modules/rtp_rtcp/source/ulpfec_generator_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 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 "modules/rtp_rtcp/source/ulpfec_generator.h"

 #include <list>
 #include <memory>
 #include <utility>
 #include <vector>

 #include "modules/rtp_rtcp/source/byte_io.h"
 #include "modules/rtp_rtcp/source/fec_test_helper.h"
 #include "modules/rtp_rtcp/source/forward_error_correction.h"
 #include "test/gtest.h"

 namespace webrtc {

 namespace {
 using test::fec::AugmentedPacket;
 using test::fec::AugmentedPacketGenerator;

 constexpr int kFecPayloadType = 96;
 constexpr int kRedPayloadType = 97;
 constexpr uint32_t kMediaSsrc = 835424;
 }  // namespace

 void VerifyHeader(uint16_t seq_num,
                   uint32_t timestamp,
                   int red_payload_type,
                   int fec_payload_type,
                   bool marker_bit,
                   const rtc::CopyOnWriteBuffer& data) {
   // Marker bit not set.
   EXPECT_EQ(marker_bit ? 0x80 : 0, data[1] & 0x80);
   EXPECT_EQ(red_payload_type, data[1] & 0x7F);
   EXPECT_EQ(seq_num, (data[2] << 8) + data[3]);
   uint32_t parsed_timestamp =
       (data[4] << 24) + (data[5] << 16) + (data[6] << 8) + data[7];
   EXPECT_EQ(timestamp, parsed_timestamp);
   EXPECT_EQ(static_cast<uint8_t>(fec_payload_type), data[kRtpHeaderSize]);
 }

 class UlpfecGeneratorTest : public ::testing::Test {
  protected:
   UlpfecGeneratorTest()
       : fake_clock_(1),
         ulpfec_generator_(kRedPayloadType, kFecPayloadType, &fake_clock_),
         packet_generator_(kMediaSsrc) {}

   SimulatedClock fake_clock_;
   UlpfecGenerator ulpfec_generator_;
   AugmentedPacketGenerator packet_generator_;
 };

 // Verifies bug found via fuzzing, where a gap in the packet sequence caused us
 // to move past the end of the current FEC packet mask byte without moving to
 // the next byte. That likely caused us to repeatedly read from the same byte,
 // and if that byte didn't protect packets we would generate empty FEC.
 TEST_F(UlpfecGeneratorTest, NoEmptyFecWithSeqNumGaps) {
   struct Packet {
     size_t header_size;
     size_t payload_size;
     uint16_t seq_num;
     bool marker_bit;
   };
   std::vector<Packet> protected_packets;
   protected_packets.push_back({15, 3, 41, 0});
   protected_packets.push_back({14, 1, 43, 0});
   protected_packets.push_back({19, 0, 48, 0});
   protected_packets.push_back({19, 0, 50, 0});
   protected_packets.push_back({14, 3, 51, 0});
   protected_packets.push_back({13, 8, 52, 0});
   protected_packets.push_back({19, 2, 53, 0});
   protected_packets.push_back({12, 3, 54, 0});
   protected_packets.push_back({21, 0, 55, 0});
   protected_packets.push_back({13, 3, 57, 1});
   FecProtectionParams params = {117, 3, kFecMaskBursty};
   ulpfec_generator_.SetProtectionParameters(params, params);
   for (Packet p : protected_packets) {
     RtpPacketToSend packet(nullptr);
     packet.SetMarker(p.marker_bit);
     packet.AllocateExtension(RTPExtensionType::kRtpExtensionMid,
                              p.header_size - packet.headers_size());
     packet.SetSequenceNumber(p.seq_num);
     packet.AllocatePayload(p.payload_size);
     ulpfec_generator_.AddPacketAndGenerateFec(packet);

     std::vector<std::unique_ptr<RtpPacketToSend>> fec_packets =
         ulpfec_generator_.GetFecPackets();
     if (!p.marker_bit) {
       EXPECT_TRUE(fec_packets.empty());
     } else {
       EXPECT_FALSE(fec_packets.empty());
     }
   }
 }

