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/*
* Copyright 2012 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include <memory>
#include <string>
#include <vector>
#include "webrtc/api/test/fakeconstraints.h"
#include "webrtc/api/videocapturertracksource.h"
#include "webrtc/base/gunit.h"
#include "webrtc/media/base/fakemediaengine.h"
#include "webrtc/media/base/fakevideocapturer.h"
#include "webrtc/media/base/fakevideorenderer.h"
#include "webrtc/media/engine/webrtcvideoframe.h"
using webrtc::FakeConstraints;
using webrtc::VideoCapturerTrackSource;
using webrtc::MediaConstraintsInterface;
using webrtc::MediaSourceInterface;
using webrtc::ObserverInterface;
using webrtc::VideoTrackSourceInterface;
namespace {
// Max wait time for a test.
const int kMaxWaitMs = 100;
} // anonymous namespace
// TestVideoCapturer extends cricket::FakeVideoCapturer so it can be used for
// testing without known camera formats.
// It keeps its own lists of cricket::VideoFormats for the unit tests in this
// file.
class TestVideoCapturer : public cricket::FakeVideoCapturer {
public:
explicit TestVideoCapturer(bool is_screencast)
: FakeVideoCapturer(is_screencast), test_without_formats_(false) {
std::vector<cricket::VideoFormat> formats;
formats.push_back(
cricket::VideoFormat(1280, 720, cricket::VideoFormat::FpsToInterval(30),
cricket::FOURCC_I420));
formats.push_back(
cricket::VideoFormat(640, 480, cricket::VideoFormat::FpsToInterval(30),
cricket::FOURCC_I420));
formats.push_back(
cricket::VideoFormat(640, 400, cricket::VideoFormat::FpsToInterval(30),
cricket::FOURCC_I420));
formats.push_back(
cricket::VideoFormat(320, 240, cricket::VideoFormat::FpsToInterval(30),
cricket::FOURCC_I420));
formats.push_back(
cricket::VideoFormat(352, 288, cricket::VideoFormat::FpsToInterval(30),
cricket::FOURCC_I420));
ResetSupportedFormats(formats);
}
// This function is used for resetting the supported capture formats and
// simulating a cricket::VideoCapturer implementation that don't support
// capture format enumeration. This is used to simulate the current
// Chrome implementation.
void TestWithoutCameraFormats() {
test_without_formats_ = true;
std::vector<cricket::VideoFormat> formats;
ResetSupportedFormats(formats);
}
virtual cricket::CaptureState Start(
const cricket::VideoFormat& capture_format) {
if (test_without_formats_) {
std::vector<cricket::VideoFormat> formats;
formats.push_back(capture_format);
ResetSupportedFormats(formats);
}
return FakeVideoCapturer::Start(capture_format);
}
virtual bool GetBestCaptureFormat(const cricket::VideoFormat& desired,
cricket::VideoFormat* best_format) {
if (test_without_formats_) {
*best_format = desired;
return true;
}
return FakeVideoCapturer::GetBestCaptureFormat(desired, best_format);
}
private:
bool test_without_formats_;
};
class StateObserver : public ObserverInterface {
public:
explicit StateObserver(VideoTrackSourceInterface* source)
: state_(source->state()), source_(source) {}
virtual void OnChanged() { state_ = source_->state(); }
MediaSourceInterface::SourceState state() const { return state_; }
private:
MediaSourceInterface::SourceState state_;
rtc::scoped_refptr<VideoTrackSourceInterface> source_;
};
class VideoCapturerTrackSourceTest : public testing::Test {
protected:
VideoCapturerTrackSourceTest() { InitCapturer(false); }
void InitCapturer(bool is_screencast) {
capturer_cleanup_ = std::unique_ptr<TestVideoCapturer>(
new TestVideoCapturer(is_screencast));
capturer_ = capturer_cleanup_.get();
}
void InitScreencast() { InitCapturer(true); }
void CreateVideoCapturerSource() { CreateVideoCapturerSource(NULL); }
void CreateVideoCapturerSource(
const webrtc::MediaConstraintsInterface* constraints) {
// VideoSource take ownership of |capturer_|
source_ = VideoCapturerTrackSource::Create(rtc::Thread::Current(),
capturer_cleanup_.release(),
constraints, false);
ASSERT_TRUE(source_.get() != NULL);
state_observer_.reset(new StateObserver(source_));
source_->RegisterObserver(state_observer_.get());
source_->AddOrUpdateSink(&renderer_, rtc::VideoSinkWants());
}
std::unique_ptr<TestVideoCapturer> capturer_cleanup_;
TestVideoCapturer* capturer_;
cricket::FakeVideoRenderer renderer_;
std::unique_ptr<StateObserver> state_observer_;
rtc::scoped_refptr<VideoTrackSourceInterface> source_;
};
// Test that a VideoSource transition to kLive state when the capture
// device have started and kEnded if it is stopped.
