gecko/gfx/layers/client/TextureClient.cpp

1036 lines
28 KiB
C++

/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "mozilla/layers/TextureClient.h"
#include <stdint.h> // for uint8_t, uint32_t, etc
#include "Layers.h" // for Layer, etc
#include "gfx2DGlue.h"
#include "gfxContext.h" // for gfxContext, etc
#include "gfxPlatform.h" // for gfxPlatform
#include "gfxPoint.h" // for gfxIntSize, gfxSize
#include "gfxReusableSurfaceWrapper.h" // for gfxReusableSurfaceWrapper
#include "mozilla/gfx/BaseSize.h" // for BaseSize
#include "mozilla/ipc/SharedMemory.h" // for SharedMemory, etc
#include "mozilla/layers/CompositableClient.h" // for CompositableClient
#include "mozilla/layers/CompositableForwarder.h"
#include "mozilla/layers/ISurfaceAllocator.h"
#include "mozilla/layers/ImageDataSerializer.h"
#include "mozilla/layers/ShadowLayers.h" // for ShadowLayerForwarder
#include "mozilla/layers/SharedPlanarYCbCrImage.h"
#include "mozilla/layers/YCbCrImageDataSerializer.h"
#include "mozilla/layers/PTextureChild.h"
#include "nsDebug.h" // for NS_ASSERTION, NS_WARNING, etc
#include "nsTraceRefcnt.h" // for MOZ_COUNT_CTOR, etc
#include "ImageContainer.h" // for PlanarYCbCrImage, etc
#include "mozilla/gfx/2D.h"
#ifdef MOZ_ANDROID_OMTC
# include "gfxReusableImageSurfaceWrapper.h"
# include "gfxImageSurface.h"
#else
# include "gfxReusableSharedImageSurfaceWrapper.h"
# include "gfxSharedImageSurface.h"
#endif
using namespace mozilla::gl;
using namespace mozilla::gfx;
namespace mozilla {
namespace layers {
/**
* TextureChild is the content-side incarnation of the PTexture IPDL actor.
*
* TextureChild is used to synchronize a texture client and its corresponding
* TextureHost if needed (a TextureClient that is not shared with the compositor
* does not have a TextureChild)
*
* During the deallocation phase, a TextureChild may hold its recently destroyed
* TextureClient's data until the compositor side confirmed that it is safe to
* deallocte or recycle the it.
*/
class TextureChild : public PTextureChild
, public AtomicRefCounted<TextureChild>
{
public:
TextureChild()
: mForwarder(nullptr)
, mTextureData(nullptr)
, mTextureClient(nullptr)
, mIPCOpen(false)
{
MOZ_COUNT_CTOR(TextureChild);
}
~TextureChild()
{
MOZ_COUNT_DTOR(TextureChild);
}
bool Recv__delete__() MOZ_OVERRIDE;
/**
* Only used during the deallocation phase iff we need synchronization between
* the client and host side for deallocation (that is, when the data is going
* to be deallocated or recycled on the client side).
*/
void SetTextureData(TextureClientData* aData)
{
mTextureData = aData;
}
void DeleteTextureData();
CompositableForwarder* GetForwarder() { return mForwarder; }
ISurfaceAllocator* GetAllocator() { return mForwarder; }
void ActorDestroy(ActorDestroyReason why) MOZ_OVERRIDE;
bool IPCOpen() const { return mIPCOpen; }
private:
// AddIPDLReference and ReleaseIPDLReference are only to be called by CreateIPDLActor
// and DestroyIPDLActor, respectively. We intentionally make them private to prevent misuse.