 TEST_F(UlpfecGeneratorTest, OneFrameFec) {
   // The number of media packets (|kNumPackets|), number of frames (one for
   // this test), and the protection factor (|params->fec_rate|) are set to make
   // sure the conditions for generating FEC are satisfied. This means:
   // (1) protection factor is high enough so that actual overhead over 1 frame
   // of packets is within |kMaxExcessOverhead|, and (2) the total number of
   // media packets for 1 frame is at least |minimum_media_packets_fec_|.
   constexpr size_t kNumPackets = 4;
   FecProtectionParams params = {15, 3, kFecMaskRandom};
   packet_generator_.NewFrame(kNumPackets);
   // Expecting one FEC packet.
   ulpfec_generator_.SetProtectionParameters(params, params);
   uint32_t last_timestamp = 0;
   for (size_t i = 0; i < kNumPackets; ++i) {
     std::unique_ptr<AugmentedPacket> packet =
         packet_generator_.NextPacket(i, 10);
     RtpPacketToSend rtp_packet(nullptr);
     EXPECT_TRUE(rtp_packet.Parse(packet->data.data(), packet->data.size()));
     ulpfec_generator_.AddPacketAndGenerateFec(rtp_packet);
     last_timestamp = packet->header.timestamp;
   }
   std::vector<std::unique_ptr<RtpPacketToSend>> fec_packets =
       ulpfec_generator_.GetFecPackets();
   EXPECT_EQ(fec_packets.size(), 1u);
   uint16_t seq_num = packet_generator_.NextPacketSeqNum();
   fec_packets[0]->SetSequenceNumber(seq_num);
   EXPECT_TRUE(ulpfec_generator_.GetFecPackets().empty());

   EXPECT_EQ(fec_packets[0]->headers_size(), kRtpHeaderSize);

   VerifyHeader(seq_num, last_timestamp, kRedPayloadType, kFecPayloadType, false,
                fec_packets[0]->Buffer());
 }

 TEST_F(UlpfecGeneratorTest, TwoFrameFec) {
   // The number of media packets/frame (|kNumPackets|), the number of frames
   // (|kNumFrames|), and the protection factor (|params->fec_rate|) are set to
   // make sure the conditions for generating FEC are satisfied. This means:
   // (1) protection factor is high enough so that actual overhead over
   // |kNumFrames| is within |kMaxExcessOverhead|, and (2) the total number of
   // media packets for |kNumFrames| frames is at least
   // |minimum_media_packets_fec_|.
   constexpr size_t kNumPackets = 2;
   constexpr size_t kNumFrames = 2;

   FecProtectionParams params = {15, 3, kFecMaskRandom};
   // Expecting one FEC packet.
   ulpfec_generator_.SetProtectionParameters(params, params);
   uint32_t last_timestamp = 0;
   for (size_t i = 0; i < kNumFrames; ++i) {
     packet_generator_.NewFrame(kNumPackets);
     for (size_t j = 0; j < kNumPackets; ++j) {
       std::unique_ptr<AugmentedPacket> packet =
           packet_generator_.NextPacket(i * kNumPackets + j, 10);
       RtpPacketToSend rtp_packet(nullptr);
       EXPECT_TRUE(rtp_packet.Parse(packet->data.data(), packet->data.size()));
       ulpfec_generator_.AddPacketAndGenerateFec(rtp_packet);
       last_timestamp = packet->header.timestamp;
     }
   }
   std::vector<std::unique_ptr<RtpPacketToSend>> fec_packets =
       ulpfec_generator_.GetFecPackets();
   EXPECT_EQ(fec_packets.size(), 1u);
   const uint16_t seq_num = packet_generator_.NextPacketSeqNum();
   fec_packets[0]->SetSequenceNumber(seq_num);
   VerifyHeader(seq_num, last_timestamp, kRedPayloadType, kFecPayloadType, false,
                fec_packets[0]->Buffer());
 }

 TEST_F(UlpfecGeneratorTest, MixedMediaRtpHeaderLengths) {
   constexpr size_t kShortRtpHeaderLength = 12;
   constexpr size_t kLongRtpHeaderLength = 16;

   // Only one frame required to generate FEC.
   FecProtectionParams params = {127, 1, kFecMaskRandom};
   ulpfec_generator_.SetProtectionParameters(params, params);

