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fune/gfx/ipc/GPUProcessManager.cpp
Jamie Nicol 2cf59fe695 Bug 1767128 - Rework and re-enable SurfaceControl rendering path on Android. r=agi,gfx-reviewers,aosmond 
In bug 1762424 we introduced a rendering path on Android using the
SurfaceControl API, in order to work around a bug preventing recovery
from a GPU process crash. However, the initial implementation caused
this bug: repeatedly sending the same SurfaceControl objects over AIDL
to the GPU process resulted in them being leaked, eventually causing
severe display issues. Not only were we duplicating the SurfaceControl
for each widget, but each time a widget was resized too.

This patch reworks our usage of the SurfaceControl API to avoid ever
having to send them cross-process. Instead, we create a single child
SurfaceControl object for each SurfaceControl that is attached to a
widget. (Typically there will be a single one shared between all
widgets, changing only when the app is paused and resumed, which is
much fewer than one per widget per resize.)

In the parent process we obtain the Surfaces that will be rendered in
to from the child SurfaceControls, and only send those Surfaces to the
GPU process. Thankfully unlike SurfaceControls, sending Surfaces
cross-process does not cause leaks. When the GPU process dies we
simply destroy all of the child SurfaceControls, and recreate them
again on-demand.

Differential Revision: https://phabricator.services.mozilla.com/D147437
2022-05-31 18:41:07 +00:00

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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 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 "GPUProcessManager.h"
#include "gfxConfig.h"
#include "gfxPlatform.h"
#include "GPUProcessHost.h"
#include "GPUProcessListener.h"
#include "mozilla/AppShutdown.h"
#include "mozilla/MemoryReportingProcess.h"
#include "mozilla/Preferences.h"
#include "mozilla/Sprintf.h"
#include "mozilla/StaticPtr.h"
#include "mozilla/StaticPrefs_gfx.h"
#include "mozilla/StaticPrefs_layers.h"
#include "mozilla/StaticPrefs_media.h"
#include "mozilla/RemoteDecoderManagerChild.h"
#include "mozilla/RemoteDecoderManagerParent.h"
#include "mozilla/Telemetry.h"
#include "mozilla/dom/ContentParent.h"
#include "mozilla/gfx/gfxVars.h"
#include "mozilla/gfx/GPUChild.h"
#include "mozilla/ipc/Endpoint.h"
#include "mozilla/ipc/ProcessChild.h"
#include "mozilla/layers/APZCTreeManagerChild.h"
#include "mozilla/layers/APZInputBridgeChild.h"
#include "mozilla/layers/CompositorBridgeChild.h"
#include "mozilla/layers/CompositorBridgeParent.h"
#include "mozilla/layers/CompositorManagerChild.h"
#include "mozilla/layers/CompositorManagerParent.h"
#include "mozilla/layers/CompositorOptions.h"
#include "mozilla/layers/ImageBridgeChild.h"
#include "mozilla/layers/ImageBridgeParent.h"
#include "mozilla/layers/InProcessCompositorSession.h"
#include "mozilla/layers/LayerTreeOwnerTracker.h"
#include "mozilla/layers/RemoteCompositorSession.h"
#include "mozilla/webrender/RenderThread.h"
#include "mozilla/widget/PlatformWidgetTypes.h"
#include "nsAppRunner.h"
#include "mozilla/widget/CompositorWidget.h"
#ifdef MOZ_WIDGET_SUPPORTS_OOP_COMPOSITING
# include "mozilla/widget/CompositorWidgetChild.h"
#endif
#include "nsBaseWidget.h"
#include "nsContentUtils.h"
#include "VRManagerChild.h"
#include "VRManagerParent.h"
#include "VsyncBridgeChild.h"
#include "VsyncIOThreadHolder.h"
#include "VsyncSource.h"
#include "nsExceptionHandler.h"
#include "nsPrintfCString.h"
#if defined(MOZ_WIDGET_ANDROID)
# include "mozilla/java/SurfaceControlManagerWrappers.h"
# include "mozilla/widget/AndroidUiThread.h"
# include "mozilla/layers/UiCompositorControllerChild.h"
#endif // defined(MOZ_WIDGET_ANDROID)
#if defined(XP_WIN)
# include "gfxWindowsPlatform.h"
#endif
namespace mozilla {
namespace gfx {
using namespace mozilla::layers;
enum class FallbackType : uint32_t {
NONE = 0,
DECODINGDISABLED,
DISABLED,
};
static StaticAutoPtr<GPUProcessManager> sSingleton;
GPUProcessManager* GPUProcessManager::Get() { return sSingleton; }
void GPUProcessManager::Initialize() {
MOZ_ASSERT(XRE_IsParentProcess());
sSingleton = new GPUProcessManager();
}
void GPUProcessManager::Shutdown() { sSingleton = nullptr; }
GPUProcessManager::GPUProcessManager()
: mTaskFactory(this),
mNextNamespace(0),
mIdNamespace(0),
mResourceId(0),
mUnstableProcessAttempts(0),
mTotalProcessAttempts(0),
mDeviceResetCount(0),
mAppInForeground(true),
mProcess(nullptr),
mProcessToken(0),
mProcessStable(true),
mGPUChild(nullptr) {
MOZ_COUNT_CTOR(GPUProcessManager);
mIdNamespace = AllocateNamespace();
mDeviceResetLastTime = TimeStamp::Now();
LayerTreeOwnerTracker::Initialize();
CompositorBridgeParent::InitializeStatics();
}
GPUProcessManager::~GPUProcessManager() {
MOZ_COUNT_DTOR(GPUProcessManager);
LayerTreeOwnerTracker::Shutdown();
// The GPU process should have already been shut down.
MOZ_ASSERT(!mProcess && !mGPUChild);
// We should have already removed observers.
MOZ_ASSERT(!mObserver);
}
NS_IMPL_ISUPPORTS(GPUProcessManager::Observer, nsIObserver);
GPUProcessManager::Observer::Observer(GPUProcessManager* aManager)
: mManager(aManager) {}
NS_IMETHODIMP
GPUProcessManager::Observer::Observe(nsISupports* aSubject, const char* aTopic,
const char16_t* aData) {
if (!strcmp(aTopic, NS_XPCOM_SHUTDOWN_OBSERVER_ID)) {
mManager->OnXPCOMShutdown();
} else if (!strcmp(aTopic, "nsPref:changed")) {
mManager->OnPreferenceChange(aData);
} else if (!strcmp(aTopic, "application-foreground")) {
mManager->mAppInForeground = true;
if (!mManager->mProcess && gfxConfig::IsEnabled(Feature::GPU_PROCESS)) {
Unused << mManager->LaunchGPUProcess();
}
} else if (!strcmp(aTopic, "application-background")) {
mManager->mAppInForeground = false;
}
return NS_OK;
}
void GPUProcessManager::OnXPCOMShutdown() {
if (mObserver) {
nsContentUtils::UnregisterShutdownObserver(mObserver);
Preferences::RemoveObserver(mObserver, "");
nsCOMPtr<nsIObserverService> obsServ = services::GetObserverService();
if (obsServ) {
obsServ->RemoveObserver(mObserver, "application-foreground");
obsServ->RemoveObserver(mObserver, "application-background");
}
mObserver = nullptr;
}
CleanShutdown();
}
void GPUProcessManager::OnPreferenceChange(const char16_t* aData) {
// We know prefs are ASCII here.
