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android / platform / external / chromium_org / afae5d83d66c1d041a1fa433fbb087c5cc604b67 / . / content / browser / renderer_host / media / web_contents_video_capture_device.cc
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// 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.
//
// Implementation notes: This needs to work on a variety of hardware
// configurations where the speed of the CPU and GPU greatly affect overall
// performance. Spanning several threads, the process of capturing has been
// split up into four conceptual stages:
//
// 1. Reserve Buffer: Before a frame can be captured, a slot in the client's
// shared-memory IPC buffer is reserved. There are only a few of these;
// when they run out, it indicates that the downstream client -- likely a
// video encoder -- is the performance bottleneck, and that the rate of
// frame capture should be throttled back.
//
// 2. Capture: A bitmap is snapshotted/copied from the RenderView's backing
// store. This is initiated on the UI BrowserThread, and often occurs
// asynchronously. Where supported, the GPU scales and color converts
// frames to our desired size, and the readback happens directly into the
// shared-memory buffer. But this is not always possible, particularly when
// accelerated compositing is disabled.
//
// 3. Render (if needed): If the web contents cannot be captured directly into
// our target size and color format, scaling and colorspace conversion must
// be done on the CPU. A dedicated thread is used for this operation, to
// avoid blocking the UI thread. The Render stage always reads from a
// bitmap returned by Capture, and writes into the reserved slot in the
// shared-memory buffer.
//
// 4. Deliver: The rendered video frame is returned to the client (which
// implements the VideoCaptureDevice::Client interface). Because all
// paths have written the frame into the IPC buffer, this step should
// never need to do an additional copy of the pixel data.
//
// In the best-performing case, the Render step is bypassed: Capture produces
// ready-to-Deliver frames. But when accelerated readback is not possible, the
// system is designed so that Capture and Render may run concurrently. A timing
// diagram helps illustrate this point (@30 FPS):
//
// Time: 0ms 33ms 66ms 99ms
// thread1: |-Capture-f1------v |-Capture-f2------v |-Capture-f3----v |-Capt
// thread2: |-Render-f1-----v |-Render-f2-----v |-Render-f3
//
// In the above example, both capturing and rendering *each* take almost the
// full 33 ms available between frames, yet we see that the required throughput
// is obtained.
//
// Turning on verbose logging will cause the effective frame rate to be logged
// at 5-second intervals.
#include "content/browser/renderer_host/media/web_contents_video_capture_device.h"
#include "base/basictypes.h"
#include "base/bind.h"
#include "base/callback_helpers.h"
#include "base/logging.h"
#include "base/memory/scoped_ptr.h"
#include "base/message_loop/message_loop_proxy.h"
#include "base/metrics/histogram.h"
#include "base/sequenced_task_runner.h"
#include "base/threading/thread.h"
#include "base/threading/thread_checker.h"
#include "base/time/time.h"
#include "content/browser/renderer_host/media/video_capture_device_impl.h"
#include "content/browser/renderer_host/media/video_capture_oracle.h"
#include "content/browser/renderer_host/media/web_contents_capture_util.h"
#include "content/browser/renderer_host/render_widget_host_impl.h"
#include "content/browser/web_contents/web_contents_impl.h"
#include "content/port/browser/render_widget_host_view_frame_subscriber.h"
#include "content/port/browser/render_widget_host_view_port.h"
#include "content/public/browser/browser_thread.h"
#include "content/public/browser/notification_source.h"
#include "content/public/browser/notification_types.h"
#include "content/public/browser/render_view_host.h"
#include "content/public/browser/render_widget_host_view.h"
#include "content/public/browser/web_contents_observer.h"
#include "media/base/video_util.h"
#include "media/video/capture/video_capture_types.h"
#include "skia/ext/image_operations.h"
#include "third_party/skia/include/core/SkBitmap.h"
#include "third_party/skia/include/core/SkColor.h"
namespace content {
namespace {
// Compute a letterbox region, aligned to even coordinates.
