modules/audio_coding/test/TestStereo.cc - external/webrtc - 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/audio_coding/test/TestStereo.h"

 #include <string>

 #include "absl/strings/match.h"
 #include "api/audio_codecs/builtin_audio_decoder_factory.h"
 #include "api/audio_codecs/builtin_audio_encoder_factory.h"
 #include "modules/audio_coding/include/audio_coding_module_typedefs.h"
 #include "modules/include/module_common_types.h"
 #include "rtc_base/strings/string_builder.h"
 #include "test/gtest.h"
 #include "test/testsupport/file_utils.h"

 namespace webrtc {

 // Class for simulating packet handling
 TestPackStereo::TestPackStereo()
     : receiver_acm_(NULL),
       seq_no_(0),
       timestamp_diff_(0),
       last_in_timestamp_(0),
       total_bytes_(0),
       payload_size_(0),
       lost_packet_(false) {}

 TestPackStereo::~TestPackStereo() {}

 void TestPackStereo::RegisterReceiverACM(AudioCodingModule* acm) {
   receiver_acm_ = acm;
   return;
 }

 int32_t TestPackStereo::SendData(const AudioFrameType frame_type,
                                  const uint8_t payload_type,
                                  const uint32_t timestamp,
                                  const uint8_t* payload_data,
                                  const size_t payload_size) {
   RTPHeader rtp_header;
   int32_t status = 0;

   rtp_header.markerBit = false;
   rtp_header.ssrc = 0;
   rtp_header.sequenceNumber = seq_no_++;
   rtp_header.payloadType = payload_type;
   rtp_header.timestamp = timestamp;
   if (frame_type == AudioFrameType::kEmptyFrame) {
     // Skip this frame
     return 0;
   }

   if (lost_packet_ == false) {
     status =
         receiver_acm_->IncomingPacket(payload_data, payload_size, rtp_header);

     if (frame_type != AudioFrameType::kAudioFrameCN) {
       payload_size_ = static_cast<int>(payload_size);
     } else {
       payload_size_ = -1;
     }

     timestamp_diff_ = timestamp - last_in_timestamp_;
     last_in_timestamp_ = timestamp;
     total_bytes_ += payload_size;
   }
   return status;
 }

 uint16_t TestPackStereo::payload_size() {
   return static_cast<uint16_t>(payload_size_);
 }

 uint32_t TestPackStereo::timestamp_diff() {
   return timestamp_diff_;
 }

 void TestPackStereo::reset_payload_size() {
   payload_size_ = 0;
 }

 void TestPackStereo::set_codec_mode(enum StereoMonoMode mode) {
   codec_mode_ = mode;
 }

 void TestPackStereo::set_lost_packet(bool lost) {
   lost_packet_ = lost;
 }

 TestStereo::TestStereo()
     : acm_a_(AudioCodingModule::Create(
           AudioCodingModule::Config(CreateBuiltinAudioDecoderFactory()))),
       acm_b_(AudioCodingModule::Create(
           AudioCodingModule::Config(CreateBuiltinAudioDecoderFactory()))),
       channel_a2b_(NULL),
       test_cntr_(0),
       pack_size_samp_(0),
       pack_size_bytes_(0),
       counter_(0) {}

 TestStereo::~TestStereo() {
   if (channel_a2b_ != NULL) {
     delete channel_a2b_;
     channel_a2b_ = NULL;
   }
 }

 void TestStereo::Perform() {
   uint16_t frequency_hz;
   int audio_channels;
   int codec_channels;

   // Open both mono and stereo test files in 32 kHz.
   const std::string file_name_stereo =
       webrtc::test::ResourcePath("audio_coding/teststereo32kHz", "pcm");
   const std::string file_name_mono =
       webrtc::test::ResourcePath("audio_coding/testfile32kHz", "pcm");
   frequency_hz = 32000;
   in_file_stereo_ = new PCMFile();
   in_file_mono_ = new PCMFile();
   in_file_stereo_->Open(file_name_stereo, frequency_hz, "rb");
   in_file_stereo_->ReadStereo(true);
   in_file_mono_->Open(file_name_mono, frequency_hz, "rb");
   in_file_mono_->ReadStereo(false);

