gecko-dev/gfx/layers/ipc/CompositorParent.cpp

1847 lines
57 KiB
C++

/* -*- 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/CompositorParent.h"
#include <stdio.h> // for fprintf, stdout
#include <stdint.h> // for uint64_t
#include <map> // for _Rb_tree_iterator, etc
#include <utility> // for pair
#include "LayerTransactionParent.h" // for LayerTransactionParent
#include "RenderTrace.h" // for RenderTraceLayers
#include "base/message_loop.h" // for MessageLoop
#include "base/process.h" // for ProcessHandle
#include "base/process_util.h" // for OpenProcessHandle
#include "base/task.h" // for CancelableTask, etc
#include "base/thread.h" // for Thread
#include "base/tracked.h" // for FROM_HERE
#include "gfxContext.h" // for gfxContext
#include "gfxPlatform.h" // for gfxPlatform
#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/gfx/2D.h" // for DrawTarget
#include "mozilla/gfx/Point.h" // for IntSize
#include "mozilla/ipc/Transport.h" // for Transport
#include "mozilla/layers/APZCTreeManager.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/CompositorTypes.h"
#include "mozilla/layers/LayerManagerComposite.h"
#include "mozilla/layers/LayersTypes.h"
#include "mozilla/layers/PLayerTransactionParent.h"
#include "mozilla/layers/ShadowLayersManager.h" // for ShadowLayersManager
#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_ABORT_IF_FALSE, etc
#include "nsISupportsImpl.h" // for MOZ_COUNT_CTOR, etc
#include "nsIWidget.h" // for nsIWidget
#include "nsRect.h" // for nsIntRect
#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"
#ifdef MOZ_ENABLE_PROFILER_SPS
#include "ProfilerMarkers.h"
#endif
#include "mozilla/VsyncDispatcher.h"
#ifdef MOZ_WIDGET_GONK
#include "GeckoTouchDispatcher.h"
#endif
namespace mozilla {
namespace layers {
using namespace base;
using namespace mozilla::ipc;
using namespace mozilla::gfx;
using namespace std;
CompositorParent::LayerTreeState::LayerTreeState()
: mParent(nullptr)
, mLayerManager(nullptr)
, mCrossProcessParent(nullptr)
, mLayerTree(nullptr)
{
}
typedef map<uint64_t, CompositorParent::LayerTreeState> LayerTreeMap;
static LayerTreeMap sIndirectLayerTrees;
static StaticAutoPtr<mozilla::Monitor> sIndirectLayerTreesLock;
static void EnsureLayerTreeMapReady()
{
MOZ_ASSERT(NS_IsMainThread());
if (!sIndirectLayerTreesLock) {
sIndirectLayerTreesLock = new Monitor("IndirectLayerTree");
mozilla::ClearOnShutdown(&sIndirectLayerTreesLock);
}
}
/**
* 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<uint64_t,CompositorParent*> CompositorMap;
static CompositorMap* sCompositorMap;
static void CreateCompositorMap()
{
MOZ_ASSERT(!sCompositorMap);
sCompositorMap = new CompositorMap;
}
static void DestroyCompositorMap()
{
MOZ_ASSERT(sCompositorMap);
MOZ_ASSERT(sCompositorMap->empty());
delete sCompositorMap;
sCompositorMap = nullptr;
}
// See ImageBridgeChild.cpp
void ReleaseImageBridgeParentSingleton();
CompositorThreadHolder::CompositorThreadHolder()
: mCompositorThread(CreateCompositorThread())
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_COUNT_CTOR(CompositorThreadHolder);
}
CompositorThreadHolder::~CompositorThreadHolder()
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_COUNT_DTOR(CompositorThreadHolder);
DestroyCompositorThread(mCompositorThread);
}
static StaticRefPtr<CompositorThreadHolder> sCompositorThreadHolder;
static bool sFinishedCompositorShutDown = false;
CompositorThreadHolder* GetCompositorThreadHolder()
{
return sCompositorThreadHolder;
}
/* static */ Thread*
CompositorThreadHolder::CreateCompositorThread()
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(!sCompositorThreadHolder, "The compositor thread has already been started!");
Thread* compositorThread = new Thread("Compositor");
Thread::Options options;
/* Timeout values are powers-of-two to enable us get better data.
128ms is chosen for transient hangs because 8Hz should be the minimally
acceptable goal for Compositor responsiveness (normal goal is 60Hz). */
options.transient_hang_timeout = 128; // milliseconds
/* 2048ms is chosen for permanent hangs because it's longer than most
* Compositor hangs seen in the wild, but is short enough to not miss getting
* native hang stacks. */
options.permanent_hang_timeout = 2048; // milliseconds
#if defined(_WIN32)
/* With d3d9 the compositor thread creates native ui, see DeviceManagerD3D9. As
* such the thread is a gui thread, and must process a windows message queue or
* risk deadlocks. Chromium message loop TYPE_UI does exactly what we need. */
options.message_loop_type = MessageLoop::TYPE_UI;
#endif
if (!compositorThread->StartWithOptions(options)) {
delete compositorThread;
return nullptr;
}
EnsureLayerTreeMapReady();
CreateCompositorMap();
return compositorThread;
}
/* static */ void
CompositorThreadHolder::DestroyCompositorThread(Thread* aCompositorThread)
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(!sCompositorThreadHolder, "We shouldn't be destroying the compositor thread yet.");
DestroyCompositorMap();
delete aCompositorThread;
sFinishedCompositorShutDown = true;
}
static Thread* CompositorThread() {
return sCompositorThreadHolder ? sCompositorThreadHolder->GetCompositorThread() : nullptr;
}
static void SetThreadPriority()
{
hal::SetCurrentThreadPriority(hal::THREAD_PRIORITY_COMPOSITOR);
}
CompositorVsyncObserver::CompositorVsyncObserver(CompositorParent* aCompositorParent, nsIWidget* aWidget)
: mNeedsComposite(false)
, mIsObservingVsync(false)
, mVsyncNotificationsSkipped(0)
, mCompositorParent(aCompositorParent)
, mCurrentCompositeTaskMonitor("CurrentCompositeTaskMonitor")
, mCurrentCompositeTask(nullptr)
, mSetNeedsCompositeMonitor("SetNeedsCompositeMonitor")
, mSetNeedsCompositeTask(nullptr)
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(aWidget != nullptr);
mCompositorVsyncDispatcher = aWidget->GetCompositorVsyncDispatcher();
#ifdef MOZ_WIDGET_GONK
GeckoTouchDispatcher::SetCompositorVsyncObserver(this);
#endif
}
CompositorVsyncObserver::~CompositorVsyncObserver()
{
MOZ_ASSERT(!mIsObservingVsync);
// The CompositorVsyncDispatcher is cleaned up before this in the nsBaseWidget, which stops vsync listeners
mCompositorParent = nullptr;
mCompositorVsyncDispatcher = nullptr;
}
void
CompositorVsyncObserver::Destroy()
{
MOZ_ASSERT(CompositorParent::IsInCompositorThread());
UnobserveVsync();
CancelCurrentCompositeTask();
CancelCurrentSetNeedsCompositeTask();
}
void
CompositorVsyncObserver::CancelCurrentSetNeedsCompositeTask()
{
MOZ_ASSERT(CompositorParent::IsInCompositorThread());
MonitorAutoLock lock(mSetNeedsCompositeMonitor);
if (mSetNeedsCompositeTask) {
mSetNeedsCompositeTask->Cancel();
mSetNeedsCompositeTask = nullptr;
}
mNeedsComposite = false;
}
/**
* TODO Potential performance heuristics:
* If a composite takes 17 ms, do we composite ASAP or wait until next vsync?
