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chromium / chromium / src / 4950173d4782941bd49f90be89c1d77422e8ca73 / . / gpu / ipc / client / command_buffer_proxy_impl.cc
blob: 233df390153b184341d48cd12c81c88d0cd9981d [file] [log] [blame]
// Copyright (c) 2012 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "gpu/ipc/client/command_buffer_proxy_impl.h"
#include <utility>
#include <vector>
#include "base/callback.h"
#include "base/location.h"
#include "base/logging.h"
#include "base/memory/ptr_util.h"
#include "base/memory/shared_memory.h"
#include "base/optional.h"
#include "base/profiler/scoped_tracker.h"
#include "base/stl_util.h"
#include "base/threading/thread_task_runner_handle.h"
#include "base/trace_event/trace_event.h"
#include "gpu/command_buffer/client/gpu_control_client.h"
#include "gpu/command_buffer/client/gpu_memory_buffer_manager.h"
#include "gpu/command_buffer/common/cmd_buffer_common.h"
#include "gpu/command_buffer/common/command_buffer_id.h"
#include "gpu/command_buffer/common/command_buffer_shared.h"
#include "gpu/command_buffer/common/gpu_memory_allocation.h"
#include "gpu/command_buffer/common/gpu_memory_buffer_support.h"
#include "gpu/command_buffer/common/sync_token.h"
#include "gpu/ipc/client/gpu_channel_host.h"
#include "gpu/ipc/common/gpu_messages.h"
#include "gpu/ipc/common/gpu_param_traits.h"
#include "ui/gfx/geometry/size.h"
#include "ui/gl/gl_bindings.h"
#if defined(OS_MACOSX)
#include "gpu/ipc/client/gpu_process_hosted_ca_layer_tree_params.h"
#endif
namespace gpu {
namespace {
gpu::CommandBufferId CommandBufferProxyID(int channel_id, int32_t route_id) {
return gpu::CommandBufferId::FromUnsafeValue(
(static_cast<uint64_t>(channel_id) << 32) | route_id);
}
} // namespace
CommandBufferProxyImpl::CommandBufferProxyImpl(int channel_id,
int32_t route_id,
int32_t stream_id)
: lock_(nullptr),
gpu_control_client_(nullptr),
command_buffer_id_(CommandBufferProxyID(channel_id, route_id)),
route_id_(route_id),
stream_id_(stream_id),
flush_count_(0),
last_put_offset_(-1),
last_barrier_put_offset_(-1),
next_fence_sync_release_(1),
flushed_fence_sync_release_(0),
verified_fence_sync_release_(0),
next_signal_id_(0),
weak_this_(AsWeakPtr()) {
DCHECK(route_id);
DCHECK_NE(stream_id, GPU_STREAM_INVALID);
}
// static
std::unique_ptr<CommandBufferProxyImpl> CommandBufferProxyImpl::Create(
scoped_refptr<GpuChannelHost> host,
gpu::SurfaceHandle surface_handle,
CommandBufferProxyImpl* share_group,
int32_t stream_id,
gpu::GpuStreamPriority stream_priority,
const gpu::gles2::ContextCreationAttribHelper& attribs,
const GURL& active_url,
scoped_refptr<base::SingleThreadTaskRunner> task_runner) {
DCHECK(!share_group || (stream_id == share_group->stream_id_));
TRACE_EVENT1("gpu", "GpuChannelHost::CreateViewCommandBuffer",
"surface_handle", surface_handle);
GPUCreateCommandBufferConfig init_params;
init_params.surface_handle = surface_handle;
init_params.share_group_id =
share_group ? share_group->route_id_ : MSG_ROUTING_NONE;
init_params.stream_id = stream_id;
init_params.stream_priority = stream_priority;
init_params.attribs = attribs;
init_params.active_url = active_url;
int32_t route_id = host->GenerateRouteID();
std::unique_ptr<CommandBufferProxyImpl> command_buffer = base::WrapUnique(
new CommandBufferProxyImpl(host->channel_id(), route_id, stream_id));
if (!command_buffer->Initialize(std::move(host), std::move(init_params),
std::move(task_runner)))
return nullptr;
return command_buffer;
}
CommandBufferProxyImpl::~CommandBufferProxyImpl() {
