modules/video_coding/generic_encoder_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2017 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 <vector>

 #include "modules/video_coding/encoded_frame.h"
 #include "modules/video_coding/generic_encoder.h"
 #include "modules/video_coding/include/video_coding_defines.h"
 #include "rtc_base/fakeclock.h"
 #include "test/gtest.h"

 namespace webrtc {
 namespace test {
 namespace {
 inline size_t FrameSize(const size_t& min_frame_size,
                         const size_t& max_frame_size,
                         const int& s,
                         const int& i) {
   return min_frame_size + (s + 1) * i % (max_frame_size - min_frame_size);
 }

 class FakeEncodedImageCallback : public EncodedImageCallback {
  public:
   FakeEncodedImageCallback()
       : last_frame_was_timing_(false),
         num_frames_dropped_(0),
         last_capture_timestamp_(-1) {}
   Result OnEncodedImage(const EncodedImage& encoded_image,
                         const CodecSpecificInfo* codec_specific_info,
                         const RTPFragmentationHeader* fragmentation) override {
     last_frame_was_timing_ =
         encoded_image.timing_.flags != VideoSendTiming::kInvalid &&
         encoded_image.timing_.flags != VideoSendTiming::kNotTriggered;
     last_capture_timestamp_ = encoded_image.capture_time_ms_;
     return Result(Result::OK);
   };

   void OnDroppedFrame(DropReason reason) override { ++num_frames_dropped_; }

   bool WasTimingFrame() { return last_frame_was_timing_; }

   size_t GetNumFramesDropped() { return num_frames_dropped_; }

   int64_t GetLastCaptureTimestamp() { return last_capture_timestamp_; }

  private:
   bool last_frame_was_timing_;
   size_t num_frames_dropped_;
   int64_t last_capture_timestamp_;
 };

 enum class FrameType {
   kNormal,
   kTiming,
   kDropped,
 };

 // Emulates |num_frames| on |num_streams| frames with capture timestamps
 // increased by 1 from 0. Size of each frame is between
 // |min_frame_size| and |max_frame_size|, outliers are counted relatevely to
 // |average_frame_sizes[]| for each stream.
 std::vector<std::vector<FrameType>> GetTimingFrames(
     const int64_t delay_ms,
     const size_t min_frame_size,
     const size_t max_frame_size,
     std::vector<size_t> average_frame_sizes,
     const int num_streams,
     const int num_frames) {
   FakeEncodedImageCallback sink;
   VCMEncodedFrameCallback callback(&sink, nullptr);
   const size_t kFramerate = 30;
   callback.SetTimingFramesThresholds(
       {delay_ms, kDefaultOutlierFrameSizePercent});
   callback.OnFrameRateChanged(kFramerate);
   int s, i;
   std::vector<std::vector<FrameType>> result(num_streams);
   for (s = 0; s < num_streams; ++s)
     callback.OnTargetBitrateChanged(average_frame_sizes[s] * kFramerate, s);
   int64_t current_timestamp = 0;
   for (i = 0; i < num_frames; ++i) {
     current_timestamp += 1;
     for (s = 0; s < num_streams; ++s) {
       // every (5+s)-th frame is dropped on s-th stream by design.
       bool dropped = i % (5 + s) == 0;

       EncodedImage image;
       CodecSpecificInfo codec_specific;
       image._length = FrameSize(min_frame_size, max_frame_size, s, i);
       image.capture_time_ms_ = current_timestamp;
       image.SetTimestamp(static_cast<uint32_t>(current_timestamp * 90));
       codec_specific.codecType = kVideoCodecGeneric;
       codec_specific.codecSpecific.generic.simulcast_idx = s;
       callback.OnEncodeStarted(static_cast<uint32_t>(current_timestamp * 90),
                                current_timestamp, s);
       if (dropped) {
         result[s].push_back(FrameType::kDropped);
         continue;
       }
       callback.OnEncodedImage(image, &codec_specific, nullptr);
       if (sink.WasTimingFrame()) {
         result[s].push_back(FrameType::kTiming);
       } else {
         result[s].push_back(FrameType::kNormal);
       }
     }
   }
   return result;
 }
 }  // namespace