NS_LossyConvertUTF16toASCII strData(aData);
mozilla::dom::Pref pref(strData, /* isLocked */ false,
/* isSanitized */ false, Nothing(), Nothing());
Preferences::GetPreference(&pref, GeckoProcessType_GPU,
/* remoteType */ ""_ns);
if (!!mGPUChild) {
MOZ_ASSERT(mQueuedPrefs.IsEmpty());
mGPUChild->SendPreferenceUpdate(pref);
} else if (IsGPUProcessLaunching()) {
mQueuedPrefs.AppendElement(pref);
}
}
void GPUProcessManager::ResetProcessStable() {
mTotalProcessAttempts++;
mProcessStable = false;
mProcessAttemptLastTime = TimeStamp::Now();
}
bool GPUProcessManager::IsProcessStable(const TimeStamp& aNow) {
if (mTotalProcessAttempts > 0) {
auto delta = (int32_t)(aNow - mProcessAttemptLastTime).ToMilliseconds();
if (delta < StaticPrefs::layers_gpu_process_stable_min_uptime_ms()) {
return false;
}
}
return mProcessStable;
}
bool GPUProcessManager::LaunchGPUProcess() {
if (mProcess) {
return true;
}
if (AppShutdown::IsInOrBeyond(ShutdownPhase::XPCOMShutdown)) {
return false;
}
// Start listening for pref changes so we can
// forward them to the process once it is running.
if (!mObserver) {
mObserver = new Observer(this);
nsContentUtils::RegisterShutdownObserver(mObserver);
Preferences::AddStrongObserver(mObserver, "");
nsCOMPtr<nsIObserverService> obsServ = services::GetObserverService();
if (obsServ) {
obsServ->AddObserver(mObserver, "application-foreground", false);
obsServ->AddObserver(mObserver, "application-background", false);
}
}
// Start the Vsync I/O thread so can use it as soon as the process launches.
EnsureVsyncIOThread();
// If the process didn't live long enough, reset the stable flag so that we
// don't end up in a restart loop.
auto newTime = TimeStamp::Now();
if (IsProcessStable(newTime)) {
mUnstableProcessAttempts++;
}
mTotalProcessAttempts++;
mProcessAttemptLastTime = newTime;
mProcessStable = false;
std::vector<std::string> extraArgs;
ipc::ProcessChild::AddPlatformBuildID(extraArgs);
// The subprocess is launched asynchronously, so we wait for a callback to
// acquire the IPDL actor.
mProcess = new GPUProcessHost(this);
if (!mProcess->Launch(extraArgs)) {
DisableGPUProcess("Failed to launch GPU process");
}
return true;
}
bool GPUProcessManager::IsGPUProcessLaunching() {
MOZ_ASSERT(NS_IsMainThread());
return !!mProcess && !mGPUChild;
}
void GPUProcessManager::DisableGPUProcess(const char* aMessage) {
MaybeDisableGPUProcess(aMessage, /* aAllowRestart */ false);
}
bool GPUProcessManager::MaybeDisableGPUProcess(const char* aMessage,
bool aAllowRestart) {
if (!gfxConfig::IsEnabled(Feature::GPU_PROCESS)) {
return true;
}
if (!aAllowRestart) {
gfxConfig::SetFailed(Feature::GPU_PROCESS, FeatureStatus::Failed, aMessage);
}
bool wantRestart;
if (mLastError) {
wantRestart =
FallbackFromAcceleration(mLastError.value(), mLastErrorMsg.ref());
mLastError.reset();
mLastErrorMsg.reset();
} else {
wantRestart = gfxPlatform::FallbackFromAcceleration(
FeatureStatus::Unavailable, "GPU Process is disabled",
"FEATURE_FAILURE_GPU_PROCESS_DISABLED"_ns);
}
if (aAllowRestart && wantRestart) {
// The fallback method can make use of the GPU process.
return false;
}
if (aAllowRestart) {
gfxConfig::SetFailed(Feature::GPU_PROCESS, FeatureStatus::Failed, aMessage);
}
gfxCriticalNote << aMessage;
gfxPlatform::DisableGPUProcess();
Telemetry::Accumulate(Telemetry::GPU_PROCESS_CRASH_FALLBACKS,
uint32_t(FallbackType::DISABLED));
DestroyProcess();
ShutdownVsyncIOThread();
// Now the stability state is based upon the in process compositor session.
ResetProcessStable();
// We may have been in the middle of guaranteeing our various services are
// available when one failed. Some callers may fallback to using the same
// process equivalent, and we need to make sure those services are setup
// correctly. We cannot re-enter DisableGPUProcess from this call because we
// know that it is disabled in the config above.
EnsureProtocolsReady();
// If we disable the GPU process during reinitialization after a previous
// crash, then we need to tell the content processes again, because they
// need to rebind to the UI process.
HandleProcessLost();
return true;
}
bool GPUProcessManager::EnsureGPUReady() {
MOZ_ASSERT(NS_IsMainThread());
// Launch the GPU process if it is enabled but hasn't been (re-)launched yet.
if (!mProcess && gfxConfig::IsEnabled(Feature::GPU_PROCESS)) {
if (!LaunchGPUProcess()) {
return false;
}
}
if (mProcess && !mProcess->IsConnected()) {
if (!mProcess->WaitForLaunch()) {
// If this fails, we should have fired OnProcessLaunchComplete and
// removed the process.
MOZ_ASSERT(!mProcess && !mGPUChild);
return false;
}
}
if (mGPUChild) {
if (mGPUChild->EnsureGPUReady()) {
return true;
}
// If the initialization above fails, we likely have a GPU process teardown
// waiting in our message queue (or will soon). We need to ensure we don't
// restart it later because if we fail here, our callers assume they should
// fall back to a combined UI/GPU process. This also ensures our internal
// state is consistent (e.g. process token is reset).