for (auto& observer : deletion_observers_)
observer.OnWillDeleteImpl();
DisconnectChannel();
}
bool CommandBufferProxyImpl::OnMessageReceived(const IPC::Message& message) {
base::Optional<base::AutoLock> lock;
if (lock_)
lock.emplace(*lock_);
bool handled = true;
IPC_BEGIN_MESSAGE_MAP(CommandBufferProxyImpl, message)
IPC_MESSAGE_HANDLER(GpuCommandBufferMsg_Destroyed, OnDestroyed);
IPC_MESSAGE_HANDLER(GpuCommandBufferMsg_ConsoleMsg, OnConsoleMessage);
IPC_MESSAGE_HANDLER(GpuCommandBufferMsg_SignalAck, OnSignalAck);
IPC_MESSAGE_HANDLER(GpuCommandBufferMsg_SwapBuffersCompleted,
OnSwapBuffersCompleted);
IPC_MESSAGE_HANDLER(GpuCommandBufferMsg_UpdateVSyncParameters,
OnUpdateVSyncParameters);
IPC_MESSAGE_UNHANDLED(handled = false)
IPC_END_MESSAGE_MAP()
if (!handled) {
LOG(ERROR) << "Gpu process sent invalid message.";
base::AutoLock last_state_lock(last_state_lock_);
OnGpuAsyncMessageError(gpu::error::kInvalidGpuMessage,
gpu::error::kLostContext);
}
return handled;
}
void CommandBufferProxyImpl::OnChannelError() {
base::Optional<base::AutoLock> lock;
if (lock_)
lock.emplace(*lock_);
base::AutoLock last_state_lock(last_state_lock_);
gpu::error::ContextLostReason context_lost_reason =
gpu::error::kGpuChannelLost;
if (shared_state_shm_ && shared_state_shm_->memory()) {
// The GPU process might have intentionally been crashed
// (exit_on_context_lost), so try to find out the original reason.
TryUpdateStateDontReportError();
if (last_state_.error == gpu::error::kLostContext)
context_lost_reason = last_state_.context_lost_reason;
}
OnGpuAsyncMessageError(context_lost_reason, gpu::error::kLostContext);
}
void CommandBufferProxyImpl::OnDestroyed(gpu::error::ContextLostReason reason,
gpu::error::Error error) {
base::AutoLock lock(last_state_lock_);
OnGpuAsyncMessageError(reason, error);
}
void CommandBufferProxyImpl::OnConsoleMessage(
const GPUCommandBufferConsoleMessage& message) {
if (gpu_control_client_)
gpu_control_client_->OnGpuControlErrorMessage(message.message.c_str(),
message.id);
}
void CommandBufferProxyImpl::AddDeletionObserver(DeletionObserver* observer) {
std::unique_ptr<base::AutoLock> lock;
if (lock_)
lock.reset(new base::AutoLock(*lock_));
deletion_observers_.AddObserver(observer);
}
void CommandBufferProxyImpl::RemoveDeletionObserver(
DeletionObserver* observer) {
std::unique_ptr<base::AutoLock> lock;
if (lock_)
lock.reset(new base::AutoLock(*lock_));
deletion_observers_.RemoveObserver(observer);
}
void CommandBufferProxyImpl::OnSignalAck(uint32_t id) {
SignalTaskMap::iterator it = signal_tasks_.find(id);
if (it == signal_tasks_.end()) {
LOG(ERROR) << "Gpu process sent invalid SignalAck.";
base::AutoLock lock(last_state_lock_);
OnGpuAsyncMessageError(gpu::error::kInvalidGpuMessage,
gpu::error::kLostContext);
return;
}
base::Closure callback = it->second;
signal_tasks_.erase(it);
callback.Run();
}
bool CommandBufferProxyImpl::Initialize(
scoped_refptr<GpuChannelHost> channel,
const GPUCreateCommandBufferConfig& config,
scoped_refptr<base::SingleThreadTaskRunner> task_runner) {
DCHECK(!channel_);
TRACE_EVENT0("gpu", "CommandBufferProxyImpl::Initialize");
shared_state_shm_ =
channel->factory()->AllocateSharedMemory(sizeof(*shared_state()));
if (!shared_state_shm_)
return false;
if (!shared_state_shm_->Map(sizeof(*shared_state())))
return false;
shared_state()->Initialize();
// This handle is owned by the GPU process and must be passed to it or it
// will leak. In otherwords, do not early out on error between here and the
// sending of the CreateCommandBuffer IPC below.