// The purpose of these methods is to be aware of when the IPC system around this
// actor goes down: mIPCOpen is then set to false.
void AddIPDLReference() {
MOZ_ASSERT(mIPCOpen == false);
mIPCOpen = true;
AddRef();
}
void ReleaseIPDLReference() {
MOZ_ASSERT(mIPCOpen == true);
mIPCOpen = false;
Release();
}
CompositableForwarder* mForwarder;
TextureClientData* mTextureData;
TextureClient* mTextureClient;
bool mIPCOpen;
friend class TextureClient;
};
void
TextureChild::DeleteTextureData()
{
if (mTextureData) {
mTextureData->DeallocateSharedData(GetAllocator());
delete mTextureData;
mTextureData = nullptr;
}
}
bool
TextureChild::Recv__delete__()
{
DeleteTextureData();
return true;
}
void
TextureChild::ActorDestroy(ActorDestroyReason why)
{
if (mTextureClient) {
mTextureClient->mActor = nullptr;
}
}
// static
PTextureChild*
TextureClient::CreateIPDLActor()
{
TextureChild* c = new TextureChild();
c->AddIPDLReference();
return c;
}
// static
bool
TextureClient::DestroyIPDLActor(PTextureChild* actor)
{
static_cast<TextureChild*>(actor)->ReleaseIPDLReference();
return true;
}
bool
TextureClient::InitIPDLActor(CompositableForwarder* aForwarder)
{
MOZ_ASSERT(aForwarder);
if (mActor && mActor->GetForwarder() == aForwarder) {
return true;
}
MOZ_ASSERT(!mActor, "Cannot use a texture on several IPC channels.");
SurfaceDescriptor desc;
if (!ToSurfaceDescriptor(desc)) {
return false;
}
mActor = static_cast<TextureChild*>(aForwarder->CreateTexture(desc, GetFlags()));
MOZ_ASSERT(mActor);
mActor->mForwarder = aForwarder;
mActor->mTextureClient = this;
mShared = true;
return mActor->IPCOpen();
}
PTextureChild*
TextureClient::GetIPDLActor()
{
return mActor;
}
class ShmemTextureClientData : public TextureClientData
{
public:
ShmemTextureClientData(ipc::Shmem& aShmem)
: mShmem(aShmem)
{
MOZ_COUNT_CTOR(ShmemTextureClientData);
}
~ShmemTextureClientData()
{
MOZ_COUNT_CTOR(ShmemTextureClientData);
}
virtual void DeallocateSharedData(ISurfaceAllocator* allocator)
{
allocator->DeallocShmem(mShmem);
mShmem = ipc::Shmem();
}
private:
ipc::Shmem mShmem;
};
class MemoryTextureClientData : public TextureClientData
{
public:
MemoryTextureClientData(uint8_t* aBuffer)
: mBuffer(aBuffer)
{
MOZ_COUNT_CTOR(MemoryTextureClientData);
}
~MemoryTextureClientData()
{
MOZ_ASSERT(!mBuffer, "Forgot to deallocate the shared texture data?");
MOZ_COUNT_CTOR(MemoryTextureClientData);
}
virtual void DeallocateSharedData(ISurfaceAllocator*)
{
delete[] mBuffer;
mBuffer = nullptr;
}
private:
uint8_t* mBuffer;
};
TextureClientData*
MemoryTextureClient::DropTextureData()
{
if (!mBuffer) {
return nullptr;
}
TextureClientData* result = new MemoryTextureClientData(mBuffer);
MarkInvalid();
mBuffer = nullptr;
return result;
}
TextureClientData*
ShmemTextureClient::DropTextureData()
{
if (!mShmem.IsReadable()) {
return nullptr;
}
TextureClientData* result = new ShmemTextureClientData(mShmem);
MarkInvalid();
mShmem = ipc::Shmem();
return result;
}
TextureClient::TextureClient(TextureFlags aFlags)
: mFlags(aFlags)
, mShared(false)
, mValid(true)
{}
TextureClient::~TextureClient()
{
// All the destruction code that may lead to virtual method calls must
// be in Finalize() which is called just before the destructor.
}
void TextureClient::ForceRemove()
{
if (mValid && mActor) {
if (GetFlags() & TEXTURE_DEALLOCATE_CLIENT) {
mActor->SetTextureData(DropTextureData());
if (mActor->IPCOpen()) {
mActor->SendRemoveTextureSync();
}
mActor->DeleteTextureData();
} else {
if (mActor->IPCOpen()) {
mActor->SendRemoveTexture();
}
}
}
MarkInvalid();
}
void
TextureClient::Finalize()
{
// Always make a temporary strong reference to the actor before we use it,
// in case TextureChild::ActorDestroy might null mActor concurrently.
