/* * Copyright (c) 2013 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 #include "testing/gtest/include/gtest/gtest.h" #include "webrtc/base/checks.h" #include "webrtc/modules/audio_coding/codecs/opus/opus_interface.h" #include "webrtc/modules/audio_coding/codecs/opus/opus_inst.h" #include "webrtc/modules/audio_coding/neteq/tools/audio_loop.h" #include "webrtc/test/testsupport/fileutils.h" namespace webrtc { using test::AudioLoop; using ::testing::TestWithParam; using ::testing::Values; using ::testing::Combine; // Maximum number of bytes in output bitstream. const size_t kMaxBytes = 1000; // Sample rate of Opus. const size_t kOpusRateKhz = 48; // Number of samples-per-channel in a 20 ms frame, sampled at 48 kHz. const size_t kOpus20msFrameSamples = kOpusRateKhz * 20; // Number of samples-per-channel in a 10 ms frame, sampled at 48 kHz. const size_t kOpus10msFrameSamples = kOpusRateKhz * 10; class OpusTest : public TestWithParam<::testing::tuple> { protected: OpusTest(); void TestDtxEffect(bool dtx, int block_length_ms); // Prepare |speech_data_| for encoding, read from a hard-coded file. // After preparation, |speech_data_.GetNextBlock()| returns a pointer to a // block of |block_length_ms| milliseconds. The data is looped every // |loop_length_ms| milliseconds. void PrepareSpeechData(size_t channel, int block_length_ms, int loop_length_ms); int EncodeDecode(WebRtcOpusEncInst* encoder, rtc::ArrayView input_audio, WebRtcOpusDecInst* decoder, int16_t* output_audio, int16_t* audio_type); void SetMaxPlaybackRate(WebRtcOpusEncInst* encoder, opus_int32 expect, int32_t set); void CheckAudioBounded(const int16_t* audio, size_t samples, size_t channels, uint16_t bound) const; WebRtcOpusEncInst* opus_encoder_; WebRtcOpusDecInst* opus_decoder_; AudioLoop speech_data_; uint8_t bitstream_[kMaxBytes]; size_t encoded_bytes_; size_t channels_; int application_; }; OpusTest::OpusTest() : opus_encoder_(NULL), opus_decoder_(NULL), encoded_bytes_(0), channels_(static_cast(::testing::get<0>(GetParam()))), application_(::testing::get<1>(GetParam())) { } void OpusTest::PrepareSpeechData(size_t channel, int block_length_ms, int loop_length_ms) { const std::string file_name = webrtc::test::ResourcePath((channel == 1) ? "audio_coding/testfile32kHz" : "audio_coding/teststereo32kHz", "pcm"); if (loop_length_ms < block_length_ms) { loop_length_ms = block_length_ms; } EXPECT_TRUE(speech_data_.Init(file_name, loop_length_ms * kOpusRateKhz * channel, block_length_ms * kOpusRateKhz * channel)); } void OpusTest::SetMaxPlaybackRate(WebRtcOpusEncInst* encoder, opus_int32 expect, int32_t set) { opus_int32 bandwidth; EXPECT_EQ(0, WebRtcOpus_SetMaxPlaybackRate(opus_encoder_, set)); opus_encoder_ctl(opus_encoder_->encoder, OPUS_GET_MAX_BANDWIDTH(&bandwidth)); EXPECT_EQ(expect, bandwidth); } void OpusTest::CheckAudioBounded(const int16_t* audio, size_t samples, size_t channels, uint16_t bound) const { for (size_t i = 0; i < samples; ++i) { for (size_t c = 0; c < channels; ++c) { ASSERT_GE(audio[i * channels + c], -bound); ASSERT_LE(audio[i * channels + c], bound); } } } int OpusTest::EncodeDecode(WebRtcOpusEncInst* encoder, rtc::ArrayView input_audio, WebRtcOpusDecInst* decoder, int16_t* output_audio, int16_t* audio_type) { int