trunk/src/modules/video_coding/main/source/jitter_buffer_unittest.cc - vendor/opensource/webrtc - Git at Google

 /*
  *  Copyright (c) 2011 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 <string.h>

 #include <list>

 #include "gtest/gtest.h"
 #include "modules/video_coding/main/source/jitter_buffer.h"
 #include "modules/video_coding/main/source/media_opt_util.h"
 #include "modules/video_coding/main/source/mock/fake_tick_time.h"
 #include "modules/video_coding/main/source/packet.h"

 namespace webrtc {

 class StreamGenerator {
  public:
   StreamGenerator(uint16_t start_seq_num, uint32_t start_timestamp,
                   int64_t current_time)
       : packets_(),
         sequence_number_(start_seq_num),
         timestamp_(start_timestamp),
         start_time_(current_time) {}

   void Init(uint16_t start_seq_num, uint32_t start_timestamp,
             int64_t current_time) {
     packets_.clear();
     sequence_number_ = start_seq_num;
     timestamp_ = start_timestamp;
     start_time_ = current_time;
   }

   void GenerateFrame(FrameType type, int num_media_packets,
                      int num_empty_packets, int64_t current_time) {
     timestamp_ += 90 * (current_time - start_time_);
     // Move the sequence number counter if all packets from the previous frame
     // wasn't collected.
     sequence_number_ += packets_.size();
     packets_.clear();
     for (int i = 0; i < num_media_packets; ++i) {
       packets_.push_back(GeneratePacket(sequence_number_,
                                         timestamp_,
                                         (i == 0),
                                         (i == num_media_packets - 1),
                                         type));
       ++sequence_number_;
     }
     for (int i = 0; i < num_empty_packets; ++i) {
       packets_.push_back(GeneratePacket(sequence_number_,
                                         timestamp_,
                                         false,
                                         false,
                                         kFrameEmpty));
       ++sequence_number_;
     }
   }

   static VCMPacket GeneratePacket(uint16_t sequence_number,
                                   uint32_t timestamp,
                                   bool first_packet,
                                   bool marker_bit,
                                   FrameType type) {
     VCMPacket packet;
     packet.seqNum = sequence_number;
     packet.timestamp = timestamp;
     packet.frameType = type;
     packet.isFirstPacket = first_packet;
     packet.markerBit = marker_bit;
     if (packet.isFirstPacket)
       packet.completeNALU = kNaluStart;
     else if (packet.markerBit)
       packet.completeNALU = kNaluEnd;
     else
       packet.completeNALU = kNaluIncomplete;
     return packet;
   }

   bool PopPacket(VCMPacket* packet, int index) {
     std::list<VCMPacket>::iterator it = GetPacketIterator(index);
     if (it == packets_.end())
       return false;
     if (packet)
       *packet = (*it);
     packets_.erase(it);
     return true;
   }

   bool GetPacket(VCMPacket* packet, int index) {
     std::list<VCMPacket>::iterator it = GetPacketIterator(index);
     if (it == packets_.end())
       return false;
     if (packet)
       *packet = (*it);
     return true;
   }

   bool NextPacket(VCMPacket* packet) {
     if (packets_.empty())
       return false;
     if (packet != NULL)
       *packet = packets_.front();
     packets_.pop_front();
     return true;
   }

   uint16_t NextSequenceNumber() const {
     if (packets_.empty())
       return sequence_number_;
     return packets_.front().seqNum;
   }

   int PacketsRemaining() const {
     return packets_.size();
   }

  private:
   std::list<VCMPacket>::iterator GetPacketIterator(int index) {
     std::list<VCMPacket>::iterator it = packets_.begin();
     for (int i = 0; i < index; ++i) {
       ++it;
       if (it == packets_.end()) break;
     }
     return it;
   }

   std::list<VCMPacket> packets_;
   uint16_t sequence_number_;
   uint32_t timestamp_;
   int64_t start_time_;

