/* vim: set ts=2 sw=2 et tw=80: */ /* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 2 -*- * 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 "ImageBridgeParent.h" #include // for uint64_t, uint32_t #include "CompositableHost.h" // for CompositableParent, Create #include "base/message_loop.h" // for MessageLoop #include "base/process.h" // for ProcessId #include "base/task.h" // for CancelableTask, DeleteTask, etc #include "mozilla/ClearOnShutdown.h" #include "mozilla/gfx/Point.h" // for IntSize #include "mozilla/Hal.h" // for hal::SetCurrentThreadPriority() #include "mozilla/HalTypes.h" // for hal::THREAD_PRIORITY_COMPOSITOR #include "mozilla/ipc/MessageChannel.h" // for MessageChannel, etc #include "mozilla/ipc/ProtocolUtils.h" #include "mozilla/ipc/Transport.h" // for Transport #include "mozilla/media/MediaSystemResourceManagerParent.h" // for MediaSystemResourceManagerParent #include "mozilla/layers/CompositableTransactionParent.h" #include "mozilla/layers/LayerManagerComposite.h" #include "mozilla/layers/LayersMessages.h" // for EditReply #include "mozilla/layers/LayersSurfaces.h" // for PGrallocBufferParent #include "mozilla/layers/PCompositableParent.h" #include "mozilla/layers/PImageBridgeParent.h" #include "mozilla/layers/TextureHostOGL.h" // for TextureHostOGL #include "mozilla/layers/Compositor.h" #include "mozilla/Monitor.h" #include "mozilla/mozalloc.h" // for operator new, etc #include "mozilla/Unused.h" #include "nsDebug.h" // for NS_RUNTIMEABORT, etc #include "nsISupportsImpl.h" // for ImageBridgeParent::Release, etc #include "nsTArray.h" // for nsTArray, nsTArray_Impl #include "nsTArrayForwardDeclare.h" // for InfallibleTArray #include "nsXULAppAPI.h" // for XRE_GetIOMessageLoop #include "mozilla/layers/TextureHost.h" #include "nsThreadUtils.h" namespace mozilla { namespace layers { using namespace mozilla::ipc; using namespace mozilla::gfx; using namespace mozilla::media; std::map ImageBridgeParent::sImageBridges; StaticAutoPtr sImageBridgesLock; // defined in CompositorBridgeParent.cpp CompositorThreadHolder* GetCompositorThreadHolder(); /* static */ void ImageBridgeParent::Setup() { MOZ_ASSERT(NS_IsMainThread()); if (!sImageBridgesLock) { sImageBridgesLock = new Monitor("ImageBridges"); mozilla::ClearOnShutdown(&sImageBridgesLock); } } ImageBridgeParent::ImageBridgeParent(MessageLoop* aLoop, ProcessId aChildProcessId) : mMessageLoop(aLoop) , mSetChildThreadPriority(false) , mClosed(false) { MOZ_ASSERT(NS_IsMainThread()); // creates the map only if it has not been created already, so it is safe // with several bridges CompositableMap::Create(); { MonitorAutoLock lock(*sImageBridgesLock); sImageBridges[aChildProcessId] = this; } SetOtherProcessId(aChildProcessId); } ImageBridgeParent::~ImageBridgeParent() { nsTArray parents; ManagedPImageContainerParent(parents); for (PImageContainerParent* p : parents) { delete p; } } static StaticRefPtr sImageBridgeParentSingleton; void ReleaseImageBridgeParentSingleton() { sImageBridgeParentSingleton = nullptr; } /* static */ ImageBridgeParent* ImageBridgeParent::CreateSameProcess() { RefPtr parent = new ImageBridgeParent(CompositorThreadHolder::Loop(), base::GetCurrentProcId()); parent->mSelfRef = parent; sImageBridgeParentSingleton = parent; return parent; } /* static */ bool ImageBridgeParent::CreateForGPUProcess(Endpoint&& aEndpoint) { MOZ_ASSERT(XRE_GetProcessType() == GeckoProcessType_GPU); MessageLoop* loop = CompositorThreadHolder::Loop(); RefPtr parent = new ImageBridgeParent(loop, aEndpoint.OtherPid()); loop->PostTask(NewRunnableMethod&&>( parent, &ImageBridgeParent::Bind, Move(aEndpoint))); sImageBridgeParentSingleton = parent; return true; } void ImageBridgeParent::ActorDestroy(ActorDestroyReason aWhy) { // Can't alloc/dealloc shmems from now on. mClosed = true; { MonitorAutoLock