::AllocPLayerTransactionParent(const nsTArray& aBackendHints, const uint64_t& aId, TextureFactoryIdentifier* aTextureFactoryIdentifier, bool *aSuccess) { MOZ_ASSERT(aId == 0); InitializeLayerManager(aBackendHints); if (!mLayerManager) { NS_WARNING("Failed to initialise Compositor"); *aSuccess = false; LayerTransactionParent* p = new LayerTransactionParent(nullptr, this, 0); p->AddIPDLReference(); return p; } mCompositionManager = new AsyncCompositionManager(mLayerManager); *aSuccess = true; *aTextureFactoryIdentifier = mCompositor->GetTextureFactoryIdentifier(); LayerTransactionParent* p = new LayerTransactionParent(mLayerManager, this, 0); p->AddIPDLReference(); return p; } bool CompositorBridgeParent::DeallocPLayerTransactionParent(PLayerTransactionParent* actor) { static_cast(actor)->ReleaseIPDLReference(); return true; } CompositorBridgeParent* CompositorBridgeParent::GetCompositorBridgeParent(uint64_t id) { CompositorMap::iterator it = sCompositorMap->find(id); return it != sCompositorMap->end() ? it->second : nullptr; } void CompositorBridgeParent::AddCompositor(CompositorBridgeParent* compositor, uint64_t* outID) { static uint64_t sNextID = 1; ++sNextID; (*sCompositorMap)[sNextID] = compositor; *outID = sNextID; } CompositorBridgeParent* CompositorBridgeParent::RemoveCompositor(uint64_t id) { CompositorMap::iterator it = sCompositorMap->find(id); if (it == sCompositorMap->end()) { return nullptr; } CompositorBridgeParent *retval = it->second; sCompositorMap->erase(it); return retval; } void CompositorBridgeParent::NotifyVsync(const TimeStamp& aTimeStamp, const uint64_t& aLayersId) { MOZ_ASSERT(XRE_GetProcessType() == GeckoProcessType_GPU); MOZ_ASSERT(CompositorThreadHolder::IsInCompositorThread()); MonitorAutoLock lock(*sIndirectLayerTreesLock); auto it = sIndirectLayerTrees.find(aLayersId); if (it == sIndirectLayerTrees.end()) return; CompositorBridgeParent* cbp = it->second.mParent; if (!cbp || !cbp->mWidget) return; RefPtr obs = cbp->mWidget->GetVsyncObserver(); if (!obs) return; obs->NotifyVsync(aTimeStamp); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvNotifyChildCreated(const uint64_t& child) { MonitorAutoLock lock(*sIndirectLayerTreesLock); NotifyChildCreated(child); return IPC_OK(); } mozilla::ipc::IPCResult CompositorBridgeParent::RecvNotifyChildRecreated(const uint64_t& aChild) { MonitorAutoLock lock(*sIndirectLayerTreesLock); if (sIndirectLayerTrees.find(aChild) != sIndirectLayerTrees.end()) { // Invalid to register the same layer tree twice. return IPC_FAIL_NO_REASON(this); } NotifyChildCreated(aChild); return IPC_OK(); } void CompositorBridgeParent::NotifyChildCreated(uint64_t aChild) { sIndirectLayerTreesLock->AssertCurrentThreadOwns(); sIndirectLayerTrees[aChild].mParent = this; sIndirectLayerTrees[aChild].mLayerManager = mLayerManager; } mozilla::ipc::IPCResult CompositorBridgeParent::RecvAdoptChild(const uint64_t& child) { APZCTreeManagerParent* parent; { MonitorAutoLock lock(*sIndirectLayerTreesLock); NotifyChildCreated(child); if (sIndirectLayerTrees[child].mLayerTree) { sIndirectLayerTrees[child].mLayerTree->mLayerManager = mLayerManager; } if (sIndirectLayerTrees[child].mRoot) { sIndirectLayerTrees[child].mRoot->AsLayerComposite()->SetLayerManager(mLayerManager); } parent = sIndirectLayerTrees[child].mApzcTreeManagerParent; } if (mApzcTreeManager && parent) { parent->ChildAdopted(mApzcTreeManager); } return IPC_OK(); } static void EraseLayerState(uint64_t aId) { MonitorAutoLock lock(*sIndirectLayerTreesLock); auto iter = sIndirectLayerTrees.find(aId); if (iter != sIndirectLayerTrees.end()) { CompositorBridgeParent* parent = iter->second.mParent; if (parent) { parent->ClearApproximatelyVisibleRegions(aId, Nothing()); } sIndirectLayerTrees.erase(iter); } } /*static*/ void CompositorBridgeParent::DeallocateLayerTreeId(uint64_t aId) { MOZ_ASSERT(NS_IsMainThread()); // Here main thread notifies compositor to remove an element from // sIndirectLayerTrees. This removed element might be queried soon. // Checking the elements of sIndirectLayerTrees exist or not before using. if (!CompositorLoop()) { gfxCriticalError() << "Attempting to post to a invalid Compositor Loop"; return; } CompositorLoop()->PostTask(NewRunnableFunction(&EraseLayerState, aId)); } static void UpdateControllerForLayersId(uint64_t aLayersId, GeckoContentController* aController) { // Adopt ref given to us by SetControllerForLayerTree() MonitorAutoLock lock(*sIndirectLayerTreesLock); sIndirectLayerTrees[aLayersId].mController = already_AddRefed(aController); } ScopedLayerTreeRegistration::ScopedLayerTreeRegistration(APZCTreeManager* aApzctm, uint64_t aLayersId, Layer* aRoot, GeckoContentController* aController) : mLayersId(aLayersId) { EnsureLayerTreeMapReady(); MonitorAutoLock lock(*sIndirectLayerTreesLock); sIndirectLayerTrees[aLayersId].mRoot = aRoot; sIndirectLayerTrees[aLayersId].mController = aController; } ScopedLayerTreeRegistration::~ScopedLayerTreeRegistration() { MonitorAutoLock lock(*sIndirectLayerTreesLock); sIndirectLayerTrees.erase(mLayersId); } /*static*/ void CompositorBridgeParent::SetControllerForLayerTree(uint64_t aLayersId, GeckoContentController* aController) { // This ref is adopted by UpdateControllerForLayersId(). aController->AddRef(); CompositorLoop()->PostTask(NewRunnableFunction(&UpdateControllerForLayersId, aLayersId, aController)); } /*static*/ already_AddRefed CompositorBridgeParent::GetAPZCTreeManager(uint64_t aLayersId) { EnsureLayerTreeMapReady(); MonitorAutoLock lock(*sIndirectLayerTreesLock); LayerTreeMap::iterator cit = sIndirectLayerTrees.find(aLayersId); if (sIndirectLayerTrees.end() == cit) { return nullptr; } LayerTreeState* lts = &cit->second; RefPtr apzctm = lts->mParent ? lts->mParent->mApzcTreeManager.get() : nullptr; return apzctm.forget(); } static void InsertVsyncProfilerMarker(TimeStamp aVsyncTimestamp) { #ifdef MOZ_ENABLE_PROFILER_SPS MOZ_ASSERT(CompositorThreadHolder::IsInCompositorThread()); VsyncPayload* payload = new VsyncPayload(aVsyncTimestamp); PROFILER_MARKER_PAYLOAD("VsyncTimestamp", payload); #endif } /*static */ void CompositorBridgeParent::PostInsertVsyncProfilerMarker(TimeStamp aVsyncTimestamp) { // Called in the vsync thread if (profiler_is_active() && CompositorThreadHolder::IsActive()) { CompositorLoop()->PostTask( NewRunnableFunction(InsertVsyncProfilerMarker, aVsyncTimestamp)); } } widget::PCompositorWidgetParent* CompositorBridgeParent::AllocPCompositorWidgetParent(const CompositorWidgetInitData& aInitData) { #if defined(MOZ_WIDGET_SUPPORTS_OOP_COMPOSITING) if (mWidget) { // Should not create two widgets on the same compositor. return nullptr; } widget::CompositorWidgetParent* widget = new