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1eda4e3db60f484d179cee359e150c4f0c9c7c67
platform-external-webrtc/webrtc/modules/audio_coding/neteq/audio_decoder_unittest.cc
henrik.lundin@webrtc.org 1eda4e3db6 Reland r8476 "Set decoder output frequency in AudioDecoder::Decode call" 
This should be safe to land now that issue 4143 was resolved (in r8492).
This change effectively reverts 8488.

TBR=kwiberg@webrtc.org

Original commit message:
This CL changes the way the decoder sample rate is set and updated. In
practice, it only concerns the iSAC (float) codec.

One single iSAC decoder instance is used for both wideband and
super-wideband decoding, and the instance must be told to switch
output frequency if the payload type changes. This used to be done
through a call to UpdateDecoderSampleRate, but is now instead done in
the Decode call as an extra parameter.

Review URL: https://webrtc-codereview.appspot.com/39289004

Cr-Commit-Position: refs/heads/master@{#8496}
git-svn-id: http://webrtc.googlecode.com/svn/trunk@8496 4adac7df-926f-26a2-2b94-8c16560cd09d
2015-02-25 10:03:19 +00:00

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/*
* 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 "webrtc/modules/audio_coding/neteq/audio_decoder_impl.h"
#include <assert.h>
#include <stdlib.h>
#include <string>
#include <vector>
#include "testing/gtest/include/gtest/gtest.h"
#include "webrtc/modules/audio_coding/codecs/g711/include/audio_encoder_pcm.h"
#include "webrtc/modules/audio_coding/codecs/g722/include/audio_encoder_g722.h"
#include "webrtc/modules/audio_coding/codecs/ilbc/interface/audio_encoder_ilbc.h"
#include "webrtc/modules/audio_coding/codecs/isac/fix/interface/audio_encoder_isacfix.h"
#include "webrtc/modules/audio_coding/codecs/isac/main/interface/audio_encoder_isac.h"
#include "webrtc/modules/audio_coding/codecs/opus/interface/audio_encoder_opus.h"
#include "webrtc/modules/audio_coding/codecs/pcm16b/include/audio_encoder_pcm16b.h"
#include "webrtc/modules/audio_coding/neteq/tools/resample_input_audio_file.h"
#include "webrtc/system_wrappers/interface/data_log.h"
#include "webrtc/system_wrappers/interface/scoped_ptr.h"
#include "webrtc/test/testsupport/fileutils.h"
namespace webrtc {
namespace {
// The absolute difference between the input and output (the first channel) is
// compared vs |tolerance|. The parameter |delay| is used to correct for codec
// delays.
void CompareInputOutput(const std::vector<int16_t>& input,
const std::vector<int16_t>& output,
size_t num_samples,
size_t channels,
int tolerance,
int delay) {
ASSERT_LE(num_samples, input.size());
ASSERT_LE(num_samples * channels, output.size());
for (unsigned int n = 0; n < num_samples - delay; ++n) {
ASSERT_NEAR(input[n], output[channels * n + delay], tolerance)
<< "Exit test on first diff; n = " << n;
DataLog::InsertCell("CodecTest", "input", input[n]);
DataLog::InsertCell("CodecTest", "output", output[channels * n]);
DataLog::NextRow("CodecTest");
}
}
// The absolute difference between the first two channels in |output| is
// compared vs |tolerance|.
void CompareTwoChannels(const std::vector<int16_t>& output,
size_t samples_per_channel,
size_t channels,
int tolerance) {
ASSERT_GE(channels, 2u);
ASSERT_LE(samples_per_channel * channels, output.size());
for (unsigned int n = 0; n < samples_per_channel; ++n)
ASSERT_NEAR(output[channels * n], output[channels * n + 1], tolerance)
<< "Stereo samples differ.";
}
// Calculates mean-squared error between input and output (the first channel).