lock(*sImageBridgesLock); sImageBridges.erase(OtherPid()); } MessageLoop::current()->PostTask(NewRunnableMethod(this, &ImageBridgeParent::DeferredDestroy)); // It is very important that this method gets called at shutdown (be it a clean // or an abnormal shutdown), because DeferredDestroy is what clears mSelfRef. // If mSelfRef is not null and ActorDestroy is not called, the ImageBridgeParent // is leaked which causes the CompositorThreadHolder to be leaked and // CompsoitorParent's shutdown ends up spinning the event loop forever, waiting // for the compositor thread to terminate. } bool ImageBridgeParent::RecvImageBridgeThreadId(const PlatformThreadId& aThreadId) { MOZ_ASSERT(!mSetChildThreadPriority); if (mSetChildThreadPriority) { return false; } mSetChildThreadPriority = true; return true; } class MOZ_STACK_CLASS AutoImageBridgeParentAsyncMessageSender { public: explicit AutoImageBridgeParentAsyncMessageSender(ImageBridgeParent* aImageBridge, InfallibleTArray* aToDestroy = nullptr) : mImageBridge(aImageBridge) , mToDestroy(aToDestroy) { mImageBridge->SetAboutToSendAsyncMessages(); } ~AutoImageBridgeParentAsyncMessageSender() { mImageBridge->SendPendingAsyncMessages(); if (mToDestroy) { for (const auto& op : *mToDestroy) { mImageBridge->DestroyActor(op); } } } private: ImageBridgeParent* mImageBridge; InfallibleTArray* mToDestroy; }; bool ImageBridgeParent::RecvUpdate(EditArray&& aEdits, OpDestroyArray&& aToDestroy, const uint64_t& aFwdTransactionId, EditReplyArray* aReply) { // This ensures that destroy operations are always processed. It is not safe // to early-return from RecvUpdate without doing so. AutoImageBridgeParentAsyncMessageSender autoAsyncMessageSender(this, &aToDestroy); UpdateFwdTransactionId(aFwdTransactionId); EditReplyVector replyv; for (EditArray::index_type i = 0; i < aEdits.Length(); ++i) { if (!ReceiveCompositableUpdate(aEdits[i], replyv)) { return false; } } aReply->SetCapacity(replyv.size()); if (replyv.size() > 0) { aReply->AppendElements(&replyv.front(), replyv.size()); } if (!IsSameProcess()) { // Ensure that any pending operations involving back and front // buffers have completed, so that neither process stomps on the // other's buffer contents. LayerManagerComposite::PlatformSyncBeforeReplyUpdate(); } return true; } bool ImageBridgeParent::RecvUpdateNoSwap(EditArray&& aEdits, OpDestroyArray&& aToDestroy, const uint64_t& aFwdTransactionId) { InfallibleTArray noReplies; bool success = RecvUpdate(Move(aEdits), Move(aToDestroy), aFwdTransactionId, &noReplies); MOZ_ASSERT(noReplies.Length() == 0, "RecvUpdateNoSwap requires a sync Update to carry Edits"); return success; } /* static */ bool ImageBridgeParent::CreateForContent(Endpoint&& aEndpoint) { MessageLoop* loop = CompositorThreadHolder::Loop(); RefPtr bridge = new ImageBridgeParent(loop, aEndpoint.OtherPid()); loop->PostTask(NewRunnableMethod&&>( bridge, &ImageBridgeParent::Bind, Move(aEndpoint))); return true; } void ImageBridgeParent::Bind(Endpoint&& aEndpoint) { if (!aEndpoint.Bind(this)) return; mSelfRef = this; } bool ImageBridgeParent::RecvWillClose() { // If there is any texture still alive we have to force it to deallocate the // device data (GL textures, etc.) now because shortly after SenStop() returns // on the child side the widget will be destroyed along with it's associated // GL context. InfallibleTArray textures; ManagedPTextureParent(textures); for (unsigned int i = 0; i < textures.Length(); ++i) { RefPtr tex = TextureHost::AsTextureHost(textures[i]); tex->DeallocateDeviceData(); } return true; } static uint64_t GenImageContainerID() { static uint64_t sNextImageID = 1; ++sNextImageID; return sNextImageID; } PCompositableParent* ImageBridgeParent::AllocPCompositableParent(const TextureInfo& aInfo, PImageContainerParent* aImageContainer, uint64_t* aID) { uint64_t id = GenImageContainerID(); *aID = id; return CompositableHost::CreateIPDLActor(this, aInfo, id, aImageContainer); } bool