gfx::Rect ComputeYV12LetterboxRegion(const gfx::Size& frame_size,
const gfx::Size& content_size) {
gfx::Rect result = media::ComputeLetterboxRegion(gfx::Rect(frame_size),
content_size);
result.set_x(MakeEven(result.x()));
result.set_y(MakeEven(result.y()));
result.set_width(std::max(kMinFrameWidth, MakeEven(result.width())));
result.set_height(std::max(kMinFrameHeight, MakeEven(result.height())));
return result;
}
// Wrapper function to invoke ThreadSafeCaptureOracle::CaptureFrameCallback, is
// compatible with RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback.
void InvokeCaptureFrameCallback(
const ThreadSafeCaptureOracle::CaptureFrameCallback& capture_frame_cb,
base::Time timestamp,
bool frame_captured) {
capture_frame_cb.Run(timestamp, frame_captured);
}
// FrameSubscriber is a proxy to the ThreadSafeCaptureOracle that's compatible
// with RenderWidgetHostViewFrameSubscriber. We create one per event type.
class FrameSubscriber : public RenderWidgetHostViewFrameSubscriber {
public:
FrameSubscriber(VideoCaptureOracle::Event event_type,
const scoped_refptr<ThreadSafeCaptureOracle>& oracle)
: event_type_(event_type),
oracle_proxy_(oracle) {}
virtual bool ShouldCaptureFrame(
base::Time present_time,
scoped_refptr<media::VideoFrame>* storage,
RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback*
deliver_frame_cb) OVERRIDE;
private:
const VideoCaptureOracle::Event event_type_;
scoped_refptr<ThreadSafeCaptureOracle> oracle_proxy_;
};
// ContentCaptureSubscription is the relationship between a RenderWidgetHost
// whose content is updating, a subscriber that is deciding which of these
// updates to capture (and where to deliver them to), and a callback that
// knows how to do the capture and prepare the result for delivery.
//
// In practice, this means (a) installing a RenderWidgetHostFrameSubscriber in
// the RenderWidgetHostView, to process updates that occur via accelerated
// compositing, (b) installing itself as an observer of updates to the
// RenderWidgetHost's backing store, to hook updates that occur via software
// rendering, and (c) running a timer to possibly initiate non-event-driven
// captures that the subscriber might request.
//
// All of this happens on the UI thread, although the
// RenderWidgetHostViewFrameSubscriber we install may be dispatching updates
// autonomously on some other thread.
class ContentCaptureSubscription : public content::NotificationObserver {
public:
typedef base::Callback<void(
const base::Time&,
const scoped_refptr<media::VideoFrame>&,
const RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback&)>
CaptureCallback;
// Create a subscription. Whenever a manual capture is required, the
// subscription will invoke |capture_callback| on the UI thread to do the
// work.
ContentCaptureSubscription(
const RenderWidgetHost& source,
const scoped_refptr<ThreadSafeCaptureOracle>& oracle_proxy,
const CaptureCallback& capture_callback);
virtual ~ContentCaptureSubscription();
// content::NotificationObserver implementation.
virtual void Observe(int type,
const content::NotificationSource& source,
const content::NotificationDetails& details) OVERRIDE;
private:
void OnTimer();
const int render_process_id_;
const int render_view_id_;
FrameSubscriber paint_subscriber_;
FrameSubscriber timer_subscriber_;
content::NotificationRegistrar registrar_;
CaptureCallback capture_callback_;
base::Timer timer_;
DISALLOW_COPY_AND_ASSIGN(ContentCaptureSubscription);
};
// Render the SkBitmap |input| into the given VideoFrame buffer |output|, then
// invoke |done_cb| to indicate success or failure. |input| is expected to be
// ARGB. |output| must be YV12 or I420. Colorspace conversion is always done.
// Scaling and letterboxing will be done as needed.
//
// This software implementation should be used only when GPU acceleration of
// these activities is not possible. This operation may be expensive (tens to
// hundreds of milliseconds), so the caller should ensure that it runs on a
// thread where such a pause would cause UI jank.
void RenderVideoFrame(const SkBitmap& input,
const scoped_refptr<media::VideoFrame>& output,
const base::Callback<void(bool)>& done_cb);
// Keeps track of the RenderView to be sourced, and executes copying of the
// backing store on the UI BrowserThread.
