webrtc/modules/audio_processing/beamformer/nonlinear_beamformer_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2015 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.
  */

 // MSVC++ requires this to be set before any other includes to get M_PI.
 #define _USE_MATH_DEFINES

 #include "webrtc/modules/audio_processing/beamformer/nonlinear_beamformer.h"

 #include <math.h>

 #include "testing/gtest/include/gtest/gtest.h"
 #include "webrtc/base/array_view.h"
 #include "webrtc/modules/audio_processing/audio_buffer.h"
 #include "webrtc/modules/audio_processing/test/audio_buffer_tools.h"
 #include "webrtc/modules/audio_processing/test/bitexactness_tools.h"

 namespace webrtc {
 namespace {

 const int kChunkSizeMs = 10;
 const int kSampleRateHz = 16000;

 SphericalPointf AzimuthToSphericalPoint(float azimuth_radians) {
   return SphericalPointf(azimuth_radians, 0.f, 1.f);
 }

 void Verify(NonlinearBeamformer* bf, float target_azimuth_radians) {
   EXPECT_TRUE(bf->IsInBeam(AzimuthToSphericalPoint(target_azimuth_radians)));
   EXPECT_TRUE(bf->IsInBeam(AzimuthToSphericalPoint(
       target_azimuth_radians - NonlinearBeamformer::kHalfBeamWidthRadians +
       0.001f)));
   EXPECT_TRUE(bf->IsInBeam(AzimuthToSphericalPoint(
       target_azimuth_radians + NonlinearBeamformer::kHalfBeamWidthRadians -
       0.001f)));
   EXPECT_FALSE(bf->IsInBeam(AzimuthToSphericalPoint(
       target_azimuth_radians - NonlinearBeamformer::kHalfBeamWidthRadians -
       0.001f)));
   EXPECT_FALSE(bf->IsInBeam(AzimuthToSphericalPoint(
       target_azimuth_radians + NonlinearBeamformer::kHalfBeamWidthRadians +
       0.001f)));
 }

 void AimAndVerify(NonlinearBeamformer* bf, float target_azimuth_radians) {
   bf->AimAt(AzimuthToSphericalPoint(target_azimuth_radians));
   Verify(bf, target_azimuth_radians);
 }

 // Bitexactness test code.
 const size_t kNumFramesToProcess = 1000;

 void ProcessOneFrame(int sample_rate_hz,
                      AudioBuffer* capture_audio_buffer,
                      NonlinearBeamformer* beamformer) {
   if (sample_rate_hz > AudioProcessing::kSampleRate16kHz) {
     capture_audio_buffer->SplitIntoFrequencyBands();
   }

   beamformer->AnalyzeChunk(*capture_audio_buffer->split_data_f());
   capture_audio_buffer->set_num_channels(1);
   beamformer->PostFilter(capture_audio_buffer->split_data_f());

   if (sample_rate_hz > AudioProcessing::kSampleRate16kHz) {
     capture_audio_buffer->MergeFrequencyBands();
   }
 }

 int BeamformerSampleRate(int sample_rate_hz) {
   return (sample_rate_hz > AudioProcessing::kSampleRate16kHz
               ? AudioProcessing::kSampleRate16kHz
               : sample_rate_hz);
 }

 void RunBitExactnessTest(int sample_rate_hz,
                          const std::vector<Point>& array_geometry,
                          const SphericalPointf& target_direction,
                          rtc::ArrayView<const float> output_reference) {
   NonlinearBeamformer beamformer(array_geometry, 1u, target_direction);
   beamformer.Initialize(AudioProcessing::kChunkSizeMs,
                         BeamformerSampleRate(sample_rate_hz));