   // Create and initialize two ACMs, one for each side of a one-to-one call.
   ASSERT_TRUE((acm_a_.get() != NULL) && (acm_b_.get() != NULL));
   EXPECT_EQ(0, acm_a_->InitializeReceiver());
   EXPECT_EQ(0, acm_b_->InitializeReceiver());

   acm_b_->SetReceiveCodecs({{103, {"ISAC", 16000, 1}},
                             {104, {"ISAC", 32000, 1}},
                             {107, {"L16", 8000, 1}},
                             {108, {"L16", 16000, 1}},
                             {109, {"L16", 32000, 1}},
                             {111, {"L16", 8000, 2}},
                             {112, {"L16", 16000, 2}},
                             {113, {"L16", 32000, 2}},
                             {0, {"PCMU", 8000, 1}},
                             {110, {"PCMU", 8000, 2}},
                             {8, {"PCMA", 8000, 1}},
                             {118, {"PCMA", 8000, 2}},
                             {102, {"ILBC", 8000, 1}},
                             {9, {"G722", 8000, 1}},
                             {119, {"G722", 8000, 2}},
                             {120, {"OPUS", 48000, 2, {{"stereo", "1"}}}},
                             {13, {"CN", 8000, 1}},
                             {98, {"CN", 16000, 1}},
                             {99, {"CN", 32000, 1}}});

   // Create and connect the channel.
   channel_a2b_ = new TestPackStereo;
   EXPECT_EQ(0, acm_a_->RegisterTransportCallback(channel_a2b_));
   channel_a2b_->RegisterReceiverACM(acm_b_.get());

   char codec_pcma_temp[] = "PCMA";
   RegisterSendCodec('A', codec_pcma_temp, 8000, 64000, 80, 2);

   //
   // Test Stereo-To-Stereo for all codecs.
   //
   audio_channels = 2;
   codec_channels = 2;

   // All codecs are tested for all allowed sampling frequencies, rates and
   // packet sizes.
   channel_a2b_->set_codec_mode(kStereo);
   test_cntr_++;
   OpenOutFile(test_cntr_);
   char codec_g722[] = "G722";
   RegisterSendCodec('A', codec_g722, 16000, 64000, 160, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_g722, 16000, 64000, 320, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_g722, 16000, 64000, 480, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_g722, 16000, 64000, 640, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_g722, 16000, 64000, 800, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_g722, 16000, 64000, 960, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();

   channel_a2b_->set_codec_mode(kStereo);
   test_cntr_++;
   OpenOutFile(test_cntr_);
   char codec_l16[] = "L16";
   RegisterSendCodec('A', codec_l16, 8000, 128000, 80, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_l16, 8000, 128000, 160, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_l16, 8000, 128000, 240, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_l16, 8000, 128000, 320, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();

   test_cntr_++;
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_l16, 16000, 256000, 160, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_l16, 16000, 256000, 320, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_l16, 16000, 256000, 480, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_l16, 16000, 256000, 640, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();

   test_cntr_++;
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_l16, 32000, 512000, 320, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_l16, 32000, 512000, 640, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();
 #ifdef PCMA_AND_PCMU
   channel_a2b_->set_codec_mode(kStereo);
   audio_channels = 2;
   codec_channels = 2;
   test_cntr_++;
   OpenOutFile(test_cntr_);
   char codec_pcma[] = "PCMA";
   RegisterSendCodec('A', codec_pcma, 8000, 64000, 80, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcma, 8000, 64000, 160, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcma, 8000, 64000, 240, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcma, 8000, 64000, 320, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcma, 8000, 64000, 400, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcma, 8000, 64000, 480, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();

   test_cntr_++;
   OpenOutFile(test_cntr_);
   char codec_pcmu[] = "PCMU";
   RegisterSendCodec('A', codec_pcmu, 8000, 64000, 80, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcmu, 8000, 64000, 160, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcmu, 8000, 64000, 240, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcmu, 8000, 64000, 320, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcmu, 8000, 64000, 400, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcmu, 8000, 64000, 480, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();
 #endif
 #ifdef WEBRTC_CODEC_OPUS
   channel_a2b_->set_codec_mode(kStereo);
   audio_channels = 2;
   codec_channels = 2;
   test_cntr_++;
   OpenOutFile(test_cntr_);

   char codec_opus[] = "opus";
   // Run Opus with 10 ms frame size.
   RegisterSendCodec('A', codec_opus, 48000, 64000, 480, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   // Run Opus with 20 ms frame size.
   RegisterSendCodec('A', codec_opus, 48000, 64000, 480 * 2, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   // Run Opus with 40 ms frame size.
   RegisterSendCodec('A', codec_opus, 48000, 64000, 480 * 4, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   // Run Opus with 60 ms frame size.
   RegisterSendCodec('A', codec_opus, 48000, 64000, 480 * 6, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   // Run Opus with 20 ms frame size and different bitrates.
   RegisterSendCodec('A', codec_opus, 48000, 40000, 960, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_opus, 48000, 510000, 960, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();
 #endif
   //
   // Test Mono-To-Stereo for all codecs.
   //
   audio_channels = 1;
   codec_channels = 2;