encoded_bytes_int = WebRtcOpus_Encode( encoder, input_audio.data(), rtc::CheckedDivExact(input_audio.size(), channels_), kMaxBytes, bitstream_); EXPECT_GE(encoded_bytes_int, 0); encoded_bytes_ = static_cast(encoded_bytes_int); int est_len = WebRtcOpus_DurationEst(decoder, bitstream_, encoded_bytes_); int act_len = WebRtcOpus_Decode(decoder, bitstream_, encoded_bytes_, output_audio, audio_type); EXPECT_EQ(est_len, act_len); return act_len; } // Test if encoder/decoder can enter DTX mode properly and do not enter DTX when // they should not. This test is signal dependent. void OpusTest::TestDtxEffect(bool dtx, int block_length_ms) { PrepareSpeechData(channels_, block_length_ms, 2000); const size_t samples = kOpusRateKhz * block_length_ms; // Create encoder memory. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); EXPECT_EQ(0, WebRtcOpus_DecoderCreate(&opus_decoder_, channels_)); // Set bitrate. EXPECT_EQ(0, WebRtcOpus_SetBitRate(opus_encoder_, channels_ == 1 ? 32000 : 64000)); // Set input audio as silence. std::vector silence(samples * channels_, 0); // Setting DTX. EXPECT_EQ(0, dtx ? WebRtcOpus_EnableDtx(opus_encoder_) : WebRtcOpus_DisableDtx(opus_encoder_)); int16_t audio_type; int16_t* output_data_decode = new int16_t[samples * channels_]; for (int i = 0; i < 100; ++i) { EXPECT_EQ(samples, static_cast(EncodeDecode( opus_encoder_, speech_data_.GetNextBlock(), opus_decoder_, output_data_decode, &audio_type))); // If not DTX, it should never enter DTX mode. If DTX, we do not care since // whether it enters DTX depends on the signal type. if (!dtx) { EXPECT_GT(encoded_bytes_, 1U); EXPECT_EQ(0, opus_encoder_->in_dtx_mode); EXPECT_EQ(0, opus_decoder_->in_dtx_mode); EXPECT_EQ(0, audio_type); // Speech. } } // We input some silent segments. In DTX mode, the encoder will stop sending. // However, DTX may happen after a while. for (int i = 0; i < 30; ++i) { EXPECT_EQ(samples, static_cast(EncodeDecode( opus_encoder_, silence, opus_decoder_, output_data_decode, &audio_type))); if (!dtx) { EXPECT_GT(encoded_bytes_, 1U); EXPECT_EQ(0, opus_encoder_->in_dtx_mode); EXPECT_EQ(0, opus_decoder_->in_dtx_mode); EXPECT_EQ(0, audio_type); // Speech. } else if (encoded_bytes_ == 1) { EXPECT_EQ(1, opus_encoder_->in_dtx_mode); EXPECT_EQ(1, opus_decoder_->in_dtx_mode); EXPECT_EQ(2, audio_type); // Comfort noise. break; } } // When Opus is in DTX, it wakes up in a regular basis. It sends two packets, // one with an arbitrary size and the other of 1-byte, then stops sending for // a certain number of frames. // |max_dtx_frames| is the maximum number of frames Opus can stay in DTX. const int max_dtx_frames = 400 / block_length_ms + 1; // We run |kRunTimeMs| milliseconds of pure silence. const int kRunTimeMs = 2000; // We check that, after a |kCheckTimeMs| milliseconds (given that the CNG in // Opus needs time to adapt), the absolute values of DTX decoded signal are // bounded by |kOutputValueBound|. const int kCheckTimeMs = 1500; #if defined(OPUS_FIXED_POINT) const uint16_t kOutputValueBound = 20; #else const uint16_t kOutputValueBound = 2; #endif int time = 0; while (time < kRunTimeMs) { // DTX mode is maintained for maximum |max_dtx_frames| frames. int i = 0; for (; i < max_dtx_frames; ++i) { time += block_length_ms; EXPECT_EQ(samples, static_cast(EncodeDecode( opus_encoder_, silence, opus_decoder_, output_data_decode, &audio_type))); if (dtx) { if (encoded_bytes_ > 1) break; EXPECT_EQ(0U, encoded_bytes_) // Send 0 byte. << "Opus should have entered DTX mode."; EXPECT_EQ(1, opus_encoder_->in_dtx_mode); EXPECT_EQ(1, opus_decoder_->in_dtx_mode); EXPECT_EQ(2, audio_type); // Comfort noise. if (time >= kCheckTimeMs) { CheckAudioBounded(output_data_decode, samples, channels_, kOutputValueBound); } } else { EXPECT_GT(encoded_bytes_, 1U); EXPECT_EQ(0, opus_encoder_->in_dtx_mode); EXPECT_EQ(0, opus_decoder_->in_dtx_mode); EXPECT_EQ(0, audio_type); // Speech. } } if (dtx) { // With DTX, Opus must stop transmission for some time. EXPECT_GT(i, 1); } // We expect a normal payload. EXPECT_EQ(0, opus_encoder_->in_dtx_mode); EXPECT_EQ(0, opus_decoder_->in_dtx_mode); EXPECT_EQ(0, audio_type); // Speech. // Enters DTX again immediately. time += block_length_ms; EXPECT_EQ(samples, static_cast(EncodeDecode( opus_encoder_, silence, opus_decoder_, output_data_decode, &audio_type))); if (dtx) { EXPECT_EQ(1U, encoded_bytes_); // Send 1 byte. EXPECT_EQ(1, opus_encoder_->in_dtx_mode); EXPECT_EQ(1, opus_decoder_->in_dtx_mode); EXPECT_EQ(2, audio_type); // Comfort noise. if (time >= kCheckTimeMs) { CheckAudioBounded(output_data_decode, samples, channels_, kOutputValueBound); } } else { EXPECT_GT(encoded_bytes_, 1U); EXPECT_EQ(0, opus_encoder_->in_dtx_mode); EXPECT_EQ(0, opus_decoder_->in_dtx_mode); EXPECT_EQ(0, audio_type); // Speech. } } silence[0] = 10000; if (dtx) { // Verify that encoder/decoder can jump out from DTX mode. EXPECT_EQ(samples, static_cast(EncodeDecode( opus_encoder_, silence, opus_decoder_, output_data_decode, &audio_type))); EXPECT_GT(encoded_bytes_, 1U); EXPECT_EQ(0, opus_encoder_->in_dtx_mode); EXPECT_EQ(0, opus_decoder_->in_dtx_mode); EXPECT_EQ(0, audio_type); // Speech. } // Free memory. delete[] output_data_decode; EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); EXPECT_EQ(0, WebRtcOpus_DecoderFree(opus_decoder_)); } // Test failing Create. TEST(OpusTest, OpusCreateFail) { WebRtcOpusEncInst* opus_encoder; WebRtcOpusDecInst* opus_decoder; // Test to see that an invalid pointer is caught. EXPECT_EQ(-1, WebRtcOpus_EncoderCreate(NULL, 1, 0)); // Invalid channel number. EXPECT_EQ(-1, WebRtcOpus_EncoderCreate(&opus_encoder, 3, 0)); // Invalid applciation mode. EXPECT_EQ(-1, WebRtcOpus_EncoderCreate(&opus_encoder, 1, 2)); EXPECT_EQ(-1, WebRtcOpus_DecoderCreate(NULL, 1)); // Invalid channel number. EXPECT_EQ(-1, WebRtcOpus_DecoderCreate(&opus_decoder, 3)); } // Test failing Free. TEST(OpusTest, OpusFreeFail) { // Test to see that an invalid pointer is caught. EXPECT_EQ(-1, WebRtcOpus_EncoderFree(NULL)); EXPECT_EQ(-1, WebRtcOpus_DecoderFree(NULL)); } // Test normal Create and Free. TEST_P(OpusTest, OpusCreateFree) { EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); EXPECT_EQ(0, WebRtcOpus_DecoderCreate(&opus_decoder_, channels_)); EXPECT_TRUE(opus_encoder_ != NULL); EXPECT_TRUE(opus_decoder_ != NULL); // Free encoder and decoder memory. EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); EXPECT_EQ(0, WebRtcOpus_DecoderFree(opus_decoder_)); } TEST_P(OpusTest, OpusEncodeDecode) { PrepareSpeechData(channels_, 20, 20); // Create encoder memory. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); EXPECT_EQ(0, WebRtcOpus_DecoderCreate(&opus_decoder_, channels_)); // Set bitrate. EXPECT_EQ(0, WebRtcOpus_SetBitRate(opus_encoder_, channels_ == 1 ? 32000 : 64000)); // Check number of channels for decoder. EXPECT_EQ(channels_, WebRtcOpus_DecoderChannels(opus_decoder_)); // Check application mode. opus_int32 app; opus_encoder_ctl(opus_encoder_->encoder, OPUS_GET_APPLICATION(&app)); EXPECT_EQ(application_ == 0 ? OPUS_APPLICATION_VOIP : OPUS_APPLICATION_AUDIO, app); // Encode & decode. int16_t audio_type; int16_t* output_data_decode = new int16_t[kOpus20msFrameSamples * channels_]; EXPECT_EQ(kOpus20msFrameSamples, static_cast( EncodeDecode(opus_encoder_, speech_data_.GetNextBlock(), opus_decoder_, output_data_decode, &audio_type))); // Free memory. delete[] output_data_decode; EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); EXPECT_EQ(0, WebRtcOpus_DecoderFree(opus_decoder_)); } TEST_P(OpusTest, OpusSetBitRate) { // Test without creating encoder memory. EXPECT_EQ(-1, WebRtcOpus_SetBitRate(opus_encoder_, 60000)); // Create encoder memory, try with different bitrates. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); EXPECT_EQ(0, WebRtcOpus_SetBitRate(opus_encoder_, 30000)); EXPECT_EQ(0, WebRtcOpus_SetBitRate(opus_encoder_, 60000)); EXPECT_EQ(0, WebRtcOpus_SetBitRate(opus_encoder_, 300000)); EXPECT_EQ(0, WebRtcOpus_SetBitRate(opus_encoder_, 600000)); // Free memory. EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); } TEST_P(OpusTest, OpusSetComplexity) { // Test without creating encoder memory. EXPECT_EQ(-1, WebRtcOpus_SetComplexity(opus_encoder_, 9)); // Create encoder memory, try with different complexities. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); EXPECT_EQ(0, WebRtcOpus_SetComplexity(opus_encoder_, 0)); EXPECT_EQ(0, WebRtcOpus_SetComplexity(opus_encoder_, 10)); EXPECT_EQ(-1, WebRtcOpus_SetComplexity(opus_encoder_, 11)); // Free memory. EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); } // Encode and decode one frame, initialize the decoder and // decode once more. TEST_P(OpusTest, OpusDecodeInit) { PrepareSpeechData(channels_, 20, 20); // Create encoder memory. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); EXPECT_EQ(0, WebRtcOpus_DecoderCreate(&opus_decoder_, channels_)); // Encode & decode. int16_t audio_type; int16_t* output_data_decode = new int16_t[kOpus20msFrameSamples * channels_]; EXPECT_EQ(kOpus20msFrameSamples, static_cast( EncodeDecode(opus_encoder_, speech_data_.GetNextBlock(), opus_decoder_, output_data_decode, &audio_type))); WebRtcOpus_DecoderInit(opus_decoder_); EXPECT_EQ(kOpus20msFrameSamples, static_cast(WebRtcOpus_Decode( opus_decoder_, bitstream_, encoded_bytes_, output_data_decode, &audio_type))); // Free memory. delete[] output_data_decode; EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); EXPECT_EQ(0, WebRtcOpus_DecoderFree(opus_decoder_)); } TEST_P(OpusTest, OpusEnableDisableFec) { // Test without creating encoder memory. EXPECT_EQ(-1, WebRtcOpus_EnableFec(opus_encoder_)); EXPECT_EQ(-1, WebRtcOpus_DisableFec(opus_encoder_)); // Create encoder memory. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); EXPECT_EQ(0, WebRtcOpus_EnableFec(opus_encoder_)); EXPECT_EQ(0, WebRtcOpus_DisableFec(opus_encoder_)); // Free memory. EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); } TEST_P(OpusTest, OpusEnableDisableDtx) { // Test without creating encoder memory. EXPECT_EQ(-1, WebRtcOpus_EnableDtx(opus_encoder_)); EXPECT_EQ(-1, WebRtcOpus_DisableDtx(opus_encoder_)); // Create encoder memory. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); opus_int32 dtx; // DTX is off by default. opus_encoder_ctl(opus_encoder_->encoder, OPUS_GET_DTX(&dtx)); EXPECT_EQ(0, dtx); // Test to enable DTX. EXPECT_EQ(0, WebRtcOpus_EnableDtx(opus_encoder_)); opus_encoder_ctl(opus_encoder_->encoder, OPUS_GET_DTX(&dtx)); EXPECT_EQ(1, dtx); // Test to disable DTX. EXPECT_EQ(0, WebRtcOpus_DisableDtx(opus_encoder_)); opus_encoder_ctl(opus_encoder_->encoder, OPUS_GET_DTX(&dtx)); EXPECT_EQ(0, dtx); // Free memory. EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); } TEST_P(OpusTest, OpusDtxOff) { TestDtxEffect(false, 10); TestDtxEffect(false, 20); TestDtxEffect(false, 40); } TEST_P(OpusTest, OpusDtxOn) { TestDtxEffect(true, 10); TestDtxEffect(true, 20); TestDtxEffect(true, 40); } TEST_P(OpusTest, OpusSetPacketLossRate) { // Test without creating encoder memory. EXPECT_EQ(-1, WebRtcOpus_SetPacketLossRate(opus_encoder_, 50)); // Create encoder memory. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); EXPECT_EQ(0, WebRtcOpus_SetPacketLossRate(opus_encoder_, 50)); EXPECT_EQ(-1, WebRtcOpus_SetPacketLossRate(opus_encoder_, -1)); EXPECT_EQ(-1, WebRtcOpus_SetPacketLossRate(opus_encoder_, 101)); // Free memory. EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); } TEST_P(OpusTest, OpusSetMaxPlaybackRate) { // Test without creating encoder memory. EXPECT_EQ(-1, WebRtcOpus_SetMaxPlaybackRate(opus_encoder_, 20000)); // Create encoder memory. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); SetMaxPlaybackRate(opus_encoder_, OPUS_BANDWIDTH_FULLBAND, 48000); SetMaxPlaybackRate(opus_encoder_, OPUS_BANDWIDTH_FULLBAND, 24001); SetMaxPlaybackRate(opus_encoder_, OPUS_BANDWIDTH_SUPERWIDEBAND, 24000); SetMaxPlaybackRate(opus_encoder_, OPUS_BANDWIDTH_SUPERWIDEBAND, 16001); SetMaxPlaybackRate(opus_encoder_, OPUS_BANDWIDTH_WIDEBAND, 16000); SetMaxPlaybackRate(opus_encoder_, OPUS_BANDWIDTH_WIDEBAND, 12001); SetMaxPlaybackRate(opus_encoder_, OPUS_BANDWIDTH_MEDIUMBAND, 12000); SetMaxPlaybackRate(opus_encoder_, OPUS_BANDWIDTH_MEDIUMBAND, 8001); SetMaxPlaybackRate(opus_encoder_, OPUS_BANDWIDTH_NARROWBAND, 8000); SetMaxPlaybackRate(opus_encoder_, OPUS_BANDWIDTH_NARROWBAND, 4000); // Free memory. EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); } // Test PLC. TEST_P(OpusTest, OpusDecodePlc) { PrepareSpeechData(channels_, 20, 20); // Create encoder memory. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); EXPECT_EQ(0, WebRtcOpus_DecoderCreate(&opus_decoder_, channels_)); // Set bitrate. EXPECT_EQ(0, WebRtcOpus_SetBitRate(opus_encoder_, channels_== 1 ? 