   const StreamConfig capture_config(sample_rate_hz, array_geometry.size(),
                                     false);
   AudioBuffer capture_buffer(
       capture_config.num_frames(), capture_config.num_channels(),
       capture_config.num_frames(), capture_config.num_channels(),
       capture_config.num_frames());
   test::InputAudioFile capture_file(
       test::GetApmCaptureTestVectorFileName(sample_rate_hz));
   std::vector<float> capture_input(capture_config.num_frames() *
                                    capture_config.num_channels());
   for (size_t frame_no = 0u; frame_no < kNumFramesToProcess; ++frame_no) {
     ReadFloatSamplesFromStereoFile(capture_config.num_frames(),
                                    capture_config.num_channels(), &capture_file,
                                    capture_input);

     test::CopyVectorToAudioBuffer(capture_config, capture_input,
                                   &capture_buffer);

     ProcessOneFrame(sample_rate_hz, &capture_buffer, &beamformer);
   }

   // Extract and verify the test results.
   std::vector<float> capture_output;
   test::ExtractVectorFromAudioBuffer(capture_config, &capture_buffer,
                                      &capture_output);

   const float kElementErrorBound = 1.f / static_cast<float>(1 << 15);

   // Compare the output with the reference. Only the first values of the output
   // from last frame processed are compared in order not having to specify all
   // preceeding frames as testvectors. As the algorithm being tested has a
   // memory, testing only the last frame implicitly also tests the preceeding
   // frames.
   EXPECT_TRUE(test::VerifyDeinterleavedArray(
       capture_config.num_frames(), capture_config.num_channels(),
       output_reference, capture_output, kElementErrorBound));
 }

 // TODO(peah): Add bitexactness tests for scenarios with more than 2 input
 // channels.
 std::vector<Point> CreateArrayGeometry(int variant) {
   std::vector<Point> array_geometry;
   switch (variant) {
     case 1:
       array_geometry.push_back(Point(-0.025f, 0.f, 0.f));
       array_geometry.push_back(Point(0.025f, 0.f, 0.f));
       break;
     case 2:
       array_geometry.push_back(Point(-0.035f, 0.f, 0.f));
       array_geometry.push_back(Point(0.035f, 0.f, 0.f));
       break;
     case 3:
       array_geometry.push_back(Point(-0.5f, 0.f, 0.f));
       array_geometry.push_back(Point(0.5f, 0.f, 0.f));
       break;
     default:
       RTC_CHECK(false);
   }
   return array_geometry;
 }

 const SphericalPointf TargetDirection1(0.4f * static_cast<float>(M_PI) / 2.f,
                                        0.f,
                                        1.f);
 const SphericalPointf TargetDirection2(static_cast<float>(M_PI) / 2.f,
                                        1.f,
                                        2.f);

 }  // namespace

 TEST(NonlinearBeamformerTest, AimingModifiesBeam) {
   std::vector<Point> array_geometry;
   array_geometry.push_back(Point(-0.025f, 0.f, 0.f));
   array_geometry.push_back(Point(0.025f, 0.f, 0.f));
   NonlinearBeamformer bf(array_geometry, 1u);
   bf.Initialize(kChunkSizeMs, kSampleRateHz);
   // The default constructor parameter sets the target angle to PI / 2.
   Verify(&bf, static_cast<float>(M_PI) / 2.f);
   AimAndVerify(&bf, static_cast<float>(M_PI) / 3.f);
   AimAndVerify(&bf, 3.f * static_cast<float>(M_PI) / 4.f);
   AimAndVerify(&bf, static_cast<float>(M_PI) / 6.f);
   AimAndVerify(&bf, static_cast<float>(M_PI));
 }