   test_cntr_++;
   channel_a2b_->set_codec_mode(kStereo);
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_g722, 16000, 64000, 160, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();

   test_cntr_++;
   channel_a2b_->set_codec_mode(kStereo);
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_l16, 8000, 128000, 80, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();

   test_cntr_++;
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_l16, 16000, 256000, 160, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();

   test_cntr_++;
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_l16, 32000, 512000, 320, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();
 #ifdef PCMA_AND_PCMU
   test_cntr_++;
   channel_a2b_->set_codec_mode(kStereo);
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_pcmu, 8000, 64000, 80, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcma, 8000, 64000, 80, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();
 #endif
 #ifdef WEBRTC_CODEC_OPUS
   // Keep encode and decode in stereo.
   test_cntr_++;
   channel_a2b_->set_codec_mode(kStereo);
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_opus, 48000, 64000, 960, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);

   // Encode in mono, decode in stereo mode.
   RegisterSendCodec('A', codec_opus, 48000, 64000, 960, 1);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();
 #endif

   //
   // Test Stereo-To-Mono for all codecs.
   //
   audio_channels = 2;
   codec_channels = 1;
   channel_a2b_->set_codec_mode(kMono);

   // Run stereo audio and mono codec.
   test_cntr_++;
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_g722, 16000, 64000, 160, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();

   test_cntr_++;
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_l16, 8000, 128000, 80, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();

   test_cntr_++;
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_l16, 16000, 256000, 160, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();

   test_cntr_++;
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_l16, 32000, 512000, 320, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();
 #ifdef PCMA_AND_PCMU
   test_cntr_++;
   OpenOutFile(test_cntr_);
   RegisterSendCodec('A', codec_pcmu, 8000, 64000, 80, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   RegisterSendCodec('A', codec_pcma, 8000, 64000, 80, codec_channels);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();
 #endif
 #ifdef WEBRTC_CODEC_OPUS
   test_cntr_++;
   OpenOutFile(test_cntr_);
   // Encode and decode in mono.
   RegisterSendCodec('A', codec_opus, 48000, 32000, 960, codec_channels);
   acm_b_->SetReceiveCodecs({{120, {"OPUS", 48000, 2}}});
   Run(channel_a2b_, audio_channels, codec_channels);

   // Encode in stereo, decode in mono.
   RegisterSendCodec('A', codec_opus, 48000, 32000, 960, 2);
   Run(channel_a2b_, audio_channels, codec_channels);

   out_file_.Close();

   // Test switching between decoding mono and stereo for Opus.

   // Decode in mono.
   test_cntr_++;
   OpenOutFile(test_cntr_);
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();
   // Decode in stereo.
   test_cntr_++;
   OpenOutFile(test_cntr_);
   acm_b_->SetReceiveCodecs({{120, {"OPUS", 48000, 2, {{"stereo", "1"}}}}});
   Run(channel_a2b_, audio_channels, 2);
   out_file_.Close();
   // Decode in mono.
   test_cntr_++;
   OpenOutFile(test_cntr_);
   acm_b_->SetReceiveCodecs({{120, {"OPUS", 48000, 2}}});
   Run(channel_a2b_, audio_channels, codec_channels);
   out_file_.Close();
 #endif

   // Delete the file pointers.
   delete in_file_stereo_;
   delete in_file_mono_;
 }

 // Register Codec to use in the test
 //
 // Input:   side             - which ACM to use, 'A' or 'B'
 //          codec_name       - name to use when register the codec
 //          sampling_freq_hz - sampling frequency in Herz
 //          rate             - bitrate in bytes
 //          pack_size        - packet size in samples
 //          channels         - number of channels; 1 for mono, 2 for stereo
 void TestStereo::RegisterSendCodec(char side,
                                    char* codec_name,
                                    int32_t sampling_freq_hz,
                                    int rate,
                                    int pack_size,
                                    int channels) {
   // Store packet size in samples, used to validate the received packet
   pack_size_samp_ = pack_size;

   // Store the expected packet size in bytes, used to validate the received
   // packet. Add 0.875 to always round up to a whole byte.
   pack_size_bytes_ = (uint16_t)(static_cast<float>(pack_size * rate) /
                                     static_cast<float>(sampling_freq_hz * 8) +
                                 0.875);