   // Fill up internal buffer with media packets with short RTP header length.
   packet_generator_.NewFrame(kUlpfecMaxMediaPackets + 1);
   for (size_t i = 0; i < kUlpfecMaxMediaPackets; ++i) {
     std::unique_ptr<AugmentedPacket> packet =
         packet_generator_.NextPacket(i, 10);
     RtpPacketToSend rtp_packet(nullptr);
     EXPECT_TRUE(rtp_packet.Parse(packet->data.data(), packet->data.size()));
     EXPECT_EQ(rtp_packet.headers_size(), kShortRtpHeaderLength);
     ulpfec_generator_.AddPacketAndGenerateFec(rtp_packet);
     EXPECT_TRUE(ulpfec_generator_.GetFecPackets().empty());
   }

   // Kick off FEC generation with media packet with long RTP header length.
   // Since the internal buffer is full, this packet will not be protected.
   std::unique_ptr<AugmentedPacket> packet =
       packet_generator_.NextPacket(kUlpfecMaxMediaPackets, 10);
   RtpPacketToSend rtp_packet(nullptr);
   EXPECT_TRUE(rtp_packet.Parse(packet->data.data(), packet->data.size()));
   EXPECT_TRUE(rtp_packet.SetPayloadSize(0) != nullptr);
   const uint32_t csrcs[]{1};
   rtp_packet.SetCsrcs(csrcs);

   EXPECT_EQ(rtp_packet.headers_size(), kLongRtpHeaderLength);

   ulpfec_generator_.AddPacketAndGenerateFec(rtp_packet);
   std::vector<std::unique_ptr<RtpPacketToSend>> fec_packets =
       ulpfec_generator_.GetFecPackets();
   EXPECT_FALSE(fec_packets.empty());

   // Ensure that the RED header is placed correctly, i.e. the correct
   // RTP header length was used in the RED packet creation.
   uint16_t seq_num = packet_generator_.NextPacketSeqNum();
   for (const auto& fec_packet : fec_packets) {
     fec_packet->SetSequenceNumber(seq_num++);
     EXPECT_EQ(kFecPayloadType, fec_packet->data()[kShortRtpHeaderLength]);
   }
 }

 TEST_F(UlpfecGeneratorTest, UpdatesProtectionParameters) {
   const FecProtectionParams kKeyFrameParams = {25, /*max_fec_frames=*/2,
                                                kFecMaskRandom};
   const FecProtectionParams kDeltaFrameParams = {25, /*max_fec_frames=*/5,
                                                  kFecMaskRandom};

   ulpfec_generator_.SetProtectionParameters(kDeltaFrameParams, kKeyFrameParams);

   // No params applied yet.
   EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 0);

   // Helper function to add a single-packet frame market as either key-frame
   // or delta-frame.
   auto add_frame = [&](bool is_keyframe) {
     packet_generator_.NewFrame(1);
     std::unique_ptr<AugmentedPacket> packet =
         packet_generator_.NextPacket(0, 10);
     RtpPacketToSend rtp_packet(nullptr);
     EXPECT_TRUE(rtp_packet.Parse(packet->data.data(), packet->data.size()));
     rtp_packet.set_is_key_frame(is_keyframe);
     ulpfec_generator_.AddPacketAndGenerateFec(rtp_packet);
   };

   // Add key-frame, keyframe params should apply, no FEC generated yet.
   add_frame(true);
   EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 2);
   EXPECT_TRUE(ulpfec_generator_.GetFecPackets().empty());

   // Add delta-frame, generated FEC packet. Params will not be updated until
   // next added packet though.
   add_frame(false);
   EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 2);
   EXPECT_FALSE(ulpfec_generator_.GetFecPackets().empty());

   // Add delta-frame, now params get updated.
   add_frame(false);
   EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 5);
   EXPECT_TRUE(ulpfec_generator_.GetFecPackets().empty());

   // Add yet another delta-frame.
   add_frame(false);
   EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 5);
   EXPECT_TRUE(ulpfec_generator_.GetFecPackets().empty());

   // Add key-frame, params immediately switch to key-frame ones. The two
   // buffered frames plus the key-frame is protected and fec emitted,
   // even though the frame count is technically over the keyframe frame count
   // threshold.
   add_frame(true);
   EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 2);
   EXPECT_FALSE(ulpfec_generator_.GetFecPackets().empty());
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 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 "modules/rtp_rtcp/source/ulpfec_generator.h"