// The parameter |delay| is used to correct for codec delays.
double MseInputOutput(const std::vector<int16_t>& input,
const std::vector<int16_t>& output,
size_t num_samples,
size_t channels,
int delay) {
assert(delay < static_cast<int>(num_samples));
assert(num_samples <= input.size());
assert(num_samples * channels <= output.size());
if (num_samples == 0)
return 0.0;
double squared_sum = 0.0;
for (unsigned int n = 0; n < num_samples - delay; ++n) {
squared_sum += (input[n] - output[channels * n + delay]) *
(input[n] - output[channels * n + delay]);
}
return squared_sum / (num_samples - delay);
}
} // namespace
class AudioDecoderTest : public ::testing::Test {
protected:
AudioDecoderTest()
: input_audio_(webrtc::test::ProjectRootPath() +
"resources/audio_coding/testfile32kHz.pcm",
32000),
codec_input_rate_hz_(32000), // Legacy default value.
encoded_(NULL),
frame_size_(0),
data_length_(0),
encoded_bytes_(0),
channels_(1),
payload_type_(17),
decoder_(NULL) {}
virtual ~AudioDecoderTest() {}
virtual void SetUp() {
if (audio_encoder_)
codec_input_rate_hz_ = audio_encoder_->SampleRateHz();
// Create arrays.
ASSERT_GT(data_length_, 0u) << "The test must set data_length_ > 0";
// Longest encoded data is produced by PCM16b with 2 bytes per sample.
encoded_ = new uint8_t[data_length_ * 2];
// Logging to view input and output in Matlab.
// Use 'gyp -Denable_data_logging=1' to enable logging.
DataLog::CreateLog();
DataLog::AddTable("CodecTest");
DataLog::AddColumn("CodecTest", "input", 1);
DataLog::AddColumn("CodecTest", "output", 1);
}
virtual void TearDown() {
delete decoder_;
decoder_ = NULL;
// Delete arrays.
delete [] encoded_;
encoded_ = NULL;
// Close log.
DataLog::ReturnLog();
}
virtual void InitEncoder() { }
// TODO(henrik.lundin) Change return type to size_t once most/all overriding
// implementations are gone.
virtual int EncodeFrame(const int16_t* input,
size_t input_len_samples,
uint8_t* output) {
encoded_info_.encoded_bytes = 0;
const size_t samples_per_10ms = audio_encoder_->SampleRateHz() / 100;
CHECK_EQ(samples_per_10ms * audio_encoder_->Num10MsFramesInNextPacket(),
input_len_samples);
scoped_ptr<int16_t[]> interleaved_input(
new int16_t[channels_ * samples_per_10ms]);
for (int i = 0; i < audio_encoder_->Num10MsFramesInNextPacket(); ++i) {
EXPECT_EQ(0u, encoded_info_.encoded_bytes);
// Duplicate the mono input signal to however many channels the test
// wants.
test::InputAudioFile::DuplicateInterleaved(input + i * samples_per_10ms,
samples_per_10ms, channels_,
interleaved_input.get());
EXPECT_TRUE(audio_encoder_->Encode(
0, interleaved_input.get(), audio_encoder_->SampleRateHz() / 100,
data_length_ * 2, output, &encoded_info_));
}
EXPECT_EQ(payload_type_, encoded_info_.payload_type);
return static_cast<int>(encoded_info_.encoded_bytes);
}
// Encodes and decodes audio. The absolute difference between the input and
// output is compared vs |tolerance|, and the mean-squared error is compared
// with |mse|. The encoded stream should contain |expected_bytes|. For stereo
// audio, the absolute difference between the two channels is compared vs
// |channel_diff_tolerance|.
void EncodeDecodeTest(size_t expected_bytes, int tolerance, double mse,
int delay = 0, int channel_diff_tolerance = 0) {
ASSERT_GE(tolerance, 0) << "Test must define a tolerance >= 0";
ASSERT_GE(channel_diff_tolerance, 0) <<
"Test must define a channel_diff_tolerance >= 0";
size_t processed_samples = 0u;
encoded_bytes_ = 0u;
InitEncoder();
EXPECT_EQ(0, decoder_->Init());
std::vector<int16_t> input;
std::vector<int16_t> decoded;
while (processed_samples + frame_size_ <= data_length_) {
// Extend input vector with |frame_size_|.
input.resize(input.size() + frame_size_, 0);
// Read from input file.