   // Set pointer to the ACM where to register the codec
   AudioCodingModule* my_acm = NULL;
   switch (side) {
     case 'A': {
       my_acm = acm_a_.get();
       break;
     }
     case 'B': {
       my_acm = acm_b_.get();
       break;
     }
     default:
       break;
   }
   ASSERT_TRUE(my_acm != NULL);

   auto encoder_factory = CreateBuiltinAudioEncoderFactory();
   const int clockrate_hz = absl::EqualsIgnoreCase(codec_name, "g722")
                                ? sampling_freq_hz / 2
                                : sampling_freq_hz;
   const std::string ptime = rtc::ToString(rtc::CheckedDivExact(
       pack_size, rtc::CheckedDivExact(sampling_freq_hz, 1000)));
   SdpAudioFormat::Parameters params = {{"ptime", ptime}};
   RTC_CHECK(channels == 1 || channels == 2);
   if (absl::EqualsIgnoreCase(codec_name, "opus")) {
     if (channels == 2) {
       params["stereo"] = "1";
     }
     channels = 2;
     params["maxaveragebitrate"] = rtc::ToString(rate);
   }
   constexpr int payload_type = 17;
   auto encoder = encoder_factory->MakeAudioEncoder(
       payload_type, SdpAudioFormat(codec_name, clockrate_hz, channels, params),
       absl::nullopt);
   EXPECT_NE(nullptr, encoder);
   my_acm->SetEncoder(std::move(encoder));

   send_codec_name_ = codec_name;
 }

 void TestStereo::Run(TestPackStereo* channel,
                      int in_channels,
                      int out_channels,
                      int percent_loss) {
   AudioFrame audio_frame;

   int32_t out_freq_hz_b = out_file_.SamplingFrequency();
   uint16_t rec_size;
   uint32_t time_stamp_diff;
   channel->reset_payload_size();
   int error_count = 0;
   int variable_bytes = 0;
   int variable_packets = 0;
   // Set test length to 500 ms (50 blocks of 10 ms each).
   in_file_mono_->SetNum10MsBlocksToRead(50);
   in_file_stereo_->SetNum10MsBlocksToRead(50);
   // Fast-forward 1 second (100 blocks) since the files start with silence.
   in_file_stereo_->FastForward(100);
   in_file_mono_->FastForward(100);

   while (1) {
     // Simulate packet loss by setting |packet_loss_| to "true" in
     // |percent_loss| percent of the loops.
     if (percent_loss > 0) {
       if (counter_ == floor((100 / percent_loss) + 0.5)) {
         counter_ = 0;
         channel->set_lost_packet(true);
       } else {
         channel->set_lost_packet(false);
       }
       counter_++;
     }

     // Add 10 msec to ACM
     if (in_channels == 1) {
       if (in_file_mono_->EndOfFile()) {
         break;
       }
       in_file_mono_->Read10MsData(audio_frame);
     } else {
       if (in_file_stereo_->EndOfFile()) {
         break;
       }
       in_file_stereo_->Read10MsData(audio_frame);
     }
     EXPECT_GE(acm_a_->Add10MsData(audio_frame), 0);

     // Verify that the received packet size matches the settings.
     rec_size = channel->payload_size();
     if ((0 < rec_size) & (rec_size < 65535)) {
       if (strcmp(send_codec_name_, "opus") == 0) {
         // Opus is a variable rate codec, hence calculate the average packet
         // size, and later make sure the average is in the right range.
         variable_bytes += rec_size;
         variable_packets++;
       } else {
         // For fixed rate codecs, check that packet size is correct.
         if ((rec_size != pack_size_bytes_ * out_channels) &&
             (pack_size_bytes_ < 65535)) {
           error_count++;
         }
       }
       // Verify that the timestamp is updated with expected length
       time_stamp_diff = channel->timestamp_diff();
       if ((counter_ > 10) && (time_stamp_diff != pack_size_samp_)) {
         error_count++;
       }
     }

     // Run receive side of ACM
     bool muted;
     EXPECT_EQ(0, acm_b_->PlayoutData10Ms(out_freq_hz_b, &audio_frame, &muted));
     ASSERT_FALSE(muted);

     // Write output speech to file
     out_file_.Write10MsData(
         audio_frame.data(),
         audio_frame.samples_per_channel_ * audio_frame.num_channels_);
   }

   EXPECT_EQ(0, error_count);

   // Check that packet size is in the right range for variable rate codecs,
   // such as Opus.
   if (variable_packets > 0) {
     variable_bytes /= variable_packets;
     EXPECT_NEAR(variable_bytes, pack_size_bytes_, 18);
   }

   if (in_file_mono_->EndOfFile()) {
     in_file_mono_->Rewind();
   }
   if (in_file_stereo_->EndOfFile()) {
     in_file_stereo_->Rewind();
   }
   // Reset in case we ended with a lost packet
   channel->set_lost_packet(false);
 }

 void TestStereo::OpenOutFile(int16_t test_number) {
   std::string file_name;
   rtc::StringBuilder file_stream;
   file_stream << webrtc::test::OutputPath() << "teststereo_out_" << test_number
               << ".pcm";
   file_name = file_stream.str();
   out_file_.Open(file_name, 32000, "wb");
 }