* If a layer transaction comes after vsync, do we composite ASAP or wait until
* next vsync?
* How many skipped vsync events until we stop listening to vsync events?
*/
void
CompositorVsyncObserver::SetNeedsComposite(bool aNeedsComposite)
{
if (!CompositorParent::IsInCompositorThread()) {
MonitorAutoLock lock(mSetNeedsCompositeMonitor);
mSetNeedsCompositeTask = NewRunnableMethod(this,
&CompositorVsyncObserver::SetNeedsComposite,
aNeedsComposite);
MOZ_ASSERT(CompositorParent::CompositorLoop());
CompositorParent::CompositorLoop()->PostTask(FROM_HERE, mSetNeedsCompositeTask);
return;
} else {
MonitorAutoLock lock(mSetNeedsCompositeMonitor);
mSetNeedsCompositeTask = nullptr;
}
mNeedsComposite = aNeedsComposite;
if (!mIsObservingVsync && mNeedsComposite) {
ObserveVsync();
}
}
bool
CompositorVsyncObserver::NotifyVsync(TimeStamp aVsyncTimestamp)
{
// Called from the vsync dispatch thread
MOZ_ASSERT(!CompositorParent::IsInCompositorThread());
MOZ_ASSERT(!NS_IsMainThread());
MonitorAutoLock lock(mCurrentCompositeTaskMonitor);
if (mCurrentCompositeTask == nullptr) {
mCurrentCompositeTask = NewRunnableMethod(this,
&CompositorVsyncObserver::Composite,
aVsyncTimestamp);
MOZ_ASSERT(CompositorParent::CompositorLoop());
CompositorParent::CompositorLoop()->PostTask(FROM_HERE, mCurrentCompositeTask);
}
return true;
}
void
CompositorVsyncObserver::CancelCurrentCompositeTask()
{
MOZ_ASSERT(CompositorParent::IsInCompositorThread() || NS_IsMainThread());
MonitorAutoLock lock(mCurrentCompositeTaskMonitor);
if (mCurrentCompositeTask) {
mCurrentCompositeTask->Cancel();
mCurrentCompositeTask = nullptr;
}
}
void
CompositorVsyncObserver::Composite(TimeStamp aVsyncTimestamp)
{
MOZ_ASSERT(CompositorParent::IsInCompositorThread());
{
MonitorAutoLock lock(mCurrentCompositeTaskMonitor);
mCurrentCompositeTask = nullptr;
}
if (mNeedsComposite && mCompositorParent) {
mNeedsComposite = false;
mCompositorParent->CompositeCallback(aVsyncTimestamp);
mVsyncNotificationsSkipped = 0;
} else if (mVsyncNotificationsSkipped++ > gfxPrefs::CompositorUnobserveCount()) {
UnobserveVsync();
}
DispatchTouchEvents(aVsyncTimestamp);
}
bool
CompositorVsyncObserver::NeedsComposite()
{
MOZ_ASSERT(CompositorParent::IsInCompositorThread());
return mNeedsComposite;
}
void
CompositorVsyncObserver::ObserveVsync()
{
MOZ_ASSERT(CompositorParent::IsInCompositorThread());
mCompositorVsyncDispatcher->SetCompositorVsyncObserver(this);
mIsObservingVsync = true;
}
void
CompositorVsyncObserver::UnobserveVsync()
{
MOZ_ASSERT(CompositorParent::IsInCompositorThread());
mCompositorVsyncDispatcher->SetCompositorVsyncObserver(nullptr);
mIsObservingVsync = false;
}
void
CompositorVsyncObserver::DispatchTouchEvents(TimeStamp aVsyncTimestamp)
{
#ifdef MOZ_WIDGET_GONK
GeckoTouchDispatcher::NotifyVsync(aVsyncTimestamp);
#endif
}
void CompositorParent::StartUp()
{
MOZ_ASSERT(NS_IsMainThread(), "Should be on the main Thread!");
MOZ_ASSERT(!sCompositorThreadHolder, "The compositor thread has already been started!");
sCompositorThreadHolder = new CompositorThreadHolder();
}
void CompositorParent::ShutDown()
{
MOZ_ASSERT(NS_IsMainThread(), "Should be on the main Thread!");
MOZ_ASSERT(sCompositorThreadHolder, "The compositor thread has already been shut down!");
ReleaseImageBridgeParentSingleton();
sCompositorThreadHolder = nullptr;
// No locking is needed around sFinishedCompositorShutDown because it is only
// ever accessed on the main thread.
while (!sFinishedCompositorShutDown) {
NS_ProcessNextEvent(nullptr, true);
}
}
MessageLoop* CompositorParent::CompositorLoop()
{
return CompositorThread() ? CompositorThread()->message_loop() : nullptr;
}
CompositorParent::CompositorParent(nsIWidget* aWidget,
bool aUseExternalSurfaceSize,
int aSurfaceWidth, int aSurfaceHeight)
: mWidget(aWidget)
, mCurrentCompositeTask(nullptr)
, mIsTesting(false)
, mPendingTransaction(0)
, mPaused(false)
, mUseExternalSurfaceSize(aUseExternalSurfaceSize)
, mEGLSurfaceSize(aSurfaceWidth, aSurfaceHeight)
, mPauseCompositionMonitor("PauseCompositionMonitor")
, mResumeCompositionMonitor("ResumeCompositionMonitor")
, mOverrideComposeReadiness(false)
, mForceCompositionTask(nullptr)
, mCompositorThreadHolder(sCompositorThreadHolder)
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(CompositorThread(),
"The compositor thread must be Initialized before instanciating a CompositorParent.");
MOZ_COUNT_CTOR(CompositorParent);
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(FROM_HERE, NewRunnableFunction(&AddCompositor,
this, &mCompositorID));
CompositorLoop()->PostTask(FROM_HERE, NewRunnableFunction(SetThreadPriority));
mRootLayerTreeID = AllocateLayerTreeId();
{ // scope lock
MonitorAutoLock lock(*sIndirectLayerTreesLock);
sIndirectLayerTrees[mRootLayerTreeID].mParent = this;
}
if (gfxPrefs::AsyncPanZoomEnabled()) {
mApzcTreeManager = new APZCTreeManager();
}
if (gfxPrefs::VsyncAlignedCompositor()) {
mCompositorVsyncObserver = new CompositorVsyncObserver(this, aWidget);
}
gfxPlatform::GetPlatform()->ComputeTileSize();
}
bool
CompositorParent::IsInCompositorThread()
{
return CompositorThread() && CompositorThread()->thread_id() == PlatformThread::CurrentId();
}
uint64_t
CompositorParent::RootLayerTreeId()
{
return mRootLayerTreeID;
}
CompositorParent::~CompositorParent()
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_COUNT_DTOR(CompositorParent);
}
void
CompositorParent::Destroy()
{
NS_ABORT_IF_FALSE(ManagedPLayerTransactionParent().Length() == 0,
"CompositorParent destroyed before managed PLayerTransactionParent");
MOZ_ASSERT(mPaused); // Ensure RecvWillStop was called
// Ensure that the layer manager is destructed on the compositor thread.