//
// TODO(nick): It would be nice to merge this with WebContentsTracker, but its
// implementation is currently asynchronous -- in our case, the "rvh changed"
// notification would get posted back to the UI thread and processed later, and
// this seems disadvantageous.
class WebContentsCaptureMachine
: public VideoCaptureMachine,
public WebContentsObserver,
public base::SupportsWeakPtr<WebContentsCaptureMachine> {
public:
WebContentsCaptureMachine(int render_process_id, int render_view_id);
virtual ~WebContentsCaptureMachine();
// VideoCaptureMachine overrides.
virtual bool Start(
const scoped_refptr<ThreadSafeCaptureOracle>& oracle_proxy) OVERRIDE;
virtual void Stop() OVERRIDE;
// Starts a copy from the backing store or the composited surface. Must be run
// on the UI BrowserThread. |deliver_frame_cb| will be run when the operation
// completes. The copy will occur to |target|.
//
// This may be used as a ContentCaptureSubscription::CaptureCallback.
void Capture(
const base::Time& start_time,
const scoped_refptr<media::VideoFrame>& target,
const RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback&
deliver_frame_cb);
// content::WebContentsObserver implementation.
virtual void DidShowFullscreenWidget(int routing_id) OVERRIDE {
fullscreen_widget_id_ = routing_id;
RenewFrameSubscription();
}
virtual void DidDestroyFullscreenWidget(int routing_id) OVERRIDE {
DCHECK_EQ(fullscreen_widget_id_, routing_id);
fullscreen_widget_id_ = MSG_ROUTING_NONE;
RenewFrameSubscription();
}
virtual void RenderViewReady() OVERRIDE {
RenewFrameSubscription();
}
virtual void AboutToNavigateRenderView(RenderViewHost* rvh) OVERRIDE {
RenewFrameSubscription();
}
virtual void DidNavigateMainFrame(
const LoadCommittedDetails& details,
const FrameNavigateParams& params) OVERRIDE {
RenewFrameSubscription();
}
virtual void WebContentsDestroyed(WebContents* web_contents) OVERRIDE;
private:
// Starts observing the web contents, returning false if lookup fails.
bool StartObservingWebContents();
// Helper function to determine the view that we are currently tracking.
RenderWidgetHost* GetTarget();
// Response callback for RenderWidgetHost::CopyFromBackingStore().
void DidCopyFromBackingStore(
const base::Time& start_time,
const scoped_refptr<media::VideoFrame>& target,
const RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback&
deliver_frame_cb,
bool success,
const SkBitmap& bitmap);
// Response callback for RWHVP::CopyFromCompositingSurfaceToVideoFrame().
void DidCopyFromCompositingSurfaceToVideoFrame(
const base::Time& start_time,
const RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback&
deliver_frame_cb,
bool success);
// Remove the old subscription, and start a new one. This should be called
// after any change to the WebContents that affects the RenderWidgetHost or
// attached views.
void RenewFrameSubscription();
// Parameters saved in constructor.
const int initial_render_process_id_;
const int initial_render_view_id_;
// A dedicated worker thread on which SkBitmap->VideoFrame conversion will
// occur. Only used when this activity cannot be done on the GPU.
base::Thread render_thread_;
// Makes all the decisions about which frames to copy, and how.
scoped_refptr<ThreadSafeCaptureOracle> oracle_proxy_;
// Routing ID of any active fullscreen render widget or MSG_ROUTING_NONE
// otherwise.
int fullscreen_widget_id_;
// Last known RenderView size.
gfx::Size last_view_size_;
// Responsible for forwarding events from the active RenderWidgetHost to the
// oracle, and initiating captures accordingly.
scoped_ptr<ContentCaptureSubscription> subscription_;
DISALLOW_COPY_AND_ASSIGN(WebContentsCaptureMachine);
};
// Responsible for logging the effective frame rate.
// TODO(nick): Make this compatible with the push model and hook it back up.
class VideoFrameDeliveryLog {
public:
VideoFrameDeliveryLog();
// Treat |frame_number| as having been delivered, and update the
// frame rate statistics accordingly.
void ChronicleFrameDelivery(int frame_number);
private:
// The following keep track of and log the effective frame rate whenever
// verbose logging is turned on.