 }  // 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/audio_coding/test/TestStereo.h"

	#include <string>

	#include "absl/strings/match.h"
	#include "api/audio_codecs/builtin_audio_decoder_factory.h"
	#include "api/audio_codecs/builtin_audio_encoder_factory.h"
	#include "modules/audio_coding/include/audio_coding_module_typedefs.h"
	#include "modules/include/module_common_types.h"
	#include "rtc_base/strings/string_builder.h"
	#include "test/gtest.h"
	#include "test/testsupport/file_utils.h"

	namespace webrtc {

	// Class for simulating packet handling
	TestPackStereo::TestPackStereo()
	: receiver_acm_(NULL),
	seq_no_(0),
	timestamp_diff_(0),
	last_in_timestamp_(0),
	total_bytes_(0),
	payload_size_(0),
	lost_packet_(false) {}

	TestPackStereo::~TestPackStereo() {}

	void TestPackStereo::RegisterReceiverACM(AudioCodingModule* acm) {
	receiver_acm_ = acm;
	return;
	}

	int32_t TestPackStereo::SendData(const AudioFrameType frame_type,
	const uint8_t payload_type,
	const uint32_t timestamp,
	const uint8_t* payload_data,
	const size_t payload_size) {
	RTPHeader rtp_header;
	int32_t status = 0;

	rtp_header.markerBit = false;
	rtp_header.ssrc = 0;
	rtp_header.sequenceNumber = seq_no_++;
	rtp_header.payloadType = payload_type;
	rtp_header.timestamp = timestamp;
	if (frame_type == AudioFrameType::kEmptyFrame) {
	// Skip this frame
	return 0;
	}

	if (lost_packet_ == false) {
	status =
	receiver_acm_->IncomingPacket(payload_data, payload_size, rtp_header);

	if (frame_type != AudioFrameType::kAudioFrameCN) {
	payload_size_ = static_cast<int>(payload_size);
	} else {
	payload_size_ = -1;
	}

	timestamp_diff_ = timestamp - last_in_timestamp_;
	last_in_timestamp_ = timestamp;
	total_bytes_ += payload_size;
	}
	return status;
	}

	uint16_t TestPackStereo::payload_size() {
	return static_cast<uint16_t>(payload_size_);
	}

	uint32_t TestPackStereo::timestamp_diff() {
	return timestamp_diff_;
	}

	void TestPackStereo::reset_payload_size() {
	payload_size_ = 0;
	}

	void TestPackStereo::set_codec_mode(enum StereoMonoMode mode) {
	codec_mode_ = mode;
	}

	void TestPackStereo::set_lost_packet(bool lost) {
	lost_packet_ = lost;
	}

	TestStereo::TestStereo()
	: acm_a_(AudioCodingModule::Create(
	AudioCodingModule::Config(CreateBuiltinAudioDecoderFactory()))),
	acm_b_(AudioCodingModule::Create(
	AudioCodingModule::Config(CreateBuiltinAudioDecoderFactory()))),
	channel_a2b_(NULL),
	test_cntr_(0),
	pack_size_samp_(0),
	pack_size_bytes_(0),
	counter_(0) {}

	TestStereo::~TestStereo() {
	if (channel_a2b_ != NULL) {
	delete channel_a2b_;
	channel_a2b_ = NULL;
	}
	}

	void TestStereo::Perform() {
	uint16_t frequency_hz;
	int audio_channels;
	int codec_channels;

	// Open both mono and stereo test files in 32 kHz.
	const std::string file_name_stereo =
	webrtc::test::ResourcePath("audio_coding/teststereo32kHz", "pcm");
	const std::string file_name_mono =
	webrtc::test::ResourcePath("audio_coding/testfile32kHz", "pcm");
	frequency_hz = 32000;
	in_file_stereo_ = new PCMFile();
	in_file_mono_ = new PCMFile();
	in_file_stereo_->Open(file_name_stereo, frequency_hz, "rb");
	in_file_stereo_->ReadStereo(true);
	in_file_mono_->Open(file_name_mono, frequency_hz, "rb");
	in_file_mono_->ReadStereo(false);