base::SharedMemoryHandle handle =
channel->ShareToGpuProcess(shared_state_shm_->handle());
if (!base::SharedMemory::IsHandleValid(handle))
return false;
// TODO(vadimt): Remove ScopedTracker below once crbug.com/125248 is fixed.
tracked_objects::ScopedTracker tracking_profile(
FROM_HERE_WITH_EXPLICIT_FUNCTION(
"125248 CommandBufferProxyImpl::Initialize"));
// Route must be added before sending the message, otherwise messages sent
// from the GPU process could race against adding ourselves to the filter.
channel->AddRouteWithTaskRunner(route_id_, AsWeakPtr(), task_runner);
// We're blocking the UI thread, which is generally undesirable.
// In this case we need to wait for this before we can show any UI /anyway/,
// so it won't cause additional jank.
// TODO(piman): Make this asynchronous (http://crbug.com/125248).
bool result = false;
bool sent = channel->Send(new GpuChannelMsg_CreateCommandBuffer(
config, route_id_, handle, &result, &capabilities_));
if (!sent || !result) {
DLOG(ERROR) << "Failed to send GpuChannelMsg_CreateCommandBuffer.";
channel->RemoveRoute(route_id_);
return false;
}
channel_ = std::move(channel);
callback_thread_ = std::move(task_runner);
return true;
}
CommandBuffer::State CommandBufferProxyImpl::GetLastState() {
base::AutoLock lock(last_state_lock_);
TryUpdateState();
return last_state_;
}
void CommandBufferProxyImpl::Flush(int32_t put_offset) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return;
TRACE_EVENT1("gpu", "CommandBufferProxyImpl::Flush", "put_offset",
put_offset);
bool put_offset_changed = last_put_offset_ != put_offset;
last_put_offset_ = put_offset;
last_barrier_put_offset_ = put_offset;
if (channel_) {
uint32_t highest_verified_flush_id;
const uint32_t flush_id = channel_->OrderingBarrier(
route_id_, stream_id_, put_offset, ++flush_count_, latency_info_,
put_offset_changed, true, &highest_verified_flush_id);
if (put_offset_changed) {
DCHECK(flush_id);
const uint64_t fence_sync_release = next_fence_sync_release_ - 1;
if (fence_sync_release > flushed_fence_sync_release_) {
flushed_fence_sync_release_ = fence_sync_release;
flushed_release_flush_id_.push(
std::make_pair(fence_sync_release, flush_id));
}
}
CleanupFlushedReleases(highest_verified_flush_id);
}
if (put_offset_changed)
latency_info_.clear();
}
void CommandBufferProxyImpl::OrderingBarrier(int32_t put_offset) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return;
TRACE_EVENT1("gpu", "CommandBufferProxyImpl::OrderingBarrier", "put_offset",
put_offset);
bool put_offset_changed = last_barrier_put_offset_ != put_offset;
last_barrier_put_offset_ = put_offset;
if (channel_) {
uint32_t highest_verified_flush_id;
const uint32_t flush_id = channel_->OrderingBarrier(
route_id_, stream_id_, put_offset, ++flush_count_, latency_info_,
put_offset_changed, false, &highest_verified_flush_id);
if (put_offset_changed) {
DCHECK(flush_id);
const uint64_t fence_sync_release = next_fence_sync_release_ - 1;
if (fence_sync_release > flushed_fence_sync_release_) {
flushed_fence_sync_release_ = fence_sync_release;
flushed_release_flush_id_.push(
std::make_pair(fence_sync_release, flush_id));
}
}
CleanupFlushedReleases(highest_verified_flush_id);
}
if (put_offset_changed)
latency_info_.clear();
}
void CommandBufferProxyImpl::SetLatencyInfo(
const std::vector<ui::LatencyInfo>& latency_info) {
CheckLock();
for (size_t i = 0; i < latency_info.size(); i++)
latency_info_.push_back(latency_info[i]);
}
void CommandBufferProxyImpl::SetSwapBuffersCompletionCallback(
const SwapBuffersCompletionCallback& callback) {
CheckLock();
swap_buffers_completion_callback_ = callback;
}
void CommandBufferProxyImpl::SetUpdateVSyncParametersCallback(
const UpdateVSyncParametersCallback& callback) {
CheckLock();
update_vsync_parameters_completion_callback_ = callback;
}
void CommandBufferProxyImpl::SetNeedsVSync(bool needs_vsync) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return;
Send(new GpuCommandBufferMsg_SetNeedsVSync(route_id_, needs_vsync));
}
gpu::CommandBuffer::State CommandBufferProxyImpl::WaitForTokenInRange(
int32_t start,
int32_t end) {
CheckLock();
base::AutoLock lock(last_state_lock_);
TRACE_EVENT2("gpu", "CommandBufferProxyImpl::WaitForToken", "start", start,
"end", end);
// Error needs to be checked in case the state was updated on another thread.