widget::CompositorWidgetParent(aInitData); widget->AddRef(); // Sending the constructor acts as initialization as well. mWidget = widget; return widget; #else return nullptr; #endif } bool CompositorBridgeParent::DeallocPCompositorWidgetParent(PCompositorWidgetParent* aActor) { #if defined(MOZ_WIDGET_SUPPORTS_OOP_COMPOSITING) static_cast(aActor)->Release(); return true; #else return false; #endif } bool CompositorBridgeParent::IsPendingComposite() { MOZ_ASSERT(CompositorThreadHolder::IsInCompositorThread()); if (!mCompositor) { return false; } return mCompositor->IsPendingComposite(); } void CompositorBridgeParent::FinishPendingComposite() { MOZ_ASSERT(CompositorThreadHolder::IsInCompositorThread()); if (!mCompositor) { return; } return mCompositor->FinishPendingComposite(); } CompositorController* CompositorBridgeParent::LayerTreeState::GetCompositorController() const { return mParent; } MetricsSharingController* CompositorBridgeParent::LayerTreeState::CrossProcessSharingController() const { return mCrossProcessParent; } MetricsSharingController* CompositorBridgeParent::LayerTreeState::InProcessSharingController() const { return mParent; } void CompositorBridgeParent::DidComposite(TimeStamp& aCompositeStart, TimeStamp& aCompositeEnd) { Unused << SendDidComposite(0, mPendingTransaction, aCompositeStart, aCompositeEnd); mPendingTransaction = 0; if (mLayerManager) { nsTArray notifications; mLayerManager->ExtractImageCompositeNotifications(¬ifications); if (!notifications.IsEmpty()) { Unused << ImageBridgeParent::NotifyImageComposites(notifications); } } MonitorAutoLock lock(*sIndirectLayerTreesLock); ForEachIndirectLayerTree([&] (LayerTreeState* lts, const uint64_t& aLayersId) -> void { if (lts->mCrossProcessParent) { CrossProcessCompositorBridgeParent* cpcp = lts->mCrossProcessParent; cpcp->DidComposite(aLayersId, aCompositeStart, aCompositeEnd); } }); } void CompositorBridgeParent::InvalidateRemoteLayers() { MOZ_ASSERT(CompositorLoop() == MessageLoop::current()); Unused << PCompositorBridgeParent::SendInvalidateLayers(0); MonitorAutoLock lock(*sIndirectLayerTreesLock); ForEachIndirectLayerTree([] (LayerTreeState* lts, const uint64_t& aLayersId) -> void { if (lts->mCrossProcessParent) { CrossProcessCompositorBridgeParent* cpcp = lts->mCrossProcessParent; Unused << cpcp->SendInvalidateLayers(aLayersId); } }); } bool CompositorBridgeParent::ResetCompositor(const nsTArray& aBackendHints, uint64_t aSeqNo, TextureFactoryIdentifier* aOutIdentifier) { Maybe newIdentifier; { MonitorAutoLock lock(mResetCompositorMonitor); CompositorLoop()->PostTask(NewRunnableMethod >, uint64_t, Maybe*>(this, &CompositorBridgeParent::ResetCompositorTask, aBackendHints, aSeqNo, &newIdentifier)); mResetCompositorMonitor.Wait(); } if (!newIdentifier) { return false; } *aOutIdentifier = newIdentifier.value(); return true; } // Invoked on the compositor thread. The main thread is waiting on the given // monitor. void CompositorBridgeParent::ResetCompositorTask(const nsTArray& aBackendHints, uint64_t aSeqNo, Maybe* aOutNewIdentifier) { // Perform the reset inside a lock, so the main thread can wake up as soon as // possible. We notify child processes (if necessary) outside the lock. Maybe newIdentifier; { MonitorAutoLock lock(mResetCompositorMonitor); newIdentifier = ResetCompositorImpl(aBackendHints); *aOutNewIdentifier = newIdentifier; mResetCompositorMonitor.NotifyAll(); } // NOTE: |aBackendHints|, and |aOutNewIdentifier| are now all invalid since // they are allocated on ResetCompositor's stack on the main thread, which // is no longer waiting on the lock. if (!newIdentifier) { // No compositor change; nothing to do. return; } MonitorAutoLock lock(*sIndirectLayerTreesLock); ForEachIndirectLayerTree([&] (LayerTreeState* lts, uint64_t layersId) -> void { if (CrossProcessCompositorBridgeParent* cpcp = lts->mCrossProcessParent) { Unused << cpcp->SendCompositorUpdated(layersId, newIdentifier.value(), aSeqNo); if (LayerTransactionParent* ltp = lts->mLayerTree) { ltp->AddPendingCompositorUpdate(); } lts->mPendingCompositorUpdates++; } }); } Maybe CompositorBridgeParent::ResetCompositorImpl(const nsTArray& aBackendHints) { if (!mLayerManager) { return Nothing(); } RefPtr compositor = NewCompositor(aBackendHints); if (!compositor) { MOZ_RELEASE_ASSERT(compositor, "Failed to reset compositor."); } // Don't bother changing from basic->basic. if (mCompositor && mCompositor->GetBackendType() == LayersBackend::LAYERS_BASIC && compositor->GetBackendType() == LayersBackend::LAYERS_BASIC) { return Nothing(); } if (mCompositor) { mCompositor->SetInvalid(); } mCompositor = compositor; mLayerManager->ChangeCompositor(compositor); return Some(compositor->GetTextureFactoryIdentifier()); } static void OpenCompositor(RefPtr aCompositor, Endpoint&& aEndpoint) { aCompositor->Bind(Move(aEndpoint)); } /* static */ bool CompositorBridgeParent::CreateForContent(Endpoint&& aEndpoint) { gfxPlatform::InitLayersIPC(); RefPtr cpcp = new CrossProcessCompositorBridgeParent(); CompositorLoop()->PostTask(NewRunnableFunction(OpenCompositor, cpcp, Move(aEndpoint))); return true; } static void UpdateIndirectTree(uint64_t aId, Layer* aRoot, const TargetConfig& aTargetConfig) { MonitorAutoLock lock(*sIndirectLayerTreesLock); sIndirectLayerTrees[aId].mRoot = aRoot; sIndirectLayerTrees[aId].mTargetConfig = aTargetConfig; } /* static */ CompositorBridgeParent::LayerTreeState* CompositorBridgeParent::GetIndirectShadowTree(uint64_t aId) { MonitorAutoLock lock(*sIndirectLayerTreesLock); LayerTreeMap::iterator cit = sIndirectLayerTrees.find(aId); if (sIndirectLayerTrees.end() == cit) { return nullptr; } return &cit->second; } static CompositorBridgeParent::LayerTreeState* GetStateForRoot(uint64_t aContentLayersId, const MonitorAutoLock& aProofOfLock) { CompositorBridgeParent::LayerTreeState* state = nullptr; LayerTreeMap::iterator itr = sIndirectLayerTrees.find(aContentLayersId); if (sIndirectLayerTrees.end() != itr) { state = &itr->second; } // |state| is the state for the content process, but we want the APZCTMParent // for the parent process owning that content process. So we have to jump to // the LayerTreeState for the root layer tree id for that layer tree, and use // the mApzcTreeManagerParent from that. This should also work with nested // content processes, because RootLayerTreeId() will bypass any intermediate // processes' ids and go straight to the root. if (state) { uint64_t rootLayersId = state->mParent->RootLayerTreeId(); itr = sIndirectLayerTrees.find(rootLayersId); state = (sIndirectLayerTrees.end() != itr) ? &itr->second : nullptr; } return state; } /* static */ APZCTreeManagerParent* CompositorBridgeParent::GetApzcTreeManagerParentForRoot(uint64_t