	// Create and initialize two ACMs, one for each side of a one-to-one call.
	ASSERT_TRUE((acm_a_.get() != NULL) && (acm_b_.get() != NULL));
	EXPECT_EQ(0, acm_a_->InitializeReceiver());
	EXPECT_EQ(0, acm_b_->InitializeReceiver());

	acm_b_->SetReceiveCodecs({{103, {"ISAC", 16000, 1}},
	{104, {"ISAC", 32000, 1}},
	{107, {"L16", 8000, 1}},
	{108, {"L16", 16000, 1}},
	{109, {"L16", 32000, 1}},
	{111, {"L16", 8000, 2}},
	{112, {"L16", 16000, 2}},
	{113, {"L16", 32000, 2}},
	{0, {"PCMU", 8000, 1}},
	{110, {"PCMU", 8000, 2}},
	{8, {"PCMA", 8000, 1}},
	{118, {"PCMA", 8000, 2}},
	{102, {"ILBC", 8000, 1}},
	{9, {"G722", 8000, 1}},
	{119, {"G722", 8000, 2}},
	{120, {"OPUS", 48000, 2, {{"stereo", "1"}}}},
	{13, {"CN", 8000, 1}},
	{98, {"CN", 16000, 1}},
	{99, {"CN", 32000, 1}}});

	// Create and connect the channel.
	channel_a2b_ = new TestPackStereo;
	EXPECT_EQ(0, acm_a_->RegisterTransportCallback(channel_a2b_));
	channel_a2b_->RegisterReceiverACM(acm_b_.get());

	char codec_pcma_temp[] = "PCMA";
	RegisterSendCodec('A', codec_pcma_temp, 8000, 64000, 80, 2);

	//
	// Test Stereo-To-Stereo for all codecs.
	//
	audio_channels = 2;
	codec_channels = 2;

	// All codecs are tested for all allowed sampling frequencies, rates and
	// packet sizes.
	channel_a2b_->set_codec_mode(kStereo);
	test_cntr_++;
	OpenOutFile(test_cntr_);
	char codec_g722[] = "G722";
	RegisterSendCodec('A', codec_g722, 16000, 64000, 160, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_g722, 16000, 64000, 320, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_g722, 16000, 64000, 480, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_g722, 16000, 64000, 640, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_g722, 16000, 64000, 800, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_g722, 16000, 64000, 960, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();

	channel_a2b_->set_codec_mode(kStereo);
	test_cntr_++;
	OpenOutFile(test_cntr_);
	char codec_l16[] = "L16";
	RegisterSendCodec('A', codec_l16, 8000, 128000, 80, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_l16, 8000, 128000, 160, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_l16, 8000, 128000, 240, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_l16, 8000, 128000, 320, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();

	test_cntr_++;
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_l16, 16000, 256000, 160, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_l16, 16000, 256000, 320, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_l16, 16000, 256000, 480, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_l16, 16000, 256000, 640, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();

	test_cntr_++;
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_l16, 32000, 512000, 320, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_l16, 32000, 512000, 640, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();
	#ifdef PCMA_AND_PCMU
	channel_a2b_->set_codec_mode(kStereo);
	audio_channels = 2;
	codec_channels = 2;
	test_cntr_++;
	OpenOutFile(test_cntr_);
	char codec_pcma[] = "PCMA";
	RegisterSendCodec('A', codec_pcma, 8000, 64000, 80, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcma, 8000, 64000, 160, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcma, 8000, 64000, 240, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcma, 8000, 64000, 320, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcma, 8000, 64000, 400, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcma, 8000, 64000, 480, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();

	test_cntr_++;
	OpenOutFile(test_cntr_);
	char codec_pcmu[] = "PCMU";
	RegisterSendCodec('A', codec_pcmu, 8000, 64000, 80, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcmu, 8000, 64000, 160, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcmu, 8000, 64000, 240, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcmu, 8000, 64000, 320, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcmu, 8000, 64000, 400, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcmu, 8000, 64000, 480, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();
	#endif
	#ifdef WEBRTC_CODEC_OPUS
	channel_a2b_->set_codec_mode(kStereo);
	audio_channels = 2;
	codec_channels = 2;
	test_cntr_++;
	OpenOutFile(test_cntr_);

	char codec_opus[] = "opus";
	// Run Opus with 10 ms frame size.
	RegisterSendCodec('A', codec_opus, 48000, 64000, 480, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	// Run Opus with 20 ms frame size.
	RegisterSendCodec('A', codec_opus, 48000, 64000, 480 * 2, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	// Run Opus with 40 ms frame size.
	RegisterSendCodec('A', codec_opus, 48000, 64000, 480 * 4, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	// Run Opus with 60 ms frame size.
	RegisterSendCodec('A', codec_opus, 48000, 64000, 480 * 6, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	// Run Opus with 20 ms frame size and different bitrates.
	RegisterSendCodec('A', codec_opus, 48000, 40000, 960, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_opus, 48000, 510000, 960, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();
	#endif
	//
	// Test Mono-To-Stereo for all codecs.
	//
	audio_channels = 1;
	codec_channels = 2;

	test_cntr_++;
	channel_a2b_->set_codec_mode(kStereo);
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_g722, 16000, 64000, 160, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();