RefPtr<TextureChild> actor = mActor;
if (actor) {
// this will call ForceRemove in the right thread, using a sync proxy if needed
actor->GetForwarder()->RemoveTexture(this);
// The actor has a raw pointer to us, actor->mTextureClient. Null it before we die.
actor->mTextureClient = nullptr;
}
}
bool
TextureClient::ShouldDeallocateInDestructor() const
{
if (!IsAllocated()) {
return false;
}
// If we're meant to be deallocated by the host,
// but we haven't been shared yet, then we should
// deallocate on the client instead.
return !IsSharedWithCompositor();
}
bool
ShmemTextureClient::ToSurfaceDescriptor(SurfaceDescriptor& aDescriptor)
{
MOZ_ASSERT(IsValid());
if (!IsAllocated() || GetFormat() == gfx::SurfaceFormat::UNKNOWN) {
return false;
}
aDescriptor = SurfaceDescriptorShmem(mShmem, GetFormat());
return true;
}
ISurfaceAllocator*
ShmemTextureClient::GetAllocator() const
{
return mCompositable->GetForwarder();
}
bool
ShmemTextureClient::Allocate(uint32_t aSize)
{
MOZ_ASSERT(mValid);
ipc::SharedMemory::SharedMemoryType memType = OptimalShmemType();
mAllocated = GetAllocator()->AllocUnsafeShmem(aSize, memType, &mShmem);
return mAllocated;
}
uint8_t*
ShmemTextureClient::GetBuffer() const
{
MOZ_ASSERT(IsValid());
if (mAllocated) {
return mShmem.get<uint8_t>();
}
return nullptr;
}
size_t
ShmemTextureClient::GetBufferSize() const
{
MOZ_ASSERT(IsValid());
return mShmem.Size<uint8_t>();
}
ShmemTextureClient::ShmemTextureClient(CompositableClient* aCompositable,
gfx::SurfaceFormat aFormat,
TextureFlags aFlags)
: BufferTextureClient(aCompositable, aFormat, aFlags)
, mAllocated(false)
{
MOZ_COUNT_CTOR(ShmemTextureClient);
}
ShmemTextureClient::~ShmemTextureClient()
{
MOZ_COUNT_DTOR(ShmemTextureClient);
if (ShouldDeallocateInDestructor()) {
// if the buffer has never been shared we must deallocate it or ir would
// leak.
mCompositable->GetForwarder()->DeallocShmem(mShmem);
}
}
bool
MemoryTextureClient::ToSurfaceDescriptor(SurfaceDescriptor& aDescriptor)
{
MOZ_ASSERT(IsValid());
if (!IsAllocated() || GetFormat() == gfx::SurfaceFormat::UNKNOWN) {
return false;
}
aDescriptor = SurfaceDescriptorMemory(reinterpret_cast<uintptr_t>(mBuffer),
GetFormat());
return true;
}
bool
MemoryTextureClient::Allocate(uint32_t aSize)
{
MOZ_ASSERT(!mBuffer);
static const fallible_t fallible = fallible_t();
mBuffer = new(fallible) uint8_t[aSize];
if (!mBuffer) {
NS_WARNING("Failed to allocate buffer");
return false;
}
GfxMemoryImageReporter::DidAlloc(mBuffer);
mBufSize = aSize;
return true;
}
MemoryTextureClient::MemoryTextureClient(CompositableClient* aCompositable,
gfx::SurfaceFormat aFormat,
TextureFlags aFlags)
: BufferTextureClient(aCompositable, aFormat, aFlags)
, mBuffer(nullptr)
, mBufSize(0)
{
MOZ_COUNT_CTOR(MemoryTextureClient);
}
MemoryTextureClient::~MemoryTextureClient()
{
MOZ_COUNT_DTOR(MemoryTextureClient);
if (mBuffer && ShouldDeallocateInDestructor()) {
// if the buffer has never been shared we must deallocate it or it would
// leak.