   DISALLOW_COPY_AND_ASSIGN(StreamGenerator);
 };

 class TestRunningJitterBuffer : public ::testing::Test {
  protected:
   enum { kDataBufferSize = 10 };
   enum { kDefaultFrameRate = 25 };
   enum { kDefaultFramePeriodMs = 1000 / kDefaultFrameRate };

   virtual void SetUp() {
     clock_ = new FakeTickTime(0);
     jitter_buffer_ = new VCMJitterBuffer(clock_);
     stream_generator = new StreamGenerator(0, 0,
                                            clock_->MillisecondTimestamp());
     jitter_buffer_->Start();
     memset(data_buffer_, 0, kDataBufferSize);
   }

   virtual void TearDown() {
     jitter_buffer_->Stop();
     delete stream_generator;
     delete jitter_buffer_;
     delete clock_;
   }

   VCMFrameBufferEnum InsertPacketAndPop(int index) {
     VCMPacket packet;
     VCMEncodedFrame* frame;

     packet.dataPtr = data_buffer_;
     bool packet_available = stream_generator->PopPacket(&packet, index);
     EXPECT_TRUE(packet_available);
     if (!packet_available)
       return kStateError;  // Return here to avoid crashes below.
     EXPECT_EQ(VCM_OK, jitter_buffer_->GetFrame(packet, frame));
     return jitter_buffer_->InsertPacket(frame, packet);
   }

   VCMFrameBufferEnum InsertPacket(int index) {
     VCMPacket packet;
     VCMEncodedFrame* frame;

     packet.dataPtr = data_buffer_;
     bool packet_available = stream_generator->GetPacket(&packet, index);
     EXPECT_TRUE(packet_available);
     if (!packet_available)
       return kStateError;  // Return here to avoid crashes below.
     EXPECT_EQ(VCM_OK, jitter_buffer_->GetFrame(packet, frame));
     return jitter_buffer_->InsertPacket(frame, packet);
   }

   void InsertFrame(FrameType frame_type) {
     stream_generator->GenerateFrame(frame_type,
                                     (frame_type != kFrameEmpty) ? 1 : 0,
                                     (frame_type == kFrameEmpty) ? 1 : 0,
                                     clock_->MillisecondTimestamp());
     EXPECT_EQ(kFirstPacket, InsertPacketAndPop(0));
     clock_->IncrementDebugClock(kDefaultFramePeriodMs);
   }

   void InsertFrames(int num_frames, FrameType frame_type) {
     for (int i = 0; i < num_frames; ++i) {
       InsertFrame(frame_type);
     }
   }

   void DropFrame(int num_packets) {
     stream_generator->GenerateFrame(kVideoFrameDelta, num_packets, 0,
                                     clock_->MillisecondTimestamp());
     clock_->IncrementDebugClock(kDefaultFramePeriodMs);
   }

   bool DecodeCompleteFrame() {
     VCMEncodedFrame* frame = jitter_buffer_->GetCompleteFrameForDecoding(0);
     bool ret = (frame != NULL);
     jitter_buffer_->ReleaseFrame(frame);
     return ret;
   }

   bool DecodeFrame() {
     VCMEncodedFrame* frame = jitter_buffer_->GetFrameForDecoding();
     bool ret = (frame != NULL);
     jitter_buffer_->ReleaseFrame(frame);
     return ret;
   }

   VCMJitterBuffer* jitter_buffer_;
   StreamGenerator* stream_generator;
   FakeTickTime* clock_;
   uint8_t data_buffer_[kDataBufferSize];
 };

 class TestJitterBufferNack : public TestRunningJitterBuffer {
  protected:
   virtual void SetUp() {
     TestRunningJitterBuffer::SetUp();
     jitter_buffer_->SetNackMode(kNackInfinite, -1, -1);
   }

   virtual void TearDown() {
     TestRunningJitterBuffer::TearDown();
   }
 };