ASSERT_GE(input.size() - processed_samples, frame_size_);
ASSERT_TRUE(input_audio_.Read(
frame_size_, codec_input_rate_hz_, &input[processed_samples]));
size_t enc_len = EncodeFrame(
&input[processed_samples], frame_size_, &encoded_[encoded_bytes_]);
// Make sure that frame_size_ * channels_ samples are allocated and free.
decoded.resize((processed_samples + frame_size_) * channels_, 0);
AudioDecoder::SpeechType speech_type;
size_t dec_len = decoder_->Decode(
&encoded_[encoded_bytes_], enc_len, codec_input_rate_hz_,
&decoded[processed_samples * channels_], &speech_type);
EXPECT_EQ(frame_size_ * channels_, dec_len);
encoded_bytes_ += enc_len;
processed_samples += frame_size_;
}
// For some codecs it doesn't make sense to check expected number of bytes,
// since the number can vary for different platforms. Opus and iSAC are
// such codecs. In this case expected_bytes is set to 0.
if (expected_bytes) {
EXPECT_EQ(expected_bytes, encoded_bytes_);
}
CompareInputOutput(
input, decoded, processed_samples, channels_, tolerance, delay);
if (channels_ == 2)
CompareTwoChannels(
decoded, processed_samples, channels_, channel_diff_tolerance);
EXPECT_LE(
MseInputOutput(input, decoded, processed_samples, channels_, delay),
mse);
}
// Encodes a payload and decodes it twice with decoder re-init before each
// decode. Verifies that the decoded result is the same.
void ReInitTest() {
InitEncoder();
scoped_ptr<int16_t[]> input(new int16_t[frame_size_]);
ASSERT_TRUE(
input_audio_.Read(frame_size_, codec_input_rate_hz_, input.get()));
size_t enc_len = EncodeFrame(input.get(), frame_size_, encoded_);
size_t dec_len;
AudioDecoder::SpeechType speech_type1, speech_type2;
EXPECT_EQ(0, decoder_->Init());
scoped_ptr<int16_t[]> output1(new int16_t[frame_size_ * channels_]);
dec_len = decoder_->Decode(encoded_, enc_len, codec_input_rate_hz_,
output1.get(), &speech_type1);
ASSERT_LE(dec_len, frame_size_ * channels_);
EXPECT_EQ(frame_size_ * channels_, dec_len);
// Re-init decoder and decode again.
EXPECT_EQ(0, decoder_->Init());
scoped_ptr<int16_t[]> output2(new int16_t[frame_size_ * channels_]);
dec_len = decoder_->Decode(encoded_, enc_len, codec_input_rate_hz_,
output2.get(), &speech_type2);
ASSERT_LE(dec_len, frame_size_ * channels_);
EXPECT_EQ(frame_size_ * channels_, dec_len);
for (unsigned int n = 0; n < frame_size_; ++n) {
ASSERT_EQ(output1[n], output2[n]) << "Exit test on first diff; n = " << n;
}
EXPECT_EQ(speech_type1, speech_type2);
}
// Call DecodePlc and verify that the correct number of samples is produced.
void DecodePlcTest() {
InitEncoder();
scoped_ptr<int16_t[]> input(new int16_t[frame_size_]);
ASSERT_TRUE(
input_audio_.Read(frame_size_, codec_input_rate_hz_, input.get()));
size_t enc_len = EncodeFrame(input.get(), frame_size_, encoded_);
AudioDecoder::SpeechType speech_type;
EXPECT_EQ(0, decoder_->Init());
scoped_ptr<int16_t[]> output(new int16_t[frame_size_ * channels_]);
size_t dec_len = decoder_->Decode(encoded_, enc_len, codec_input_rate_hz_,
output.get(), &speech_type);
EXPECT_EQ(frame_size_ * channels_, dec_len);
// Call DecodePlc and verify that we get one frame of data.