aContentLayersId) { MonitorAutoLock lock(*sIndirectLayerTreesLock); CompositorBridgeParent::LayerTreeState* state = GetStateForRoot(aContentLayersId, lock); return state ? state->mApzcTreeManagerParent : nullptr; } /* static */ GeckoContentController* CompositorBridgeParent::GetGeckoContentControllerForRoot(uint64_t aContentLayersId) { MonitorAutoLock lock(*sIndirectLayerTreesLock); CompositorBridgeParent::LayerTreeState* state = GetStateForRoot(aContentLayersId, lock); return state ? state->mController.get() : nullptr; } PTextureParent* CompositorBridgeParent::AllocPTextureParent(const SurfaceDescriptor& aSharedData, const LayersBackend& aLayersBackend, const TextureFlags& aFlags, const uint64_t& aId, const uint64_t& aSerial) { return TextureHost::CreateIPDLActor(this, aSharedData, aLayersBackend, aFlags, aSerial); } bool CompositorBridgeParent::DeallocPTextureParent(PTextureParent* actor) { return TextureHost::DestroyIPDLActor(actor); } bool CompositorBridgeParent::IsSameProcess() const { return OtherPid() == base::GetCurrentProcId(); } #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) //#define PLUGINS_LOG(...) printf_stderr("CP [%s]: ", __FUNCTION__); // printf_stderr(__VA_ARGS__); // printf_stderr("\n"); #define PLUGINS_LOG(...) bool CompositorBridgeParent::UpdatePluginWindowState(uint64_t aId) { MonitorAutoLock lock(*sIndirectLayerTreesLock); CompositorBridgeParent::LayerTreeState& lts = sIndirectLayerTrees[aId]; if (!lts.mParent) { PLUGINS_LOG("[%" PRIu64 "] layer tree compositor parent pointer is null", aId); return false; } // Check if this layer tree has received any shadow layer updates if (!lts.mUpdatedPluginDataAvailable) { PLUGINS_LOG("[%" PRIu64 "] no plugin data", aId); return false; } // pluginMetricsChanged tracks whether we need to send plugin update // data to the main thread. If we do we'll have to block composition, // which we want to avoid if at all possible. bool pluginMetricsChanged = false; // Same layer tree checks if (mLastPluginUpdateLayerTreeId == aId) { // no plugin data and nothing has changed, bail. if (!mCachedPluginData.Length() && !lts.mPluginData.Length()) { PLUGINS_LOG("[%" PRIu64 "] no data, no changes", aId); return false; } if (mCachedPluginData.Length() == lts.mPluginData.Length()) { // check for plugin data changes for (uint32_t idx = 0; idx < lts.mPluginData.Length(); idx++) { if (!(mCachedPluginData[idx] == lts.mPluginData[idx])) { pluginMetricsChanged = true; break; } } } else { // array lengths don't match, need to update pluginMetricsChanged = true; } } else { // exchanging layer trees, we need to update pluginMetricsChanged = true; } // Check if plugin windows are currently hidden due to scrolling if (mDeferPluginWindows) { PLUGINS_LOG("[%" PRIu64 "] suppressing", aId); return false; } // If the plugin windows were hidden but now are not, we need to force // update the metrics to make sure they are visible again. if (mPluginWindowsHidden) { PLUGINS_LOG("[%" PRIu64 "] re-showing", aId); mPluginWindowsHidden = false; pluginMetricsChanged = true; } if (!lts.mPluginData.Length()) { // Don't hide plugins if the previous remote layer tree didn't contain any. if (!mCachedPluginData.Length()) { PLUGINS_LOG("[%" PRIu64 "] nothing to hide", aId); return false; } uintptr_t parentWidget = GetWidget()->GetWidgetKey(); // We will pass through here in cases