mLayerManager = nullptr;
if (mCompositor) {
mCompositor->Destroy();
}
mCompositor = nullptr;
mCompositionManager = nullptr;
if (mApzcTreeManager) {
mApzcTreeManager->ClearTree();
mApzcTreeManager = nullptr;
}
{ // scope lock
MonitorAutoLock lock(*sIndirectLayerTreesLock);
sIndirectLayerTrees.erase(mRootLayerTreeID);
}
if (mCompositorVsyncObserver) {
mCompositorVsyncObserver->Destroy();
mCompositorVsyncObserver = nullptr;
}
}
void
CompositorParent::ForceIsFirstPaint()
{
mCompositionManager->ForceIsFirstPaint();
}
bool
CompositorParent::RecvWillStop()
{
mPaused = true;
RemoveCompositor(mCompositorID);
// Ensure that the layer manager is destroyed before CompositorChild.
if (mLayerManager) {
MonitorAutoLock lock(*sIndirectLayerTreesLock);
for (LayerTreeMap::iterator it = sIndirectLayerTrees.begin();
it != sIndirectLayerTrees.end(); it++)
{
LayerTreeState* lts = &it->second;
if (lts->mParent == this) {
mLayerManager->ClearCachedResources(lts->mRoot);
lts->mLayerManager = nullptr;
lts->mParent = nullptr;
}
}
mLayerManager->Destroy();
mLayerManager = nullptr;
mCompositionManager = nullptr;
}
return true;
}
void CompositorParent::DeferredDestroy()
{
MOZ_ASSERT(!NS_IsMainThread());
mCompositorThreadHolder = nullptr;
Release();
}
bool
CompositorParent::RecvStop()
{
Destroy();
// 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.
this->AddRef(); // Corresponds to DeferredDestroy's Release
MessageLoop::current()->PostTask(FROM_HERE,
NewRunnableMethod(this,&CompositorParent::DeferredDestroy));
return true;
}
bool
CompositorParent::RecvPause()
{
PauseComposition();
return true;
}
bool
CompositorParent::RecvResume()
{
ResumeComposition();
return true;
}
bool
CompositorParent::RecvMakeSnapshot(const SurfaceDescriptor& aInSnapshot,
const nsIntRect& aRect)
{
RefPtr<DrawTarget> target = GetDrawTargetForDescriptor(aInSnapshot, gfx::BackendType::CAIRO);
ForceComposeToTarget(target, &aRect);
return true;
}
bool
CompositorParent::RecvFlushRendering()
{
if (gfxPrefs::VsyncAlignedCompositor() && mCompositorVsyncObserver->NeedsComposite()) {
mCompositorVsyncObserver->SetNeedsComposite(false);
CancelCurrentCompositeTask();
ForceComposeToTarget(nullptr);
} else if (mCurrentCompositeTask) {
// If we're waiting to do a composite, then cancel it
// and do it immediately instead.
CancelCurrentCompositeTask();
ForceComposeToTarget(nullptr);
}
return true;
}
bool
CompositorParent::RecvGetTileSize(int32_t* aWidth, int32_t* aHeight)
{
*aWidth = gfxPlatform::GetPlatform()->GetTileWidth();
*aHeight = gfxPlatform::GetPlatform()->GetTileHeight();
return true;
}
bool
CompositorParent::RecvNotifyRegionInvalidated(const nsIntRegion& aRegion)
{
if (mLayerManager) {
mLayerManager->AddInvalidRegion(aRegion);
}
return true;
}
bool
CompositorParent::RecvStartFrameTimeRecording(const int32_t& aBufferSize, uint32_t* aOutStartIndex)
{
if (mLayerManager) {
*aOutStartIndex = mLayerManager->StartFrameTimeRecording(aBufferSize);
} else {
*aOutStartIndex = 0;
}
return true;
}
bool
CompositorParent::RecvStopFrameTimeRecording(const uint32_t& aStartIndex,
InfallibleTArray<float>* intervals)
{
if (mLayerManager) {
mLayerManager->StopFrameTimeRecording(aStartIndex, *intervals);
}
return true;
}
void
CompositorParent::ActorDestroy(ActorDestroyReason why)
{
CancelCurrentCompositeTask();
if (mForceCompositionTask) {
mForceCompositionTask->Cancel();
mForceCompositionTask = nullptr;
}
mPaused = true;
RemoveCompositor(mCompositorID);
if (mLayerManager) {
mLayerManager->Destroy();
mLayerManager = nullptr;
{ // scope lock
MonitorAutoLock lock(*sIndirectLayerTreesLock);
sIndirectLayerTrees[mRootLayerTreeID].mLayerManager = nullptr;
}
mCompositionManager = nullptr;
mCompositor = nullptr;
}
}
void
CompositorParent::ScheduleRenderOnCompositorThread()
{
CancelableTask *renderTask = NewRunnableMethod(this, &CompositorParent::ScheduleComposition);
MOZ_ASSERT(CompositorLoop());
CompositorLoop()->PostTask(FROM_HERE, renderTask);
}
void
CompositorParent::PauseComposition()
{
MOZ_ASSERT(IsInCompositorThread(),
"PauseComposition() can only be called on the compositor thread");
MonitorAutoLock lock(mPauseCompositionMonitor);
if (!mPaused) {
mPaused = true;
mCompositor->Pause();
DidComposite();
}
// if anyone's waiting to make sure that composition really got paused, tell them
lock.NotifyAll();
}
void
CompositorParent::ResumeComposition()
{
MOZ_ASSERT(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, "CompositorParent", "Unable to renew compositor surface; remaining in paused state");
#endif
lock.NotifyAll();
return;
}
mPaused = false;
mLastCompose = TimeStamp::Now();
CompositeToTarget(nullptr);
// if anyone's waiting to make sure that composition really got resumed, tell them
lock.NotifyAll();
}
void
CompositorParent::ForceComposition()
{
// Cancel the orientation changed state to force composition
mForceCompositionTask = nullptr;
ScheduleRenderOnCompositorThread();
}
void
CompositorParent::CancelCurrentCompositeTask()
{
if (gfxPrefs::VsyncAlignedCompositor()) {
mCompositorVsyncObserver->CancelCurrentCompositeTask();
} else if (mCurrentCompositeTask) {
mCurrentCompositeTask->Cancel();
mCurrentCompositeTask = nullptr;
}
}
void
CompositorParent::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
CompositorParent::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
CompositorParent::SchedulePauseOnCompositorThread()
{
MonitorAutoLock lock(mPauseCompositionMonitor);
CancelableTask *pauseTask = NewRunnableMethod(this,
&CompositorParent::PauseComposition);
MOZ_ASSERT(CompositorLoop());
CompositorLoop()->PostTask(FROM_HERE, pauseTask);
// Wait until the pause has actually been processed by the compositor thread
lock.Wait();
}
bool
CompositorParent::ScheduleResumeOnCompositorThread(int width, int height)
{
MonitorAutoLock lock(mResumeCompositionMonitor);
CancelableTask *resumeTask =
NewRunnableMethod(this, &CompositorParent::ResumeCompositionAndResize, width, height);
MOZ_ASSERT(CompositorLoop());
CompositorLoop()->PostTask(FROM_HERE, resumeTask);
// Wait until the resume has actually been processed by the compositor thread
lock.Wait();
return !mPaused;
}
void
CompositorParent::ScheduleTask(CancelableTask* task, int time)
{
if (time == 0) {
MessageLoop::current()->PostTask(FROM_HERE, task);
} else {
MessageLoop::current()->PostDelayedTask(FROM_HERE, task, time);
}
}
void
CompositorParent::NotifyShadowTreeTransaction(uint64_t aId, bool aIsFirstPaint,
bool aScheduleComposite, uint32_t aPaintSequenceNumber,
bool aIsRepeatTransaction)
{
if (mApzcTreeManager &&
!aIsRepeatTransaction &&
mLayerManager &&
mLayerManager->GetRoot()) {
AutoResolveRefLayers resolve(mCompositionManager);
mApzcTreeManager->UpdateHitTestingTree(this, mLayerManager->GetRoot(),
aIsFirstPaint, aId, aPaintSequenceNumber);
mLayerManager->NotifyShadowTreeTransaction();
}
if (aScheduleComposite) {
ScheduleComposition();
}
}
// Used when layout.frame_rate is -1. Needs to be kept in sync with
// DEFAULT_FRAME_RATE in nsRefreshDriver.cpp.