// (Overwrite the output from the above Decode call, but that does not
// matter.)
dec_len = decoder_->DecodePlc(1, output.get());
EXPECT_EQ(frame_size_ * channels_, dec_len);
}
test::ResampleInputAudioFile input_audio_;
int codec_input_rate_hz_;
uint8_t* encoded_;
size_t frame_size_;
size_t data_length_;
size_t encoded_bytes_;
size_t channels_;
const int payload_type_;
AudioEncoder::EncodedInfo encoded_info_;
AudioDecoder* decoder_;
scoped_ptr<AudioEncoder> audio_encoder_;
};
class AudioDecoderPcmUTest : public AudioDecoderTest {
protected:
AudioDecoderPcmUTest() : AudioDecoderTest() {
frame_size_ = 160;
data_length_ = 10 * frame_size_;
decoder_ = new AudioDecoderPcmU;
AudioEncoderPcmU::Config config;
config.frame_size_ms = static_cast<int>(frame_size_ / 8);
config.payload_type = payload_type_;
audio_encoder_.reset(new AudioEncoderPcmU(config));
}
};
class AudioDecoderPcmATest : public AudioDecoderTest {
protected:
AudioDecoderPcmATest() : AudioDecoderTest() {
frame_size_ = 160;
data_length_ = 10 * frame_size_;
decoder_ = new AudioDecoderPcmA;
AudioEncoderPcmA::Config config;
config.frame_size_ms = static_cast<int>(frame_size_ / 8);
config.payload_type = payload_type_;
audio_encoder_.reset(new AudioEncoderPcmA(config));
}
};
class AudioDecoderPcm16BTest : public AudioDecoderTest {
protected:
AudioDecoderPcm16BTest() : AudioDecoderTest() {
codec_input_rate_hz_ = 16000;
frame_size_ = 20 * codec_input_rate_hz_ / 1000;
data_length_ = 10 * frame_size_;
decoder_ = new AudioDecoderPcm16B;
assert(decoder_);
AudioEncoderPcm16B::Config config;
config.sample_rate_hz = codec_input_rate_hz_;
config.frame_size_ms =
static_cast<int>(frame_size_ / (config.sample_rate_hz / 1000));
config.payload_type = payload_type_;
audio_encoder_.reset(new AudioEncoderPcm16B(config));
}
};
class AudioDecoderIlbcTest : public AudioDecoderTest {
protected:
AudioDecoderIlbcTest() : AudioDecoderTest() {
codec_input_rate_hz_ = 8000;
frame_size_ = 240;
data_length_ = 10 * frame_size_;
decoder_ = new AudioDecoderIlbc;
assert(decoder_);
AudioEncoderIlbc::Config config;
config.frame_size_ms = 30;
config.payload_type = payload_type_;
audio_encoder_.reset(new AudioEncoderIlbc(config));
}
// Overload the default test since iLBC's function WebRtcIlbcfix_NetEqPlc does
// not return any data. It simply resets a few states and returns 0.
void DecodePlcTest() {
InitEncoder();
scoped_ptr<int16_t[]> input(new int16_t[frame_size_]);
ASSERT_TRUE(
input_audio_.Read(frame_size_, codec_input_rate_hz_, input.get()));
size_t enc_len = EncodeFrame(input.get(), frame_size_, encoded_);
AudioDecoder::SpeechType speech_type;
EXPECT_EQ(0, decoder_->Init());
scoped_ptr<int16_t[]> output(new int16_t[frame_size_ * channels_]);
size_t dec_len = decoder_->Decode(encoded_, enc_len, codec_input_rate_hz_,
output.get(), &speech_type);
EXPECT_EQ(frame_size_, dec_len);
// Simply call DecodePlc and verify that we get 0 as return value.