GfxMemoryImageReporter::WillFree(mBuffer);
delete mBuffer;
}
}
BufferTextureClient::BufferTextureClient(CompositableClient* aCompositable,
gfx::SurfaceFormat aFormat,
TextureFlags aFlags)
: TextureClient(aFlags)
, mCompositable(aCompositable)
, mFormat(aFormat)
, mUsingFallbackDrawTarget(false)
, mLocked(false)
{}
BufferTextureClient::~BufferTextureClient()
{}
bool
BufferTextureClient::UpdateSurface(gfxASurface* aSurface)
{
MOZ_ASSERT(aSurface);
MOZ_ASSERT(!IsImmutable());
MOZ_ASSERT(IsValid());
ImageDataSerializer serializer(GetBuffer());
if (!serializer.IsValid()) {
return false;
}
if (gfxPlatform::GetPlatform()->SupportsAzureContent()) {
RefPtr<DrawTarget> dt = GetAsDrawTarget();
RefPtr<SourceSurface> source = gfxPlatform::GetPlatform()->GetSourceSurfaceForSurface(dt, aSurface);
dt->CopySurface(source, IntRect(IntPoint(), serializer.GetSize()), IntPoint());
// XXX - if the Moz2D backend is D2D, we would be much better off memcpying
// the content of the surface directly because with D2D, GetAsDrawTarget is
// very expensive.
} else {
RefPtr<gfxImageSurface> surf = serializer.GetAsThebesSurface();
if (!surf) {
return false;
}
nsRefPtr<gfxContext> tmpCtx = new gfxContext(surf.get());
tmpCtx->SetOperator(gfxContext::OPERATOR_SOURCE);
tmpCtx->DrawSurface(aSurface, gfxSize(serializer.GetSize().width,
serializer.GetSize().height));
}
if (TextureRequiresLocking(mFlags) && !ImplementsLocking()) {
// We don't have support for proper locking yet, so we'll
// have to be immutable instead.
MarkImmutable();
}
return true;
}
already_AddRefed<gfxASurface>
BufferTextureClient::GetAsSurface()
{
MOZ_ASSERT(IsValid());
ImageDataSerializer serializer(GetBuffer());
if (!serializer.IsValid()) {
return nullptr;
}
RefPtr<gfxImageSurface> surf = serializer.GetAsThebesSurface();
nsRefPtr<gfxASurface> result = surf.get();
return result.forget();
}
bool
BufferTextureClient::AllocateForSurface(gfx::IntSize aSize, TextureAllocationFlags aFlags)
{
MOZ_ASSERT(IsValid());
MOZ_ASSERT(mFormat != gfx::SurfaceFormat::YUV, "This textureClient cannot use YCbCr data");
MOZ_ASSERT(aSize.width * aSize.height);
int bufSize
= ImageDataSerializer::ComputeMinBufferSize(aSize, mFormat);
if (!Allocate(bufSize)) {
return false;
}
if (aFlags & ALLOC_CLEAR_BUFFER) {
memset(GetBuffer(), 0, bufSize);
}
ImageDataSerializer serializer(GetBuffer());
serializer.InitializeBufferInfo(aSize, mFormat);
mSize = aSize;
return true;
}
TemporaryRef<gfx::DrawTarget>
BufferTextureClient::GetAsDrawTarget()
{
MOZ_ASSERT(IsValid());
// XXX - Turn this into a fatal assertion as soon as Bug 952507 is fixed
NS_WARN_IF_FALSE(mLocked, "GetAsDrawTarget should be called on locked textures only");
if (mDrawTarget) {
return mDrawTarget;
}
ImageDataSerializer serializer(GetBuffer());
if (!serializer.IsValid()) {
return nullptr;
}
MOZ_ASSERT(mUsingFallbackDrawTarget == false);
mDrawTarget = serializer.GetAsDrawTarget();
if (mDrawTarget) {