DisableGPUProcess("Failed to initialize GPU process");
}
// This is the first time we are trying to use the in-process compositor.
if (mTotalProcessAttempts == 0) {
ResetProcessStable();
}
return false;
}
void GPUProcessManager::EnsureProtocolsReady() {
EnsureCompositorManagerChild();
EnsureImageBridgeChild();
EnsureVRManager();
}
void GPUProcessManager::EnsureCompositorManagerChild() {
bool gpuReady = EnsureGPUReady();
if (CompositorManagerChild::IsInitialized(mProcessToken)) {
return;
}
if (!gpuReady) {
CompositorManagerChild::InitSameProcess(AllocateNamespace(), mProcessToken);
return;
}
ipc::Endpoint<PCompositorManagerParent> parentPipe;
ipc::Endpoint<PCompositorManagerChild> childPipe;
nsresult rv = PCompositorManager::CreateEndpoints(
mGPUChild->OtherPid(), base::GetCurrentProcId(), &parentPipe, &childPipe);
if (NS_FAILED(rv)) {
DisableGPUProcess("Failed to create PCompositorManager endpoints");
return;
}
mGPUChild->SendInitCompositorManager(std::move(parentPipe));
CompositorManagerChild::Init(std::move(childPipe), AllocateNamespace(),
mProcessToken);
}
void GPUProcessManager::EnsureImageBridgeChild() {
if (ImageBridgeChild::GetSingleton()) {
return;
}
if (!EnsureGPUReady()) {
ImageBridgeChild::InitSameProcess(AllocateNamespace());
return;
}
ipc::Endpoint<PImageBridgeParent> parentPipe;
ipc::Endpoint<PImageBridgeChild> childPipe;
nsresult rv = PImageBridge::CreateEndpoints(
mGPUChild->OtherPid(), base::GetCurrentProcId(), &parentPipe, &childPipe);
if (NS_FAILED(rv)) {
DisableGPUProcess("Failed to create PImageBridge endpoints");
return;
}
mGPUChild->SendInitImageBridge(std::move(parentPipe));
ImageBridgeChild::InitWithGPUProcess(std::move(childPipe),
AllocateNamespace());
}
void GPUProcessManager::EnsureVRManager() {
if (VRManagerChild::IsCreated()) {
return;
}
if (!EnsureGPUReady()) {
VRManagerChild::InitSameProcess();
return;
}
ipc::Endpoint<PVRManagerParent> parentPipe;
ipc::Endpoint<PVRManagerChild> childPipe;
nsresult rv = PVRManager::CreateEndpoints(
mGPUChild->OtherPid(), base::GetCurrentProcId(), &parentPipe, &childPipe);
if (NS_FAILED(rv)) {
DisableGPUProcess("Failed to create PVRManager endpoints");
return;
}
mGPUChild->SendInitVRManager(std::move(parentPipe));
VRManagerChild::InitWithGPUProcess(std::move(childPipe));
}
#if defined(MOZ_WIDGET_ANDROID)
already_AddRefed<UiCompositorControllerChild>
GPUProcessManager::CreateUiCompositorController(nsBaseWidget* aWidget,
const LayersId aId) {
RefPtr<UiCompositorControllerChild> result;
if (!EnsureGPUReady()) {
result = UiCompositorControllerChild::CreateForSameProcess(aId, aWidget);
} else {
ipc::Endpoint<PUiCompositorControllerParent> parentPipe;
ipc::Endpoint<PUiCompositorControllerChild> childPipe;
nsresult rv = PUiCompositorController::CreateEndpoints(
mGPUChild->OtherPid(), base::GetCurrentProcId(), &parentPipe,
&childPipe);
if (NS_FAILED(rv)) {
DisableGPUProcess("Failed to create PUiCompositorController endpoints");
return nullptr;
}
mGPUChild->SendInitUiCompositorController(aId, std::move(parentPipe));
result = UiCompositorControllerChild::CreateForGPUProcess(
mProcessToken, std::move(childPipe), aWidget);
if (result) {
result->SetCompositorSurfaceManager(
mProcess->GetCompositorSurfaceManager());
}
}
return result.forget();
}
#endif // defined(MOZ_WIDGET_ANDROID)
void GPUProcessManager::OnProcessLaunchComplete(GPUProcessHost* aHost) {
MOZ_ASSERT(mProcess && mProcess == aHost);
if (!mProcess->IsConnected()) {
DisableGPUProcess("Failed to connect GPU process");
return;
}
mGPUChild = mProcess->GetActor();
mProcessToken = mProcess->GetProcessToken();
ipc::Endpoint<PVsyncBridgeParent> vsyncParent;
ipc::Endpoint<PVsyncBridgeChild> vsyncChild;
nsresult rv = PVsyncBridge::CreateEndpoints(mGPUChild->OtherPid(),
base::GetCurrentProcId(),
&vsyncParent, &vsyncChild);
if (NS_FAILED(rv)) {
DisableGPUProcess("Failed to create PVsyncBridge endpoints");
return;
}
mVsyncBridge = VsyncBridgeChild::Create(mVsyncIOThread, mProcessToken,
std::move(vsyncChild));
mGPUChild->SendInitVsyncBridge(std::move(vsyncParent));
// Flush any pref updates that happened during launch and weren't
// included in the blobs set up in LaunchGPUProcess.
for (const mozilla::dom::Pref& pref : mQueuedPrefs) {
Unused << NS_WARN_IF(!mGPUChild->SendPreferenceUpdate(pref));
}
mQueuedPrefs.Clear();
CrashReporter::AnnotateCrashReport(
CrashReporter::Annotation::GPUProcessStatus, "Running"_ns);
CrashReporter::AnnotateCrashReport(
CrashReporter::Annotation::GPUProcessLaunchCount,
static_cast<int>(mTotalProcessAttempts));
ReinitializeRendering();
}
void GPUProcessManager::OnProcessDeclaredStable() { mProcessStable = true; }
static bool ShouldLimitDeviceResets(uint32_t count, int32_t deltaMilliseconds) {
// We decide to limit by comparing the amount of resets that have happened
// and time since the last reset to two prefs.
int32_t timeLimit = StaticPrefs::gfx_device_reset_threshold_ms_AtStartup();
int32_t countLimit = StaticPrefs::gfx_device_reset_limit_AtStartup();
bool hasTimeLimit = timeLimit >= 0;
bool hasCountLimit = countLimit >= 0;
bool triggeredTime = deltaMilliseconds < timeLimit;
bool triggeredCount = count > (uint32_t)countLimit;
// If we have both prefs set then it needs to trigger both limits,
// otherwise we only test the pref that is set or none
if (hasTimeLimit && hasCountLimit) {
return triggeredTime && triggeredCount;
} else if (hasTimeLimit) {
return triggeredTime;
} else if (hasCountLimit) {
return triggeredCount;
}
return false;
}
void GPUProcessManager::ResetCompositors() {
// Note: this will recreate devices in addition to recreating compositors.