 TEST(NonlinearBeamformerTest, InterfAnglesTakeAmbiguityIntoAccount) {
   {
     // For linear arrays there is ambiguity.
     std::vector<Point> array_geometry;
     array_geometry.push_back(Point(-0.1f, 0.f, 0.f));
     array_geometry.push_back(Point(0.f, 0.f, 0.f));
     array_geometry.push_back(Point(0.2f, 0.f, 0.f));
     NonlinearBeamformer bf(array_geometry, 1u);
     bf.Initialize(kChunkSizeMs, kSampleRateHz);
     EXPECT_EQ(2u, bf.interf_angles_radians_.size());
     EXPECT_FLOAT_EQ(M_PI / 2.f - bf.away_radians_,
                     bf.interf_angles_radians_[0]);
     EXPECT_FLOAT_EQ(M_PI / 2.f + bf.away_radians_,
                     bf.interf_angles_radians_[1]);
     bf.AimAt(AzimuthToSphericalPoint(bf.away_radians_ / 2.f));
     EXPECT_EQ(2u, bf.interf_angles_radians_.size());
     EXPECT_FLOAT_EQ(M_PI - bf.away_radians_ / 2.f,
                     bf.interf_angles_radians_[0]);
     EXPECT_FLOAT_EQ(3.f * bf.away_radians_ / 2.f, bf.interf_angles_radians_[1]);
   }
   {
     // For planar arrays with normal in the xy-plane there is ambiguity.
     std::vector<Point> array_geometry;
     array_geometry.push_back(Point(-0.1f, 0.f, 0.f));
     array_geometry.push_back(Point(0.f, 0.f, 0.f));
     array_geometry.push_back(Point(0.2f, 0.f, 0.f));
     array_geometry.push_back(Point(0.1f, 0.f, 0.2f));
     array_geometry.push_back(Point(0.f, 0.f, -0.1f));
     NonlinearBeamformer bf(array_geometry, 1u);
     bf.Initialize(kChunkSizeMs, kSampleRateHz);
     EXPECT_EQ(2u, bf.interf_angles_radians_.size());
     EXPECT_FLOAT_EQ(M_PI / 2.f - bf.away_radians_,
                     bf.interf_angles_radians_[0]);
     EXPECT_FLOAT_EQ(M_PI / 2.f + bf.away_radians_,
                     bf.interf_angles_radians_[1]);
     bf.AimAt(AzimuthToSphericalPoint(bf.away_radians_ / 2.f));
     EXPECT_EQ(2u, bf.interf_angles_radians_.size());
     EXPECT_FLOAT_EQ(M_PI - bf.away_radians_ / 2.f,
                     bf.interf_angles_radians_[0]);
     EXPECT_FLOAT_EQ(3.f * bf.away_radians_ / 2.f, bf.interf_angles_radians_[1]);
   }
   {
     // For planar arrays with normal not in the xy-plane there is no ambiguity.
     std::vector<Point> array_geometry;
     array_geometry.push_back(Point(0.f, 0.f, 0.f));
     array_geometry.push_back(Point(0.2f, 0.f, 0.f));
     array_geometry.push_back(Point(0.f, 0.1f, -0.2f));
     NonlinearBeamformer bf(array_geometry, 1u);
     bf.Initialize(kChunkSizeMs, kSampleRateHz);
     EXPECT_EQ(2u, bf.interf_angles_radians_.size());
     EXPECT_FLOAT_EQ(M_PI / 2.f - bf.away_radians_,
                     bf.interf_angles_radians_[0]);
     EXPECT_FLOAT_EQ(M_PI / 2.f + bf.away_radians_,
                     bf.interf_angles_radians_[1]);
     bf.AimAt(AzimuthToSphericalPoint(bf.away_radians_ / 2.f));
     EXPECT_EQ(2u, bf.interf_angles_radians_.size());
     EXPECT_FLOAT_EQ(-bf.away_radians_ / 2.f, bf.interf_angles_radians_[0]);
     EXPECT_FLOAT_EQ(3.f * bf.away_radians_ / 2.f, bf.interf_angles_radians_[1]);
   }
   {
     // For arrays which are not linear or planar there is no ambiguity.
     std::vector<Point> array_geometry;
     array_geometry.push_back(Point(0.f, 0.f, 0.f));
     array_geometry.push_back(Point(0.1f, 0.f, 0.f));
     array_geometry.push_back(Point(0.f, 0.2f, 0.f));
     array_geometry.push_back(Point(0.f, 0.f, 0.3f));
     NonlinearBeamformer bf(array_geometry, 1u);
     bf.Initialize(kChunkSizeMs, kSampleRateHz);
     EXPECT_EQ(2u, bf.interf_angles_radians_.size());
     EXPECT_FLOAT_EQ(M_PI / 2.f - bf.away_radians_,
                     bf.interf_angles_radians_[0]);
     EXPECT_FLOAT_EQ(M_PI / 2.f + bf.away_radians_,
                     bf.interf_angles_radians_[1]);
     bf.AimAt(AzimuthToSphericalPoint(bf.away_radians_ / 2.f));
     EXPECT_EQ(2u, bf.interf_angles_radians_.size());
     EXPECT_FLOAT_EQ(-bf.away_radians_ / 2.f, bf.interf_angles_radians_[0]);
     EXPECT_FLOAT_EQ(3.f * bf.away_radians_ / 2.f, bf.interf_angles_radians_[1]);
   }
 }