return mDrawTarget;
}
// fallback path, probably because the Moz2D backend can't create a
// DrawTarget around raw memory. This is going to be slow :(
mDrawTarget = gfxPlatform::GetPlatform()->CreateOffscreenContentDrawTarget(
serializer.GetSize(), serializer.GetFormat());
if (!mDrawTarget) {
return nullptr;
}
mUsingFallbackDrawTarget = true;
if (mOpenMode & OPEN_READ) {
RefPtr<DataSourceSurface> surface = serializer.GetAsSurface();
IntRect rect(0, 0, surface->GetSize().width, surface->GetSize().height);
mDrawTarget->CopySurface(surface, rect, IntPoint(0,0));
}
return mDrawTarget;
}
bool
BufferTextureClient::Lock(OpenMode aMode)
{
// XXX - Turn this into a fatal assertion as soon as Bug 952507 is fixed
NS_WARN_IF_FALSE(!mLocked, "The TextureClient is already Locked!");
mOpenMode = aMode;
mLocked = true;
return IsValid() && IsAllocated();
}
void
BufferTextureClient::Unlock()
{
// XXX - Turn this into a fatal assertion as soon as Bug 952507 is fixed
NS_WARN_IF_FALSE(mLocked, "The TextureClient is already Unlocked!");
mLocked = false;
if (!mDrawTarget) {
mUsingFallbackDrawTarget = false;
return;
}
mDrawTarget->Flush();
if (mUsingFallbackDrawTarget && (mOpenMode & OPEN_WRITE)) {
// When we are using a fallback DrawTarget, it means we could not create
// a DrawTarget wrapping the TextureClient's shared memory. In this scenario
// we need to put the content of the fallback draw target back into our shared
// memory.
RefPtr<SourceSurface> snapshot = mDrawTarget->Snapshot();
RefPtr<DataSourceSurface> surface = snapshot->GetDataSurface();
ImageDataSerializer serializer(GetBuffer());
if (!serializer.IsValid() || serializer.GetSize() != surface->GetSize()) {
NS_WARNING("Could not write the data back into the texture.");
mDrawTarget = nullptr;
mUsingFallbackDrawTarget = false;
return;
}
MOZ_ASSERT(surface->GetSize() == serializer.GetSize());
MOZ_ASSERT(surface->GetFormat() == serializer.GetFormat());
int bpp = BytesPerPixel(surface->GetFormat());
for (int i = 0; i < surface->GetSize().height; ++i) {
memcpy(serializer.GetData() + i*serializer.GetStride(),
surface->GetData() + i*surface->Stride(),
surface->GetSize().width * bpp);
}
}
mDrawTarget = nullptr;
mUsingFallbackDrawTarget = false;
}
bool
BufferTextureClient::UpdateYCbCr(const PlanarYCbCrData& aData)
{
MOZ_ASSERT(mFormat == gfx::SurfaceFormat::YUV, "This textureClient can only use YCbCr data");
MOZ_ASSERT(!IsImmutable());
MOZ_ASSERT(IsValid());
MOZ_ASSERT(aData.mCbSkip == aData.mCrSkip);
YCbCrImageDataSerializer serializer(GetBuffer());
MOZ_ASSERT(serializer.IsValid());
if (!serializer.CopyData(aData.mYChannel, aData.mCbChannel, aData.mCrChannel,
aData.mYSize, aData.mYStride,
aData.mCbCrSize, aData.mCbCrStride,
aData.mYSkip, aData.mCbSkip)) {
NS_WARNING("Failed to copy image data!");
return false;
}
if (TextureRequiresLocking(mFlags)) {
// We don't have support for proper locking yet, so we'll
// have to be immutable instead.