	#include <list>
	#include <memory>
	#include <utility>
	#include <vector>

	#include "modules/rtp_rtcp/source/byte_io.h"
	#include "modules/rtp_rtcp/source/fec_test_helper.h"
	#include "modules/rtp_rtcp/source/forward_error_correction.h"
	#include "test/gtest.h"

	namespace webrtc {

	namespace {
	using test::fec::AugmentedPacket;
	using test::fec::AugmentedPacketGenerator;

	constexpr int kFecPayloadType = 96;
	constexpr int kRedPayloadType = 97;
	constexpr uint32_t kMediaSsrc = 835424;
	} // namespace

	void VerifyHeader(uint16_t seq_num,
	uint32_t timestamp,
	int red_payload_type,
	int fec_payload_type,
	bool marker_bit,
	const rtc::CopyOnWriteBuffer& data) {
	// Marker bit not set.
	EXPECT_EQ(marker_bit ? 0x80 : 0, data[1] & 0x80);
	EXPECT_EQ(red_payload_type, data[1] & 0x7F);
	EXPECT_EQ(seq_num, (data[2] << 8) + data[3]);
	uint32_t parsed_timestamp =
	(data[4] << 24) + (data[5] << 16) + (data[6] << 8) + data[7];
	EXPECT_EQ(timestamp, parsed_timestamp);
	EXPECT_EQ(static_cast<uint8_t>(fec_payload_type), data[kRtpHeaderSize]);
	}

	class UlpfecGeneratorTest : public ::testing::Test {
	protected:
	UlpfecGeneratorTest()
	: fake_clock_(1),
	ulpfec_generator_(kRedPayloadType, kFecPayloadType, &fake_clock_),
	packet_generator_(kMediaSsrc) {}

	SimulatedClock fake_clock_;
	UlpfecGenerator ulpfec_generator_;
	AugmentedPacketGenerator packet_generator_;
	};

	// Verifies bug found via fuzzing, where a gap in the packet sequence caused us
	// to move past the end of the current FEC packet mask byte without moving to
	// the next byte. That likely caused us to repeatedly read from the same byte,
	// and if that byte didn't protect packets we would generate empty FEC.
	TEST_F(UlpfecGeneratorTest, NoEmptyFecWithSeqNumGaps) {
	struct Packet {
	size_t header_size;
	size_t payload_size;
	uint16_t seq_num;
	bool marker_bit;
	};
	std::vector<Packet> protected_packets;
	protected_packets.push_back({15, 3, 41, 0});
	protected_packets.push_back({14, 1, 43, 0});
	protected_packets.push_back({19, 0, 48, 0});
	protected_packets.push_back({19, 0, 50, 0});
	protected_packets.push_back({14, 3, 51, 0});
	protected_packets.push_back({13, 8, 52, 0});
	protected_packets.push_back({19, 2, 53, 0});
	protected_packets.push_back({12, 3, 54, 0});
	protected_packets.push_back({21, 0, 55, 0});
	protected_packets.push_back({13, 3, 57, 1});
	FecProtectionParams params = {117, 3, kFecMaskBursty};
	ulpfec_generator_.SetProtectionParameters(params, params);
	for (Packet p : protected_packets) {
	RtpPacketToSend packet(nullptr);
	packet.SetMarker(p.marker_bit);
	packet.AllocateExtension(RTPExtensionType::kRtpExtensionMid,
	p.header_size - packet.headers_size());
	packet.SetSequenceNumber(p.seq_num);
	packet.AllocatePayload(p.payload_size);
	ulpfec_generator_.AddPacketAndGenerateFec(packet);

	std::vector<std::unique_ptr<RtpPacketToSend>> fec_packets =
	ulpfec_generator_.GetFecPackets();
	if (!p.marker_bit) {
	EXPECT_TRUE(fec_packets.empty());
	} else {
	EXPECT_FALSE(fec_packets.empty());
	}
	}
	}