 // TODO(peah): Investigate why the nonlinear_beamformer.cc causes a DCHECK in
 // this setup.
 TEST(BeamformerBitExactnessTest,
      DISABLED_Stereo8kHz_ArrayGeometry1_TargetDirection1) {
   const float kOutputReference[] = {0.001318f, -0.001091f, 0.000990f,
                                     0.001318f, -0.001091f, 0.000990f};

   RunBitExactnessTest(AudioProcessing::kSampleRate8kHz, CreateArrayGeometry(1),
                       TargetDirection1, kOutputReference);
 }

 TEST(BeamformerBitExactnessTest,
      Stereo16kHz_ArrayGeometry1_TargetDirection1) {
   const float kOutputReference[] = {-0.000077f, -0.000147f, -0.000138f,
                                     -0.000077f, -0.000147f, -0.000138f};

   RunBitExactnessTest(AudioProcessing::kSampleRate16kHz, CreateArrayGeometry(1),
                       TargetDirection1, kOutputReference);
 }

 TEST(BeamformerBitExactnessTest,
      Stereo32kHz_ArrayGeometry1_TargetDirection1) {
   const float kOutputReference[] = {-0.000061f, -0.000061f, -0.000061f,
                                     -0.000061f, -0.000061f, -0.000061f};

   RunBitExactnessTest(AudioProcessing::kSampleRate32kHz, CreateArrayGeometry(1),
                       TargetDirection1, kOutputReference);
 }

 TEST(BeamformerBitExactnessTest,
      Stereo48kHz_ArrayGeometry1_TargetDirection1) {
   const float kOutputReference[] = {0.000450f, 0.000436f, 0.000433f,
                                     0.000450f, 0.000436f, 0.000433f};

   RunBitExactnessTest(AudioProcessing::kSampleRate48kHz, CreateArrayGeometry(1),
                       TargetDirection1, kOutputReference);
 }

 // TODO(peah): Investigate why the nonlinear_beamformer.cc causes a DCHECK in
 // this setup.
 TEST(BeamformerBitExactnessTest,
      DISABLED_Stereo8kHz_ArrayGeometry1_TargetDirection2) {
   const float kOutputReference[] = {0.001144f,  -0.001026f, 0.001074f,
                                     -0.016205f, -0.007324f, -0.015656f};

   RunBitExactnessTest(AudioProcessing::kSampleRate8kHz, CreateArrayGeometry(1),
                       TargetDirection2, kOutputReference);
 }

 TEST(BeamformerBitExactnessTest,
      Stereo16kHz_ArrayGeometry1_TargetDirection2) {
   const float kOutputReference[] = {0.000221f, -0.000249f, 0.000140f,
                                     0.000221f, -0.000249f, 0.000140f};