EXPECT_EQ(0, decoder_->DecodePlc(1, output.get()));
}
};
class AudioDecoderIsacFloatTest : public AudioDecoderTest {
protected:
AudioDecoderIsacFloatTest() : AudioDecoderTest() {
codec_input_rate_hz_ = 16000;
frame_size_ = 480;
data_length_ = 10 * frame_size_;
AudioEncoderDecoderIsac::Config config;
config.payload_type = payload_type_;
config.sample_rate_hz = codec_input_rate_hz_;
config.frame_size_ms =
1000 * static_cast<int>(frame_size_) / codec_input_rate_hz_;
// We need to create separate AudioEncoderDecoderIsac objects for encoding
// and decoding, because the test class destructor destroys them both.
audio_encoder_.reset(new AudioEncoderDecoderIsac(config));
decoder_ = new AudioEncoderDecoderIsac(config);
}
};
class AudioDecoderIsacSwbTest : public AudioDecoderTest {
protected:
AudioDecoderIsacSwbTest() : AudioDecoderTest() {
codec_input_rate_hz_ = 32000;
frame_size_ = 960;
data_length_ = 10 * frame_size_;
AudioEncoderDecoderIsac::Config config;
config.payload_type = payload_type_;
config.sample_rate_hz = codec_input_rate_hz_;
config.frame_size_ms =
1000 * static_cast<int>(frame_size_) / codec_input_rate_hz_;
// We need to create separate AudioEncoderDecoderIsac objects for encoding
// and decoding, because the test class destructor destroys them both.
audio_encoder_.reset(new AudioEncoderDecoderIsac(config));
decoder_ = new AudioEncoderDecoderIsac(config);
}
};
class AudioDecoderIsacFixTest : public AudioDecoderTest {
protected:
AudioDecoderIsacFixTest() : AudioDecoderTest() {
codec_input_rate_hz_ = 16000;
frame_size_ = 480;
data_length_ = 10 * frame_size_;
AudioEncoderDecoderIsacFix::Config config;
config.payload_type = payload_type_;
config.sample_rate_hz = codec_input_rate_hz_;
config.frame_size_ms =
1000 * static_cast<int>(frame_size_) / codec_input_rate_hz_;
// We need to create separate AudioEncoderDecoderIsacFix objects for
// encoding and decoding, because the test class destructor destroys them
// both.
audio_encoder_.reset(new AudioEncoderDecoderIsacFix(config));
decoder_ = new AudioEncoderDecoderIsacFix(config);
}
};
class AudioDecoderG722Test : public AudioDecoderTest {
protected:
AudioDecoderG722Test() : AudioDecoderTest() {
codec_input_rate_hz_ = 16000;
frame_size_ = 160;
data_length_ = 10 * frame_size_;
decoder_ = new AudioDecoderG722;
assert(decoder_);
AudioEncoderG722::Config config;
config.frame_size_ms = 10;
config.payload_type = payload_type_;
config.num_channels = 1;
audio_encoder_.reset(new AudioEncoderG722(config));
}
};
class AudioDecoderG722StereoTest : public AudioDecoderTest {
protected:
AudioDecoderG722StereoTest() : AudioDecoderTest() {
channels_ = 2;
codec_input_rate_hz_ = 16000;
frame_size_ = 160;
data_length_ = 10 * frame_size_;
decoder_ = new AudioDecoderG722Stereo;
assert(decoder_);
AudioEncoderG722::Config config;
config.frame_size_ms = 10;
config.payload_type = payload_type_;
config.num_channels = 2;
audio_encoder_.reset(new AudioEncoderG722(config));
}
};
class AudioDecoderOpusTest : public AudioDecoderTest {