// It also test that an output can receive video frames.
TEST_F(VideoCapturerTrackSourceTest, CapturerStartStop) {
// Initialize without constraints.
CreateVideoCapturerSource();
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
ASSERT_TRUE(capturer_->CaptureFrame());
EXPECT_EQ(1, renderer_.num_rendered_frames());
capturer_->Stop();
EXPECT_EQ_WAIT(MediaSourceInterface::kEnded, state_observer_->state(),
kMaxWaitMs);
}
// Test that a VideoSource transition to kEnded if the capture device
// fails.
TEST_F(VideoCapturerTrackSourceTest, CameraFailed) {
CreateVideoCapturerSource();
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
capturer_->SignalStateChange(capturer_, cricket::CS_FAILED);
EXPECT_EQ_WAIT(MediaSourceInterface::kEnded, state_observer_->state(),
kMaxWaitMs);
}
// Test that the capture output is CIF if we set max constraints to CIF.
// and the capture device support CIF.
TEST_F(VideoCapturerTrackSourceTest, MandatoryConstraintCif5Fps) {
FakeConstraints constraints;
constraints.AddMandatory(MediaConstraintsInterface::kMaxWidth, 352);
constraints.AddMandatory(MediaConstraintsInterface::kMaxHeight, 288);
constraints.AddMandatory(MediaConstraintsInterface::kMaxFrameRate, 5);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
const cricket::VideoFormat* format = capturer_->GetCaptureFormat();
ASSERT_TRUE(format != NULL);
EXPECT_EQ(352, format->width);
EXPECT_EQ(288, format->height);
EXPECT_EQ(5, format->framerate());
}
// Test that the capture output is 720P if the camera support it and the
// optional constraint is set to 720P.
TEST_F(VideoCapturerTrackSourceTest, MandatoryMinVgaOptional720P) {
FakeConstraints constraints;
constraints.AddMandatory(MediaConstraintsInterface::kMinWidth, 640);
constraints.AddMandatory(MediaConstraintsInterface::kMinHeight, 480);
constraints.AddOptional(MediaConstraintsInterface::kMinWidth, 1280);
constraints.AddOptional(MediaConstraintsInterface::kMinAspectRatio,
1280.0 / 720);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
const cricket::VideoFormat* format = capturer_->GetCaptureFormat();
ASSERT_TRUE(format != NULL);
EXPECT_EQ(1280, format->width);
EXPECT_EQ(720, format->height);
EXPECT_EQ(30, format->framerate());
}
// Test that the capture output have aspect ratio 4:3 if a mandatory constraint
// require it even if an optional constraint request a higher resolution
// that don't have this aspect ratio.
TEST_F(VideoCapturerTrackSourceTest, MandatoryAspectRatio4To3) {
FakeConstraints constraints;
constraints.AddMandatory(MediaConstraintsInterface::kMinWidth, 640);
constraints.AddMandatory(MediaConstraintsInterface::kMinHeight, 480);
constraints.AddMandatory(MediaConstraintsInterface::kMaxAspectRatio,
640.0 / 480);
constraints.AddOptional(MediaConstraintsInterface::kMinWidth, 1280);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
const cricket::VideoFormat* format = capturer_->GetCaptureFormat();
ASSERT_TRUE(format != NULL);
EXPECT_EQ(640, format->width);
EXPECT_EQ(480, format->height);
EXPECT_EQ(30, format->framerate());
}
// Test that the source state transition to kEnded if the mandatory aspect ratio
// is set higher than supported.
TEST_F(VideoCapturerTrackSourceTest, MandatoryAspectRatioTooHigh) {
FakeConstraints constraints;
constraints.AddMandatory(MediaConstraintsInterface::kMinAspectRatio, 2);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kEnded, state_observer_->state(),
kMaxWaitMs);
}
// Test that the source ignores an optional aspect ratio that is higher than
// supported.