   RunBitExactnessTest(AudioProcessing::kSampleRate16kHz, CreateArrayGeometry(1),
                       TargetDirection2, kOutputReference);
 }

 TEST(BeamformerBitExactnessTest,
      Stereo32kHz_ArrayGeometry1_TargetDirection2) {
   const float kOutputReference[] = {0.000763f, -0.000336f, 0.000549f,
                                     0.000763f, -0.000336f, 0.000549f};

   RunBitExactnessTest(AudioProcessing::kSampleRate32kHz, CreateArrayGeometry(1),
                       TargetDirection2, kOutputReference);
 }

 TEST(BeamformerBitExactnessTest,
      Stereo48kHz_ArrayGeometry1_TargetDirection2) {
   const float kOutputReference[] = {-0.000004f, -0.000494f, 0.000255f,
                                     -0.000004f, -0.000494f, 0.000255f};

   RunBitExactnessTest(AudioProcessing::kSampleRate48kHz, CreateArrayGeometry(1),
                       TargetDirection2, kOutputReference);
 }

 TEST(BeamformerBitExactnessTest,
      Stereo8kHz_ArrayGeometry2_TargetDirection2) {
   const float kOutputReference[] = {-0.000914f, 0.002170f, -0.002382f,
                                     -0.000914f, 0.002170f, -0.002382f};

   RunBitExactnessTest(AudioProcessing::kSampleRate8kHz, CreateArrayGeometry(2),
                       TargetDirection2, kOutputReference);
 }

 TEST(BeamformerBitExactnessTest,
      Stereo16kHz_ArrayGeometry2_TargetDirection2) {
   const float kOutputReference[] = {0.000179f, -0.000179f, 0.000081f,
                                     0.000179f, -0.000179f, 0.000081f};

   RunBitExactnessTest(AudioProcessing::kSampleRate16kHz, CreateArrayGeometry(2),
                       TargetDirection2, kOutputReference);
 }

 TEST(BeamformerBitExactnessTest,
      Stereo32kHz_ArrayGeometry2_TargetDirection2) {
   const float kOutputReference[] = {0.000549f, -0.000214f, 0.000366f,
                                     0.000549f, -0.000214f, 0.000366f};

   RunBitExactnessTest(AudioProcessing::kSampleRate32kHz, CreateArrayGeometry(2),
                       TargetDirection2, kOutputReference);
 }

 TEST(BeamformerBitExactnessTest,
      Stereo48kHz_ArrayGeometry2_TargetDirection2) {
   const float kOutputReference[] = {0.000019f, -0.000310f, 0.000182f,
                                     0.000019f, -0.000310f, 0.000182f};

   RunBitExactnessTest(AudioProcessing::kSampleRate48kHz, CreateArrayGeometry(2),
                       TargetDirection2, kOutputReference);
 }

 // TODO(peah): Investigate why the nonlinear_beamformer.cc causes a DCHECK in
 // this setup.
 TEST(BeamformerBitExactnessTest,
      DISABLED_Stereo16kHz_ArrayGeometry3_TargetDirection1) {
   const float kOutputReference[] = {-0.000161f, 0.000171f, -0.000096f,
                                     0.001007f,  0.000427f, 0.000977f};

   RunBitExactnessTest(AudioProcessing::kSampleRate16kHz, CreateArrayGeometry(3),
                       TargetDirection1, kOutputReference);
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2015 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.
	*/

	// MSVC++ requires this to be set before any other includes to get M_PI.
	#define _USE_MATH_DEFINES

	#include "webrtc/modules/audio_processing/beamformer/nonlinear_beamformer.h"

	#include <math.h>

	#include "testing/gtest/include/gtest/gtest.h"
	#include "webrtc/base/array_view.h"
	#include "webrtc/modules/audio_processing/audio_buffer.h"
	#include "webrtc/modules/audio_processing/test/audio_buffer_tools.h"
	#include "webrtc/modules/audio_processing/test/bitexactness_tools.h"

	namespace webrtc {
	namespace {

	const int kChunkSizeMs = 10;
	const int kSampleRateHz = 16000;