	test_cntr_++;
	channel_a2b_->set_codec_mode(kStereo);
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_l16, 8000, 128000, 80, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();

	test_cntr_++;
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_l16, 16000, 256000, 160, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();

	test_cntr_++;
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_l16, 32000, 512000, 320, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();
	#ifdef PCMA_AND_PCMU
	test_cntr_++;
	channel_a2b_->set_codec_mode(kStereo);
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_pcmu, 8000, 64000, 80, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcma, 8000, 64000, 80, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();
	#endif
	#ifdef WEBRTC_CODEC_OPUS
	// Keep encode and decode in stereo.
	test_cntr_++;
	channel_a2b_->set_codec_mode(kStereo);
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_opus, 48000, 64000, 960, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);

	// Encode in mono, decode in stereo mode.
	RegisterSendCodec('A', codec_opus, 48000, 64000, 960, 1);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();
	#endif

	//
	// Test Stereo-To-Mono for all codecs.
	//
	audio_channels = 2;
	codec_channels = 1;
	channel_a2b_->set_codec_mode(kMono);

	// Run stereo audio and mono codec.
	test_cntr_++;
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_g722, 16000, 64000, 160, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();

	test_cntr_++;
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_l16, 8000, 128000, 80, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();

	test_cntr_++;
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_l16, 16000, 256000, 160, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();

	test_cntr_++;
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_l16, 32000, 512000, 320, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();
	#ifdef PCMA_AND_PCMU
	test_cntr_++;
	OpenOutFile(test_cntr_);
	RegisterSendCodec('A', codec_pcmu, 8000, 64000, 80, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	RegisterSendCodec('A', codec_pcma, 8000, 64000, 80, codec_channels);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();
	#endif
	#ifdef WEBRTC_CODEC_OPUS
	test_cntr_++;
	OpenOutFile(test_cntr_);
	// Encode and decode in mono.
	RegisterSendCodec('A', codec_opus, 48000, 32000, 960, codec_channels);
	acm_b_->SetReceiveCodecs({{120, {"OPUS", 48000, 2}}});
	Run(channel_a2b_, audio_channels, codec_channels);

	// Encode in stereo, decode in mono.
	RegisterSendCodec('A', codec_opus, 48000, 32000, 960, 2);
	Run(channel_a2b_, audio_channels, codec_channels);

	out_file_.Close();

	// Test switching between decoding mono and stereo for Opus.

	// Decode in mono.
	test_cntr_++;
	OpenOutFile(test_cntr_);
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();
	// Decode in stereo.
	test_cntr_++;
	OpenOutFile(test_cntr_);
	acm_b_->SetReceiveCodecs({{120, {"OPUS", 48000, 2, {{"stereo", "1"}}}}});
	Run(channel_a2b_, audio_channels, 2);
	out_file_.Close();
	// Decode in mono.
	test_cntr_++;
	OpenOutFile(test_cntr_);
	acm_b_->SetReceiveCodecs({{120, {"OPUS", 48000, 2}}});
	Run(channel_a2b_, audio_channels, codec_channels);
	out_file_.Close();
	#endif

	// Delete the file pointers.
	delete in_file_stereo_;
	delete in_file_mono_;
	}

	// Register Codec to use in the test
	//
	// Input: side - which ACM to use, 'A' or 'B'
	// codec_name - name to use when register the codec
	// sampling_freq_hz - sampling frequency in Herz
	// rate - bitrate in bytes
	// pack_size - packet size in samples
	// channels - number of channels; 1 for mono, 2 for stereo
	void TestStereo::RegisterSendCodec(char side,
	char* codec_name,
	int32_t sampling_freq_hz,
	int rate,
	int pack_size,
	int channels) {
	// Store packet size in samples, used to validate the received packet
	pack_size_samp_ = pack_size;

	// Store the expected packet size in bytes, used to validate the received
	// packet. Add 0.875 to always round up to a whole byte.
	pack_size_bytes_ = (uint16_t)(static_cast<float>(pack_size * rate) /
	static_cast<float>(sampling_freq_hz * 8) +
	0.875);