static const int32_t kDefaultFrameRate = 60;
static int32_t
CalculateCompositionFrameRate()
{
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 kDefaultFrameRate;
}
return layoutFrameRatePref;
}
return compositionFrameRatePref;
}
void
CompositorParent::ScheduleSoftwareTimerComposition()
{
MOZ_ASSERT(!gfxPrefs::VsyncAlignedCompositor());
if (mCurrentCompositeTask) {
return;
}
bool initialComposition = mLastCompose.IsNull();
TimeDuration delta;
if (!initialComposition)
delta = TimeStamp::Now() - mLastCompose;
int32_t rate = CalculateCompositionFrameRate();
// If rate == 0 (ASAP mode), minFrameDelta must be 0 so there's no delay.
TimeDuration minFrameDelta = TimeDuration::FromMilliseconds(
rate == 0 ? 0.0 : std::max(0.0, 1000.0 / rate));
mCurrentCompositeTask = NewRunnableMethod(this,
&CompositorParent::CompositeCallback,
TimeStamp::Now());
if (!initialComposition && delta < minFrameDelta) {
TimeDuration delay = minFrameDelta - delta;
#ifdef COMPOSITOR_PERFORMANCE_WARNING
mExpectedComposeStartTime = TimeStamp::Now() + delay;
#endif
ScheduleTask(mCurrentCompositeTask, delay.ToMilliseconds());
} else {
#ifdef COMPOSITOR_PERFORMANCE_WARNING
mExpectedComposeStartTime = TimeStamp::Now();
#endif
ScheduleTask(mCurrentCompositeTask, 0);
}
}
void
CompositorParent::ScheduleComposition()
{
MOZ_ASSERT(IsInCompositorThread());
if (mPaused) {
return;
}
if (gfxPrefs::VsyncAlignedCompositor()) {
mCompositorVsyncObserver->SetNeedsComposite(true);
} else {
ScheduleSoftwareTimerComposition();
}
}
void
CompositorParent::CompositeCallback(TimeStamp aScheduleTime)
{
if (gfxPrefs::VsyncAlignedCompositor()) {
// Align OMTA to vsync time.
// TODO: ensure it aligns with the refresh / start time of
// animations
mLastCompose = aScheduleTime;
} else {
mLastCompose = TimeStamp::Now();
}
mCurrentCompositeTask = nullptr;
CompositeToTarget(nullptr);
}
// Go down the composite layer tree, setting properties to match their
// content-side counterparts.
/* static */ void
CompositorParent::SetShadowProperties(Layer* aLayer)
{
// FIXME: Bug 717688 -- Do these updates in LayerTransactionParent::RecvUpdate.
LayerComposite* layerComposite = aLayer->AsLayerComposite();
// Set the layerComposite's base transform to the layer's base transform.
layerComposite->SetShadowTransform(aLayer->GetBaseTransform());
layerComposite->SetShadowTransformSetByAnimation(false);
layerComposite->SetShadowVisibleRegion(aLayer->GetVisibleRegion());
layerComposite->SetShadowClipRect(aLayer->GetClipRect());
layerComposite->SetShadowOpacity(aLayer->GetOpacity());
for (Layer* child = aLayer->GetFirstChild();
child; child = child->GetNextSibling()) {
SetShadowProperties(child);
}
}
void
CompositorParent::CompositeToTarget(DrawTarget* aTarget, const nsIntRect* aRect)
{
profiler_tracing("Paint", "Composite", TRACING_INTERVAL_START);
PROFILER_LABEL("CompositorParent", "Composite",
js::ProfileEntry::Category::GRAPHICS);
MOZ_ASSERT(IsInCompositorThread(),
"Composite can only be called on the compositor thread");
TimeStamp start = TimeStamp::Now();
#ifdef COMPOSITOR_PERFORMANCE_WARNING
TimeDuration scheduleDelta = TimeStamp::Now() - mExpectedComposeStartTime;
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()) {
DidComposite();
return;
}
AutoResolveRefLayers resolve(mCompositionManager);
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 : mLastCompose;
bool requestNextFrame = mCompositionManager->TransformShadowTree(time);
if (requestNextFrame) {
ScheduleComposition();
}
RenderTraceLayers(mLayerManager->GetRoot(), "0000");
#ifdef MOZ_DUMP_PAINTING
static bool gDumpCompositorTree = false;
if (gDumpCompositorTree) {
printf_stderr("Painting --- compositing layer tree:\n");
mLayerManager->Dump();
}
#endif
mLayerManager->SetDebugOverlayWantsNextFrame(false);
mLayerManager->EndEmptyTransaction();
if (!aTarget) {
DidComposite();
}
if (mLayerManager->DebugOverlayWantsNextFrame()) {
ScheduleComposition();
}
#ifdef COMPOSITOR_PERFORMANCE_WARNING
TimeDuration executionTime = TimeStamp::Now() - mLastCompose;
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();
}
mozilla::Telemetry::AccumulateTimeDelta(mozilla::Telemetry::COMPOSITE_TIME, start);
profiler_tracing("Paint", "Composite", TRACING_INTERVAL_END);
}
void
CompositorParent::ForceComposeToTarget(DrawTarget* aTarget, const nsIntRect* aRect)
{
PROFILER_LABEL("CompositorParent", "ForceComposeToTarget",
js::ProfileEntry::Category::GRAPHICS);
AutoRestore<bool> override(mOverrideComposeReadiness);
mOverrideComposeReadiness = true;
mLastCompose = TimeStamp::Now();
CompositeToTarget(aTarget, aRect);
}
bool
CompositorParent::CanComposite()
{
return mLayerManager &&
mLayerManager->GetRoot() &&
!mPaused;
}
void
CompositorParent::ScheduleRotationOnCompositorThread(const TargetConfig& aTargetConfig,
bool aIsFirstPaint)
{
MOZ_ASSERT(IsInCompositorThread());
if (!aIsFirstPaint &&
!mCompositionManager->IsFirstPaint() &&
mCompositionManager->RequiresReorientation(aTargetConfig.orientation())) {
if (mForceCompositionTask != nullptr) {
mForceCompositionTask->Cancel();
}
mForceCompositionTask = NewRunnableMethod(this, &CompositorParent::ForceComposition);