	SphericalPointf AzimuthToSphericalPoint(float azimuth_radians) {
	return SphericalPointf(azimuth_radians, 0.f, 1.f);
	}

	void Verify(NonlinearBeamformer* bf, float target_azimuth_radians) {
	EXPECT_TRUE(bf->IsInBeam(AzimuthToSphericalPoint(target_azimuth_radians)));
	EXPECT_TRUE(bf->IsInBeam(AzimuthToSphericalPoint(
	target_azimuth_radians - NonlinearBeamformer::kHalfBeamWidthRadians +
	0.001f)));
	EXPECT_TRUE(bf->IsInBeam(AzimuthToSphericalPoint(
	target_azimuth_radians + NonlinearBeamformer::kHalfBeamWidthRadians -
	0.001f)));
	EXPECT_FALSE(bf->IsInBeam(AzimuthToSphericalPoint(
	target_azimuth_radians - NonlinearBeamformer::kHalfBeamWidthRadians -
	0.001f)));
	EXPECT_FALSE(bf->IsInBeam(AzimuthToSphericalPoint(
	target_azimuth_radians + NonlinearBeamformer::kHalfBeamWidthRadians +
	0.001f)));
	}

	void AimAndVerify(NonlinearBeamformer* bf, float target_azimuth_radians) {
	bf->AimAt(AzimuthToSphericalPoint(target_azimuth_radians));
	Verify(bf, target_azimuth_radians);
	}

	// Bitexactness test code.
	const size_t kNumFramesToProcess = 1000;

	void ProcessOneFrame(int sample_rate_hz,
	AudioBuffer* capture_audio_buffer,
	NonlinearBeamformer* beamformer) {
	if (sample_rate_hz > AudioProcessing::kSampleRate16kHz) {
	capture_audio_buffer->SplitIntoFrequencyBands();
	}

	beamformer->AnalyzeChunk(*capture_audio_buffer->split_data_f());
	capture_audio_buffer->set_num_channels(1);
	beamformer->PostFilter(capture_audio_buffer->split_data_f());

	if (sample_rate_hz > AudioProcessing::kSampleRate16kHz) {
	capture_audio_buffer->MergeFrequencyBands();
	}
	}

	int BeamformerSampleRate(int sample_rate_hz) {
	return (sample_rate_hz > AudioProcessing::kSampleRate16kHz
	? AudioProcessing::kSampleRate16kHz
	: sample_rate_hz);
	}

	void RunBitExactnessTest(int sample_rate_hz,
	const std::vector<Point>& array_geometry,
	const SphericalPointf& target_direction,
	rtc::ArrayView<const float> output_reference) {
	NonlinearBeamformer beamformer(array_geometry, 1u, target_direction);
	beamformer.Initialize(AudioProcessing::kChunkSizeMs,
	BeamformerSampleRate(sample_rate_hz));

	const StreamConfig capture_config(sample_rate_hz, array_geometry.size(),
	false);
	AudioBuffer capture_buffer(
	capture_config.num_frames(), capture_config.num_channels(),
	capture_config.num_frames(), capture_config.num_channels(),
	capture_config.num_frames());
	test::InputAudioFile capture_file(
	test::GetApmCaptureTestVectorFileName(sample_rate_hz));
	std::vector<float> capture_input(capture_config.num_frames() *
	capture_config.num_channels());
	for (size_t frame_no = 0u; frame_no < kNumFramesToProcess; ++frame_no) {
	ReadFloatSamplesFromStereoFile(capture_config.num_frames(),
	capture_config.num_channels(), &capture_file,
	capture_input);

	test::CopyVectorToAudioBuffer(capture_config, capture_input,
	&capture_buffer);