// We need to make sure that the reentrant context loss callback is called so
// that the share group is also lost before we return any error up the stack.
if (last_state_.error != gpu::error::kNoError) {
if (gpu_control_client_)
gpu_control_client_->OnGpuControlLostContextMaybeReentrant();
return last_state_;
}
TryUpdateState();
if (!InRange(start, end, last_state_.token) &&
last_state_.error == gpu::error::kNoError) {
gpu::CommandBuffer::State state;
if (Send(new GpuCommandBufferMsg_WaitForTokenInRange(route_id_, start, end,
&state))) {
SetStateFromSyncReply(state);
}
}
if (!InRange(start, end, last_state_.token) &&
last_state_.error == gpu::error::kNoError) {
LOG(ERROR) << "GPU state invalid after WaitForTokenInRange.";
OnGpuSyncReplyError();
}
return last_state_;
}
gpu::CommandBuffer::State CommandBufferProxyImpl::WaitForGetOffsetInRange(
int32_t start,
int32_t end) {
CheckLock();
base::AutoLock lock(last_state_lock_);
TRACE_EVENT2("gpu", "CommandBufferProxyImpl::WaitForGetOffset", "start",
start, "end", end);
// Error needs to be checked in case the state was updated on another thread.
// We need to make sure that the reentrant context loss callback is called so
// that the share group is also lost before we return any error up the stack.
if (last_state_.error != gpu::error::kNoError) {
if (gpu_control_client_)
gpu_control_client_->OnGpuControlLostContextMaybeReentrant();
return last_state_;
}
TryUpdateState();
if (!InRange(start, end, last_state_.get_offset) &&
last_state_.error == gpu::error::kNoError) {
gpu::CommandBuffer::State state;
if (Send(new GpuCommandBufferMsg_WaitForGetOffsetInRange(route_id_, start,
end, &state)))
SetStateFromSyncReply(state);
}
if (!InRange(start, end, last_state_.get_offset) &&
last_state_.error == gpu::error::kNoError) {
LOG(ERROR) << "GPU state invalid after WaitForGetOffsetInRange.";
OnGpuSyncReplyError();
}
return last_state_;
}
void CommandBufferProxyImpl::SetGetBuffer(int32_t shm_id) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return;
Send(new GpuCommandBufferMsg_SetGetBuffer(route_id_, shm_id));
last_put_offset_ = -1;
}
scoped_refptr<gpu::Buffer> CommandBufferProxyImpl::CreateTransferBuffer(
size_t size,
int32_t* id) {
CheckLock();
base::AutoLock lock(last_state_lock_);
*id = -1;
if (last_state_.error != gpu::error::kNoError)
return NULL;
int32_t new_id = channel_->ReserveTransferBufferId();
std::unique_ptr<base::SharedMemory> shared_memory(
channel_->factory()->AllocateSharedMemory(size));
if (!shared_memory) {
if (last_state_.error == gpu::error::kNoError)
OnClientError(gpu::error::kOutOfBounds);
return NULL;
}
DCHECK(!shared_memory->memory());
if (!shared_memory->Map(size)) {
if (last_state_.error == gpu::error::kNoError)
OnClientError(gpu::error::kOutOfBounds);
return NULL;
}
// This handle is owned by the GPU process and must be passed to it or it
// will leak. In otherwords, do not early out on error between here and the
// sending of the RegisterTransferBuffer IPC below.