TEST_F(VideoCapturerTrackSourceTest, OptionalAspectRatioTooHigh) {
FakeConstraints constraints;
constraints.AddOptional(MediaConstraintsInterface::kMinAspectRatio, 2);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
const cricket::VideoFormat* format = capturer_->GetCaptureFormat();
ASSERT_TRUE(format != NULL);
double aspect_ratio = static_cast<double>(format->width) / format->height;
EXPECT_LT(aspect_ratio, 2);
}
// Test that the source starts video with the default resolution if the
// camera doesn't support capability enumeration and there are no constraints.
TEST_F(VideoCapturerTrackSourceTest, NoCameraCapability) {
capturer_->TestWithoutCameraFormats();
CreateVideoCapturerSource();
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
const cricket::VideoFormat* format = capturer_->GetCaptureFormat();
ASSERT_TRUE(format != NULL);
EXPECT_EQ(640, format->width);
EXPECT_EQ(480, format->height);
EXPECT_EQ(30, format->framerate());
}
// Test that the source can start the video and get the requested aspect ratio
// if the camera doesn't support capability enumeration and the aspect ratio is
// set.
TEST_F(VideoCapturerTrackSourceTest, NoCameraCapability16To9Ratio) {
capturer_->TestWithoutCameraFormats();
FakeConstraints constraints;
double requested_aspect_ratio = 640.0 / 360;
constraints.AddMandatory(MediaConstraintsInterface::kMinWidth, 640);
constraints.AddMandatory(MediaConstraintsInterface::kMinAspectRatio,
requested_aspect_ratio);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
const cricket::VideoFormat* format = capturer_->GetCaptureFormat();
double aspect_ratio = static_cast<double>(format->width) / format->height;
EXPECT_LE(requested_aspect_ratio, aspect_ratio);
}
// Test that the source state transitions to kEnded if an unknown mandatory
// constraint is found.
TEST_F(VideoCapturerTrackSourceTest, InvalidMandatoryConstraint) {
FakeConstraints constraints;
constraints.AddMandatory("weird key", 640);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kEnded, state_observer_->state(),
kMaxWaitMs);
}
// Test that the source ignores an unknown optional constraint.
TEST_F(VideoCapturerTrackSourceTest, InvalidOptionalConstraint) {
FakeConstraints constraints;
constraints.AddOptional("weird key", 640);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
}
TEST_F(VideoCapturerTrackSourceTest, SetValidDenoisingConstraint) {
FakeConstraints constraints;
constraints.AddMandatory(MediaConstraintsInterface::kNoiseReduction, "false");
CreateVideoCapturerSource(&constraints);
EXPECT_EQ(rtc::Optional<bool>(false), source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest, NoiseReductionConstraintNotSet) {
FakeConstraints constraints;
CreateVideoCapturerSource(&constraints);
EXPECT_EQ(rtc::Optional<bool>(), source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest,
MandatoryDenoisingConstraintOverridesOptional) {
FakeConstraints constraints;
constraints.AddMandatory(MediaConstraintsInterface::kNoiseReduction, false);
constraints.AddOptional(MediaConstraintsInterface::kNoiseReduction, true);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ(rtc::Optional<bool>(false), source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest, NoiseReductionAndInvalidKeyOptional) {
FakeConstraints constraints;
constraints.AddOptional(MediaConstraintsInterface::kNoiseReduction, true);
constraints.AddOptional("invalidKey", false);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
EXPECT_EQ(rtc::Optional<bool>(true), source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest, NoiseReductionAndInvalidKeyMandatory) {
FakeConstraints constraints;
constraints.AddMandatory(MediaConstraintsInterface::kNoiseReduction, false);
constraints.AddMandatory("invalidKey", false);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kEnded, state_observer_->state(),
kMaxWaitMs);
EXPECT_EQ(rtc::Optional<bool>(), source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest, InvalidDenoisingValueOptional) {
FakeConstraints constraints;
constraints.AddOptional(MediaConstraintsInterface::kNoiseReduction,
"not a boolean");
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
EXPECT_EQ(rtc::Optional<bool>(), source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest, InvalidDenoisingValueMandatory) {
FakeConstraints constraints;
// Optional constraints should be ignored if the mandatory constraints fail.
constraints.AddOptional(MediaConstraintsInterface::kNoiseReduction, "false");
// Values are case-sensitive and must be all lower-case.