// This isn't optimal, but this is only used on linux where acceleration
// isn't enabled by default, and this way we don't need a new code path.
SimulateDeviceReset();
}
void GPUProcessManager::SimulateDeviceReset() {
// Make sure we rebuild environment and configuration for accelerated
// features.
gfxPlatform::GetPlatform()->CompositorUpdated();
if (mProcess) {
if (mGPUChild) {
mGPUChild->SendSimulateDeviceReset();
}
} else {
wr::RenderThread::Get()->SimulateDeviceReset();
}
}
bool GPUProcessManager::FallbackFromAcceleration(wr::WebRenderError aError,
const nsCString& aMsg) {
if (aError == wr::WebRenderError::INITIALIZE) {
return gfxPlatform::FallbackFromAcceleration(
gfx::FeatureStatus::Unavailable, "WebRender initialization failed",
aMsg);
} else if (aError == wr::WebRenderError::MAKE_CURRENT) {
return gfxPlatform::FallbackFromAcceleration(
gfx::FeatureStatus::Unavailable,
"Failed to make render context current",
"FEATURE_FAILURE_WEBRENDER_MAKE_CURRENT"_ns);
} else if (aError == wr::WebRenderError::RENDER) {
return gfxPlatform::FallbackFromAcceleration(
gfx::FeatureStatus::Unavailable, "Failed to render WebRender",
"FEATURE_FAILURE_WEBRENDER_RENDER"_ns);
} else if (aError == wr::WebRenderError::NEW_SURFACE) {
// If we cannot create a new Surface even in the final fallback
// configuration then force a crash.
return gfxPlatform::FallbackFromAcceleration(
gfx::FeatureStatus::Unavailable, "Failed to create new surface",
"FEATURE_FAILURE_WEBRENDER_NEW_SURFACE"_ns,
/* aCrashAfterFinalFallback */ true);
} else if (aError == wr::WebRenderError::BEGIN_DRAW) {
return gfxPlatform::FallbackFromAcceleration(
gfx::FeatureStatus::Unavailable, "BeginDraw() failed",
"FEATURE_FAILURE_WEBRENDER_BEGIN_DRAW"_ns);
} else if (aError == wr::WebRenderError::EXCESSIVE_RESETS) {
return gfxPlatform::FallbackFromAcceleration(
gfx::FeatureStatus::Unavailable, "Device resets exceeded threshold",
"FEATURE_FAILURE_WEBRENDER_EXCESSIVE_RESETS"_ns);
} else {
MOZ_ASSERT_UNREACHABLE("Invalid value");
return gfxPlatform::FallbackFromAcceleration(
gfx::FeatureStatus::Unavailable, "Unhandled failure reason",
"FEATURE_FAILURE_WEBRENDER_UNHANDLED"_ns);
}
}
bool GPUProcessManager::DisableWebRenderConfig(wr::WebRenderError aError,
const nsCString& aMsg) {
if (!gfx::gfxVars::UseWebRender()) {
return false;
}
// If we have a stable compositor process, this may just be due to an OOM or
// bad driver state. In that case, we should consider restarting the GPU
// process, or simulating a device reset to teardown the compositors to
// hopefully alleviate the situation.
if (IsProcessStable(TimeStamp::Now())) {
if (mProcess) {
mProcess->KillProcess();
} else {
SimulateDeviceReset();
}
mLastError = Some(aError);
mLastErrorMsg = Some(aMsg);
return false;
}
mLastError.reset();
mLastErrorMsg.reset();
// Disable WebRender
bool wantRestart = FallbackFromAcceleration(aError, aMsg);
gfx::gfxVars::SetUseWebRenderDCompVideoOverlayWin(false);
// If we still have the GPU process, and we fallback to a new configuration
// that prefers to have the GPU process, reset the counter.
if (wantRestart && mProcess) {
mUnstableProcessAttempts = 1;
}
return true;
}
void GPUProcessManager::DisableWebRender(wr::WebRenderError aError,
const nsCString& aMsg) {
if (DisableWebRenderConfig(aError, aMsg)) {
if (mProcess) {
DestroyRemoteCompositorSessions();
} else {
DestroyInProcessCompositorSessions();
}
NotifyListenersOnCompositeDeviceReset();
}
}
void GPUProcessManager::NotifyWebRenderError(wr::WebRenderError aError) {
if (aError == wr::WebRenderError::VIDEO_OVERLAY) {
#ifdef XP_WIN
gfxVars::SetUseWebRenderDCompVideoOverlayWin(false);
#else
MOZ_ASSERT_UNREACHABLE("unexpected to be called");
#endif
return;
}
DisableWebRender(aError, nsCString());
}
/* static */ void GPUProcessManager::RecordDeviceReset(
DeviceResetReason aReason) {
if (aReason != DeviceResetReason::FORCED_RESET) {
Telemetry::Accumulate(Telemetry::DEVICE_RESET_REASON, uint32_t(aReason));
}
CrashReporter::AnnotateCrashReport(
CrashReporter::Annotation::DeviceResetReason, int(aReason));
}
bool GPUProcessManager::OnDeviceReset(bool aTrackThreshold) {
#ifdef XP_WIN
// Disable double buffering when device reset happens.
if (!gfxVars::UseWebRender() && gfxVars::UseDoubleBufferingWithCompositor()) {
gfxVars::SetUseDoubleBufferingWithCompositor(false);
}
#endif
// Ignore resets for thresholding if requested.
if (!aTrackThreshold) {
return false;
}
// Detect whether the device is resetting too quickly or too much
// indicating that we should give up and use software
mDeviceResetCount++;
auto newTime = TimeStamp::Now();
auto delta = (int32_t)(newTime - mDeviceResetLastTime).ToMilliseconds();
mDeviceResetLastTime = newTime;
// Returns true if we should disable acceleration due to the reset.
return ShouldLimitDeviceResets(mDeviceResetCount, delta);
}
void GPUProcessManager::OnInProcessDeviceReset(bool aTrackThreshold) {
if (OnDeviceReset(aTrackThreshold)) {
gfxCriticalNoteOnce << "In-process device reset threshold exceeded";
#ifdef MOZ_WIDGET_GTK
// FIXME(aosmond): Should we disable WebRender on other platforms?
DisableWebRenderConfig(wr::WebRenderError::EXCESSIVE_RESETS, nsCString());
#endif
}
#ifdef XP_WIN
// Ensure device reset handling before re-creating in process sessions.