ImageBridgeParent::DeallocPCompositableParent(PCompositableParent* aActor) { return CompositableHost::DestroyIPDLActor(aActor); } PTextureParent* ImageBridgeParent::AllocPTextureParent(const SurfaceDescriptor& aSharedData, const LayersBackend& aLayersBackend, const TextureFlags& aFlags, const uint64_t& aSerial) { return TextureHost::CreateIPDLActor(this, aSharedData, aLayersBackend, aFlags, aSerial); } bool ImageBridgeParent::DeallocPTextureParent(PTextureParent* actor) { return TextureHost::DestroyIPDLActor(actor); } PMediaSystemResourceManagerParent* ImageBridgeParent::AllocPMediaSystemResourceManagerParent() { return new mozilla::media::MediaSystemResourceManagerParent(); } bool ImageBridgeParent::DeallocPMediaSystemResourceManagerParent(PMediaSystemResourceManagerParent* aActor) { MOZ_ASSERT(aActor); delete static_cast(aActor); return true; } PImageContainerParent* ImageBridgeParent::AllocPImageContainerParent() { return new ImageContainerParent(); } bool ImageBridgeParent::DeallocPImageContainerParent(PImageContainerParent* actor) { delete actor; return true; } void ImageBridgeParent::SendAsyncMessage(const InfallibleTArray& aMessage) { mozilla::Unused << SendParentAsyncMessages(aMessage); } class ProcessIdComparator { public: bool Equals(const ImageCompositeNotification& aA, const ImageCompositeNotification& aB) const { return aA.imageContainerParent()->OtherPid() == aB.imageContainerParent()->OtherPid(); } bool LessThan(const ImageCompositeNotification& aA, const ImageCompositeNotification& aB) const { return aA.imageContainerParent()->OtherPid() < aB.imageContainerParent()->OtherPid(); } }; /* static */ bool ImageBridgeParent::NotifyImageComposites(nsTArray& aNotifications) { // Group the notifications by destination process ID and then send the // notifications in one message per group. aNotifications.Sort(ProcessIdComparator()); uint32_t i = 0; bool ok = true; while (i < aNotifications.Length()) { AutoTArray notifications; notifications.AppendElement(aNotifications[i]); uint32_t end = i + 1; MOZ_ASSERT(aNotifications[i].imageContainerParent()); ProcessId pid = aNotifications[i].imageContainerParent()->OtherPid(); while (end < aNotifications.Length() && aNotifications[end].imageContainerParent()->OtherPid() == pid) { notifications.AppendElement(aNotifications[end]); ++end; } GetInstance(pid)->SendPendingAsyncMessages(); if (!GetInstance(pid)->SendDidComposite(notifications)) { ok = false; } i = end; } return ok; } void ImageBridgeParent::DeferredDestroy() { mCompositorThreadHolder = nullptr; mSelfRef = nullptr; // "this" ImageBridge may get deleted here. } RefPtr ImageBridgeParent::GetInstance(ProcessId aId) { MOZ_ASSERT(CompositorThreadHolder::IsInCompositorThread()); MonitorAutoLock lock(*sImageBridgesLock); NS_ASSERTION(sImageBridges.count(aId) == 1, "ImageBridgeParent for the process"); return sImageBridges[aId]; } void ImageBridgeParent::OnChannelConnected(int32_t aPid) { mCompositorThreadHolder = GetCompositorThreadHolder(); } bool ImageBridgeParent::AllocShmem(size_t aSize, ipc::SharedMemory::SharedMemoryType aType, ipc::Shmem* aShmem) { if (mClosed) { return false; } return PImageBridgeParent::AllocShmem(aSize, aType, aShmem); } bool ImageBridgeParent::AllocUnsafeShmem(size_t aSize, ipc::SharedMemory::SharedMemoryType aType, ipc::Shmem* aShmem) { if (mClosed) { return false; } return PImageBridgeParent::AllocUnsafeShmem(aSize, aType, aShmem); } void ImageBridgeParent::DeallocShmem(ipc::Shmem& aShmem) { if (mClosed) { return; } PImageBridgeParent::DeallocShmem(aShmem); } bool ImageBridgeParent::IsSameProcess() const { return OtherPid() == base::GetCurrentProcId(); } void ImageBridgeParent::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)); if (!IsAboutToSendAsyncMessages()) { SendPendingAsyncMessages(); } } } // namespace layers } // namespace mozilla