 TEST_F(TestRunningJitterBuffer, TestFull) {
   // Insert a key frame and decode it.
   InsertFrame(kVideoFrameKey);
   EXPECT_TRUE(DecodeCompleteFrame());
   DropFrame(1);
   // Fill the jitter buffer.
   InsertFrames(kMaxNumberOfFrames, kVideoFrameDelta);
   // Make sure we can't decode these frames.
   EXPECT_FALSE(DecodeCompleteFrame());
   // This frame will make the jitter buffer recycle frames until a key frame.
   // Since none is found it will have to wait until the next key frame before
   // decoding.
   InsertFrame(kVideoFrameDelta);
   EXPECT_FALSE(DecodeCompleteFrame());
 }

 TEST_F(TestRunningJitterBuffer, TestEmptyPackets) {
   // Make sure a frame can get complete even though empty packets are missing.
   stream_generator->GenerateFrame(kVideoFrameKey, 3, 3,
                                   clock_->MillisecondTimestamp());
   EXPECT_EQ(kFirstPacket, InsertPacketAndPop(4));
   EXPECT_EQ(kIncomplete, InsertPacketAndPop(4));
   EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
   EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
   EXPECT_EQ(kCompleteSession, InsertPacketAndPop(0));
 }

 TEST_F(TestJitterBufferNack, TestEmptyPackets) {
   // Make sure empty packets doesn't clog the jitter buffer.
   jitter_buffer_->SetNackMode(kNackHybrid, kLowRttNackMs, -1);
   InsertFrames(kMaxNumberOfFrames, kFrameEmpty);
   InsertFrame(kVideoFrameKey);
   EXPECT_TRUE(DecodeCompleteFrame());
 }

 TEST_F(TestJitterBufferNack, TestNackListFull) {
   // Insert a key frame and decode it.
   InsertFrame(kVideoFrameKey);
   EXPECT_TRUE(DecodeCompleteFrame());

   // Generate and drop |kNackHistoryLength| packets to fill the NACK list.
   DropFrame(kNackHistoryLength);
   // Insert a frame which should trigger a recycle until the next key frame.
   InsertFrame(kVideoFrameDelta);
   EXPECT_FALSE(DecodeCompleteFrame());

   uint16_t nack_list_length = kNackHistoryLength;
   bool extended;
   uint16_t* nack_list = jitter_buffer_->GetNackList(nack_list_length, extended);
   // Verify that the jitter buffer requests a key frame.
   EXPECT_TRUE(nack_list_length == 0xffff && nack_list == NULL);

   InsertFrame(kVideoFrameDelta);
   EXPECT_FALSE(DecodeCompleteFrame());
   EXPECT_FALSE(DecodeFrame());
 }

 TEST_F(TestJitterBufferNack, TestNackBeforeDecode) {
   DropFrame(10);
   // Insert a frame and try to generate a NACK list. Shouldn't get one.
   InsertFrame(kVideoFrameDelta);
   uint16_t nack_list_size = 0;
   bool extended = false;
   uint16_t* list = jitter_buffer_->GetNackList(nack_list_size, extended);
   // No list generated, and a key frame request is signaled.
   EXPECT_TRUE(list == NULL);
   EXPECT_EQ(0xFFFF, nack_list_size);
 }

 TEST_F(TestJitterBufferNack, TestNormalOperation) {
   EXPECT_EQ(kNackInfinite, jitter_buffer_->GetNackMode());

   InsertFrame(kVideoFrameKey);
   EXPECT_TRUE(DecodeFrame());

   //  ----------------------------------------------------------------
   // | 1 | 2 | .. | 8 | 9 | x | 11 | 12 | .. | 19 | x | 21 | .. | 100 |
   //  ----------------------------------------------------------------
   stream_generator->GenerateFrame(kVideoFrameKey, 100, 0,
                                   clock_->MillisecondTimestamp());
   clock_->IncrementDebugClock(kDefaultFramePeriodMs);
   EXPECT_EQ(kFirstPacket, InsertPacketAndPop(0));
   // Verify that the frame is incomplete.
   EXPECT_FALSE(DecodeCompleteFrame());
   while (stream_generator->PacketsRemaining() > 1) {
     if (stream_generator->NextSequenceNumber() % 10 != 0)
       EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
     else
       stream_generator->NextPacket(NULL);  // Drop packet
   }
   EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
   EXPECT_EQ(0, stream_generator->PacketsRemaining());
   EXPECT_FALSE(DecodeCompleteFrame());
   EXPECT_FALSE(DecodeFrame());
   uint16_t nack_list_size = 0;
   bool extended = false;
   uint16_t* list = jitter_buffer_->GetNackList(nack_list_size, extended);
   // Verify the NACK list.
   const int kExpectedNackSize = 9;
   ASSERT_EQ(kExpectedNackSize, nack_list_size);
   for (int i = 0; i < nack_list_size; ++i)
     EXPECT_EQ((1 + i) * 10, list[i]);
 }