 TEST(TestVCMEncodedFrameCallback, MarksTimingFramesPeriodicallyTogether) {
   const int64_t kDelayMs = 29;
   const size_t kMinFrameSize = 10;
   const size_t kMaxFrameSize = 20;
   const int kNumFrames = 1000;
   const int kNumStreams = 3;
   // No outliers as 1000 is larger than anything from range [10,20].
   const std::vector<size_t> kAverageSize = {1000, 1000, 1000};
   auto frames = GetTimingFrames(kDelayMs, kMinFrameSize, kMaxFrameSize,
                                 kAverageSize, kNumStreams, kNumFrames);
   // Timing frames should be tirggered every delayMs.
   // As no outliers are expected, frames on all streams have to be
   // marked together.
   int last_timing_frame = -1;
   for (int i = 0; i < kNumFrames; ++i) {
     int num_normal = 0;
     int num_timing = 0;
     int num_dropped = 0;
     for (int s = 0; s < kNumStreams; ++s) {
       if (frames[s][i] == FrameType::kTiming) {
         ++num_timing;
       } else if (frames[s][i] == FrameType::kNormal) {
         ++num_normal;
       } else {
         ++num_dropped;
       }
     }
     // Can't have both normal and timing frames at the same timstamp.
     EXPECT_TRUE(num_timing == 0 || num_normal == 0);
     if (num_dropped < kNumStreams) {
       if (last_timing_frame == -1 || i >= last_timing_frame + kDelayMs) {
         // If didn't have timing frames for a period, current sent frame has to
         // be one. No normal frames should be sent.
         EXPECT_EQ(num_normal, 0);
       } else {
         // No unneeded timing frames should be sent.
         EXPECT_EQ(num_timing, 0);
       }
     }
     if (num_timing > 0)
       last_timing_frame = i;
   }
 }

 TEST(TestVCMEncodedFrameCallback, MarksOutliers) {
   const int64_t kDelayMs = 29;
   const size_t kMinFrameSize = 2495;
   const size_t kMaxFrameSize = 2505;
   const int kNumFrames = 1000;
   const int kNumStreams = 3;
   // Possible outliers as 1000 lies in range [995, 1005].
   const std::vector<size_t> kAverageSize = {998, 1000, 1004};
   auto frames = GetTimingFrames(kDelayMs, kMinFrameSize, kMaxFrameSize,
                                 kAverageSize, kNumStreams, kNumFrames);
   // All outliers should be marked.
   for (int i = 0; i < kNumFrames; ++i) {
     for (int s = 0; s < kNumStreams; ++s) {
       if (FrameSize(kMinFrameSize, kMaxFrameSize, s, i) >=
           kAverageSize[s] * kDefaultOutlierFrameSizePercent / 100) {
         // Too big frame. May be dropped or timing, but not normal.
         EXPECT_NE(frames[s][i], FrameType::kNormal);
       }
     }
   }
 }

 TEST(TestVCMEncodedFrameCallback, NoTimingFrameIfNoEncodeStartTime) {
   EncodedImage image;
   CodecSpecificInfo codec_specific;
   int64_t timestamp = 1;
   image._length = 500;
   image.capture_time_ms_ = timestamp;
   image.SetTimestamp(static_cast<uint32_t>(timestamp * 90));
   codec_specific.codecType = kVideoCodecGeneric;
   codec_specific.codecSpecific.generic.simulcast_idx = 0;
   FakeEncodedImageCallback sink;
   VCMEncodedFrameCallback callback(&sink, nullptr);
   VideoCodec::TimingFrameTriggerThresholds thresholds;
   thresholds.delay_ms = 1;  // Make all frames timing frames.
   callback.SetTimingFramesThresholds(thresholds);
   callback.OnTargetBitrateChanged(500, 0);

   // Verify a single frame works with encode start time set.
   callback.OnEncodeStarted(static_cast<uint32_t>(timestamp * 90), timestamp, 0);
   callback.OnEncodedImage(image, &codec_specific, nullptr);
   EXPECT_TRUE(sink.WasTimingFrame());