ScheduleTask(mForceCompositionTask, gfxPrefs::OrientationSyncMillis());
}
}
void
CompositorParent::ShadowLayersUpdated(LayerTransactionParent* aLayerTree,
const uint64_t& aTransactionId,
const TargetConfig& aTargetConfig,
const InfallibleTArray<PluginWindowData>& aUnused,
bool aIsFirstPaint,
bool aScheduleComposite,
uint32_t aPaintSequenceNumber,
bool aIsRepeatTransaction)
{
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());
mCompositionManager->Updated(aIsFirstPaint, aTargetConfig);
Layer* root = aLayerTree->GetRoot();
mLayerManager->SetRoot(root);
if (mApzcTreeManager && !aIsRepeatTransaction) {
AutoResolveRefLayers resolve(mCompositionManager);
mApzcTreeManager->UpdateHitTestingTree(this, root, aIsFirstPaint,
mRootLayerTreeID, aPaintSequenceNumber);
}
MOZ_ASSERT(aTransactionId > mPendingTransaction);
mPendingTransaction = aTransactionId;
if (root) {
SetShadowProperties(root);
}
if (aScheduleComposite) {
ScheduleComposition();
if (mPaused) {
DidComposite();
}
// When testing we synchronously update the shadow tree with the animated
// values to avoid race conditions when calling GetAnimationTransform etc.
// (since the above SetShadowProperties will remove animation effects).
// However, we only do this update when a composite operation is already
// scheduled in order to better match the behavior under regular sampling
// conditions.
bool needTestComposite = mIsTesting && root &&
(mCurrentCompositeTask ||
(gfxPrefs::VsyncAlignedCompositor() &&
mCompositorVsyncObserver->NeedsComposite()));
if (needTestComposite) {
AutoResolveRefLayers resolve(mCompositionManager);
bool requestNextFrame =
mCompositionManager->TransformShadowTree(mTestTime);
if (!requestNextFrame) {
CancelCurrentCompositeTask();
// Pretend we composited in case someone is waiting for this event.
DidComposite();
}
}
}
mLayerManager->NotifyShadowTreeTransaction();
}
void
CompositorParent::ForceComposite(LayerTransactionParent* aLayerTree)
{
ScheduleComposition();
}
bool
CompositorParent::SetTestSampleTime(LayerTransactionParent* aLayerTree,
const TimeStamp& aTime)
{
if (aTime.IsNull()) {
return false;
}
mIsTesting = true;
mTestTime = aTime;
bool testComposite = mCompositionManager && (mCurrentCompositeTask ||
(gfxPrefs::VsyncAlignedCompositor()
&& mCompositorVsyncObserver->NeedsComposite()));
// Update but only if we were already scheduled to animate
if (testComposite) {
AutoResolveRefLayers resolve(mCompositionManager);
bool requestNextFrame = mCompositionManager->TransformShadowTree(aTime);
if (!requestNextFrame) {
CancelCurrentCompositeTask();
// Pretend we composited in case someone is wating for this event.
DidComposite();
}
}
return true;
}
void
CompositorParent::LeaveTestMode(LayerTransactionParent* aLayerTree)
{
mIsTesting = false;
}
bool
CompositorParent::RecvRequestOverfill()
{
uint32_t overfillRatio = mCompositor->GetFillRatio();
unused << SendOverfill(overfillRatio);
return true;
}
void
CompositorParent::GetAPZTestData(const LayerTransactionParent* aLayerTree,
APZTestData* aOutData)
{
MonitorAutoLock lock(*sIndirectLayerTreesLock);
*aOutData = sIndirectLayerTrees[mRootLayerTreeID].mApzTestData;
}
void
CompositorParent::InitializeLayerManager(const nsTArray<LayersBackend>& aBackendHints)
{
NS_ASSERTION(!mLayerManager, "Already initialised mLayerManager");
NS_ASSERTION(!mCompositor, "Already initialised mCompositor");
for (size_t i = 0; i < aBackendHints.Length(); ++i) {
RefPtr<Compositor> compositor;
if (aBackendHints[i] == LayersBackend::LAYERS_OPENGL) {
compositor = new CompositorOGL(mWidget,
mEGLSurfaceSize.width,
mEGLSurfaceSize.height,
mUseExternalSurfaceSize);
} else if (aBackendHints[i] == LayersBackend::LAYERS_BASIC) {
#ifdef MOZ_WIDGET_GTK
if (gfxPlatformGtk::GetPlatform()->UseXRender()) {
compositor = new X11BasicCompositor(mWidget);
} else
#endif
{
compositor = new BasicCompositor(mWidget);
}
#ifdef XP_WIN
} else if (aBackendHints[i] == LayersBackend::LAYERS_D3D11) {
compositor = new CompositorD3D11(mWidget);
} else if (aBackendHints[i] == LayersBackend::LAYERS_D3D9) {
compositor = new CompositorD3D9(this, mWidget);
#endif
}
if (!compositor) {
// We passed a backend hint for which we can't create a compositor.
// For example, we sometime pass LayersBackend::LAYERS_NONE as filler in aBackendHints.
continue;
}
compositor->SetCompositorID(mCompositorID);
RefPtr<LayerManagerComposite> layerManager = new LayerManagerComposite(compositor);
if (layerManager->Initialize()) {
mLayerManager = layerManager;
MOZ_ASSERT(compositor);
mCompositor = compositor;
MonitorAutoLock lock(*sIndirectLayerTreesLock);
sIndirectLayerTrees[mRootLayerTreeID].mLayerManager = layerManager;
return;
}
}
}
PLayerTransactionParent*
CompositorParent::AllocPLayerTransactionParent(const nsTArray<LayersBackend>& aBackendHints,
const uint64_t& aId,
TextureFactoryIdentifier* aTextureFactoryIdentifier,
bool *aSuccess)
{
MOZ_ASSERT(aId == 0);
// mWidget doesn't belong to the compositor thread, so it should be set to
// nullptr before returning from this method, to avoid accessing it elsewhere.