base::SharedMemoryHandle handle =
channel_->ShareToGpuProcess(shared_memory->handle());
if (!base::SharedMemory::IsHandleValid(handle)) {
if (last_state_.error == gpu::error::kNoError)
OnClientError(gpu::error::kLostContext);
return NULL;
}
Send(new GpuCommandBufferMsg_RegisterTransferBuffer(route_id_, new_id, handle,
size));
*id = new_id;
scoped_refptr<gpu::Buffer> buffer(
gpu::MakeBufferFromSharedMemory(std::move(shared_memory), size));
return buffer;
}
void CommandBufferProxyImpl::DestroyTransferBuffer(int32_t id) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return;
Send(new GpuCommandBufferMsg_DestroyTransferBuffer(route_id_, id));
}
void CommandBufferProxyImpl::SetGpuControlClient(GpuControlClient* client) {
CheckLock();
gpu_control_client_ = client;
}
gpu::Capabilities CommandBufferProxyImpl::GetCapabilities() {
return capabilities_;
}
int32_t CommandBufferProxyImpl::CreateImage(ClientBuffer buffer,
size_t width,
size_t height,
unsigned internal_format) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return -1;
int32_t new_id = channel_->ReserveImageId();
gpu::GpuMemoryBufferManager* gpu_memory_buffer_manager =
channel_->gpu_memory_buffer_manager();
gfx::GpuMemoryBuffer* gpu_memory_buffer =
reinterpret_cast<gfx::GpuMemoryBuffer*>(buffer);
DCHECK(gpu_memory_buffer);
// This handle is owned by the GPU process and must be passed to it or it
// will leak. In otherwords, do not early out on error between here and the
// sending of the CreateImage IPC below.
gfx::GpuMemoryBufferHandle handle =
gfx::CloneHandleForIPC(gpu_memory_buffer->GetHandle());
bool requires_sync_token = handle.type == gfx::IO_SURFACE_BUFFER;
uint64_t image_fence_sync = 0;
if (requires_sync_token) {
image_fence_sync = GenerateFenceSyncRelease();
// Make sure fence syncs were flushed before CreateImage() was called.
DCHECK_EQ(image_fence_sync, flushed_fence_sync_release_ + 1);
}
DCHECK(gpu::IsGpuMemoryBufferFormatSupported(gpu_memory_buffer->GetFormat(),
capabilities_));
DCHECK(gpu::IsImageSizeValidForGpuMemoryBufferFormat(
gfx::Size(width, height), gpu_memory_buffer->GetFormat()));
DCHECK(gpu::IsImageFormatCompatibleWithGpuMemoryBufferFormat(
internal_format, gpu_memory_buffer->GetFormat()));
GpuCommandBufferMsg_CreateImage_Params params;
params.id = new_id;
params.gpu_memory_buffer = handle;
params.size = gfx::Size(width, height);
params.format = gpu_memory_buffer->GetFormat();
params.internal_format = internal_format;
params.image_release_count = image_fence_sync;
Send(new GpuCommandBufferMsg_CreateImage(route_id_, params));
if (image_fence_sync) {
gpu::SyncToken sync_token(GetNamespaceID(), GetExtraCommandBufferData(),
GetCommandBufferID(), image_fence_sync);
// Force a synchronous IPC to validate sync token.
EnsureWorkVisible();
sync_token.SetVerifyFlush();
gpu_memory_buffer_manager->SetDestructionSyncToken(gpu_memory_buffer,
sync_token);
}
return new_id;
}
void CommandBufferProxyImpl::DestroyImage(int32_t id) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return;
Send(new GpuCommandBufferMsg_DestroyImage(route_id_, id));
}
uint32_t CommandBufferProxyImpl::CreateStreamTexture(uint32_t texture_id) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return 0;
int32_t stream_id = channel_->GenerateRouteID();
bool succeeded = false;
Send(new GpuCommandBufferMsg_CreateStreamTexture(route_id_, texture_id,
stream_id, &succeeded));
if (!succeeded) {
DLOG(ERROR) << "GpuCommandBufferMsg_CreateStreamTexture returned failure";
return 0;
}
return stream_id;
}
void CommandBufferProxyImpl::SetLock(base::Lock* lock) {
lock_ = lock;
}
void CommandBufferProxyImpl::EnsureWorkVisible() {
if (channel_)
channel_->ValidateFlushIDReachedServer(stream_id_, true);
}
gpu::CommandBufferNamespace CommandBufferProxyImpl::GetNamespaceID() const {
return gpu::CommandBufferNamespace::GPU_IO;
}
gpu::CommandBufferId CommandBufferProxyImpl::GetCommandBufferID() const {
return command_buffer_id_;
}
int32_t CommandBufferProxyImpl::GetExtraCommandBufferData() const {
return stream_id_;
}
uint64_t CommandBufferProxyImpl::GenerateFenceSyncRelease() {
CheckLock();
return next_fence_sync_release_++;
}
bool CommandBufferProxyImpl::IsFenceSyncRelease(uint64_t release) {
CheckLock();
return release != 0 && release < next_fence_sync_release_;
}
bool CommandBufferProxyImpl::IsFenceSyncFlushed(uint64_t release) {
CheckLock();
return release != 0 && release <= flushed_fence_sync_release_;
}
bool CommandBufferProxyImpl::IsFenceSyncFlushReceived(uint64_t release) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return false;
if (release <= verified_fence_sync_release_)
return true;
// Check if we have actually flushed the fence sync release.