 TEST_F(TestJitterBufferNack, TestNormalOperationWrap) {
   //  -------   ------------------------------------------------------------
   // | 65532 | | 65533 | 65534 | 65535 | x | 1 | .. | 9 | x | 11 |.....| 96 |
   //  -------   ------------------------------------------------------------
   stream_generator->Init(65532, 0, clock_->MillisecondTimestamp());
   InsertFrame(kVideoFrameKey);
   EXPECT_TRUE(DecodeCompleteFrame());
   stream_generator->GenerateFrame(kVideoFrameDelta, 100, 0,
                                   clock_->MillisecondTimestamp());
   EXPECT_EQ(kFirstPacket, InsertPacketAndPop(0));
   while (stream_generator->PacketsRemaining() > 1) {
     if (stream_generator->NextSequenceNumber() % 10 != 0)
       EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
     else
       stream_generator->NextPacket(NULL);  // Drop packet
   }
   EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
   EXPECT_EQ(0, stream_generator->PacketsRemaining());
   EXPECT_FALSE(DecodeCompleteFrame());
   EXPECT_FALSE(DecodeCompleteFrame());
   uint16_t nack_list_size = 0;
   bool extended = false;
   uint16_t* list = jitter_buffer_->GetNackList(nack_list_size, extended);
   // Verify the NACK list.
   const int kExpectedNackSize = 10;
   ASSERT_EQ(kExpectedNackSize, nack_list_size);
   for (int i = 0; i < nack_list_size; ++i)
     EXPECT_EQ(i * 10, list[i]);
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2011 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 <string.h>

	#include <list>

	#include "gtest/gtest.h"
	#include "modules/video_coding/main/source/jitter_buffer.h"
	#include "modules/video_coding/main/source/media_opt_util.h"
	#include "modules/video_coding/main/source/mock/fake_tick_time.h"
	#include "modules/video_coding/main/source/packet.h"

	namespace webrtc {

	class StreamGenerator {
	public:
	StreamGenerator(uint16_t start_seq_num, uint32_t start_timestamp,
	int64_t current_time)
	: packets_(),
	sequence_number_(start_seq_num),
	timestamp_(start_timestamp),
	start_time_(current_time) {}

	void Init(uint16_t start_seq_num, uint32_t start_timestamp,
	int64_t current_time) {
	packets_.clear();
	sequence_number_ = start_seq_num;
	timestamp_ = start_timestamp;
	start_time_ = current_time;
	}

	void GenerateFrame(FrameType type, int num_media_packets,
	int num_empty_packets, int64_t current_time) {
	timestamp_ += 90 * (current_time - start_time_);
	// Move the sequence number counter if all packets from the previous frame
	// wasn't collected.
	sequence_number_ += packets_.size();
	packets_.clear();
	for (int i = 0; i < num_media_packets; ++i) {
	packets_.push_back(GeneratePacket(sequence_number_,
	timestamp_,
	(i == 0),
	(i == num_media_packets - 1),
	type));
	++sequence_number_;
	}
	for (int i = 0; i < num_empty_packets; ++i) {
	packets_.push_back(GeneratePacket(sequence_number_,
	timestamp_,
	false,
	false,
	kFrameEmpty));
	++sequence_number_;
	}
	}