MarkImmutable();
}
return true;
}
bool
BufferTextureClient::AllocateForYCbCr(gfx::IntSize aYSize,
gfx::IntSize aCbCrSize,
StereoMode aStereoMode)
{
MOZ_ASSERT(IsValid());
size_t bufSize = YCbCrImageDataSerializer::ComputeMinBufferSize(aYSize,
aCbCrSize);
if (!Allocate(bufSize)) {
return false;
}
YCbCrImageDataSerializer serializer(GetBuffer());
serializer.InitializeBufferInfo(aYSize,
aCbCrSize,
aStereoMode);
mSize = aYSize;
return true;
}
DeprecatedTextureClient::DeprecatedTextureClient(CompositableForwarder* aForwarder,
const TextureInfo& aTextureInfo)
: mForwarder(aForwarder)
, mTextureInfo(aTextureInfo)
, mAccessMode(ACCESS_READ_WRITE)
{
MOZ_COUNT_CTOR(DeprecatedTextureClient);
}
DeprecatedTextureClient::~DeprecatedTextureClient()
{
MOZ_COUNT_DTOR(DeprecatedTextureClient);
MOZ_ASSERT(mDescriptor.type() == SurfaceDescriptor::T__None, "Need to release surface!");
}
DeprecatedTextureClientShmem::DeprecatedTextureClientShmem(CompositableForwarder* aForwarder,
const TextureInfo& aTextureInfo)
: DeprecatedTextureClient(aForwarder, aTextureInfo)
{
}
DeprecatedTextureClientShmem::~DeprecatedTextureClientShmem()
{
ReleaseResources();
}
void
DeprecatedTextureClientShmem::ReleaseResources()
{
if (mSurface) {
mSurface = nullptr;
mSurfaceAsImage = nullptr;
ShadowLayerForwarder::CloseDescriptor(mDescriptor);
}
if (!(mTextureInfo.mTextureFlags & TEXTURE_DEALLOCATE_CLIENT)) {
mDescriptor = SurfaceDescriptor();
return;
}
if (IsSurfaceDescriptorValid(mDescriptor)) {
mForwarder->DestroySharedSurface(&mDescriptor);
mDescriptor = SurfaceDescriptor();
}
}
bool
DeprecatedTextureClientShmem::EnsureAllocated(gfx::IntSize aSize,
gfxContentType aContentType)
{
if (aSize != mSize ||
aContentType != mContentType ||
!IsSurfaceDescriptorValid(mDescriptor)) {
ReleaseResources();
mContentType = aContentType;
mSize = aSize;
if (!mForwarder->AllocSurfaceDescriptor(mSize, mContentType,
&mDescriptor)) {
NS_WARNING("creating SurfaceDescriptor failed!");
}
if (mContentType == gfxContentType::COLOR_ALPHA) {
gfxASurface* surface = GetSurface();
if (!surface) {
return false;
}
nsRefPtr<gfxContext> context = new gfxContext(surface);
context->SetColor(gfxRGBA(0, 0, 0, 0));
context->SetOperator(gfxContext::OPERATOR_SOURCE);
context->Paint();
}
}
return true;
}
void
DeprecatedTextureClientShmem::SetDescriptor(const SurfaceDescriptor& aDescriptor)
{
if (aDescriptor.type() == SurfaceDescriptor::Tnull_t) {
EnsureAllocated(mSize, mContentType);
return;
}
ReleaseResources();
mDescriptor = aDescriptor;
MOZ_ASSERT(!mSurface);
NS_ASSERTION(mDescriptor.type() == SurfaceDescriptor::T__None ||
mDescriptor.type() == SurfaceDescriptor::TSurfaceDescriptorGralloc ||
mDescriptor.type() == SurfaceDescriptor::TShmem ||
mDescriptor.type() == SurfaceDescriptor::TMemoryImage ||
mDescriptor.type() == SurfaceDescriptor::TRGBImage,
"Invalid surface descriptor");
}
gfxASurface*
DeprecatedTextureClientShmem::GetSurface()
{
if (!mSurface) {
if (!IsSurfaceDescriptorValid(mDescriptor)) {
return nullptr;
}
MOZ_ASSERT(mAccessMode == ACCESS_READ_WRITE || mAccessMode == ACCESS_READ_ONLY);
OpenMode mode = mAccessMode == ACCESS_READ_WRITE
? OPEN_READ_WRITE
: OPEN_READ_ONLY;
mSurface = ShadowLayerForwarder::OpenDescriptor(mode, mDescriptor);
MOZ_ASSERT(!mSurface || mSurface->GetContentType() == mContentType);
}
return mSurface.get();
}
gfx::DrawTarget*
DeprecatedTextureClientShmem::LockDrawTarget()
{
if (mDrawTarget) {
return mDrawTarget;