base::Time last_frame_rate_log_time_;
int count_frames_rendered_;
int last_frame_number_;
DISALLOW_COPY_AND_ASSIGN(VideoFrameDeliveryLog);
};
bool FrameSubscriber::ShouldCaptureFrame(
base::Time present_time,
scoped_refptr<media::VideoFrame>* storage,
DeliverFrameCallback* deliver_frame_cb) {
TRACE_EVENT1("mirroring", "FrameSubscriber::ShouldCaptureFrame",
"instance", this);
ThreadSafeCaptureOracle::CaptureFrameCallback capture_frame_cb;
bool oracle_decision = oracle_proxy_->ObserveEventAndDecideCapture(
event_type_, present_time, storage, &capture_frame_cb);
*deliver_frame_cb = base::Bind(&InvokeCaptureFrameCallback, capture_frame_cb);
return oracle_decision;
}
ContentCaptureSubscription::ContentCaptureSubscription(
const RenderWidgetHost& source,
const scoped_refptr<ThreadSafeCaptureOracle>& oracle_proxy,
const CaptureCallback& capture_callback)
: render_process_id_(source.GetProcess()->GetID()),
render_view_id_(source.GetRoutingID()),
paint_subscriber_(VideoCaptureOracle::kSoftwarePaint, oracle_proxy),
timer_subscriber_(VideoCaptureOracle::kTimerPoll, oracle_proxy),
capture_callback_(capture_callback),
timer_(true, true) {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
RenderWidgetHostViewPort* view =
RenderWidgetHostViewPort::FromRWHV(source.GetView());
// Subscribe to accelerated presents. These will be serviced directly by the
// oracle.
if (view && kAcceleratedSubscriberIsSupported) {
scoped_ptr<RenderWidgetHostViewFrameSubscriber> subscriber(
new FrameSubscriber(VideoCaptureOracle::kCompositorUpdate,
oracle_proxy));
view->BeginFrameSubscription(subscriber.Pass());
}
// Subscribe to software paint events. This instance will service these by
// reflecting them back to the WebContentsCaptureMachine via
// |capture_callback|.
registrar_.Add(
this, content::NOTIFICATION_RENDER_WIDGET_HOST_DID_UPDATE_BACKING_STORE,
Source<RenderWidgetHost>(&source));
// Subscribe to timer events. This instance will service these as well.
timer_.Start(FROM_HERE, oracle_proxy->capture_period(),
base::Bind(&ContentCaptureSubscription::OnTimer,
base::Unretained(this)));
}
ContentCaptureSubscription::~ContentCaptureSubscription() {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
if (kAcceleratedSubscriberIsSupported) {
RenderViewHost* source = RenderViewHost::FromID(render_process_id_,
render_view_id_);
if (source) {
RenderWidgetHostViewPort* view =
RenderWidgetHostViewPort::FromRWHV(source->GetView());
if (view)
view->EndFrameSubscription();
}
}
}
void ContentCaptureSubscription::Observe(
int type,
const content::NotificationSource& source,
const content::NotificationDetails& details) {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
DCHECK_EQ(NOTIFICATION_RENDER_WIDGET_HOST_DID_UPDATE_BACKING_STORE, type);
RenderWidgetHostImpl* rwh =
RenderWidgetHostImpl::From(Source<RenderWidgetHost>(source).ptr());
// This message occurs on window resizes and visibility changes even when
// accelerated compositing is active, so we need to filter out these cases.
if (!rwh || !rwh->GetView() || (rwh->is_accelerated_compositing_active() &&
rwh->GetView()->IsSurfaceAvailableForCopy()))
return;
TRACE_EVENT1("mirroring", "ContentCaptureSubscription::Observe",
"instance", this);
base::Closure copy_done_callback;
scoped_refptr<media::VideoFrame> frame;
RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback deliver_frame_cb;
const base::Time start_time = base::Time::Now();
if (paint_subscriber_.ShouldCaptureFrame(start_time,
&frame,
&deliver_frame_cb)) {
// This message happens just before paint. If we post a task to do the copy,
// it should run soon after the paint.