	static VCMPacket GeneratePacket(uint16_t sequence_number,
	uint32_t timestamp,
	bool first_packet,
	bool marker_bit,
	FrameType type) {
	VCMPacket packet;
	packet.seqNum = sequence_number;
	packet.timestamp = timestamp;
	packet.frameType = type;
	packet.isFirstPacket = first_packet;
	packet.markerBit = marker_bit;
	if (packet.isFirstPacket)
	packet.completeNALU = kNaluStart;
	else if (packet.markerBit)
	packet.completeNALU = kNaluEnd;
	else
	packet.completeNALU = kNaluIncomplete;
	return packet;
	}

	bool PopPacket(VCMPacket* packet, int index) {
	std::list<VCMPacket>::iterator it = GetPacketIterator(index);
	if (it == packets_.end())
	return false;
	if (packet)
	packet = (it);
	packets_.erase(it);
	return true;
	}

	bool GetPacket(VCMPacket* packet, int index) {
	std::list<VCMPacket>::iterator it = GetPacketIterator(index);
	if (it == packets_.end())
	return false;
	if (packet)
	packet = (it);
	return true;
	}

	bool NextPacket(VCMPacket* packet) {
	if (packets_.empty())
	return false;
	if (packet != NULL)
	*packet = packets_.front();
	packets_.pop_front();
	return true;
	}

	uint16_t NextSequenceNumber() const {
	if (packets_.empty())
	return sequence_number_;
	return packets_.front().seqNum;
	}

	int PacketsRemaining() const {
	return packets_.size();
	}

	private:
	std::list<VCMPacket>::iterator GetPacketIterator(int index) {
	std::list<VCMPacket>::iterator it = packets_.begin();
	for (int i = 0; i < index; ++i) {
	++it;
	if (it == packets_.end()) break;
	}
	return it;
	}

	std::list<VCMPacket> packets_;
	uint16_t sequence_number_;
	uint32_t timestamp_;
	int64_t start_time_;

	DISALLOW_COPY_AND_ASSIGN(StreamGenerator);
	};

	class TestRunningJitterBuffer : public ::testing::Test {
	protected:
	enum { kDataBufferSize = 10 };
	enum { kDefaultFrameRate = 25 };
	enum { kDefaultFramePeriodMs = 1000 / kDefaultFrameRate };

	virtual void SetUp() {
	clock_ = new FakeTickTime(0);
	jitter_buffer_ = new VCMJitterBuffer(clock_);
	stream_generator = new StreamGenerator(0, 0,
	clock_->MillisecondTimestamp());
	jitter_buffer_->Start();
	memset(data_buffer_, 0, kDataBufferSize);
	}

	virtual void TearDown() {
	jitter_buffer_->Stop();
	delete stream_generator;
	delete jitter_buffer_;
	delete clock_;
	}

	VCMFrameBufferEnum InsertPacketAndPop(int index) {
	VCMPacket packet;
	VCMEncodedFrame* frame;

	packet.dataPtr = data_buffer_;
	bool packet_available = stream_generator->PopPacket(&packet, index);
	EXPECT_TRUE(packet_available);
	if (!packet_available)
	return kStateError; // Return here to avoid crashes below.
	EXPECT_EQ(VCM_OK, jitter_buffer_->GetFrame(packet, frame));
	return jitter_buffer_->InsertPacket(frame, packet);
	}

	VCMFrameBufferEnum InsertPacket(int index) {
	VCMPacket packet;
	VCMEncodedFrame* frame;

	packet.dataPtr = data_buffer_;
	bool packet_available = stream_generator->GetPacket(&packet, index);
	EXPECT_TRUE(packet_available);
	if (!packet_available)
	return kStateError; // Return here to avoid crashes below.
	EXPECT_EQ(VCM_OK, jitter_buffer_->GetFrame(packet, frame));
	return jitter_buffer_->InsertPacket(frame, packet);
	}

	void InsertFrame(FrameType frame_type) {
	stream_generator->GenerateFrame(frame_type,
	(frame_type != kFrameEmpty) ? 1 : 0,
	(frame_type == kFrameEmpty) ? 1 : 0,
	clock_->MillisecondTimestamp());
	EXPECT_EQ(kFirstPacket, InsertPacketAndPop(0));
	clock_->IncrementDebugClock(kDefaultFramePeriodMs);
	}