where the previous shadow layer // tree contained visible plugins and the new tree does not. All we need // to do here is hide the plugins for the old tree, so don't waste time // calculating clipping. mPluginsLayerOffset = nsIntPoint(0,0); mPluginsLayerVisibleRegion.SetEmpty(); Unused << lts.mParent->SendHideAllPlugins(parentWidget); lts.mUpdatedPluginDataAvailable = false; PLUGINS_LOG("[%" PRIu64 "] hide all", aId); } else { // Retrieve the offset and visible region of the layer that hosts // the plugins, CompositorBridgeChild needs these in calculating proper // plugin clipping. LayerTransactionParent* layerTree = lts.mLayerTree; Layer* contentRoot = layerTree->GetRoot(); if (contentRoot) { nsIntPoint offset; nsIntRegion visibleRegion; if (contentRoot->GetVisibleRegionRelativeToRootLayer(visibleRegion, &offset)) { // Check to see if these values have changed, if so we need to // update plugin window position within the window. if (!pluginMetricsChanged && mPluginsLayerVisibleRegion == visibleRegion && mPluginsLayerOffset == offset) { PLUGINS_LOG("[%" PRIu64 "] no change", aId); return false; } mPluginsLayerOffset = offset; mPluginsLayerVisibleRegion = visibleRegion; Unused << lts.mParent->SendUpdatePluginConfigurations( LayoutDeviceIntPoint::FromUnknownPoint(offset), LayoutDeviceIntRegion::FromUnknownRegion(visibleRegion), lts.mPluginData); lts.mUpdatedPluginDataAvailable = false; PLUGINS_LOG("[%" PRIu64 "] updated", aId); } else { PLUGINS_LOG("[%" PRIu64 "] no visibility data", aId); return false; } } else { PLUGINS_LOG("[%" PRIu64 "] no content root", aId); return false; } } mLastPluginUpdateLayerTreeId = aId; mCachedPluginData = lts.mPluginData; return true; } void CompositorBridgeParent::ScheduleShowAllPluginWindows() { MOZ_ASSERT(CompositorLoop()); CompositorLoop()->PostTask(NewRunnableMethod(this, &CompositorBridgeParent::ShowAllPluginWindows)); } void CompositorBridgeParent::ShowAllPluginWindows() { MOZ_ASSERT(!NS_IsMainThread()); mDeferPluginWindows = false; ScheduleComposition(); } void CompositorBridgeParent::ScheduleHideAllPluginWindows() { MOZ_ASSERT(CompositorLoop()); CompositorLoop()->PostTask(NewRunnableMethod(this, &CompositorBridgeParent::HideAllPluginWindows)); } void CompositorBridgeParent::HideAllPluginWindows() { MOZ_ASSERT(!NS_IsMainThread()); // No plugins in the cache implies no plugins to manage // in this content. if (!mCachedPluginData.Length() || mDeferPluginWindows) { return; } uintptr_t parentWidget = GetWidget()->GetWidgetKey(); mDeferPluginWindows = true; mPluginWindowsHidden = true; #if defined(XP_WIN) // We will get an async reply that this has happened and then send hide. mWaitForPluginsUntil = TimeStamp::Now() + mVsyncRate; Unused << SendCaptureAllPlugins(parentWidget); #else Unused << SendHideAllPlugins(parentWidget); ScheduleComposition(); #endif } #endif // #if defined(XP_WIN) || defined(MOZ_WIDGET_GTK) mozilla::ipc::IPCResult CompositorBridgeParent::RecvAllPluginsCaptured() { #if defined(XP_WIN) mWaitForPluginsUntil = TimeStamp(); mHaveBlockedForPlugins = false; ForceComposeToTarget(nullptr); Unused << SendHideAllPlugins(GetWidget()->GetWidgetKey()); return IPC_OK(); #else MOZ_ASSERT_UNREACHABLE( "CompositorBridgeParent::RecvAllPluginsCaptured calls unexpected."); return IPC_FAIL_NO_REASON(this); #endif } } // namespace layers } // namespace mozilla