BrowserThread::PostTask(
BrowserThread::UI, FROM_HERE,
base::Bind(capture_callback_, start_time, frame, deliver_frame_cb));
}
}
void ContentCaptureSubscription::OnTimer() {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
TRACE_EVENT0("mirroring", "ContentCaptureSubscription::OnTimer");
scoped_refptr<media::VideoFrame> frame;
RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback deliver_frame_cb;
const base::Time start_time = base::Time::Now();
if (timer_subscriber_.ShouldCaptureFrame(start_time,
&frame,
&deliver_frame_cb)) {
capture_callback_.Run(start_time, frame, deliver_frame_cb);
}
}
void RenderVideoFrame(const SkBitmap& input,
const scoped_refptr<media::VideoFrame>& output,
const base::Callback<void(bool)>& done_cb) {
base::ScopedClosureRunner failure_handler(base::Bind(done_cb, false));
SkAutoLockPixels locker(input);
// Sanity-check the captured bitmap.
if (input.empty() ||
!input.readyToDraw() ||
input.config() != SkBitmap::kARGB_8888_Config ||
input.width() < 2 || input.height() < 2) {
DVLOG(1) << "input unacceptable (size="
<< input.getSize()
<< ", ready=" << input.readyToDraw()
<< ", config=" << input.config() << ')';
return;
}
// Sanity-check the output buffer.
if (output->format() != media::VideoFrame::I420) {
NOTREACHED();
return;
}
// Calculate the width and height of the content region in the |output|, based
// on the aspect ratio of |input|.
gfx::Rect region_in_frame = ComputeYV12LetterboxRegion(
output->coded_size(), gfx::Size(input.width(), input.height()));
// Scale the bitmap to the required size, if necessary.
SkBitmap scaled_bitmap;
if (input.width() != region_in_frame.width() ||
input.height() != region_in_frame.height()) {
skia::ImageOperations::ResizeMethod method;
if (input.width() < region_in_frame.width() ||
input.height() < region_in_frame.height()) {
// Avoid box filtering when magnifying, because it's actually
// nearest-neighbor.
method = skia::ImageOperations::RESIZE_HAMMING1;
} else {
method = skia::ImageOperations::RESIZE_BOX;
}
TRACE_EVENT_ASYNC_STEP_INTO0("mirroring", "Capture", output.get(), "Scale");
scaled_bitmap = skia::ImageOperations::Resize(input, method,
region_in_frame.width(),
region_in_frame.height());
} else {
scaled_bitmap = input;
}
TRACE_EVENT_ASYNC_STEP_INTO0("mirroring", "Capture", output.get(), "YUV");
{
SkAutoLockPixels scaled_bitmap_locker(scaled_bitmap);
media::CopyRGBToVideoFrame(
reinterpret_cast<uint8*>(scaled_bitmap.getPixels()),
scaled_bitmap.rowBytes(),
region_in_frame,
output.get());
}
// The result is now ready.
ignore_result(failure_handler.Release());
done_cb.Run(true);
}
VideoFrameDeliveryLog::VideoFrameDeliveryLog()
: last_frame_rate_log_time_(),
count_frames_rendered_(0),
last_frame_number_(0) {
}
void VideoFrameDeliveryLog::ChronicleFrameDelivery(int frame_number) {
// Log frame rate, if verbose logging is turned on.
static const base::TimeDelta kFrameRateLogInterval =
base::TimeDelta::FromSeconds(10);
const base::Time now = base::Time::Now();
if (last_frame_rate_log_time_.is_null()) {
last_frame_rate_log_time_ = now;
count_frames_rendered_ = 0;
last_frame_number_ = frame_number;
} else {
++count_frames_rendered_;
const base::TimeDelta elapsed = now - last_frame_rate_log_time_;
if (elapsed >= kFrameRateLogInterval) {
const double measured_fps =
count_frames_rendered_ / elapsed.InSecondsF();
const int frames_elapsed = frame_number - last_frame_number_;
const int count_frames_dropped = frames_elapsed - count_frames_rendered_;
DCHECK_LE(0, count_frames_dropped);
UMA_HISTOGRAM_PERCENTAGE(
"TabCapture.FrameDropPercentage",
(count_frames_dropped * 100 + frames_elapsed / 2) / frames_elapsed);