   // New frame, now skip OnEncodeStarted. Should not result in timing frame.
   image.capture_time_ms_ = ++timestamp;
   image.SetTimestamp(static_cast<uint32_t>(timestamp * 90));
   callback.OnEncodedImage(image, &codec_specific, nullptr);
   EXPECT_FALSE(sink.WasTimingFrame());
 }

 TEST(TestVCMEncodedFrameCallback, AdjustsCaptureTimeForInternalSourceEncoder) {
   rtc::ScopedFakeClock clock;
   clock.SetTimeMicros(1234567);
   EncodedImage image;
   CodecSpecificInfo codec_specific;
   const int64_t kEncodeStartDelayMs = 2;
   const int64_t kEncodeFinishDelayMs = 10;
   int64_t timestamp = 1;
   image._length = 500;
   image.capture_time_ms_ = timestamp;
   image.SetTimestamp(static_cast<uint32_t>(timestamp * 90));
   codec_specific.codecType = kVideoCodecGeneric;
   codec_specific.codecSpecific.generic.simulcast_idx = 0;
   FakeEncodedImageCallback sink;
   VCMEncodedFrameCallback callback(&sink, nullptr);
   callback.SetInternalSource(true);
   VideoCodec::TimingFrameTriggerThresholds thresholds;
   thresholds.delay_ms = 1;  // Make all frames timing frames.
   callback.SetTimingFramesThresholds(thresholds);
   callback.OnTargetBitrateChanged(500, 0);

   // Verify a single frame without encode timestamps isn't a timing frame.
   callback.OnEncodedImage(image, &codec_specific, nullptr);
   EXPECT_FALSE(sink.WasTimingFrame());

   // New frame, but this time with encode timestamps set in timing_.
   // This should be a timing frame.
   image.capture_time_ms_ = ++timestamp;
   image.SetTimestamp(static_cast<uint32_t>(timestamp * 90));
   image.timing_.encode_start_ms = timestamp + kEncodeStartDelayMs;
   image.timing_.encode_finish_ms = timestamp + kEncodeFinishDelayMs;
   callback.OnEncodedImage(image, &codec_specific, nullptr);
   EXPECT_TRUE(sink.WasTimingFrame());
   // Frame is captured kEncodeFinishDelayMs before it's encoded, so restored
   // capture timestamp should be kEncodeFinishDelayMs in the past.
   EXPECT_EQ(
       sink.GetLastCaptureTimestamp(),
       clock.TimeNanos() / rtc::kNumNanosecsPerMillisec - kEncodeFinishDelayMs);
 }

 TEST(TestVCMEncodedFrameCallback, NotifiesAboutDroppedFrames) {
   EncodedImage image;
   CodecSpecificInfo codec_specific;
   const int64_t kTimestampMs1 = 47721840;
   const int64_t kTimestampMs2 = 47721850;
   const int64_t kTimestampMs3 = 47721860;
   const int64_t kTimestampMs4 = 47721870;
   codec_specific.codecType = kVideoCodecGeneric;
   codec_specific.codecSpecific.generic.simulcast_idx = 0;
   FakeEncodedImageCallback sink;
   VCMEncodedFrameCallback callback(&sink, nullptr);
   // Any non-zero bitrate needed to be set before the first frame.
   callback.OnTargetBitrateChanged(500, 0);
   image.capture_time_ms_ = kTimestampMs1;
   image.SetTimestamp(static_cast<uint32_t>(image.capture_time_ms_ * 90));
   callback.OnEncodeStarted(image.Timestamp(), image.capture_time_ms_, 0);
   EXPECT_EQ(0u, sink.GetNumFramesDropped());
   callback.OnEncodedImage(image, &codec_specific, nullptr);

   image.capture_time_ms_ = kTimestampMs2;
   image.SetTimestamp(static_cast<uint32_t>(image.capture_time_ms_ * 90));
   callback.OnEncodeStarted(image.Timestamp(), image.capture_time_ms_, 0);
   // No OnEncodedImageCall for timestamp2. Yet, at this moment it's not known
   // that frame with timestamp2 was dropped.
   EXPECT_EQ(0u, sink.GetNumFramesDropped());