if (release <= flushed_fence_sync_release_) {
DCHECK(!flushed_release_flush_id_.empty());
// Check if it has already been validated by another context.
UpdateVerifiedReleases(channel_->GetHighestValidatedFlushID(stream_id_));
if (release <= verified_fence_sync_release_)
return true;
// Has not been validated, validate it now.
UpdateVerifiedReleases(
channel_->ValidateFlushIDReachedServer(stream_id_, false));
return release <= verified_fence_sync_release_;
}
return false;
}
// This can be called from any thread without holding |lock_|. Use a thread-safe
// non-error throwing variant of TryUpdateState for this.
bool CommandBufferProxyImpl::IsFenceSyncReleased(uint64_t release) {
base::AutoLock lock(last_state_lock_);
TryUpdateStateThreadSafe();
return release <= last_state_.release_count;
}
void CommandBufferProxyImpl::SignalSyncToken(const gpu::SyncToken& sync_token,
const base::Closure& callback) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return;
uint32_t signal_id = next_signal_id_++;
Send(new GpuCommandBufferMsg_SignalSyncToken(route_id_, sync_token,
signal_id));
signal_tasks_.insert(std::make_pair(signal_id, callback));
}
bool CommandBufferProxyImpl::CanWaitUnverifiedSyncToken(
const gpu::SyncToken* sync_token) {
// Can only wait on an unverified sync token if it is from the same channel.
const uint64_t token_channel =
sync_token->command_buffer_id().GetUnsafeValue() >> 32;
const uint64_t channel = command_buffer_id_.GetUnsafeValue() >> 32;
if (sync_token->namespace_id() != gpu::CommandBufferNamespace::GPU_IO ||
token_channel != channel) {
return false;
}
// If waiting on a different stream, flush pending commands on that stream.
const int32_t release_stream_id = sync_token->extra_data_field();
if (release_stream_id == gpu::GPU_STREAM_INVALID)
return false;
if (release_stream_id != stream_id_)
channel_->FlushPendingStream(release_stream_id);
return true;
}
void CommandBufferProxyImpl::SignalQuery(uint32_t query,
const base::Closure& callback) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return;
// Signal identifiers are hidden, so nobody outside of this class will see
// them. (And thus, they cannot save them.) The IDs themselves only last
// until the callback is invoked, which will happen as soon as the GPU
// catches upwith the command buffer.
// A malicious caller trying to create a collision by making next_signal_id
// would have to make calls at an astounding rate (300B/s) and even if they
// could do that, all they would do is to prevent some callbacks from getting
// called, leading to stalled threads and/or memory leaks.
uint32_t signal_id = next_signal_id_++;
Send(new GpuCommandBufferMsg_SignalQuery(route_id_, query, signal_id));
signal_tasks_.insert(std::make_pair(signal_id, callback));
}
void CommandBufferProxyImpl::TakeFrontBuffer(const gpu::Mailbox& mailbox) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return;
Send(new GpuCommandBufferMsg_TakeFrontBuffer(route_id_, mailbox));
}
void CommandBufferProxyImpl::ReturnFrontBuffer(const gpu::Mailbox& mailbox,
const gpu::SyncToken& sync_token,
bool is_lost) {
CheckLock();
base::AutoLock lock(last_state_lock_);
if (last_state_.error != gpu::error::kNoError)
return;
Send(new GpuCommandBufferMsg_WaitSyncToken(route_id_, sync_token));
Send(new GpuCommandBufferMsg_ReturnFrontBuffer(route_id_, mailbox, is_lost));
}
bool CommandBufferProxyImpl::Send(IPC::Message* msg) {
DCHECK(channel_);
last_state_lock_.AssertAcquired();
DCHECK_EQ(gpu::error::kNoError, last_state_.error);
last_state_lock_.Release();
// Call is_sync() before sending message.
bool is_sync = msg->is_sync();
bool result = channel_->Send(msg);
// Send() should always return true for async messages.