UMA_HISTOGRAM_COUNTS(
"TabCapture.FrameRate",
static_cast<int>(measured_fps));
VLOG(1) << "Current measured frame rate for "
<< "WebContentsVideoCaptureDevice is " << measured_fps << " FPS.";
last_frame_rate_log_time_ = now;
count_frames_rendered_ = 0;
last_frame_number_ = frame_number;
}
}
}
WebContentsCaptureMachine::WebContentsCaptureMachine(int render_process_id,
int render_view_id)
: initial_render_process_id_(render_process_id),
initial_render_view_id_(render_view_id),
render_thread_("WebContentsVideo_RenderThread"),
fullscreen_widget_id_(MSG_ROUTING_NONE) {}
WebContentsCaptureMachine::~WebContentsCaptureMachine() {}
bool WebContentsCaptureMachine::Start(
const scoped_refptr<ThreadSafeCaptureOracle>& oracle_proxy) {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
DCHECK(!started_);
DCHECK(oracle_proxy.get());
oracle_proxy_ = oracle_proxy;
if (!render_thread_.Start()) {
DVLOG(1) << "Failed to spawn render thread.";
return false;
}
if (!StartObservingWebContents())
return false;
started_ = true;
return true;
}
void WebContentsCaptureMachine::Stop() {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
subscription_.reset();
if (web_contents()) {
web_contents()->DecrementCapturerCount();
Observe(NULL);
}
render_thread_.Stop();
started_ = false;
}
void WebContentsCaptureMachine::Capture(
const base::Time& start_time,
const scoped_refptr<media::VideoFrame>& target,
const RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback&
deliver_frame_cb) {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
RenderWidgetHost* rwh = GetTarget();
RenderWidgetHostViewPort* view =
rwh ? RenderWidgetHostViewPort::FromRWHV(rwh->GetView()) : NULL;
if (!view || !rwh) {
deliver_frame_cb.Run(base::Time(), false);
return;
}
gfx::Size video_size = target->coded_size();
gfx::Size view_size = view->GetViewBounds().size();
gfx::Size fitted_size;
if (!view_size.IsEmpty()) {
fitted_size = ComputeYV12LetterboxRegion(video_size, view_size).size();
}
if (view_size != last_view_size_) {
last_view_size_ = view_size;
// Measure the number of kilopixels.
UMA_HISTOGRAM_COUNTS_10000(
"TabCapture.ViewChangeKiloPixels",
view_size.width() * view_size.height() / 1024);
}
if (!view->IsSurfaceAvailableForCopy()) {
// Fallback to the more expensive renderer-side copy if the surface and
// backing store are not accessible.
rwh->GetSnapshotFromRenderer(
gfx::Rect(),
base::Bind(&WebContentsCaptureMachine::DidCopyFromBackingStore,
this->AsWeakPtr(), start_time, target, deliver_frame_cb));
} else if (view->CanCopyToVideoFrame()) {
view->CopyFromCompositingSurfaceToVideoFrame(
gfx::Rect(view_size),
target,
base::Bind(&WebContentsCaptureMachine::
DidCopyFromCompositingSurfaceToVideoFrame,
this->AsWeakPtr(), start_time, deliver_frame_cb));
} else {
rwh->CopyFromBackingStore(
gfx::Rect(),
fitted_size, // Size here is a request not always honored.
base::Bind(&WebContentsCaptureMachine::DidCopyFromBackingStore,
this->AsWeakPtr(), start_time, target, deliver_frame_cb));
}
}
bool WebContentsCaptureMachine::StartObservingWebContents() {
// Look-up the RenderViewHost and, from that, the WebContents that wraps it.
// If successful, begin observing the WebContents instance.
//
// Why this can be unsuccessful: The request for mirroring originates in a
// render process, and this request is based on the current RenderView
// associated with a tab. However, by the time we get up-and-running here,
// there have been multiple back-and-forth IPCs between processes, as well as
// a bit of indirection across threads. It's easily possible that, in the
// meantime, the original RenderView may have gone away.