protected:
AudioDecoderOpusTest() : AudioDecoderTest() {
codec_input_rate_hz_ = 48000;
frame_size_ = 480;
data_length_ = 10 * frame_size_;
decoder_ = new AudioDecoderOpus(1);
AudioEncoderOpus::Config config;
config.frame_size_ms = static_cast<int>(frame_size_) / 48;
config.payload_type = payload_type_;
config.application = AudioEncoderOpus::kVoip;
audio_encoder_.reset(new AudioEncoderOpus(config));
}
};
class AudioDecoderOpusStereoTest : public AudioDecoderOpusTest {
protected:
AudioDecoderOpusStereoTest() : AudioDecoderOpusTest() {
channels_ = 2;
delete decoder_;
decoder_ = new AudioDecoderOpus(2);
AudioEncoderOpus::Config config;
config.frame_size_ms = static_cast<int>(frame_size_) / 48;
config.num_channels = 2;
config.payload_type = payload_type_;
config.application = AudioEncoderOpus::kAudio;
audio_encoder_.reset(new AudioEncoderOpus(config));
}
};
TEST_F(AudioDecoderPcmUTest, EncodeDecode) {
int tolerance = 251;
double mse = 1734.0;
EXPECT_TRUE(CodecSupported(kDecoderPCMu));
EncodeDecodeTest(data_length_, tolerance, mse);
ReInitTest();
EXPECT_FALSE(decoder_->HasDecodePlc());
}
TEST_F(AudioDecoderPcmATest, EncodeDecode) {
int tolerance = 308;
double mse = 1931.0;
EXPECT_TRUE(CodecSupported(kDecoderPCMa));
EncodeDecodeTest(data_length_, tolerance, mse);
ReInitTest();
EXPECT_FALSE(decoder_->HasDecodePlc());
}
TEST_F(AudioDecoderPcm16BTest, EncodeDecode) {
int tolerance = 0;
double mse = 0.0;
EXPECT_TRUE(CodecSupported(kDecoderPCM16B));
EXPECT_TRUE(CodecSupported(kDecoderPCM16Bwb));
EXPECT_TRUE(CodecSupported(kDecoderPCM16Bswb32kHz));
EXPECT_TRUE(CodecSupported(kDecoderPCM16Bswb48kHz));
EncodeDecodeTest(2 * data_length_, tolerance, mse);
ReInitTest();
EXPECT_FALSE(decoder_->HasDecodePlc());
}
TEST_F(AudioDecoderIlbcTest, EncodeDecode) {
int tolerance = 6808;
double mse = 2.13e6;
int delay = 80; // Delay from input to output.
EXPECT_TRUE(CodecSupported(kDecoderILBC));
EncodeDecodeTest(500, tolerance, mse, delay);
ReInitTest();
EXPECT_TRUE(decoder_->HasDecodePlc());
DecodePlcTest();
}
TEST_F(AudioDecoderIsacFloatTest, EncodeDecode) {
int tolerance = 3399;
double mse = 434951.0;
int delay = 48; // Delay from input to output.
EXPECT_TRUE(CodecSupported(kDecoderISAC));
EncodeDecodeTest(0, tolerance, mse, delay);
ReInitTest();
EXPECT_TRUE(decoder_->HasDecodePlc());
DecodePlcTest();
}
TEST_F(AudioDecoderIsacSwbTest, EncodeDecode) {
int tolerance = 19757;
double mse = 8.18e6;
int delay = 160; // Delay from input to output.
EXPECT_TRUE(CodecSupported(kDecoderISACswb));
EncodeDecodeTest(0, tolerance, mse, delay);
ReInitTest();
EXPECT_TRUE(decoder_->HasDecodePlc());
DecodePlcTest();
}
// Fails Android ARM64. https://code.google.com/p/webrtc/issues/detail?id=4198
#if defined(WEBRTC_ANDROID) && defined(__aarch64__)
#define MAYBE_EncodeDecode DISABLED_EncodeDecode
#else
#define MAYBE_EncodeDecode EncodeDecode
#endif
TEST_F(AudioDecoderIsacFixTest, MAYBE_EncodeDecode) {
int tolerance = 11034;
double mse = 3.46e6;
int delay = 54; // Delay from input to output.