	TEST_F(UlpfecGeneratorTest, OneFrameFec) {
	// The number of media packets (\|kNumPackets\|), number of frames (one for
	// this test), and the protection factor (\|params->fec_rate\|) are set to make
	// sure the conditions for generating FEC are satisfied. This means:
	// (1) protection factor is high enough so that actual overhead over 1 frame
	// of packets is within \|kMaxExcessOverhead\|, and (2) the total number of
	// media packets for 1 frame is at least \|minimum_media_packets_fec_\|.
	constexpr size_t kNumPackets = 4;
	FecProtectionParams params = {15, 3, kFecMaskRandom};
	packet_generator_.NewFrame(kNumPackets);
	// Expecting one FEC packet.
	ulpfec_generator_.SetProtectionParameters(params, params);
	uint32_t last_timestamp = 0;
	for (size_t i = 0; i < kNumPackets; ++i) {
	std::unique_ptr<AugmentedPacket> packet =
	packet_generator_.NextPacket(i, 10);
	RtpPacketToSend rtp_packet(nullptr);
	EXPECT_TRUE(rtp_packet.Parse(packet->data.data(), packet->data.size()));
	ulpfec_generator_.AddPacketAndGenerateFec(rtp_packet);
	last_timestamp = packet->header.timestamp;
	}
	std::vector<std::unique_ptr<RtpPacketToSend>> fec_packets =
	ulpfec_generator_.GetFecPackets();
	EXPECT_EQ(fec_packets.size(), 1u);
	uint16_t seq_num = packet_generator_.NextPacketSeqNum();
	fec_packets[0]->SetSequenceNumber(seq_num);
	EXPECT_TRUE(ulpfec_generator_.GetFecPackets().empty());

	EXPECT_EQ(fec_packets[0]->headers_size(), kRtpHeaderSize);

	VerifyHeader(seq_num, last_timestamp, kRedPayloadType, kFecPayloadType, false,
	fec_packets[0]->Buffer());
	}

	TEST_F(UlpfecGeneratorTest, TwoFrameFec) {
	// The number of media packets/frame (\|kNumPackets\|), the number of frames
	// (\|kNumFrames\|), and the protection factor (\|params->fec_rate\|) are set to
	// make sure the conditions for generating FEC are satisfied. This means:
	// (1) protection factor is high enough so that actual overhead over
	// \|kNumFrames\| is within \|kMaxExcessOverhead\|, and (2) the total number of
	// media packets for \|kNumFrames\| frames is at least
	// \|minimum_media_packets_fec_\|.
	constexpr size_t kNumPackets = 2;
	constexpr size_t kNumFrames = 2;

	FecProtectionParams params = {15, 3, kFecMaskRandom};
	// Expecting one FEC packet.
	ulpfec_generator_.SetProtectionParameters(params, params);
	uint32_t last_timestamp = 0;
	for (size_t i = 0; i < kNumFrames; ++i) {
	packet_generator_.NewFrame(kNumPackets);
	for (size_t j = 0; j < kNumPackets; ++j) {
	std::unique_ptr<AugmentedPacket> packet =
	packet_generator_.NextPacket(i * kNumPackets + j, 10);
	RtpPacketToSend rtp_packet(nullptr);
	EXPECT_TRUE(rtp_packet.Parse(packet->data.data(), packet->data.size()));
	ulpfec_generator_.AddPacketAndGenerateFec(rtp_packet);
	last_timestamp = packet->header.timestamp;
	}
	}
	std::vector<std::unique_ptr<RtpPacketToSend>> fec_packets =
	ulpfec_generator_.GetFecPackets();
	EXPECT_EQ(fec_packets.size(), 1u);
	const uint16_t seq_num = packet_generator_.NextPacketSeqNum();
	fec_packets[0]->SetSequenceNumber(seq_num);
	VerifyHeader(seq_num, last_timestamp, kRedPayloadType, kFecPayloadType, false,
	fec_packets[0]->Buffer());
	}

	TEST_F(UlpfecGeneratorTest, MixedMediaRtpHeaderLengths) {
	constexpr size_t kShortRtpHeaderLength = 12;
	constexpr size_t kLongRtpHeaderLength = 16;

	// Only one frame required to generate FEC.
	FecProtectionParams params = {127, 1, kFecMaskRandom};
	ulpfec_generator_.SetProtectionParameters(params, params);