	void InsertFrames(int num_frames, FrameType frame_type) {
	for (int i = 0; i < num_frames; ++i) {
	InsertFrame(frame_type);
	}
	}

	void DropFrame(int num_packets) {
	stream_generator->GenerateFrame(kVideoFrameDelta, num_packets, 0,
	clock_->MillisecondTimestamp());
	clock_->IncrementDebugClock(kDefaultFramePeriodMs);
	}

	bool DecodeCompleteFrame() {
	VCMEncodedFrame* frame = jitter_buffer_->GetCompleteFrameForDecoding(0);
	bool ret = (frame != NULL);
	jitter_buffer_->ReleaseFrame(frame);
	return ret;
	}

	bool DecodeFrame() {
	VCMEncodedFrame* frame = jitter_buffer_->GetFrameForDecoding();
	bool ret = (frame != NULL);
	jitter_buffer_->ReleaseFrame(frame);
	return ret;
	}

	VCMJitterBuffer* jitter_buffer_;
	StreamGenerator* stream_generator;
	FakeTickTime* clock_;
	uint8_t data_buffer_[kDataBufferSize];
	};

	class TestJitterBufferNack : public TestRunningJitterBuffer {
	protected:
	virtual void SetUp() {
	TestRunningJitterBuffer::SetUp();
	jitter_buffer_->SetNackMode(kNackInfinite, -1, -1);
	}

	virtual void TearDown() {
	TestRunningJitterBuffer::TearDown();
	}
	};

	TEST_F(TestRunningJitterBuffer, TestFull) {
	// Insert a key frame and decode it.
	InsertFrame(kVideoFrameKey);
	EXPECT_TRUE(DecodeCompleteFrame());
	DropFrame(1);
	// Fill the jitter buffer.
	InsertFrames(kMaxNumberOfFrames, kVideoFrameDelta);
	// Make sure we can't decode these frames.
	EXPECT_FALSE(DecodeCompleteFrame());
	// This frame will make the jitter buffer recycle frames until a key frame.
	// Since none is found it will have to wait until the next key frame before
	// decoding.
	InsertFrame(kVideoFrameDelta);
	EXPECT_FALSE(DecodeCompleteFrame());
	}

	TEST_F(TestRunningJitterBuffer, TestEmptyPackets) {
	// Make sure a frame can get complete even though empty packets are missing.
	stream_generator->GenerateFrame(kVideoFrameKey, 3, 3,
	clock_->MillisecondTimestamp());
	EXPECT_EQ(kFirstPacket, InsertPacketAndPop(4));
	EXPECT_EQ(kIncomplete, InsertPacketAndPop(4));
	EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
	EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
	EXPECT_EQ(kCompleteSession, InsertPacketAndPop(0));
	}

	TEST_F(TestJitterBufferNack, TestEmptyPackets) {
	// Make sure empty packets doesn't clog the jitter buffer.
	jitter_buffer_->SetNackMode(kNackHybrid, kLowRttNackMs, -1);
	InsertFrames(kMaxNumberOfFrames, kFrameEmpty);
	InsertFrame(kVideoFrameKey);
	EXPECT_TRUE(DecodeCompleteFrame());
	}

	TEST_F(TestJitterBufferNack, TestNackListFull) {
	// Insert a key frame and decode it.
	InsertFrame(kVideoFrameKey);
	EXPECT_TRUE(DecodeCompleteFrame());

	// Generate and drop \|kNackHistoryLength\| packets to fill the NACK list.
	DropFrame(kNackHistoryLength);
	// Insert a frame which should trigger a recycle until the next key frame.
	InsertFrame(kVideoFrameDelta);
	EXPECT_FALSE(DecodeCompleteFrame());

	uint16_t nack_list_length = kNackHistoryLength;
	bool extended;
	uint16_t* nack_list = jitter_buffer_->GetNackList(nack_list_length, extended);
	// Verify that the jitter buffer requests a key frame.
	EXPECT_TRUE(nack_list_length == 0xffff && nack_list == NULL);