nsIntRect rect;
mWidget->GetClientBounds(rect);
InitializeLayerManager(aBackendHints);
mWidget = nullptr;
if (!mLayerManager) {
NS_WARNING("Failed to initialise Compositor");
*aSuccess = false;
LayerTransactionParent* p = new LayerTransactionParent(nullptr, this, 0,
// child side's process id is current process Id
base::GetProcId(base::GetCurrentProcessHandle()));
p->AddIPDLReference();
return p;
}
mCompositionManager = new AsyncCompositionManager(mLayerManager);
*aSuccess = true;
*aTextureFactoryIdentifier = mCompositor->GetTextureFactoryIdentifier();
LayerTransactionParent* p = new LayerTransactionParent(mLayerManager, this, 0,
// child side's process id is current process Id
base::GetProcId(base::GetCurrentProcessHandle()));
p->AddIPDLReference();
return p;
}
bool
CompositorParent::DeallocPLayerTransactionParent(PLayerTransactionParent* actor)
{
static_cast<LayerTransactionParent*>(actor)->ReleaseIPDLReference();
return true;
}
CompositorParent* CompositorParent::GetCompositor(uint64_t id)
{
CompositorMap::iterator it = sCompositorMap->find(id);
return it != sCompositorMap->end() ? it->second : nullptr;
}
void CompositorParent::AddCompositor(CompositorParent* compositor, uint64_t* outID)
{
static uint64_t sNextID = 1;
++sNextID;
(*sCompositorMap)[sNextID] = compositor;
*outID = sNextID;
}
CompositorParent* CompositorParent::RemoveCompositor(uint64_t id)
{
CompositorMap::iterator it = sCompositorMap->find(id);
if (it == sCompositorMap->end()) {
return nullptr;
}
CompositorParent *retval = it->second;
sCompositorMap->erase(it);
return retval;
}
bool
CompositorParent::RecvNotifyChildCreated(const uint64_t& child)
{
MonitorAutoLock lock(*sIndirectLayerTreesLock);
NotifyChildCreated(child);
return true;
}
void
CompositorParent::NotifyChildCreated(const uint64_t& aChild)
{
sIndirectLayerTreesLock->AssertCurrentThreadOwns();
sIndirectLayerTrees[aChild].mParent = this;
sIndirectLayerTrees[aChild].mLayerManager = mLayerManager;
}
bool
CompositorParent::RecvAdoptChild(const uint64_t& child)
{
MonitorAutoLock lock(*sIndirectLayerTreesLock);
NotifyChildCreated(child);
if (sIndirectLayerTrees[child].mLayerTree) {
sIndirectLayerTrees[child].mLayerTree->mLayerManager = mLayerManager;
}
if (sIndirectLayerTrees[child].mRoot) {
sIndirectLayerTrees[child].mRoot->AsLayerComposite()->SetLayerManager(mLayerManager);
}
return true;
}
/*static*/ uint64_t
CompositorParent::AllocateLayerTreeId()
{
MOZ_ASSERT(CompositorLoop());
MOZ_ASSERT(NS_IsMainThread());
static uint64_t ids = 0;
return ++ids;
}
static void
EraseLayerState(uint64_t aId)
{
MonitorAutoLock lock(*sIndirectLayerTreesLock);
sIndirectLayerTrees.erase(aId);
}
/*static*/ void
CompositorParent::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.
MOZ_ASSERT(CompositorLoop());
CompositorLoop()->PostTask(FROM_HERE,
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<GeckoContentController>(aController);
}
ScopedLayerTreeRegistration::ScopedLayerTreeRegistration(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
CompositorParent::SetControllerForLayerTree(uint64_t aLayersId,
GeckoContentController* aController)
{
// This ref is adopted by UpdateControllerForLayersId().
aController->AddRef();
CompositorLoop()->PostTask(FROM_HERE,
NewRunnableFunction(&UpdateControllerForLayersId,
aLayersId,
aController));
}
/*static*/ APZCTreeManager*
CompositorParent::GetAPZCTreeManager(uint64_t aLayersId)
{
const CompositorParent::LayerTreeState* state = CompositorParent::GetIndirectShadowTree(aLayersId);
if (state && state->mParent) {
return state->mParent->mApzcTreeManager;
}
return nullptr;
}
float
CompositorParent::ComputeRenderIntegrity()
{
if (mLayerManager) {
return mLayerManager->ComputeRenderIntegrity();
}
return 1.0f;
}
static void
InsertVsyncProfilerMarker(TimeStamp aVsyncTimestamp)
{
#ifdef MOZ_ENABLE_PROFILER_SPS
MOZ_ASSERT(CompositorParent::IsInCompositorThread());
MOZ_ASSERT(profiler_is_active());
VsyncPayload* payload = new VsyncPayload(aVsyncTimestamp);
PROFILER_MARKER_PAYLOAD("VsyncTimestamp", payload);
#endif
}
/*static */ void
CompositorParent::PostInsertVsyncProfilerMarker(TimeStamp aVsyncTimestamp)
{
if (profiler_is_active() && sCompositorThreadHolder) {
CompositorLoop()->PostTask(FROM_HERE,
NewRunnableFunction(InsertVsyncProfilerMarker, aVsyncTimestamp));
}
}
/**
* This class handles layer updates pushed directly from child
* processes to the compositor thread. It's associated with a
* CompositorParent on the compositor thread. While it uses the
* PCompositor protocol to manage these updates, it doesn't actually
* drive compositing itself. For that it hands off work to the
* CompositorParent it's associated with.
*/
class CrossProcessCompositorParent MOZ_FINAL : public PCompositorParent,
public ShadowLayersManager
{
friend class CompositorParent;
NS_INLINE_DECL_THREADSAFE_REFCOUNTING_WITH_MAIN_THREAD_DESTRUCTION(CrossProcessCompositorParent)
public:
CrossProcessCompositorParent(Transport* aTransport, ProcessId aOtherProcess)
: mTransport(aTransport)
, mChildProcessId(aOtherProcess)
, mCompositorThreadHolder(sCompositorThreadHolder)
, mNotifyAfterRemotePaint(false)
{
MOZ_ASSERT(NS_IsMainThread());
gfxPlatform::GetPlatform()->ComputeTileSize();
}
// IToplevelProtocol::CloneToplevel()
virtual IToplevelProtocol*
CloneToplevel(const InfallibleTArray<mozilla::ipc::ProtocolFdMapping>& aFds,
base::ProcessHandle aPeerProcess,
mozilla::ipc::ProtocolCloneContext* aCtx) MOZ_OVERRIDE;
virtual void ActorDestroy(ActorDestroyReason aWhy) MOZ_OVERRIDE;
// FIXME/bug 774388: work out what shutdown protocol we need.
virtual bool RecvRequestOverfill() MOZ_OVERRIDE { return true; }
virtual bool RecvWillStop() MOZ_OVERRIDE { return true; }
virtual bool RecvStop() MOZ_OVERRIDE { return true; }
virtual bool RecvPause() MOZ_OVERRIDE { return true; }
virtual bool RecvResume() MOZ_OVERRIDE { return true; }
virtual bool RecvNotifyChildCreated(const uint64_t& child) MOZ_OVERRIDE;
virtual bool RecvAdoptChild(const uint64_t& child) MOZ_OVERRIDE { return false; }
virtual bool RecvMakeSnapshot(const SurfaceDescriptor& aInSnapshot,
const nsIntRect& aRect) MOZ_OVERRIDE
{ return true; }
virtual bool RecvFlushRendering() MOZ_OVERRIDE { return true; }
virtual bool RecvNotifyRegionInvalidated(const nsIntRegion& aRegion) MOZ_OVERRIDE { return true; }
virtual bool RecvStartFrameTimeRecording(const int32_t& aBufferSize, uint32_t* aOutStartIndex) MOZ_OVERRIDE { return true; }
virtual bool RecvStopFrameTimeRecording(const uint32_t& aStartIndex, InfallibleTArray<float>* intervals) MOZ_OVERRIDE { return true; }
virtual bool RecvGetTileSize(int32_t* aWidth, int32_t* aHeight) MOZ_OVERRIDE
{
*aWidth = gfxPlatform::GetPlatform()->GetTileWidth();
*aHeight = gfxPlatform::GetPlatform()->GetTileHeight();
return true;
}
/**
* Tells this CompositorParent to send a message when the compositor has received the transaction.