EXPECT_TRUE(CodecSupported(kDecoderISAC));
#ifdef WEBRTC_ANDROID
static const int kEncodedBytes = 685;
#else
static const int kEncodedBytes = 671;
#endif
EncodeDecodeTest(kEncodedBytes, tolerance, mse, delay);
ReInitTest();
EXPECT_TRUE(decoder_->HasDecodePlc());
DecodePlcTest();
}
TEST_F(AudioDecoderG722Test, EncodeDecode) {
int tolerance = 6176;
double mse = 238630.0;
int delay = 22; // Delay from input to output.
EXPECT_TRUE(CodecSupported(kDecoderG722));
EncodeDecodeTest(data_length_ / 2, tolerance, mse, delay);
ReInitTest();
EXPECT_FALSE(decoder_->HasDecodePlc());
}
TEST_F(AudioDecoderG722StereoTest, CreateAndDestroy) {
EXPECT_TRUE(CodecSupported(kDecoderG722_2ch));
}
TEST_F(AudioDecoderG722StereoTest, EncodeDecode) {
int tolerance = 6176;
int channel_diff_tolerance = 0;
double mse = 238630.0;
int delay = 22; // Delay from input to output.
EXPECT_TRUE(CodecSupported(kDecoderG722_2ch));
EncodeDecodeTest(data_length_, tolerance, mse, delay, channel_diff_tolerance);
ReInitTest();
EXPECT_FALSE(decoder_->HasDecodePlc());
}
TEST_F(AudioDecoderOpusTest, EncodeDecode) {
int tolerance = 6176;
double mse = 238630.0;
int delay = 22; // Delay from input to output.
EXPECT_TRUE(CodecSupported(kDecoderOpus));
EncodeDecodeTest(0, tolerance, mse, delay);
ReInitTest();
EXPECT_FALSE(decoder_->HasDecodePlc());
}
TEST_F(AudioDecoderOpusStereoTest, EncodeDecode) {
int tolerance = 6176;
int channel_diff_tolerance = 0;
double mse = 238630.0;
int delay = 22; // Delay from input to output.
EXPECT_TRUE(CodecSupported(kDecoderOpus_2ch));
EncodeDecodeTest(0, tolerance, mse, delay, channel_diff_tolerance);
ReInitTest();
EXPECT_FALSE(decoder_->HasDecodePlc());
}
TEST(AudioDecoder, CodecSampleRateHz) {
EXPECT_EQ(8000, CodecSampleRateHz(kDecoderPCMu));
EXPECT_EQ(8000, CodecSampleRateHz(kDecoderPCMa));
EXPECT_EQ(8000, CodecSampleRateHz(kDecoderPCMu_2ch));
EXPECT_EQ(8000, CodecSampleRateHz(kDecoderPCMa_2ch));
EXPECT_EQ(8000, CodecSampleRateHz(kDecoderILBC));
EXPECT_EQ(16000, CodecSampleRateHz(kDecoderISAC));
EXPECT_EQ(32000, CodecSampleRateHz(kDecoderISACswb));
EXPECT_EQ(32000, CodecSampleRateHz(kDecoderISACfb));
EXPECT_EQ(8000, CodecSampleRateHz(kDecoderPCM16B));
EXPECT_EQ(16000, CodecSampleRateHz(kDecoderPCM16Bwb));
EXPECT_EQ(32000, CodecSampleRateHz(kDecoderPCM16Bswb32kHz));
EXPECT_EQ(48000, CodecSampleRateHz(kDecoderPCM16Bswb48kHz));