   image.capture_time_ms_ = kTimestampMs3;
   image.SetTimestamp(static_cast<uint32_t>(image.capture_time_ms_ * 90));
   callback.OnEncodeStarted(image.Timestamp(), image.capture_time_ms_, 0);
   callback.OnEncodedImage(image, &codec_specific, nullptr);
   EXPECT_EQ(1u, sink.GetNumFramesDropped());

   image.capture_time_ms_ = kTimestampMs4;
   image.SetTimestamp(static_cast<uint32_t>(image.capture_time_ms_ * 90));
   callback.OnEncodeStarted(image.Timestamp(), image.capture_time_ms_, 0);
   callback.OnEncodedImage(image, &codec_specific, nullptr);
   EXPECT_EQ(1u, sink.GetNumFramesDropped());
 }

 TEST(TestVCMEncodedFrameCallback, RestoresCaptureTimestamps) {
   EncodedImage image;
   CodecSpecificInfo codec_specific;
   const int64_t kTimestampMs = 123456;
   codec_specific.codecType = kVideoCodecGeneric;
   codec_specific.codecSpecific.generic.simulcast_idx = 0;
   FakeEncodedImageCallback sink;
   VCMEncodedFrameCallback callback(&sink, nullptr);
   // Any non-zero bitrate needed to be set before the first frame.
   callback.OnTargetBitrateChanged(500, 0);
   image.capture_time_ms_ = kTimestampMs;  // Incorrect timesetamp.
   image.SetTimestamp(static_cast<uint32_t>(image.capture_time_ms_ * 90));
   callback.OnEncodeStarted(image.Timestamp(), image.capture_time_ms_, 0);
   image.capture_time_ms_ = 0;  // Incorrect timesetamp.
   callback.OnEncodedImage(image, &codec_specific, nullptr);
   EXPECT_EQ(kTimestampMs, sink.GetLastCaptureTimestamp());
 }

 }  // namespace test
 }  // namespace webrtc
	/*
	* Copyright (c) 2017 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 <vector>

	#include "modules/video_coding/encoded_frame.h"
	#include "modules/video_coding/generic_encoder.h"
	#include "modules/video_coding/include/video_coding_defines.h"
	#include "rtc_base/fakeclock.h"
	#include "test/gtest.h"

	namespace webrtc {
	namespace test {
	namespace {
	inline size_t FrameSize(const size_t& min_frame_size,
	const size_t& max_frame_size,
	const int& s,
	const int& i) {
	return min_frame_size + (s + 1) * i % (max_frame_size - min_frame_size);
	}

	class FakeEncodedImageCallback : public EncodedImageCallback {
	public:
	FakeEncodedImageCallback()
	: last_frame_was_timing_(false),
	num_frames_dropped_(0),
	last_capture_timestamp_(-1) {}
	Result OnEncodedImage(const EncodedImage& encoded_image,
	const CodecSpecificInfo* codec_specific_info,
	const RTPFragmentationHeader* fragmentation) override {
	last_frame_was_timing_ =
	encoded_image.timing_.flags != VideoSendTiming::kInvalid &&
	encoded_image.timing_.flags != VideoSendTiming::kNotTriggered;
	last_capture_timestamp_ = encoded_image.capture_time_ms_;
	return Result(Result::OK);
	};

	void OnDroppedFrame(DropReason reason) override { ++num_frames_dropped_; }

	bool WasTimingFrame() { return last_frame_was_timing_; }

	size_t GetNumFramesDropped() { return num_frames_dropped_; }

	int64_t GetLastCaptureTimestamp() { return last_capture_timestamp_; }

	private:
	bool last_frame_was_timing_;
	size_t num_frames_dropped_;
	int64_t last_capture_timestamp_;
	};

	enum class FrameType {
	kNormal,
	kTiming,
	kDropped,
	};