*/
virtual bool RecvRequestNotifyAfterRemotePaint() MOZ_OVERRIDE;
virtual PLayerTransactionParent*
AllocPLayerTransactionParent(const nsTArray<LayersBackend>& aBackendHints,
const uint64_t& aId,
TextureFactoryIdentifier* aTextureFactoryIdentifier,
bool *aSuccess) MOZ_OVERRIDE;
virtual bool DeallocPLayerTransactionParent(PLayerTransactionParent* aLayers) MOZ_OVERRIDE;
virtual void ShadowLayersUpdated(LayerTransactionParent* aLayerTree,
const uint64_t& aTransactionId,
const TargetConfig& aTargetConfig,
const InfallibleTArray<PluginWindowData>& aPlugins,
bool aIsFirstPaint,
bool aScheduleComposite,
uint32_t aPaintSequenceNumber,
bool aIsRepeatTransaction) MOZ_OVERRIDE;
virtual void ForceComposite(LayerTransactionParent* aLayerTree) MOZ_OVERRIDE;
virtual bool SetTestSampleTime(LayerTransactionParent* aLayerTree,
const TimeStamp& aTime) MOZ_OVERRIDE;
virtual void LeaveTestMode(LayerTransactionParent* aLayerTree) MOZ_OVERRIDE;
virtual void GetAPZTestData(const LayerTransactionParent* aLayerTree,
APZTestData* aOutData) MOZ_OVERRIDE;
virtual AsyncCompositionManager* GetCompositionManager(LayerTransactionParent* aParent) MOZ_OVERRIDE;
void DidComposite(uint64_t aId);
private:
// Private destructor, to discourage deletion outside of Release():
virtual ~CrossProcessCompositorParent();
void DeferredDestroy();
// There can be many CPCPs, and IPDL-generated code doesn't hold a
// reference to top-level actors. So we hold a reference to
// ourself. This is released (deferred) in ActorDestroy().
nsRefPtr<CrossProcessCompositorParent> mSelfRef;
Transport* mTransport;
// Child side's process Id.
base::ProcessId mChildProcessId;
nsRefPtr<CompositorThreadHolder> mCompositorThreadHolder;
// If true, we should send a RemotePaintIsReady message when the layer transaction
// is received
bool mNotifyAfterRemotePaint;
};
void
CompositorParent::DidComposite()
{
if (mPendingTransaction) {
unused << SendDidComposite(0, mPendingTransaction);
mPendingTransaction = 0;
}
MonitorAutoLock lock(*sIndirectLayerTreesLock);
for (LayerTreeMap::iterator it = sIndirectLayerTrees.begin();
it != sIndirectLayerTrees.end(); it++) {
LayerTreeState* lts = &it->second;
if (lts->mParent == this && lts->mCrossProcessParent) {
static_cast<CrossProcessCompositorParent*>(lts->mCrossProcessParent)->DidComposite(it->first);
}
}
}
static void
OpenCompositor(CrossProcessCompositorParent* aCompositor,
Transport* aTransport, ProcessHandle aHandle,
MessageLoop* aIOLoop)
{
DebugOnly<bool> ok = aCompositor->Open(aTransport, aHandle, aIOLoop);
MOZ_ASSERT(ok);
}
/*static*/ PCompositorParent*
CompositorParent::Create(Transport* aTransport, ProcessId aOtherProcess)
{
gfxPlatform::InitLayersIPC();
nsRefPtr<CrossProcessCompositorParent> cpcp =
new CrossProcessCompositorParent(aTransport, aOtherProcess);
ProcessHandle handle;
if (!base::OpenProcessHandle(aOtherProcess, &handle)) {
// XXX need to kill |aOtherProcess|, it's boned
return nullptr;
}
cpcp->mSelfRef = cpcp;
CompositorLoop()->PostTask(
FROM_HERE,
NewRunnableFunction(OpenCompositor, cpcp.get(),
aTransport, handle, XRE_GetIOMessageLoop()));
// The return value is just compared to null for success checking,
// we're not sharing a ref.
return cpcp.get();
}
IToplevelProtocol*
CompositorParent::CloneToplevel(const InfallibleTArray<mozilla::ipc::ProtocolFdMapping>& aFds,
base::ProcessHandle aPeerProcess,
mozilla::ipc::ProtocolCloneContext* aCtx)
{
for (unsigned int i = 0; i < aFds.Length(); i++) {
if (aFds[i].protocolId() == (unsigned)GetProtocolId()) {
Transport* transport = OpenDescriptor(aFds[i].fd(),
Transport::MODE_SERVER);
PCompositorParent* compositor = Create(transport, base::GetProcId(aPeerProcess));
compositor->CloneManagees(this, aCtx);
compositor->IToplevelProtocol::SetTransport(transport);
return compositor;
}
}
return nullptr;
}
static void
UpdateIndirectTree(uint64_t aId, Layer* aRoot, const TargetConfig& aTargetConfig)
{
MonitorAutoLock lock(*sIndirectLayerTreesLock);
sIndirectLayerTrees[aId].mRoot = aRoot;
sIndirectLayerTrees[aId].mTargetConfig = aTargetConfig;
}
/* static */ CompositorParent::LayerTreeState*
CompositorParent::GetIndirectShadowTree(uint64_t aId)
{
MonitorAutoLock lock(*sIndirectLayerTreesLock);
LayerTreeMap::iterator cit = sIndirectLayerTrees.find(aId);
if (sIndirectLayerTrees.end() == cit) {
return nullptr;
}
return &cit->second;
}
bool
CrossProcessCompositorParent::RecvRequestNotifyAfterRemotePaint()
{
mNotifyAfterRemotePaint = true;
return true;
}
void
CrossProcessCompositorParent::ActorDestroy(ActorDestroyReason aWhy)
{
MessageLoop::current()->PostTask(
FROM_HERE,
NewRunnableMethod(this, &CrossProcessCompositorParent::DeferredDestroy));
}
PLayerTransactionParent*
CrossProcessCompositorParent::AllocPLayerTransactionParent(const nsTArray<LayersBackend>&,
const uint64_t& aId,
TextureFactoryIdentifier* aTextureFactoryIdentifier,
bool *aSuccess)
{
MOZ_ASSERT(aId != 0);
MonitorAutoLock lock(*sIndirectLayerTreesLock);
CompositorParent::LayerTreeState* state = nullptr;
LayerTreeMap::iterator itr = sIndirectLayerTrees.find(aId);
if (sIndirectLayerTrees.end() != itr) {
state = &itr->second;
}
if (state && state->mLayerManager) {
state->mCrossProcessParent = this;
LayerManagerComposite* lm = state->mLayerManager;
*aTextureFactoryIdentifier = lm->GetCompositor()->GetTextureFactoryIdentifier();
*aSuccess = true;
LayerTransactionParent* p = new LayerTransactionParent(lm, this, aId, mChildProcessId);
p->AddIPDLReference();
sIndirectLayerTrees[aId].mLayerTree = p;
return p;
}
NS_WARNING("Created child without a matching parent?");
// XXX: should be false, but that causes us to fail some tests on Mac w/ OMTC.