DCHECK(is_sync || result);
last_state_lock_.Acquire();
if (last_state_.error != gpu::error::kNoError) {
// Error needs to be checked in case the state was updated on another thread
// while we were waiting on Send. We need to make sure that the reentrant
// context loss callback is called so that the share group is also lost
// before we return any error up the stack.
if (gpu_control_client_)
gpu_control_client_->OnGpuControlLostContextMaybeReentrant();
return false;
}
if (!result) {
// Flag the command buffer as lost. Defer deleting the channel until
// OnChannelError is called after returning to the message loop in case it
// is referenced elsewhere.
DVLOG(1) << "CommandBufferProxyImpl::Send failed. Losing context.";
OnClientError(gpu::error::kLostContext);
return false;
}
return true;
}
void CommandBufferProxyImpl::SetStateFromSyncReply(
const gpu::CommandBuffer::State& state) {
CheckLock();
last_state_lock_.AssertAcquired();
// Handle wraparound. It works as long as we don't have more than 2B state
// updates in flight across which reordering occurs.
if (state.generation - last_state_.generation < 0x80000000U)
last_state_ = state;
if (last_state_.error != gpu::error::kNoError)
OnGpuStateError();
}
void CommandBufferProxyImpl::TryUpdateState() {
CheckLock();
last_state_lock_.AssertAcquired();
if (last_state_.error == gpu::error::kNoError) {
shared_state()->Read(&last_state_);
if (last_state_.error != gpu::error::kNoError)
OnGpuStateError();
}
}
void CommandBufferProxyImpl::TryUpdateStateThreadSafe() {
last_state_lock_.AssertAcquired();
if (last_state_.error == gpu::error::kNoError) {
shared_state()->Read(&last_state_);
if (last_state_.error != gpu::error::kNoError) {
callback_thread_->PostTask(
FROM_HERE,
base::Bind(&CommandBufferProxyImpl::LockAndDisconnectChannel,
weak_this_));
}
}
}
void CommandBufferProxyImpl::TryUpdateStateDontReportError() {
last_state_lock_.AssertAcquired();
if (last_state_.error == gpu::error::kNoError)
shared_state()->Read(&last_state_);
}
void CommandBufferProxyImpl::UpdateVerifiedReleases(uint32_t verified_flush) {
while (!flushed_release_flush_id_.empty()) {
const std::pair<uint64_t, uint32_t>& front_item =
flushed_release_flush_id_.front();
if (front_item.second > verified_flush)
break;
verified_fence_sync_release_ = front_item.first;
flushed_release_flush_id_.pop();
}
}
void CommandBufferProxyImpl::CleanupFlushedReleases(
uint32_t highest_verified_flush_id) {
DCHECK(channel_);
static const uint32_t kMaxUnverifiedFlushes = 1000;
if (flushed_release_flush_id_.size() > kMaxUnverifiedFlushes) {
// Prevent list of unverified flushes from growing indefinitely.