	// Emulates \|num_frames\| on \|num_streams\| frames with capture timestamps
	// increased by 1 from 0. Size of each frame is between
	// \|min_frame_size\| and \|max_frame_size\|, outliers are counted relatevely to
	// \|average_frame_sizes[]\| for each stream.
	std::vector<std::vector<FrameType>> GetTimingFrames(
	const int64_t delay_ms,
	const size_t min_frame_size,
	const size_t max_frame_size,
	std::vector<size_t> average_frame_sizes,
	const int num_streams,
	const int num_frames) {
	FakeEncodedImageCallback sink;
	VCMEncodedFrameCallback callback(&sink, nullptr);
	const size_t kFramerate = 30;
	callback.SetTimingFramesThresholds(
	{delay_ms, kDefaultOutlierFrameSizePercent});
	callback.OnFrameRateChanged(kFramerate);
	int s, i;
	std::vector<std::vector<FrameType>> result(num_streams);
	for (s = 0; s < num_streams; ++s)
	callback.OnTargetBitrateChanged(average_frame_sizes[s] * kFramerate, s);
	int64_t current_timestamp = 0;
	for (i = 0; i < num_frames; ++i) {
	current_timestamp += 1;
	for (s = 0; s < num_streams; ++s) {
	// every (5+s)-th frame is dropped on s-th stream by design.
	bool dropped = i % (5 + s) == 0;

	EncodedImage image;
	CodecSpecificInfo codec_specific;
	image._length = FrameSize(min_frame_size, max_frame_size, s, i);
	image.capture_time_ms_ = current_timestamp;
	image.SetTimestamp(static_cast<uint32_t>(current_timestamp * 90));
	codec_specific.codecType = kVideoCodecGeneric;
	codec_specific.codecSpecific.generic.simulcast_idx = s;
	callback.OnEncodeStarted(static_cast<uint32_t>(current_timestamp * 90),
	current_timestamp, s);
	if (dropped) {
	result[s].push_back(FrameType::kDropped);
	continue;
	}
	callback.OnEncodedImage(image, &codec_specific, nullptr);
	if (sink.WasTimingFrame()) {
	result[s].push_back(FrameType::kTiming);
	} else {
	result[s].push_back(FrameType::kNormal);
	}
	}
	}
	return result;
	}
	} // namespace

	TEST(TestVCMEncodedFrameCallback, MarksTimingFramesPeriodicallyTogether) {
	const int64_t kDelayMs = 29;
	const size_t kMinFrameSize = 10;
	const size_t kMaxFrameSize = 20;
	const int kNumFrames = 1000;
	const int kNumStreams = 3;
	// No outliers as 1000 is larger than anything from range [10,20].
	const std::vector<size_t> kAverageSize = {1000, 1000, 1000};
	auto frames = GetTimingFrames(kDelayMs, kMinFrameSize, kMaxFrameSize,
	kAverageSize, kNumStreams, kNumFrames);
	// Timing frames should be tirggered every delayMs.
	// As no outliers are expected, frames on all streams have to be
	// marked together.
	int last_timing_frame = -1;
	for (int i = 0; i < kNumFrames; ++i) {
	int num_normal = 0;
	int num_timing = 0;
	int num_dropped = 0;
	for (int s = 0; s < kNumStreams; ++s) {
	if (frames[s][i] == FrameType::kTiming) {
	++num_timing;
	} else if (frames[s][i] == FrameType::kNormal) {
	++num_normal;
	} else {
	++num_dropped;
	}
	}
	// Can't have both normal and timing frames at the same timstamp.
	EXPECT_TRUE(num_timing == 0 \|\| num_normal == 0);
	if (num_dropped < kNumStreams) {
	if (last_timing_frame == -1 \|\| i >= last_timing_frame + kDelayMs) {
	// If didn't have timing frames for a period, current sent frame has to
	// be one. No normal frames should be sent.
	EXPECT_EQ(num_normal, 0);
	} else {
	// No unneeded timing frames should be sent.
	EXPECT_EQ(num_timing, 0);
	}
	}
	if (num_timing > 0)
	last_timing_frame = i;
	}
	}