32000 : 64000)); // Check number of channels for decoder. EXPECT_EQ(channels_, WebRtcOpus_DecoderChannels(opus_decoder_)); // Encode & decode. int16_t audio_type; int16_t* output_data_decode = new int16_t[kOpus20msFrameSamples * channels_]; EXPECT_EQ(kOpus20msFrameSamples, static_cast( EncodeDecode(opus_encoder_, speech_data_.GetNextBlock(), opus_decoder_, output_data_decode, &audio_type))); // Call decoder PLC. int16_t* plc_buffer = new int16_t[kOpus20msFrameSamples * channels_]; EXPECT_EQ(kOpus20msFrameSamples, static_cast(WebRtcOpus_DecodePlc( opus_decoder_, plc_buffer, 1))); // Free memory. delete[] plc_buffer; delete[] output_data_decode; EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); EXPECT_EQ(0, WebRtcOpus_DecoderFree(opus_decoder_)); } // Duration estimation. TEST_P(OpusTest, OpusDurationEstimation) { PrepareSpeechData(channels_, 20, 20); // Create. EXPECT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); EXPECT_EQ(0, WebRtcOpus_DecoderCreate(&opus_decoder_, channels_)); // 10 ms. We use only first 10 ms of a 20 ms block. auto speech_block = speech_data_.GetNextBlock(); int encoded_bytes_int = WebRtcOpus_Encode( opus_encoder_, speech_block.data(), rtc::CheckedDivExact(speech_block.size(), 2 * channels_), kMaxBytes, bitstream_); EXPECT_GE(encoded_bytes_int, 0); EXPECT_EQ(kOpus10msFrameSamples, static_cast(WebRtcOpus_DurationEst( opus_decoder_, bitstream_, static_cast(encoded_bytes_int)))); // 20 ms speech_block = speech_data_.GetNextBlock(); encoded_bytes_int = WebRtcOpus_Encode( opus_encoder_, speech_block.data(), rtc::CheckedDivExact(speech_block.size(), channels_), kMaxBytes, bitstream_); EXPECT_GE(encoded_bytes_int, 0); EXPECT_EQ(kOpus20msFrameSamples, static_cast(WebRtcOpus_DurationEst( opus_decoder_, bitstream_, static_cast(encoded_bytes_int)))); // Free memory. EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); EXPECT_EQ(0, WebRtcOpus_DecoderFree(opus_decoder_)); } TEST_P(OpusTest, OpusDecodeRepacketized) { const int kPackets = 6; PrepareSpeechData(channels_, 20, 20 * kPackets); // Create encoder memory. ASSERT_EQ(0, WebRtcOpus_EncoderCreate(&opus_encoder_, channels_, application_)); ASSERT_EQ(0, WebRtcOpus_DecoderCreate(&opus_decoder_, channels_)); // Set bitrate. EXPECT_EQ(0, WebRtcOpus_SetBitRate(opus_encoder_, channels_ == 1 ? 32000 : 64000)); // Check number of channels for decoder. EXPECT_EQ(channels_, WebRtcOpus_DecoderChannels(opus_decoder_)); // Encode & decode. int16_t audio_type; rtc::scoped_ptr output_data_decode( new int16_t[kPackets * kOpus20msFrameSamples * channels_]); OpusRepacketizer* rp = opus_repacketizer_create(); for (int idx = 0; idx < kPackets; idx++) { auto speech_block = speech_data_.GetNextBlock(); encoded_bytes_ = WebRtcOpus_Encode(opus_encoder_, speech_block.data(), rtc::CheckedDivExact(speech_block.size(), channels_), kMaxBytes, bitstream_); EXPECT_EQ(OPUS_OK, opus_repacketizer_cat(rp, bitstream_, encoded_bytes_)); } encoded_bytes_ = opus_repacketizer_out(rp, bitstream_, kMaxBytes); EXPECT_EQ(kOpus20msFrameSamples * kPackets, static_cast(WebRtcOpus_DurationEst( opus_decoder_, bitstream_, encoded_bytes_))); EXPECT_EQ(kOpus20msFrameSamples * kPackets, static_cast(WebRtcOpus_Decode( opus_decoder_, bitstream_, encoded_bytes_, output_data_decode.get(), &audio_type))); // Free memory. opus_repacketizer_destroy(rp); EXPECT_EQ(0, WebRtcOpus_EncoderFree(opus_encoder_)); EXPECT_EQ(0, WebRtcOpus_DecoderFree(opus_decoder_)); } INSTANTIATE_TEST_CASE_P(VariousMode, OpusTest, Combine(Values(1, 2), Values(0, 1))); } // namespace webrtc