highest_verified_flush_id =
channel_->ValidateFlushIDReachedServer(stream_id_, false);
}
UpdateVerifiedReleases(highest_verified_flush_id);
}
gpu::CommandBufferSharedState* CommandBufferProxyImpl::shared_state() const {
return reinterpret_cast<gpu::CommandBufferSharedState*>(
shared_state_shm_->memory());
}
void CommandBufferProxyImpl::OnSwapBuffersCompleted(
const GpuCommandBufferMsg_SwapBuffersCompleted_Params& params) {
#if defined(OS_MACOSX)
gpu::GpuProcessHostedCALayerTreeParamsMac params_mac;
params_mac.ca_context_id = params.ca_context_id;
params_mac.fullscreen_low_power_ca_context_valid =
params.fullscreen_low_power_ca_context_valid;
params_mac.fullscreen_low_power_ca_context_id =
params.fullscreen_low_power_ca_context_id;
params_mac.io_surface.reset(IOSurfaceLookupFromMachPort(params.io_surface));
params_mac.pixel_size = params.pixel_size;
params_mac.scale_factor = params.scale_factor;
params_mac.responses = std::move(params.in_use_responses);
gpu::GpuProcessHostedCALayerTreeParamsMac* mac_frame_ptr = &params_mac;
#else
gpu::GpuProcessHostedCALayerTreeParamsMac* mac_frame_ptr = nullptr;
#endif
if (!swap_buffers_completion_callback_.is_null()) {
if (!ui::LatencyInfo::Verify(
params.latency_info,
"CommandBufferProxyImpl::OnSwapBuffersCompleted")) {
swap_buffers_completion_callback_.Run(std::vector<ui::LatencyInfo>(),
params.result, mac_frame_ptr);
} else {
swap_buffers_completion_callback_.Run(params.latency_info, params.result,
mac_frame_ptr);
}
}
}
void CommandBufferProxyImpl::OnUpdateVSyncParameters(base::TimeTicks timebase,
base::TimeDelta interval) {
if (!update_vsync_parameters_completion_callback_.is_null())
update_vsync_parameters_completion_callback_.Run(timebase, interval);
}
void CommandBufferProxyImpl::OnGpuSyncReplyError() {
CheckLock();
last_state_lock_.AssertAcquired();
last_state_.error = gpu::error::kLostContext;
last_state_.context_lost_reason = gpu::error::kInvalidGpuMessage;
// This method may be inside a callstack from the GpuControlClient (we got a
// bad reply to something we are sending to the GPU process). So avoid
// re-entering the GpuControlClient here.
DisconnectChannelInFreshCallStack();
}
void CommandBufferProxyImpl::OnGpuAsyncMessageError(
gpu::error::ContextLostReason reason,
gpu::error::Error error) {
CheckLock();
last_state_lock_.AssertAcquired();
last_state_.error = error;
last_state_.context_lost_reason = reason;
// This method only occurs when receiving IPC messages, so we know it's not in
// a callstack from the GpuControlClient. Unlock the state lock to prevent
// a deadlock when calling the context loss callback.
base::AutoUnlock unlock(last_state_lock_);
DisconnectChannel();
}
void CommandBufferProxyImpl::OnGpuStateError() {
CheckLock();
last_state_lock_.AssertAcquired();
DCHECK_NE(gpu::error::kNoError, last_state_.error);
// This method may be inside a callstack from the GpuControlClient (we
// encountered an error while trying to perform some action). So avoid
// re-entering the GpuControlClient here.
DisconnectChannelInFreshCallStack();
}
void CommandBufferProxyImpl::OnClientError(gpu::error::Error error) {
CheckLock();
last_state_lock_.AssertAcquired();
last_state_.error = error;
last_state_.context_lost_reason = gpu::error::kUnknown;
// This method may be inside a callstack from the GpuControlClient (we
// encountered an error while trying to perform some action). So avoid
// re-entering the GpuControlClient here.
DisconnectChannelInFreshCallStack();
}
void CommandBufferProxyImpl::DisconnectChannelInFreshCallStack() {
CheckLock();
last_state_lock_.AssertAcquired();
// Inform the GpuControlClient of the lost state immediately, though this may
// be a re-entrant call to the client so we use the MaybeReentrant variant.
if (gpu_control_client_)
gpu_control_client_->OnGpuControlLostContextMaybeReentrant();
// Create a fresh call stack to keep the |channel_| alive while we unwind the
// stack in case things will use it, and give the GpuChannelClient a chance to
// act fully on the lost context.
callback_thread_->PostTask(
FROM_HERE, base::Bind(&CommandBufferProxyImpl::LockAndDisconnectChannel,
weak_this_));
}
void CommandBufferProxyImpl::LockAndDisconnectChannel() {
base::Optional<base::AutoLock> hold;
if (lock_)
hold.emplace(*lock_);
DisconnectChannel();
}
void CommandBufferProxyImpl::DisconnectChannel() {
CheckLock();
// Prevent any further messages from being sent, and ensure we only call
// the client for lost context a single time.
if (!channel_)
return;
channel_->FlushPendingStream(stream_id_);
channel_->Send(new GpuChannelMsg_DestroyCommandBuffer(route_id_));
channel_->RemoveRoute(route_id_);
channel_ = nullptr;
if (gpu_control_client_)
gpu_control_client_->OnGpuControlLostContext();
}
} // namespace gpu