	TEST(TestVCMEncodedFrameCallback, MarksOutliers) {
	const int64_t kDelayMs = 29;
	const size_t kMinFrameSize = 2495;
	const size_t kMaxFrameSize = 2505;
	const int kNumFrames = 1000;
	const int kNumStreams = 3;
	// Possible outliers as 1000 lies in range [995, 1005].
	const std::vector<size_t> kAverageSize = {998, 1000, 1004};
	auto frames = GetTimingFrames(kDelayMs, kMinFrameSize, kMaxFrameSize,
	kAverageSize, kNumStreams, kNumFrames);
	// All outliers should be marked.
	for (int i = 0; i < kNumFrames; ++i) {
	for (int s = 0; s < kNumStreams; ++s) {
	if (FrameSize(kMinFrameSize, kMaxFrameSize, s, i) >=
	kAverageSize[s] * kDefaultOutlierFrameSizePercent / 100) {
	// Too big frame. May be dropped or timing, but not normal.
	EXPECT_NE(frames[s][i], FrameType::kNormal);
	}
	}
	}
	}

	TEST(TestVCMEncodedFrameCallback, NoTimingFrameIfNoEncodeStartTime) {
	EncodedImage image;
	CodecSpecificInfo codec_specific;
	int64_t timestamp = 1;
	image._length = 500;
	image.capture_time_ms_ = timestamp;
	image.SetTimestamp(static_cast<uint32_t>(timestamp * 90));
	codec_specific.codecType = kVideoCodecGeneric;
	codec_specific.codecSpecific.generic.simulcast_idx = 0;
	FakeEncodedImageCallback sink;
	VCMEncodedFrameCallback callback(&sink, nullptr);
	VideoCodec::TimingFrameTriggerThresholds thresholds;
	thresholds.delay_ms = 1; // Make all frames timing frames.
	callback.SetTimingFramesThresholds(thresholds);
	callback.OnTargetBitrateChanged(500, 0);

	// Verify a single frame works with encode start time set.
	callback.OnEncodeStarted(static_cast<uint32_t>(timestamp * 90), timestamp, 0);
	callback.OnEncodedImage(image, &codec_specific, nullptr);
	EXPECT_TRUE(sink.WasTimingFrame());

	// New frame, now skip OnEncodeStarted. Should not result in timing frame.
	image.capture_time_ms_ = ++timestamp;
	image.SetTimestamp(static_cast<uint32_t>(timestamp * 90));
	callback.OnEncodedImage(image, &codec_specific, nullptr);
	EXPECT_FALSE(sink.WasTimingFrame());
	}

	TEST(TestVCMEncodedFrameCallback, AdjustsCaptureTimeForInternalSourceEncoder) {
	rtc::ScopedFakeClock clock;
	clock.SetTimeMicros(1234567);
	EncodedImage image;
	CodecSpecificInfo codec_specific;
	const int64_t kEncodeStartDelayMs = 2;
	const int64_t kEncodeFinishDelayMs = 10;
	int64_t timestamp = 1;
	image._length = 500;
	image.capture_time_ms_ = timestamp;
	image.SetTimestamp(static_cast<uint32_t>(timestamp * 90));
	codec_specific.codecType = kVideoCodecGeneric;
	codec_specific.codecSpecific.generic.simulcast_idx = 0;
	FakeEncodedImageCallback sink;
	VCMEncodedFrameCallback callback(&sink, nullptr);
	callback.SetInternalSource(true);
	VideoCodec::TimingFrameTriggerThresholds thresholds;
	thresholds.delay_ms = 1; // Make all frames timing frames.
	callback.SetTimingFramesThresholds(thresholds);
	callback.OnTargetBitrateChanged(500, 0);

	// Verify a single frame without encode timestamps isn't a timing frame.
	callback.OnEncodedImage(image, &codec_specific, nullptr);
	EXPECT_FALSE(sink.WasTimingFrame());