}
gfxASurface* surface = GetSurface();
if (!surface) {
return nullptr;
}
mDrawTarget = gfxPlatform::GetPlatform()->CreateDrawTargetForSurface(surface, mSize);
return mDrawTarget;
}
void
DeprecatedTextureClientShmem::Unlock()
{
if (mSurface) {
mSurface = nullptr;
mSurfaceAsImage = nullptr;
ShadowLayerForwarder::CloseDescriptor(mDescriptor);
}
mDrawTarget = nullptr;
}
gfxImageSurface*
DeprecatedTextureClientShmem::LockImageSurface()
{
if (!mSurfaceAsImage) {
gfxASurface* surface = GetSurface();
if (!surface) {
return nullptr;
}
mSurfaceAsImage = surface->GetAsImageSurface();
}
return mSurfaceAsImage.get();
}
DeprecatedTextureClientTile::DeprecatedTextureClientTile(const DeprecatedTextureClientTile& aOther)
: DeprecatedTextureClient(aOther.mForwarder, aOther.mTextureInfo)
, mSurface(aOther.mSurface)
{}
DeprecatedTextureClientTile::~DeprecatedTextureClientTile()
{}
void
DeprecatedTextureClientShmemYCbCr::ReleaseResources()
{
GetForwarder()->DestroySharedSurface(&mDescriptor);
}
void
DeprecatedTextureClientShmemYCbCr::SetDescriptor(const SurfaceDescriptor& aDescriptor)
{
MOZ_ASSERT(aDescriptor.type() == SurfaceDescriptor::TYCbCrImage ||
aDescriptor.type() == SurfaceDescriptor::T__None);
if (IsSurfaceDescriptorValid(mDescriptor)) {
GetForwarder()->DestroySharedSurface(&mDescriptor);
}
mDescriptor = aDescriptor;
}
void
DeprecatedTextureClientShmemYCbCr::SetDescriptorFromReply(const SurfaceDescriptor& aDescriptor)
{
MOZ_ASSERT(aDescriptor.type() == SurfaceDescriptor::TYCbCrImage);
DeprecatedSharedPlanarYCbCrImage* shYCbCr = DeprecatedSharedPlanarYCbCrImage::FromSurfaceDescriptor(aDescriptor);
if (shYCbCr) {
shYCbCr->Release();
mDescriptor = SurfaceDescriptor();
} else {
SetDescriptor(aDescriptor);
}
}
bool
DeprecatedTextureClientShmemYCbCr::EnsureAllocated(gfx::IntSize aSize,
gfxContentType aType)
{
NS_RUNTIMEABORT("not enough arguments to do this (need both Y and CbCr sizes)");
return false;
}
DeprecatedTextureClientTile::DeprecatedTextureClientTile(CompositableForwarder* aForwarder,
const TextureInfo& aTextureInfo,
gfxReusableSurfaceWrapper* aSurface)
: DeprecatedTextureClient(aForwarder, aTextureInfo)
, mSurface(aSurface)
{
mTextureInfo.mDeprecatedTextureHostFlags = TEXTURE_HOST_TILED;
}
bool
DeprecatedTextureClientTile::EnsureAllocated(gfx::IntSize aSize, gfxContentType aType)
{
if (!mSurface ||
mSurface->Format() != gfxPlatform::GetPlatform()->OptimalFormatForContent(aType)) {
#ifdef MOZ_ANDROID_OMTC
// If we're using OMTC, we can save some cycles by not using shared
// memory. Using shared memory here is a small, but significant
// performance regression.
gfxImageSurface* tmpTile = new gfxImageSurface(gfxIntSize(aSize.width, aSize.height),
gfxPlatform::GetPlatform()->OptimalFormatForContent(aType),
aType != gfxContentType::COLOR);
mSurface = new gfxReusableImageSurfaceWrapper(tmpTile);
#else
nsRefPtr<gfxSharedImageSurface> sharedImage =
gfxSharedImageSurface::CreateUnsafe(mForwarder,
gfxIntSize(aSize.width, aSize.height),
gfxPlatform::GetPlatform()->OptimalFormatForContent(aType));
mSurface = new gfxReusableSharedImageSurfaceWrapper(mForwarder, sharedImage);
#endif
mContentType = aType;
}
return true;
}
gfxImageSurface*
DeprecatedTextureClientTile::LockImageSurface()
{
// Use the gfxReusableSurfaceWrapper, which will reuse the surface
// if the compositor no longer has a read lock, otherwise the surface
// will be copied into a new writable surface.