// Bug 900745. change *aSuccess to false to see test failures.
*aSuccess = true;
LayerTransactionParent* p = new LayerTransactionParent(nullptr, this, aId, mChildProcessId);
p->AddIPDLReference();
return p;
}
bool
CrossProcessCompositorParent::DeallocPLayerTransactionParent(PLayerTransactionParent* aLayers)
{
LayerTransactionParent* slp = static_cast<LayerTransactionParent*>(aLayers);
EraseLayerState(slp->GetId());
static_cast<LayerTransactionParent*>(aLayers)->ReleaseIPDLReference();
return true;
}
bool
CrossProcessCompositorParent::RecvNotifyChildCreated(const uint64_t& child)
{
MonitorAutoLock lock(*sIndirectLayerTreesLock);
for (LayerTreeMap::iterator it = sIndirectLayerTrees.begin();
it != sIndirectLayerTrees.end(); it++) {
CompositorParent::LayerTreeState* lts = &it->second;
if (lts->mParent && lts->mCrossProcessParent == this) {
lts->mParent->NotifyChildCreated(child);
return true;
}
}
return false;
}
void
CrossProcessCompositorParent::ShadowLayersUpdated(
LayerTransactionParent* aLayerTree,
const uint64_t& aTransactionId,
const TargetConfig& aTargetConfig,
bool aIsFirstPaint,
bool aScheduleComposite,
uint32_t aPaintSequenceNumber,
bool aIsRepeatTransaction)
{
uint64_t id = aLayerTree->GetId();
MOZ_ASSERT(id != 0);
const CompositorParent::LayerTreeState* state = CompositorParent::GetIndirectShadowTree(id);
if (!state) {
return;
}
MOZ_ASSERT(state->mParent);
state->mParent->ScheduleRotationOnCompositorThread(aTargetConfig, aIsFirstPaint);
Layer* shadowRoot = aLayerTree->GetRoot();
if (shadowRoot) {
CompositorParent::SetShadowProperties(shadowRoot);
}
UpdateIndirectTree(id, shadowRoot, aTargetConfig);
state->mParent->NotifyShadowTreeTransaction(id, aIsFirstPaint, aScheduleComposite,
aPaintSequenceNumber, aIsRepeatTransaction);
// Send the 'remote paint ready' message to the content thread if it has already asked.
if(mNotifyAfterRemotePaint) {
unused << SendRemotePaintIsReady();
mNotifyAfterRemotePaint = false;
}
aLayerTree->SetPendingTransactionId(aTransactionId);
}
void
CrossProcessCompositorParent::DidComposite(uint64_t aId)
{
sIndirectLayerTreesLock->AssertCurrentThreadOwns();
LayerTransactionParent *layerTree = sIndirectLayerTrees[aId].mLayerTree;
if (layerTree && layerTree->GetPendingTransactionId()) {
unused << SendDidComposite(aId, layerTree->GetPendingTransactionId());
layerTree->SetPendingTransactionId(0);
}
}
void
CrossProcessCompositorParent::ForceComposite(LayerTransactionParent* aLayerTree)
{
uint64_t id = aLayerTree->GetId();
MOZ_ASSERT(id != 0);
CompositorParent* parent;
{ // scope lock
MonitorAutoLock lock(*sIndirectLayerTreesLock);
parent = sIndirectLayerTrees[id].mParent;
}
if (parent) {
parent->ForceComposite(aLayerTree);
}
}
bool
CrossProcessCompositorParent::SetTestSampleTime(
LayerTransactionParent* aLayerTree, const TimeStamp& aTime)
{
uint64_t id = aLayerTree->GetId();
MOZ_ASSERT(id != 0);
const CompositorParent::LayerTreeState* state = CompositorParent::GetIndirectShadowTree(id);
if (!state) {
return false;
}
MOZ_ASSERT(state->mParent);
return state->mParent->SetTestSampleTime(aLayerTree, aTime);
}
void
CrossProcessCompositorParent::LeaveTestMode(LayerTransactionParent* aLayerTree)
{
uint64_t id = aLayerTree->GetId();
MOZ_ASSERT(id != 0);
const CompositorParent::LayerTreeState* state = CompositorParent::GetIndirectShadowTree(id);
if (!state) {
return;
}
MOZ_ASSERT(state->mParent);
state->mParent->LeaveTestMode(aLayerTree);
}
void
CrossProcessCompositorParent::GetAPZTestData(const LayerTransactionParent* aLayerTree,
APZTestData* aOutData)
{
uint64_t id = aLayerTree->GetId();
MOZ_ASSERT(id != 0);
MonitorAutoLock lock(*sIndirectLayerTreesLock);
*aOutData = sIndirectLayerTrees[id].mApzTestData;
}
AsyncCompositionManager*
CrossProcessCompositorParent::GetCompositionManager(LayerTransactionParent* aLayerTree)
{
uint64_t id = aLayerTree->GetId();
const CompositorParent::LayerTreeState* state = CompositorParent::GetIndirectShadowTree(id);
if (!state) {
return nullptr;
}
MOZ_ASSERT(state->mParent);
return state->mParent->GetCompositionManager(aLayerTree);
}
void
CrossProcessCompositorParent::DeferredDestroy()
{
mCompositorThreadHolder = nullptr;
mSelfRef = nullptr;
}
CrossProcessCompositorParent::~CrossProcessCompositorParent()
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(XRE_GetIOMessageLoop());
XRE_GetIOMessageLoop()->PostTask(FROM_HERE,
new DeleteTask<Transport>(mTransport));
}
IToplevelProtocol*
CrossProcessCompositorParent::CloneToplevel(const InfallibleTArray<mozilla::ipc::ProtocolFdMapping>& aFds,
base::ProcessHandle aPeerProcess,
mozilla::ipc::ProtocolCloneContext* aCtx)
{
for (unsigned int i = 0; i < aFds.Length(); i++) {
if (aFds[i].protocolId() == (unsigned)GetProtocolId()) {
Transport* transport = OpenDescriptor(aFds[i].fd(),
Transport::MODE_SERVER);
PCompositorParent* compositor =
CompositorParent::Create(transport, base::GetProcId(aPeerProcess));
compositor->CloneManagees(this, aCtx);
compositor->IToplevelProtocol::SetTransport(transport);
return compositor;
}
}
return nullptr;
}
} // namespace layers
} // namespace mozilla