	// New frame, but this time with encode timestamps set in timing_.
	// This should be a timing frame.
	image.capture_time_ms_ = ++timestamp;
	image.SetTimestamp(static_cast<uint32_t>(timestamp * 90));
	image.timing_.encode_start_ms = timestamp + kEncodeStartDelayMs;
	image.timing_.encode_finish_ms = timestamp + kEncodeFinishDelayMs;
	callback.OnEncodedImage(image, &codec_specific, nullptr);
	EXPECT_TRUE(sink.WasTimingFrame());
	// Frame is captured kEncodeFinishDelayMs before it's encoded, so restored
	// capture timestamp should be kEncodeFinishDelayMs in the past.
	EXPECT_EQ(
	sink.GetLastCaptureTimestamp(),
	clock.TimeNanos() / rtc::kNumNanosecsPerMillisec - kEncodeFinishDelayMs);
	}

	TEST(TestVCMEncodedFrameCallback, NotifiesAboutDroppedFrames) {
	EncodedImage image;
	CodecSpecificInfo codec_specific;
	const int64_t kTimestampMs1 = 47721840;
	const int64_t kTimestampMs2 = 47721850;
	const int64_t kTimestampMs3 = 47721860;
	const int64_t kTimestampMs4 = 47721870;
	codec_specific.codecType = kVideoCodecGeneric;
	codec_specific.codecSpecific.generic.simulcast_idx = 0;
	FakeEncodedImageCallback sink;
	VCMEncodedFrameCallback callback(&sink, nullptr);
	// Any non-zero bitrate needed to be set before the first frame.
	callback.OnTargetBitrateChanged(500, 0);
	image.capture_time_ms_ = kTimestampMs1;
	image.SetTimestamp(static_cast<uint32_t>(image.capture_time_ms_ * 90));
	callback.OnEncodeStarted(image.Timestamp(), image.capture_time_ms_, 0);
	EXPECT_EQ(0u, sink.GetNumFramesDropped());
	callback.OnEncodedImage(image, &codec_specific, nullptr);

	image.capture_time_ms_ = kTimestampMs2;
	image.SetTimestamp(static_cast<uint32_t>(image.capture_time_ms_ * 90));
	callback.OnEncodeStarted(image.Timestamp(), image.capture_time_ms_, 0);
	// No OnEncodedImageCall for timestamp2. Yet, at this moment it's not known
	// that frame with timestamp2 was dropped.
	EXPECT_EQ(0u, sink.GetNumFramesDropped());

	image.capture_time_ms_ = kTimestampMs3;
	image.SetTimestamp(static_cast<uint32_t>(image.capture_time_ms_ * 90));
	callback.OnEncodeStarted(image.Timestamp(), image.capture_time_ms_, 0);
	callback.OnEncodedImage(image, &codec_specific, nullptr);
	EXPECT_EQ(1u, sink.GetNumFramesDropped());

	image.capture_time_ms_ = kTimestampMs4;
	image.SetTimestamp(static_cast<uint32_t>(image.capture_time_ms_ * 90));
	callback.OnEncodeStarted(image.Timestamp(), image.capture_time_ms_, 0);
	callback.OnEncodedImage(image, &codec_specific, nullptr);
	EXPECT_EQ(1u, sink.GetNumFramesDropped());
	}

	TEST(TestVCMEncodedFrameCallback, RestoresCaptureTimestamps) {
	EncodedImage image;
	CodecSpecificInfo codec_specific;
	const int64_t kTimestampMs = 123456;
	codec_specific.codecType = kVideoCodecGeneric;
	codec_specific.codecSpecific.generic.simulcast_idx = 0;
	FakeEncodedImageCallback sink;
	VCMEncodedFrameCallback callback(&sink, nullptr);
	// Any non-zero bitrate needed to be set before the first frame.
	callback.OnTargetBitrateChanged(500, 0);
	image.capture_time_ms_ = kTimestampMs; // Incorrect timesetamp.
	image.SetTimestamp(static_cast<uint32_t>(image.capture_time_ms_ * 90));
	callback.OnEncodeStarted(image.Timestamp(), image.capture_time_ms_, 0);
	image.capture_time_ms_ = 0; // Incorrect timesetamp.
	callback.OnEncodedImage(image, &codec_specific, nullptr);
	EXPECT_EQ(kTimestampMs, sink.GetLastCaptureTimestamp());
	}

	} // namespace test
	} // namespace webrtc