gfxImageSurface* writableSurface = nullptr;
mSurface = mSurface->GetWritable(&writableSurface);
return writableSurface;
}
// XXX - All the code below can be removed as soon as we remove
// DeprecatedImageClientSingle (which has already been ported to the new
// textures).
bool AutoLockShmemClient::Update(Image* aImage,
uint32_t aContentFlags,
gfxASurface *aSurface)
{
if (!aImage) {
return false;
}
gfx::IntSize size = aImage->GetSize();
gfxContentType contentType = aSurface->GetContentType();
bool isOpaque = (aContentFlags & Layer::CONTENT_OPAQUE);
if (contentType != gfxContentType::ALPHA &&
isOpaque) {
contentType = gfxContentType::COLOR;
}
mDeprecatedTextureClient->EnsureAllocated(size, contentType);
OpenMode mode = mDeprecatedTextureClient->GetAccessMode() == DeprecatedTextureClient::ACCESS_READ_WRITE
? OPEN_READ_WRITE
: OPEN_READ_ONLY;
nsRefPtr<gfxASurface> tmpASurface =
ShadowLayerForwarder::OpenDescriptor(mode,
*mDeprecatedTextureClient->LockSurfaceDescriptor());
if (!tmpASurface) {
return false;
}
nsRefPtr<gfxContext> tmpCtx = new gfxContext(tmpASurface.get());
tmpCtx->SetOperator(gfxContext::OPERATOR_SOURCE);
tmpCtx->DrawSurface(aSurface, gfxSize(size.width, size.height));
return true;
}
bool
AutoLockYCbCrClient::Update(PlanarYCbCrImage* aImage)
{
MOZ_ASSERT(aImage);
MOZ_ASSERT(mDescriptor);
const PlanarYCbCrData *data = aImage->GetData();
NS_ASSERTION(data, "Must be able to retrieve yuv data from image!");
if (!data) {
return false;
}
if (!EnsureDeprecatedTextureClient(aImage)) {
return false;
}
ipc::Shmem& shmem = mDescriptor->get_YCbCrImage().data();
YCbCrImageDataSerializer serializer(shmem.get<uint8_t>());
if (!serializer.CopyData(data->mYChannel, data->mCbChannel, data->mCrChannel,
data->mYSize, data->mYStride,
data->mCbCrSize, data->mCbCrStride,
data->mYSkip, data->mCbSkip)) {
NS_WARNING("Failed to copy image data!");
return false;
}
return true;
}
bool AutoLockYCbCrClient::EnsureDeprecatedTextureClient(PlanarYCbCrImage* aImage)
{
MOZ_ASSERT(aImage);
if (!aImage) {
return false;
}
const PlanarYCbCrData *data = aImage->GetData();
NS_ASSERTION(data, "Must be able to retrieve yuv data from image!");
if (!data) {
return false;
}
bool needsAllocation = false;
if (mDescriptor->type() != SurfaceDescriptor::TYCbCrImage) {
needsAllocation = true;
} else {
ipc::Shmem& shmem = mDescriptor->get_YCbCrImage().data();
YCbCrImageDataSerializer serializer(shmem.get<uint8_t>());
if (serializer.GetYSize() != data->mYSize ||
serializer.GetCbCrSize() != data->mCbCrSize) {
needsAllocation = true;
}
}
if (!needsAllocation) {
return true;
}
mDeprecatedTextureClient->ReleaseResources();
ipc::SharedMemory::SharedMemoryType shmType = OptimalShmemType();
size_t size = YCbCrImageDataSerializer::ComputeMinBufferSize(data->mYSize,
data->mCbCrSize);
ipc::Shmem shmem;
if (!mDeprecatedTextureClient->GetForwarder()->AllocUnsafeShmem(size, shmType, &shmem)) {
return false;
}
YCbCrImageDataSerializer serializer(shmem.get<uint8_t>());
serializer.InitializeBufferInfo(data->mYSize,
data->mCbCrSize,
data->mStereoMode);
*mDescriptor = YCbCrImage(shmem, 0);
return true;
}
}
}