// Normally nsWindow::OnPaint() already handled it.
gfxWindowsPlatform::GetPlatform()->HandleDeviceReset();
#endif
DestroyInProcessCompositorSessions();
NotifyListenersOnCompositeDeviceReset();
}
void GPUProcessManager::OnRemoteProcessDeviceReset(GPUProcessHost* aHost) {
if (OnDeviceReset(/* aTrackThreshold */ true)) {
DestroyProcess();
DisableGPUProcess("GPU processed experienced too many device resets");
HandleProcessLost();
return;
}
DestroyRemoteCompositorSessions();
NotifyListenersOnCompositeDeviceReset();
}
void GPUProcessManager::NotifyListenersOnCompositeDeviceReset() {
for (const auto& listener : mListeners) {
listener->OnCompositorDeviceReset();
}
}
void GPUProcessManager::OnProcessUnexpectedShutdown(GPUProcessHost* aHost) {
MOZ_ASSERT(mProcess && mProcess == aHost);
if (StaticPrefs::layers_gpu_process_crash_also_crashes_browser()) {
MOZ_CRASH("GPU process crashed and pref is set to crash the browser.");
}
CompositorManagerChild::OnGPUProcessLost(aHost->GetProcessToken());
DestroyProcess(/* aUnexpectedShutdown */ true);
if (mUnstableProcessAttempts >
uint32_t(StaticPrefs::layers_gpu_process_max_restarts())) {
char disableMessage[64];
SprintfLiteral(disableMessage, "GPU process disabled after %d attempts",
mTotalProcessAttempts);
if (!MaybeDisableGPUProcess(disableMessage, /* aAllowRestart */ true)) {
// Fallback wants the GPU process. Reset our counter.
mUnstableProcessAttempts = 0;
HandleProcessLost();
}
} else if (mUnstableProcessAttempts >
uint32_t(StaticPrefs::
layers_gpu_process_max_restarts_with_decoder()) &&
mDecodeVideoOnGpuProcess) {
mDecodeVideoOnGpuProcess = false;
Telemetry::Accumulate(Telemetry::GPU_PROCESS_CRASH_FALLBACKS,
uint32_t(FallbackType::DECODINGDISABLED));
HandleProcessLost();
} else {
Telemetry::Accumulate(Telemetry::GPU_PROCESS_CRASH_FALLBACKS,
uint32_t(FallbackType::NONE));
HandleProcessLost();
}
}
void GPUProcessManager::HandleProcessLost() {
MOZ_ASSERT(NS_IsMainThread());
// The shutdown and restart sequence for the GPU process is as follows:
//
// (1) The GPU process dies. IPDL will enqueue an ActorDestroy message on
// each channel owning a bridge to the GPU process, on the thread owning
// that channel.
//
// (2) The first channel to process its ActorDestroy message will post a
// message to the main thread to call NotifyRemoteActorDestroyed on the
// GPUProcessManager, which calls OnProcessUnexpectedShutdown if it has
// not handled shutdown for this process yet. OnProcessUnexpectedShutdown
// is responsible for tearing down the old process and deciding whether
// or not to disable the GPU process. It then calls this function,
// HandleProcessLost.
//
// (3) We then notify each widget that its session with the compositor is now
// invalid. The widget is responsible for destroying its layer manager
// and CompositorBridgeChild. Note that at this stage, not all actors may
// have received ActorDestroy yet. CompositorBridgeChild may attempt to
// send messages, and if this happens, it will probably report a
// MsgDropped error. This is okay.
//
// (4) At this point, the UI process has a clean slate: no layers should
// exist for the old compositor. We may make a decision on whether or not
// to re-launch the GPU process. Or, on Android if the app is in the
// background we may decide to wait until it comes to the foreground
// before re-launching.
//
// (5) When we do decide to re-launch, or continue without a GPU process, we
// notify each ContentParent of the lost connection. It will request new
// endpoints from the GPUProcessManager and forward them to its
// ContentChild. The parent-side of these endpoints may come from the
// compositor thread of the UI process, or the compositor thread of the
// GPU process. However, no actual compositors should exist yet.
//
// (6) Each ContentChild will receive new endpoints. It will destroy its
// Compositor/ImageBridgeChild singletons and recreate them, as well
// as invalidate all retained layers.
//
// (7) In addition, each ContentChild will ask each of its BrowserChildren
// to re-request association with the compositor for the window
// owning the tab. The sequence of calls looks like:
// (a) [CONTENT] ContentChild::RecvReinitRendering
// (b) [CONTENT] BrowserChild::ReinitRendering
// (c) [CONTENT] BrowserChild::SendEnsureLayersConnected
// (d) [UI] BrowserParent::RecvEnsureLayersConnected
// (e) [UI] RemoteLayerTreeOwner::EnsureLayersConnected
// (f) [UI] CompositorBridgeChild::SendNotifyChildRecreated
//
// Note that at step (e), RemoteLayerTreeOwner will call
// GetWindowRenderer on the nsIWidget owning the tab. This step ensures
// that a compositor exists for the window. If we decided to launch a new
// GPU Process, at this point we block until the process has launched and
// we're able to create a new window compositor. Otherwise, if
// compositing is now in-process, this will simply create a new
// CompositorBridgeParent in the UI process. If there are multiple tabs
// in the same window, additional tabs will simply return the already-
// established compositor.
//
// Finally, this step serves one other crucial function: tabs must be
// associated with a window compositor or else they can't forward
// layer transactions. So this step both ensures that a compositor
// exists, and that the tab can forward layers.
//
// (8) Last, if the window had no remote tabs, step (7) will not have
// applied, and the window will not have a new compositor just yet. The
// next refresh tick and paint will ensure that one exists, again via
// nsIWidget::GetWindowRenderer. On Android, we called
// nsIWidgetListener::RequestRepaint back in step (3) to ensure this
// tick occurs, but on other platforms this is not necessary.
DestroyRemoteCompositorSessions();
#ifdef MOZ_WIDGET_ANDROID
java::SurfaceControlManager::GetInstance()->OnGpuProcessLoss();
#endif
// Re-launch the process if immediately if the GPU process is still enabled.
// Except on Android if the app is in the background, where we want to wait
// until the app is in the foreground again.
if (gfxConfig::IsEnabled(Feature::GPU_PROCESS)) {
if (mAppInForeground) {
Unused << LaunchGPUProcess();
}
} else {
// If the GPU process is disabled we can reinitialize rendering immediately.
// This will be handled in OnProcessLaunchComplete() if the GPU process is
// enabled.