	// Fill up internal buffer with media packets with short RTP header length.
	packet_generator_.NewFrame(kUlpfecMaxMediaPackets + 1);
	for (size_t i = 0; i < kUlpfecMaxMediaPackets; ++i) {
	std::unique_ptr<AugmentedPacket> packet =
	packet_generator_.NextPacket(i, 10);
	RtpPacketToSend rtp_packet(nullptr);
	EXPECT_TRUE(rtp_packet.Parse(packet->data.data(), packet->data.size()));
	EXPECT_EQ(rtp_packet.headers_size(), kShortRtpHeaderLength);
	ulpfec_generator_.AddPacketAndGenerateFec(rtp_packet);
	EXPECT_TRUE(ulpfec_generator_.GetFecPackets().empty());
	}

	// Kick off FEC generation with media packet with long RTP header length.
	// Since the internal buffer is full, this packet will not be protected.
	std::unique_ptr<AugmentedPacket> packet =
	packet_generator_.NextPacket(kUlpfecMaxMediaPackets, 10);
	RtpPacketToSend rtp_packet(nullptr);
	EXPECT_TRUE(rtp_packet.Parse(packet->data.data(), packet->data.size()));
	EXPECT_TRUE(rtp_packet.SetPayloadSize(0) != nullptr);
	const uint32_t csrcs[]{1};
	rtp_packet.SetCsrcs(csrcs);

	EXPECT_EQ(rtp_packet.headers_size(), kLongRtpHeaderLength);

	ulpfec_generator_.AddPacketAndGenerateFec(rtp_packet);
	std::vector<std::unique_ptr<RtpPacketToSend>> fec_packets =
	ulpfec_generator_.GetFecPackets();
	EXPECT_FALSE(fec_packets.empty());

	// Ensure that the RED header is placed correctly, i.e. the correct
	// RTP header length was used in the RED packet creation.
	uint16_t seq_num = packet_generator_.NextPacketSeqNum();
	for (const auto& fec_packet : fec_packets) {
	fec_packet->SetSequenceNumber(seq_num++);
	EXPECT_EQ(kFecPayloadType, fec_packet->data()[kShortRtpHeaderLength]);
	}
	}

	TEST_F(UlpfecGeneratorTest, UpdatesProtectionParameters) {
	const FecProtectionParams kKeyFrameParams = {25, /max_fec_frames=/2,
	kFecMaskRandom};
	const FecProtectionParams kDeltaFrameParams = {25, /max_fec_frames=/5,
	kFecMaskRandom};

	ulpfec_generator_.SetProtectionParameters(kDeltaFrameParams, kKeyFrameParams);

	// No params applied yet.
	EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 0);

	// Helper function to add a single-packet frame market as either key-frame
	// or delta-frame.
	auto add_frame = [&](bool is_keyframe) {
	packet_generator_.NewFrame(1);
	std::unique_ptr<AugmentedPacket> packet =
	packet_generator_.NextPacket(0, 10);
	RtpPacketToSend rtp_packet(nullptr);
	EXPECT_TRUE(rtp_packet.Parse(packet->data.data(), packet->data.size()));
	rtp_packet.set_is_key_frame(is_keyframe);
	ulpfec_generator_.AddPacketAndGenerateFec(rtp_packet);
	};

	// Add key-frame, keyframe params should apply, no FEC generated yet.
	add_frame(true);
	EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 2);
	EXPECT_TRUE(ulpfec_generator_.GetFecPackets().empty());

	// Add delta-frame, generated FEC packet. Params will not be updated until
	// next added packet though.
	add_frame(false);
	EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 2);
	EXPECT_FALSE(ulpfec_generator_.GetFecPackets().empty());

	// Add delta-frame, now params get updated.
	add_frame(false);
	EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 5);
	EXPECT_TRUE(ulpfec_generator_.GetFecPackets().empty());

	// Add yet another delta-frame.
	add_frame(false);
	EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 5);
	EXPECT_TRUE(ulpfec_generator_.GetFecPackets().empty());

	// Add key-frame, params immediately switch to key-frame ones. The two
	// buffered frames plus the key-frame is protected and fec emitted,
	// even though the frame count is technically over the keyframe frame count
	// threshold.
	add_frame(true);
	EXPECT_EQ(ulpfec_generator_.CurrentParams().max_fec_frames, 2);
	EXPECT_FALSE(ulpfec_generator_.GetFecPackets().empty());
	}

	} // namespace webrtc