RenderViewHost* const rvh =
RenderViewHost::FromID(initial_render_process_id_,
initial_render_view_id_);
DVLOG_IF(1, !rvh) << "RenderViewHost::FromID("
<< initial_render_process_id_ << ", "
<< initial_render_view_id_ << ") returned NULL.";
Observe(rvh ? WebContents::FromRenderViewHost(rvh) : NULL);
WebContentsImpl* contents = static_cast<WebContentsImpl*>(web_contents());
if (contents) {
contents->IncrementCapturerCount();
fullscreen_widget_id_ = contents->GetFullscreenWidgetRoutingID();
RenewFrameSubscription();
return true;
}
DVLOG(1) << "WebContents::FromRenderViewHost(" << rvh << ") returned NULL.";
return false;
}
void WebContentsCaptureMachine::WebContentsDestroyed(
WebContents* web_contents) {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
subscription_.reset();
web_contents->DecrementCapturerCount();
oracle_proxy_->ReportError();
}
RenderWidgetHost* WebContentsCaptureMachine::GetTarget() {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
if (!web_contents())
return NULL;
RenderWidgetHost* rwh = NULL;
if (fullscreen_widget_id_ != MSG_ROUTING_NONE) {
RenderProcessHost* process = web_contents()->GetRenderProcessHost();
if (process)
rwh = RenderWidgetHost::FromID(process->GetID(), fullscreen_widget_id_);
} else {
rwh = web_contents()->GetRenderViewHost();
}
return rwh;
}
void WebContentsCaptureMachine::DidCopyFromBackingStore(
const base::Time& start_time,
const scoped_refptr<media::VideoFrame>& target,
const RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback&
deliver_frame_cb,
bool success,
const SkBitmap& bitmap) {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
base::Time now = base::Time::Now();
if (success) {
UMA_HISTOGRAM_TIMES("TabCapture.CopyTimeBitmap", now - start_time);
TRACE_EVENT_ASYNC_STEP_INTO0("mirroring", "Capture", target.get(),
"Render");
render_thread_.message_loop_proxy()->PostTask(FROM_HERE, base::Bind(
&RenderVideoFrame, bitmap, target,
base::Bind(deliver_frame_cb, start_time)));
} else {
// Capture can fail due to transient issues, so just skip this frame.
DVLOG(1) << "CopyFromBackingStore failed; skipping frame.";
deliver_frame_cb.Run(start_time, false);
}
}
void WebContentsCaptureMachine::DidCopyFromCompositingSurfaceToVideoFrame(
const base::Time& start_time,
const RenderWidgetHostViewFrameSubscriber::DeliverFrameCallback&
deliver_frame_cb,
bool success) {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
base::Time now = base::Time::Now();
if (success) {
UMA_HISTOGRAM_TIMES("TabCapture.CopyTimeVideoFrame", now - start_time);
} else {
// Capture can fail due to transient issues, so just skip this frame.
DVLOG(1) << "CopyFromCompositingSurface failed; skipping frame.";
}
deliver_frame_cb.Run(start_time, success);
}
void WebContentsCaptureMachine::RenewFrameSubscription() {
DCHECK(BrowserThread::CurrentlyOn(BrowserThread::UI));
// Always destroy the old subscription before creating a new one.
subscription_.reset();
RenderWidgetHost* rwh = GetTarget();
if (!rwh || !rwh->GetView())
return;
subscription_.reset(new ContentCaptureSubscription(*rwh, oracle_proxy_,
base::Bind(&WebContentsCaptureMachine::Capture, this->AsWeakPtr())));
}
} // namespace
WebContentsVideoCaptureDevice::WebContentsVideoCaptureDevice(
int render_process_id, int render_view_id)
: impl_(new VideoCaptureDeviceImpl(scoped_ptr<VideoCaptureMachine>(
new WebContentsCaptureMachine(render_process_id, render_view_id)))) {}
WebContentsVideoCaptureDevice::~WebContentsVideoCaptureDevice() {
DVLOG(2) << "WebContentsVideoCaptureDevice@" << this << " destroying.";
}
// static
media::VideoCaptureDevice* WebContentsVideoCaptureDevice::Create(
const std::string& device_id) {
// Parse device_id into render_process_id and render_view_id.
int render_process_id = -1;
int render_view_id = -1;
if (!WebContentsCaptureUtil::ExtractTabCaptureTarget(
device_id, &render_process_id, &render_view_id)) {
return NULL;
}
return new WebContentsVideoCaptureDevice(render_process_id, render_view_id);
}
void WebContentsVideoCaptureDevice::AllocateAndStart(
const media::VideoCaptureParams& params,
scoped_ptr<Client> client) {
DVLOG(1) << "Allocating " << params.requested_format.frame_size.ToString();
impl_->AllocateAndStart(params, client.Pass());
}
void WebContentsVideoCaptureDevice::StopAndDeAllocate() {
impl_->StopAndDeAllocate();
}
} // namespace content