ReinitializeRendering();
}
}
void GPUProcessManager::ReinitializeRendering() {
// Notify content. This will ensure that each content process re-establishes
// a connection to the compositor thread (whether it's in-process or in a
// newly launched GPU process).
for (const auto& listener : mListeners) {
listener->OnCompositorUnexpectedShutdown();
}
// Notify any observers that the compositor has been reinitialized,
// eg the ZoomConstraintsClients for parent process documents.
nsCOMPtr<nsIObserverService> observerService = services::GetObserverService();
if (observerService) {
observerService->NotifyObservers(nullptr, "compositor-reinitialized",
nullptr);
}
}
void GPUProcessManager::DestroyRemoteCompositorSessions() {
// Build a list of sessions to notify, since notification might delete
// entries from the list.
nsTArray<RefPtr<RemoteCompositorSession>> sessions;
for (auto& session : mRemoteSessions) {
sessions.AppendElement(session);
}
// Notify each widget that we have lost the GPU process. This will ensure
// that each widget destroys its layer manager and CompositorBridgeChild.
for (const auto& session : sessions) {
session->NotifySessionLost();
}
}
void GPUProcessManager::DestroyInProcessCompositorSessions() {
// Build a list of sessions to notify, since notification might delete
// entries from the list.
nsTArray<RefPtr<InProcessCompositorSession>> sessions;
for (auto& session : mInProcessSessions) {
sessions.AppendElement(session);
}
// Notify each widget that we have lost the GPU process. This will ensure
// that each widget destroys its layer manager and CompositorBridgeChild.
for (const auto& session : sessions) {
session->NotifySessionLost();
}
// Ensure our stablility state is reset so that we don't necessarily crash
// right away on some WebRender errors.
CompositorBridgeParent::ResetStable();
ResetProcessStable();
}
void GPUProcessManager::NotifyRemoteActorDestroyed(
const uint64_t& aProcessToken) {
if (!NS_IsMainThread()) {
RefPtr<Runnable> task = mTaskFactory.NewRunnableMethod(
&GPUProcessManager::NotifyRemoteActorDestroyed, aProcessToken);
NS_DispatchToMainThread(task.forget());
return;
}
if (mProcessToken != aProcessToken) {
// This token is for an older process; we can safely ignore it.
return;
}
// One of the bridged top-level actors for the GPU process has been
// prematurely terminated, and we're receiving a notification. This
// can happen if the ActorDestroy for a bridged protocol fires
// before the ActorDestroy for PGPUChild.
OnProcessUnexpectedShutdown(mProcess);
}
void GPUProcessManager::CleanShutdown() {
DestroyProcess();
mVsyncIOThread = nullptr;
}
void GPUProcessManager::KillProcess() {
if (!mProcess) {
return;
}
mProcess->KillProcess();
}
void GPUProcessManager::CrashProcess() {
if (!mProcess) {
return;
}
mProcess->CrashProcess();
}
void GPUProcessManager::DestroyProcess(bool aUnexpectedShutdown) {
if (!mProcess) {
return;
}
mProcess->Shutdown(aUnexpectedShutdown);
mProcessToken = 0;
mProcess = nullptr;
mGPUChild = nullptr;
mQueuedPrefs.Clear();
if (mVsyncBridge) {
mVsyncBridge->Close();
mVsyncBridge = nullptr;
}
CrashReporter::AnnotateCrashReport(
CrashReporter::Annotation::GPUProcessStatus, "Destroyed"_ns);
}
already_AddRefed<CompositorSession> GPUProcessManager::CreateTopLevelCompositor(
nsBaseWidget* aWidget, WebRenderLayerManager* aLayerManager,
CSSToLayoutDeviceScale aScale, const CompositorOptions& aOptions,
bool aUseExternalSurfaceSize, const gfx::IntSize& aSurfaceSize,
uint64_t aInnerWindowId, bool* aRetryOut) {
MOZ_ASSERT(aRetryOut);
LayersId layerTreeId = AllocateLayerTreeId();
EnsureProtocolsReady();
RefPtr<CompositorSession> session;
if (EnsureGPUReady()) {
session = CreateRemoteSession(aWidget, aLayerManager, layerTreeId, aScale,
aOptions, aUseExternalSurfaceSize,
aSurfaceSize, aInnerWindowId);
if (!session) {
// We couldn't create a remote compositor, so abort the process.
DisableGPUProcess("Failed to create remote compositor");
*aRetryOut = true;
return nullptr;
}
} else {
session = InProcessCompositorSession::Create(
aWidget, aLayerManager, layerTreeId, aScale, aOptions,
aUseExternalSurfaceSize, aSurfaceSize, AllocateNamespace(),
aInnerWindowId);
}
#if defined(MOZ_WIDGET_ANDROID)
if (session) {
// Nothing to do if controller gets a nullptr
RefPtr<UiCompositorControllerChild> controller =
CreateUiCompositorController(aWidget, session->RootLayerTreeId());
session->SetUiCompositorControllerChild(controller);
}
#endif // defined(MOZ_WIDGET_ANDROID)
*aRetryOut = false;
return session.forget();
}
RefPtr<CompositorSession> GPUProcessManager::CreateRemoteSession(
nsBaseWidget* aWidget, WebRenderLayerManager* aLayerManager,
const LayersId& aRootLayerTreeId, CSSToLayoutDeviceScale aScale,
const CompositorOptions& aOptions, bool aUseExternalSurfaceSize,
const gfx::IntSize& aSurfaceSize, uint64_t aInnerWindowId) {
#ifdef MOZ_WIDGET_SUPPORTS_OOP_COMPOSITING
widget::CompositorWidgetInitData initData;
aWidget->GetCompositorWidgetInitData(&initData);
RefPtr<CompositorBridgeChild> child =
CompositorManagerChild::CreateWidgetCompositorBridge(
mProcessToken, aLayerManager, AllocateNamespace(), aScale, aOptions,
aUseExternalSurfaceSize, aSurfaceSize, aInnerWindowId);
if (!child) {
gfxCriticalNote << "Failed to create CompositorBridgeChild";
return nullptr;
}
RefPtr<CompositorVsyncDispatcher> dispatcher =
aWidget->GetCompositorVsyncDispatcher();
RefPtr<widget::CompositorWidgetVsyncObserver> observer =
new widget::CompositorWidgetVsyncObserver(mVsyncBridge, aRootLayerTreeId);
widget::CompositorWidgetChild* widget =
new widget::CompositorWidgetChild(dispatcher, observer, initData);
if (!child->SendPCompositorWidgetConstructor(widget, initData)) {
return nullptr;
}
if (!widget->Initialize()) {
return nullptr;
}
if (!child->SendInitialize(aRootLayerTreeId)) {
return nullptr;
}
RefPtr<APZCTreeManagerChild> apz = nullptr;
if (aOptions.UseAPZ()) {
PAPZCTreeManagerChild* papz =
child->SendPAPZCTreeManagerConstructor(LayersId{0});
if (!papz) {
return nullptr;
}
apz = static_cast<APZCTreeManagerChild*>(papz);
ipc::Endpoint<PAPZInputBridgeParent> parentPipe;
ipc::Endpoint<PAPZInputBridgeChild> childPipe;
nsresult rv = PAPZInputBridge::CreateEndpoints(mGPUChild->OtherPid(),
base::GetCurrentProcId(),
&parentPipe, &childPipe);
if (NS_FAILED(rv)) {
return nullptr;
}
mGPUChild->SendInitAPZInputBridge(aRootLayerTreeId, std::move(parentPipe));
RefPtr<APZInputBridgeChild> inputBridge =
APZInputBridgeChild::Create(mProcessToken, std::move(childPipe));
if (!inputBridge) {
return nullptr;
}
apz->SetInputBridge(inputBridge);
}
return new RemoteCompositorSession(aWidget, child, widget, apz,
aRootLayerTreeId);
#else
gfxCriticalNote << "Platform does not support out-of-process compositing";
return nullptr;
#endif
}
bool GPUProcessManager::CreateContentBridges(
base::ProcessId aOtherProcess,
ipc::Endpoint<PCompositorManagerChild>* aOutCompositor,
ipc::Endpoint<PImageBridgeChild>* aOutImageBridge,
ipc::Endpoint<PVRManagerChild>* aOutVRBridge,
ipc::Endpoint<PRemoteDecoderManagerChild>* aOutVideoManager,
nsTArray<uint32_t>* aNamespaces) {
if (!CreateContentCompositorManager(aOtherProcess, aOutCompositor) ||
!CreateContentImageBridge(aOtherProcess, aOutImageBridge) ||
!CreateContentVRManager(aOtherProcess, aOutVRBridge)) {
return false;
}
// VideoDeocderManager is only supported in the GPU process, so we allow this
// to be fallible.