EXPECT_EQ(8000, CodecSampleRateHz(kDecoderPCM16B_2ch));
EXPECT_EQ(16000, CodecSampleRateHz(kDecoderPCM16Bwb_2ch));
EXPECT_EQ(32000, CodecSampleRateHz(kDecoderPCM16Bswb32kHz_2ch));
EXPECT_EQ(48000, CodecSampleRateHz(kDecoderPCM16Bswb48kHz_2ch));
EXPECT_EQ(8000, CodecSampleRateHz(kDecoderPCM16B_5ch));
EXPECT_EQ(16000, CodecSampleRateHz(kDecoderG722));
EXPECT_EQ(16000, CodecSampleRateHz(kDecoderG722_2ch));
EXPECT_EQ(-1, CodecSampleRateHz(kDecoderRED));
EXPECT_EQ(-1, CodecSampleRateHz(kDecoderAVT));
EXPECT_EQ(8000, CodecSampleRateHz(kDecoderCNGnb));
EXPECT_EQ(16000, CodecSampleRateHz(kDecoderCNGwb));
EXPECT_EQ(32000, CodecSampleRateHz(kDecoderCNGswb32kHz));
EXPECT_EQ(48000, CodecSampleRateHz(kDecoderOpus));
EXPECT_EQ(48000, CodecSampleRateHz(kDecoderOpus_2ch));
// TODO(tlegrand): Change 32000 to 48000 below once ACM has 48 kHz support.
EXPECT_EQ(32000, CodecSampleRateHz(kDecoderCNGswb48kHz));
EXPECT_EQ(-1, CodecSampleRateHz(kDecoderArbitrary));
}
TEST(AudioDecoder, CodecSupported) {
EXPECT_TRUE(CodecSupported(kDecoderPCMu));
EXPECT_TRUE(CodecSupported(kDecoderPCMa));
EXPECT_TRUE(CodecSupported(kDecoderPCMu_2ch));
EXPECT_TRUE(CodecSupported(kDecoderPCMa_2ch));
EXPECT_TRUE(CodecSupported(kDecoderILBC));
EXPECT_TRUE(CodecSupported(kDecoderISAC));
EXPECT_TRUE(CodecSupported(kDecoderISACswb));
EXPECT_TRUE(CodecSupported(kDecoderISACfb));
EXPECT_TRUE(CodecSupported(kDecoderPCM16B));
EXPECT_TRUE(CodecSupported(kDecoderPCM16Bwb));
EXPECT_TRUE(CodecSupported(kDecoderPCM16Bswb32kHz));
EXPECT_TRUE(CodecSupported(kDecoderPCM16Bswb48kHz));
EXPECT_TRUE(CodecSupported(kDecoderPCM16B_2ch));
EXPECT_TRUE(CodecSupported(kDecoderPCM16Bwb_2ch));
EXPECT_TRUE(CodecSupported(kDecoderPCM16Bswb32kHz_2ch));
EXPECT_TRUE(CodecSupported(kDecoderPCM16Bswb48kHz_2ch));
EXPECT_TRUE(CodecSupported(kDecoderPCM16B_5ch));
EXPECT_TRUE(CodecSupported(kDecoderG722));
EXPECT_TRUE(CodecSupported(kDecoderG722_2ch));
EXPECT_TRUE(CodecSupported(kDecoderRED));
EXPECT_TRUE(CodecSupported(kDecoderAVT));
EXPECT_TRUE(CodecSupported(kDecoderCNGnb));
EXPECT_TRUE(CodecSupported(kDecoderCNGwb));
EXPECT_TRUE(CodecSupported(kDecoderCNGswb32kHz));
EXPECT_TRUE(CodecSupported(kDecoderCNGswb48kHz));
EXPECT_TRUE(CodecSupported(kDecoderArbitrary));
EXPECT_TRUE(CodecSupported(kDecoderOpus));
EXPECT_TRUE(CodecSupported(kDecoderOpus_2ch));
}
} // namespace webrtc
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