constraints.AddMandatory(MediaConstraintsInterface::kNoiseReduction, "True");
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kEnded, state_observer_->state(),
kMaxWaitMs);
EXPECT_EQ(rtc::Optional<bool>(), source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest, MixedOptionsAndConstraints) {
FakeConstraints constraints;
constraints.AddMandatory(MediaConstraintsInterface::kMaxWidth, 352);
constraints.AddMandatory(MediaConstraintsInterface::kMaxHeight, 288);
constraints.AddOptional(MediaConstraintsInterface::kMaxFrameRate, 5);
constraints.AddMandatory(MediaConstraintsInterface::kNoiseReduction, false);
constraints.AddOptional(MediaConstraintsInterface::kNoiseReduction, true);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
const cricket::VideoFormat* format = capturer_->GetCaptureFormat();
ASSERT_TRUE(format != NULL);
EXPECT_EQ(352, format->width);
EXPECT_EQ(288, format->height);
EXPECT_EQ(5, format->framerate());
EXPECT_EQ(rtc::Optional<bool>(false), source_->needs_denoising());
}
// Tests that the source starts video with the default resolution for
// screencast if no constraint is set.
TEST_F(VideoCapturerTrackSourceTest, ScreencastResolutionNoConstraint) {
InitScreencast();
capturer_->TestWithoutCameraFormats();
CreateVideoCapturerSource();
ASSERT_TRUE(source_->is_screencast());
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
const cricket::VideoFormat* format = capturer_->GetCaptureFormat();
ASSERT_TRUE(format != NULL);
EXPECT_EQ(640, format->width);
EXPECT_EQ(480, format->height);
EXPECT_EQ(30, format->framerate());
}
// Tests that the source starts video with the max width and height set by
// constraints for screencast.
TEST_F(VideoCapturerTrackSourceTest, ScreencastResolutionWithConstraint) {
FakeConstraints constraints;
constraints.AddMandatory(MediaConstraintsInterface::kMaxWidth, 480);
constraints.AddMandatory(MediaConstraintsInterface::kMaxHeight, 270);
InitScreencast();
capturer_->TestWithoutCameraFormats();
CreateVideoCapturerSource(&constraints);
ASSERT_TRUE(source_->is_screencast());
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
const cricket::VideoFormat* format = capturer_->GetCaptureFormat();
ASSERT_TRUE(format != NULL);
EXPECT_EQ(480, format->width);
EXPECT_EQ(270, format->height);
EXPECT_EQ(30, format->framerate());
}
TEST_F(VideoCapturerTrackSourceTest, DenoisingDefault) {
CreateVideoCapturerSource();
EXPECT_FALSE(source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest, DenoisingConstraintOn) {
FakeConstraints constraints;
constraints.AddOptional(MediaConstraintsInterface::kNoiseReduction, true);
CreateVideoCapturerSource(&constraints);
ASSERT_TRUE(source_->needs_denoising());
EXPECT_TRUE(*source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest, DenoisingCapturerOff) {
capturer_->SetNeedsDenoising(rtc::Optional<bool>(false));
CreateVideoCapturerSource();
ASSERT_TRUE(source_->needs_denoising());
EXPECT_FALSE(*source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest, DenoisingConstraintOverridesCapturer) {
capturer_->SetNeedsDenoising(rtc::Optional<bool>(false));
FakeConstraints constraints;
constraints.AddOptional(MediaConstraintsInterface::kNoiseReduction, true);
CreateVideoCapturerSource(&constraints);
ASSERT_TRUE(source_->needs_denoising());
EXPECT_TRUE(*source_->needs_denoising());
}
TEST_F(VideoCapturerTrackSourceTest, MandatorySubOneFpsConstraints) {
FakeConstraints constraints;
constraints.AddMandatory(MediaConstraintsInterface::kMaxFrameRate, 0.5);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kEnded, state_observer_->state(),
kMaxWaitMs);
ASSERT_TRUE(capturer_->GetCaptureFormat() == NULL);
}
TEST_F(VideoCapturerTrackSourceTest, OptionalSubOneFpsConstraints) {
FakeConstraints constraints;
constraints.AddOptional(MediaConstraintsInterface::kMaxFrameRate, 0.5);
CreateVideoCapturerSource(&constraints);
EXPECT_EQ_WAIT(MediaSourceInterface::kLive, state_observer_->state(),
kMaxWaitMs);
const cricket::VideoFormat* format = capturer_->GetCaptureFormat();
ASSERT_TRUE(format != NULL);
EXPECT_EQ(1, format->framerate());
}