	ProcessOneFrame(sample_rate_hz, &capture_buffer, &beamformer);
	}

	// Extract and verify the test results.
	std::vector<float> capture_output;
	test::ExtractVectorFromAudioBuffer(capture_config, &capture_buffer,
	&capture_output);

	const float kElementErrorBound = 1.f / static_cast<float>(1 << 15);

	// Compare the output with the reference. Only the first values of the output
	// from last frame processed are compared in order not having to specify all
	// preceeding frames as testvectors. As the algorithm being tested has a
	// memory, testing only the last frame implicitly also tests the preceeding
	// frames.
	EXPECT_TRUE(test::VerifyDeinterleavedArray(
	capture_config.num_frames(), capture_config.num_channels(),
	output_reference, capture_output, kElementErrorBound));
	}

	// TODO(peah): Add bitexactness tests for scenarios with more than 2 input
	// channels.
	std::vector<Point> CreateArrayGeometry(int variant) {
	std::vector<Point> array_geometry;
	switch (variant) {
	case 1:
	array_geometry.push_back(Point(-0.025f, 0.f, 0.f));
	array_geometry.push_back(Point(0.025f, 0.f, 0.f));
	break;
	case 2:
	array_geometry.push_back(Point(-0.035f, 0.f, 0.f));
	array_geometry.push_back(Point(0.035f, 0.f, 0.f));
	break;
	case 3:
	array_geometry.push_back(Point(-0.5f, 0.f, 0.f));
	array_geometry.push_back(Point(0.5f, 0.f, 0.f));
	break;
	default:
	RTC_CHECK(false);
	}
	return array_geometry;
	}

	const SphericalPointf TargetDirection1(0.4f * static_cast<float>(M_PI) / 2.f,
	0.f,
	1.f);
	const SphericalPointf TargetDirection2(static_cast<float>(M_PI) / 2.f,
	1.f,
	2.f);

	} // namespace

	TEST(NonlinearBeamformerTest, AimingModifiesBeam) {
	std::vector<Point> array_geometry;
	array_geometry.push_back(Point(-0.025f, 0.f, 0.f));
	array_geometry.push_back(Point(0.025f, 0.f, 0.f));
	NonlinearBeamformer bf(array_geometry, 1u);
	bf.Initialize(kChunkSizeMs, kSampleRateHz);
	// The default constructor parameter sets the target angle to PI / 2.
	Verify(&bf, static_cast<float>(M_PI) / 2.f);
	AimAndVerify(&bf, static_cast<float>(M_PI) / 3.f);
	AimAndVerify(&bf, 3.f * static_cast<float>(M_PI) / 4.f);
	AimAndVerify(&bf, static_cast<float>(M_PI) / 6.f);
	AimAndVerify(&bf, static_cast<float>(M_PI));
	}