	InsertFrame(kVideoFrameDelta);
	EXPECT_FALSE(DecodeCompleteFrame());
	EXPECT_FALSE(DecodeFrame());
	}

	TEST_F(TestJitterBufferNack, TestNackBeforeDecode) {
	DropFrame(10);
	// Insert a frame and try to generate a NACK list. Shouldn't get one.
	InsertFrame(kVideoFrameDelta);
	uint16_t nack_list_size = 0;
	bool extended = false;
	uint16_t* list = jitter_buffer_->GetNackList(nack_list_size, extended);
	// No list generated, and a key frame request is signaled.
	EXPECT_TRUE(list == NULL);
	EXPECT_EQ(0xFFFF, nack_list_size);
	}

	TEST_F(TestJitterBufferNack, TestNormalOperation) {
	EXPECT_EQ(kNackInfinite, jitter_buffer_->GetNackMode());

	InsertFrame(kVideoFrameKey);
	EXPECT_TRUE(DecodeFrame());

	// ----------------------------------------------------------------
	// \| 1 \| 2 \| .. \| 8 \| 9 \| x \| 11 \| 12 \| .. \| 19 \| x \| 21 \| .. \| 100 \|
	// ----------------------------------------------------------------
	stream_generator->GenerateFrame(kVideoFrameKey, 100, 0,
	clock_->MillisecondTimestamp());
	clock_->IncrementDebugClock(kDefaultFramePeriodMs);
	EXPECT_EQ(kFirstPacket, InsertPacketAndPop(0));
	// Verify that the frame is incomplete.
	EXPECT_FALSE(DecodeCompleteFrame());
	while (stream_generator->PacketsRemaining() > 1) {
	if (stream_generator->NextSequenceNumber() % 10 != 0)
	EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
	else
	stream_generator->NextPacket(NULL); // Drop packet
	}
	EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
	EXPECT_EQ(0, stream_generator->PacketsRemaining());
	EXPECT_FALSE(DecodeCompleteFrame());
	EXPECT_FALSE(DecodeFrame());
	uint16_t nack_list_size = 0;
	bool extended = false;
	uint16_t* list = jitter_buffer_->GetNackList(nack_list_size, extended);
	// Verify the NACK list.
	const int kExpectedNackSize = 9;
	ASSERT_EQ(kExpectedNackSize, nack_list_size);
	for (int i = 0; i < nack_list_size; ++i)
	EXPECT_EQ((1 + i) * 10, list[i]);
	}

	TEST_F(TestJitterBufferNack, TestNormalOperationWrap) {
	// ------- ------------------------------------------------------------
	// \| 65532 \| \| 65533 \| 65534 \| 65535 \| x \| 1 \| .. \| 9 \| x \| 11 \|.....\| 96 \|
	// ------- ------------------------------------------------------------
	stream_generator->Init(65532, 0, clock_->MillisecondTimestamp());
	InsertFrame(kVideoFrameKey);
	EXPECT_TRUE(DecodeCompleteFrame());
	stream_generator->GenerateFrame(kVideoFrameDelta, 100, 0,
	clock_->MillisecondTimestamp());
	EXPECT_EQ(kFirstPacket, InsertPacketAndPop(0));
	while (stream_generator->PacketsRemaining() > 1) {
	if (stream_generator->NextSequenceNumber() % 10 != 0)
	EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
	else
	stream_generator->NextPacket(NULL); // Drop packet
	}
	EXPECT_EQ(kIncomplete, InsertPacketAndPop(0));
	EXPECT_EQ(0, stream_generator->PacketsRemaining());
	EXPECT_FALSE(DecodeCompleteFrame());
	EXPECT_FALSE(DecodeCompleteFrame());
	uint16_t nack_list_size = 0;
	bool extended = false;
	uint16_t* list = jitter_buffer_->GetNackList(nack_list_size, extended);
	// Verify the NACK list.
	const int kExpectedNackSize = 10;
	ASSERT_EQ(kExpectedNackSize, nack_list_size);
	for (int i = 0; i < nack_list_size; ++i)
	EXPECT_EQ(i * 10, list[i]);
	}

	} // namespace webrtc