CreateContentRemoteDecoderManager(aOtherProcess, aOutVideoManager);
// Allocates 3 namespaces(for CompositorManagerChild, CompositorBridgeChild
// and ImageBridgeChild)
aNamespaces->AppendElement(AllocateNamespace());
aNamespaces->AppendElement(AllocateNamespace());
aNamespaces->AppendElement(AllocateNamespace());
return true;
}
bool GPUProcessManager::CreateContentCompositorManager(
base::ProcessId aOtherProcess,
ipc::Endpoint<PCompositorManagerChild>* aOutEndpoint) {
ipc::Endpoint<PCompositorManagerParent> parentPipe;
ipc::Endpoint<PCompositorManagerChild> childPipe;
base::ProcessId parentPid =
EnsureGPUReady() ? mGPUChild->OtherPid() : base::GetCurrentProcId();
nsresult rv = PCompositorManager::CreateEndpoints(parentPid, aOtherProcess,
&parentPipe, &childPipe);
if (NS_FAILED(rv)) {
gfxCriticalNote << "Could not create content compositor manager: "
<< hexa(int(rv));
return false;
}
if (mGPUChild) {
mGPUChild->SendNewContentCompositorManager(std::move(parentPipe));
} else if (!CompositorManagerParent::Create(std::move(parentPipe),
/* aIsRoot */ false)) {
return false;
}
*aOutEndpoint = std::move(childPipe);
return true;
}
bool GPUProcessManager::CreateContentImageBridge(
base::ProcessId aOtherProcess,
ipc::Endpoint<PImageBridgeChild>* aOutEndpoint) {
EnsureImageBridgeChild();
base::ProcessId parentPid =
EnsureGPUReady() ? mGPUChild->OtherPid() : base::GetCurrentProcId();
ipc::Endpoint<PImageBridgeParent> parentPipe;
ipc::Endpoint<PImageBridgeChild> childPipe;
nsresult rv = PImageBridge::CreateEndpoints(parentPid, aOtherProcess,
&parentPipe, &childPipe);
if (NS_FAILED(rv)) {
gfxCriticalNote << "Could not create content compositor bridge: "
<< hexa(int(rv));
return false;
}
if (mGPUChild) {
mGPUChild->SendNewContentImageBridge(std::move(parentPipe));
} else {
if (!ImageBridgeParent::CreateForContent(std::move(parentPipe))) {
return false;
}
}
*aOutEndpoint = std::move(childPipe);
return true;
}
base::ProcessId GPUProcessManager::GPUProcessPid() {
base::ProcessId gpuPid =
mGPUChild ? mGPUChild->OtherPid() : base::kInvalidProcessId;
return gpuPid;
}
bool GPUProcessManager::CreateContentVRManager(
base::ProcessId aOtherProcess,
ipc::Endpoint<PVRManagerChild>* aOutEndpoint) {
EnsureVRManager();
base::ProcessId parentPid =
EnsureGPUReady() ? mGPUChild->OtherPid() : base::GetCurrentProcId();
ipc::Endpoint<PVRManagerParent> parentPipe;
ipc::Endpoint<PVRManagerChild> childPipe;
nsresult rv = PVRManager::CreateEndpoints(parentPid, aOtherProcess,
&parentPipe, &childPipe);
if (NS_FAILED(rv)) {
gfxCriticalNote << "Could not create content compositor bridge: "
<< hexa(int(rv));
return false;
}
if (mGPUChild) {
mGPUChild->SendNewContentVRManager(std::move(parentPipe));
} else {
if (!VRManagerParent::CreateForContent(std::move(parentPipe))) {
return false;
}
}
*aOutEndpoint = std::move(childPipe);
return true;
}
void GPUProcessManager::CreateContentRemoteDecoderManager(
base::ProcessId aOtherProcess,
ipc::Endpoint<PRemoteDecoderManagerChild>* aOutEndpoint) {
if (!EnsureGPUReady() || !StaticPrefs::media_gpu_process_decoder() ||
!mDecodeVideoOnGpuProcess) {
return;
}
ipc::Endpoint<PRemoteDecoderManagerParent> parentPipe;
ipc::Endpoint<PRemoteDecoderManagerChild> childPipe;
nsresult rv = PRemoteDecoderManager::CreateEndpoints(
mGPUChild->OtherPid(), aOtherProcess, &parentPipe, &childPipe);
if (NS_FAILED(rv)) {
gfxCriticalNote << "Could not create content video decoder: "
<< hexa(int(rv));
return;
}
mGPUChild->SendNewContentRemoteDecoderManager(std::move(parentPipe));
*aOutEndpoint = std::move(childPipe);
}
void GPUProcessManager::InitVideoBridge(
ipc::Endpoint<PVideoBridgeParent>&& aVideoBridge) {
if (EnsureGPUReady()) {
mGPUChild->SendInitVideoBridge(std::move(aVideoBridge));
}
}
void GPUProcessManager::MapLayerTreeId(LayersId aLayersId,
base::ProcessId aOwningId) {
if (EnsureGPUReady()) {
mGPUChild->SendAddLayerTreeIdMapping(
LayerTreeIdMapping(aLayersId, aOwningId));
}
// Must do this *after* the call to EnsureGPUReady, so that if the
// process is launched as a result then it is initialized without this
// LayersId, meaning it can be successfully mapped.