	// Set pointer to the ACM where to register the codec
	AudioCodingModule* my_acm = NULL;
	switch (side) {
	case 'A': {
	my_acm = acm_a_.get();
	break;
	}
	case 'B': {
	my_acm = acm_b_.get();
	break;
	}
	default:
	break;
	}
	ASSERT_TRUE(my_acm != NULL);

	auto encoder_factory = CreateBuiltinAudioEncoderFactory();
	const int clockrate_hz = absl::EqualsIgnoreCase(codec_name, "g722")
	? sampling_freq_hz / 2
	: sampling_freq_hz;
	const std::string ptime = rtc::ToString(rtc::CheckedDivExact(
	pack_size, rtc::CheckedDivExact(sampling_freq_hz, 1000)));
	SdpAudioFormat::Parameters params = {{"ptime", ptime}};
	RTC_CHECK(channels == 1 \|\| channels == 2);
	if (absl::EqualsIgnoreCase(codec_name, "opus")) {
	if (channels == 2) {
	params["stereo"] = "1";
	}
	channels = 2;
	params["maxaveragebitrate"] = rtc::ToString(rate);
	}
	constexpr int payload_type = 17;
	auto encoder = encoder_factory->MakeAudioEncoder(
	payload_type, SdpAudioFormat(codec_name, clockrate_hz, channels, params),
	absl::nullopt);
	EXPECT_NE(nullptr, encoder);
	my_acm->SetEncoder(std::move(encoder));

	send_codec_name_ = codec_name;
	}

	void TestStereo::Run(TestPackStereo* channel,
	int in_channels,
	int out_channels,
	int percent_loss) {
	AudioFrame audio_frame;

	int32_t out_freq_hz_b = out_file_.SamplingFrequency();
	uint16_t rec_size;
	uint32_t time_stamp_diff;
	channel->reset_payload_size();
	int error_count = 0;
	int variable_bytes = 0;
	int variable_packets = 0;
	// Set test length to 500 ms (50 blocks of 10 ms each).
	in_file_mono_->SetNum10MsBlocksToRead(50);
	in_file_stereo_->SetNum10MsBlocksToRead(50);
	// Fast-forward 1 second (100 blocks) since the files start with silence.
	in_file_stereo_->FastForward(100);
	in_file_mono_->FastForward(100);

	while (1) {
	// Simulate packet loss by setting \|packet_loss_\| to "true" in
	// \|percent_loss\| percent of the loops.
	if (percent_loss > 0) {
	if (counter_ == floor((100 / percent_loss) + 0.5)) {
	counter_ = 0;
	channel->set_lost_packet(true);
	} else {
	channel->set_lost_packet(false);
	}
	counter_++;
	}

	// Add 10 msec to ACM
	if (in_channels == 1) {
	if (in_file_mono_->EndOfFile()) {
	break;
	}
	in_file_mono_->Read10MsData(audio_frame);
	} else {
	if (in_file_stereo_->EndOfFile()) {
	break;
	}
	in_file_stereo_->Read10MsData(audio_frame);
	}
	EXPECT_GE(acm_a_->Add10MsData(audio_frame), 0);

	// Verify that the received packet size matches the settings.
	rec_size = channel->payload_size();
	if ((0 < rec_size) & (rec_size < 65535)) {
	if (strcmp(send_codec_name_, "opus") == 0) {
	// Opus is a variable rate codec, hence calculate the average packet
	// size, and later make sure the average is in the right range.
	variable_bytes += rec_size;
	variable_packets++;
	} else {
	// For fixed rate codecs, check that packet size is correct.
	if ((rec_size != pack_size_bytes_ * out_channels) &&
	(pack_size_bytes_ < 65535)) {
	error_count++;
	}
	}
	// Verify that the timestamp is updated with expected length
	time_stamp_diff = channel->timestamp_diff();
	if ((counter_ > 10) && (time_stamp_diff != pack_size_samp_)) {
	error_count++;
	}
	}

	// Run receive side of ACM
	bool muted;
	EXPECT_EQ(0, acm_b_->PlayoutData10Ms(out_freq_hz_b, &audio_frame, &muted));
	ASSERT_FALSE(muted);

	// Write output speech to file
	out_file_.Write10MsData(
	audio_frame.data(),
	audio_frame.samples_per_channel_ * audio_frame.num_channels_);
	}

	EXPECT_EQ(0, error_count);

	// Check that packet size is in the right range for variable rate codecs,
	// such as Opus.
	if (variable_packets > 0) {
	variable_bytes /= variable_packets;
	EXPECT_NEAR(variable_bytes, pack_size_bytes_, 18);
	}

	if (in_file_mono_->EndOfFile()) {
	in_file_mono_->Rewind();
	}
	if (in_file_stereo_->EndOfFile()) {
	in_file_stereo_->Rewind();
	}
	// Reset in case we ended with a lost packet
	channel->set_lost_packet(false);
	}

	void TestStereo::OpenOutFile(int16_t test_number) {
	std::string file_name;
	rtc::StringBuilder file_stream;
	file_stream << webrtc::test::OutputPath() << "teststereo_out_" << test_number
	<< ".pcm";
	file_name = file_stream.str();
	out_file_.Open(file_name, 32000, "wb");
	}

	} // namespace webrtc