LayerTreeOwnerTracker::Get()->Map(aLayersId, aOwningId);
}
void GPUProcessManager::UnmapLayerTreeId(LayersId aLayersId,
base::ProcessId aOwningId) {
if (EnsureGPUReady()) {
mGPUChild->SendRemoveLayerTreeIdMapping(
LayerTreeIdMapping(aLayersId, aOwningId));
} else {
CompositorBridgeParent::DeallocateLayerTreeId(aLayersId);
}
// Must do this *after* the call to EnsureGPUReady, so that if the
// process is launched as a result then it is initialized with this
// LayersId, meaning it can be successfully unmapped.
LayerTreeOwnerTracker::Get()->Unmap(aLayersId, aOwningId);
}
bool GPUProcessManager::IsLayerTreeIdMapped(LayersId aLayersId,
base::ProcessId aRequestingId) {
return LayerTreeOwnerTracker::Get()->IsMapped(aLayersId, aRequestingId);
}
LayersId GPUProcessManager::AllocateLayerTreeId() {
// Allocate tree id by using id namespace.
// By it, tree id does not conflict with external image id and
// async image pipeline id.
MOZ_ASSERT(NS_IsMainThread());
++mResourceId;
if (mResourceId == UINT32_MAX) {
// Move to next id namespace.
mIdNamespace = AllocateNamespace();
mResourceId = 1;
}
uint64_t layerTreeId = mIdNamespace;
layerTreeId = (layerTreeId << 32) | mResourceId;
return LayersId{layerTreeId};
}
uint32_t GPUProcessManager::AllocateNamespace() {
MOZ_ASSERT(NS_IsMainThread());
return ++mNextNamespace;
}
bool GPUProcessManager::AllocateAndConnectLayerTreeId(
PCompositorBridgeChild* aCompositorBridge, base::ProcessId aOtherPid,
LayersId* aOutLayersId, CompositorOptions* aOutCompositorOptions) {
LayersId layersId = AllocateLayerTreeId();
*aOutLayersId = layersId;
if (!mGPUChild || !aCompositorBridge) {
// If we're not remoting to another process, or there is no compositor,
// then we'll send at most one message. In this case we can just keep
// the old behavior of making sure the mapping occurs, and maybe sending
// a creation notification.
MapLayerTreeId(layersId, aOtherPid);
if (!aCompositorBridge) {
return false;
}
return aCompositorBridge->SendNotifyChildCreated(layersId,
aOutCompositorOptions);
}
// Use the combined message path.
LayerTreeOwnerTracker::Get()->Map(layersId, aOtherPid);
return aCompositorBridge->SendMapAndNotifyChildCreated(layersId, aOtherPid,
aOutCompositorOptions);
}
void GPUProcessManager::EnsureVsyncIOThread() {
if (mVsyncIOThread) {
return;
}
mVsyncIOThread = new VsyncIOThreadHolder();
MOZ_RELEASE_ASSERT(mVsyncIOThread->Start());
}
void GPUProcessManager::ShutdownVsyncIOThread() { mVsyncIOThread = nullptr; }
void GPUProcessManager::RegisterRemoteProcessSession(
RemoteCompositorSession* aSession) {
mRemoteSessions.AppendElement(aSession);
}
void GPUProcessManager::UnregisterRemoteProcessSession(
RemoteCompositorSession* aSession) {
mRemoteSessions.RemoveElement(aSession);
}
void GPUProcessManager::RegisterInProcessSession(
InProcessCompositorSession* aSession) {
mInProcessSessions.AppendElement(aSession);
}
void GPUProcessManager::UnregisterInProcessSession(
InProcessCompositorSession* aSession) {
mInProcessSessions.RemoveElement(aSession);
}
void GPUProcessManager::AddListener(GPUProcessListener* aListener) {
mListeners.AppendElement(aListener);
}
void GPUProcessManager::RemoveListener(GPUProcessListener* aListener) {
mListeners.RemoveElement(aListener);
}
bool GPUProcessManager::NotifyGpuObservers(const char* aTopic) {
if (!EnsureGPUReady()) {
return false;
}
nsCString topic(aTopic);
mGPUChild->SendNotifyGpuObservers(topic);
return true;
}
class GPUMemoryReporter : public MemoryReportingProcess {
public:
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(GPUMemoryReporter, override)
bool IsAlive() const override {
if (GPUProcessManager* gpm = GPUProcessManager::Get()) {
return !!gpm->GetGPUChild();
}
return false;
}
bool SendRequestMemoryReport(
const uint32_t& aGeneration, const bool& aAnonymize,
const bool& aMinimizeMemoryUsage,
const Maybe<ipc::FileDescriptor>& aDMDFile) override {
GPUChild* child = GetChild();
if (!child) {
return false;
}
return child->SendRequestMemoryReport(aGeneration, aAnonymize,
aMinimizeMemoryUsage, aDMDFile);
}
int32_t Pid() const override {
if (GPUChild* child = GetChild()) {
return (int32_t)child->OtherPid();
}
return 0;
}
private:
GPUChild* GetChild() const {
if (GPUProcessManager* gpm = GPUProcessManager::Get()) {
if (GPUChild* child = gpm->GetGPUChild()) {
return child;
}
}
return nullptr;
}
protected:
~GPUMemoryReporter() = default;
};
RefPtr<MemoryReportingProcess> GPUProcessManager::GetProcessMemoryReporter() {
// Ensure mProcess is non-null before calling EnsureGPUReady, to avoid
// launching the process if it has not already been launched.
if (!mProcess || !EnsureGPUReady()) {
return nullptr;
}
return new GPUMemoryReporter();
}
RefPtr<PGPUChild::TestTriggerMetricsPromise>
GPUProcessManager::TestTriggerMetrics() {
if (!NS_WARN_IF(!mGPUChild)) {
return mGPUChild->SendTestTriggerMetrics();
}
return PGPUChild::TestTriggerMetricsPromise::CreateAndReject(
ipc::ResponseRejectReason::SendError, __func__);
}
} // namespace gfx
} // namespace mozilla
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