	TEST(NonlinearBeamformerTest, InterfAnglesTakeAmbiguityIntoAccount) {
	{
	// For linear arrays there is ambiguity.
	std::vector<Point> array_geometry;
	array_geometry.push_back(Point(-0.1f, 0.f, 0.f));
	array_geometry.push_back(Point(0.f, 0.f, 0.f));
	array_geometry.push_back(Point(0.2f, 0.f, 0.f));
	NonlinearBeamformer bf(array_geometry, 1u);
	bf.Initialize(kChunkSizeMs, kSampleRateHz);
	EXPECT_EQ(2u, bf.interf_angles_radians_.size());
	EXPECT_FLOAT_EQ(M_PI / 2.f - bf.away_radians_,
	bf.interf_angles_radians_[0]);
	EXPECT_FLOAT_EQ(M_PI / 2.f + bf.away_radians_,
	bf.interf_angles_radians_[1]);
	bf.AimAt(AzimuthToSphericalPoint(bf.away_radians_ / 2.f));
	EXPECT_EQ(2u, bf.interf_angles_radians_.size());
	EXPECT_FLOAT_EQ(M_PI - bf.away_radians_ / 2.f,
	bf.interf_angles_radians_[0]);
	EXPECT_FLOAT_EQ(3.f * bf.away_radians_ / 2.f, bf.interf_angles_radians_[1]);
	}
	{
	// For planar arrays with normal in the xy-plane there is ambiguity.
	std::vector<Point> array_geometry;
	array_geometry.push_back(Point(-0.1f, 0.f, 0.f));
	array_geometry.push_back(Point(0.f, 0.f, 0.f));
	array_geometry.push_back(Point(0.2f, 0.f, 0.f));
	array_geometry.push_back(Point(0.1f, 0.f, 0.2f));
	array_geometry.push_back(Point(0.f, 0.f, -0.1f));
	NonlinearBeamformer bf(array_geometry, 1u);
	bf.Initialize(kChunkSizeMs, kSampleRateHz);
	EXPECT_EQ(2u, bf.interf_angles_radians_.size());
	EXPECT_FLOAT_EQ(M_PI / 2.f - bf.away_radians_,
	bf.interf_angles_radians_[0]);
	EXPECT_FLOAT_EQ(M_PI / 2.f + bf.away_radians_,
	bf.interf_angles_radians_[1]);
	bf.AimAt(AzimuthToSphericalPoint(bf.away_radians_ / 2.f));
	EXPECT_EQ(2u, bf.interf_angles_radians_.size());
	EXPECT_FLOAT_EQ(M_PI - bf.away_radians_ / 2.f,
	bf.interf_angles_radians_[0]);
	EXPECT_FLOAT_EQ(3.f * bf.away_radians_ / 2.f, bf.interf_angles_radians_[1]);
	}
	{
	// For planar arrays with normal not in the xy-plane there is no ambiguity.
	std::vector<Point> array_geometry;
	array_geometry.push_back(Point(0.f, 0.f, 0.f));
	array_geometry.push_back(Point(0.2f, 0.f, 0.f));
	array_geometry.push_back(Point(0.f, 0.1f, -0.2f));
	NonlinearBeamformer bf(array_geometry, 1u);
	bf.Initialize(kChunkSizeMs, kSampleRateHz);
	EXPECT_EQ(2u, bf.interf_angles_radians_.size());
	EXPECT_FLOAT_EQ(M_PI / 2.f - bf.away_radians_,
	bf.interf_angles_radians_[0]);
	EXPECT_FLOAT_EQ(M_PI / 2.f + bf.away_radians_,
	bf.interf_angles_radians_[1]);
	bf.AimAt(AzimuthToSphericalPoint(bf.away_radians_ / 2.f));
	EXPECT_EQ(2u, bf.interf_angles_radians_.size());
	EXPECT_FLOAT_EQ(-bf.away_radians_ / 2.f, bf.interf_angles_radians_[0]);
	EXPECT_FLOAT_EQ(3.f * bf.away_radians_ / 2.f, bf.interf_angles_radians_[1]);
	}
	{
	// For arrays which are not linear or planar there is no ambiguity.
	std::vector<Point> array_geometry;
	array_geometry.push_back(Point(0.f, 0.f, 0.f));
	array_geometry.push_back(Point(0.1f, 0.f, 0.f));
	array_geometry.push_back(Point(0.f, 0.2f, 0.f));
	array_geometry.push_back(Point(0.f, 0.f, 0.3f));
	NonlinearBeamformer bf(array_geometry, 1u);
	bf.Initialize(kChunkSizeMs, kSampleRateHz);
	EXPECT_EQ(2u, bf.interf_angles_radians_.size());
	EXPECT_FLOAT_EQ(M_PI / 2.f - bf.away_radians_,
	bf.interf_angles_radians_[0]);
	EXPECT_FLOAT_EQ(M_PI / 2.f + bf.away_radians_,
	bf.interf_angles_radians_[1]);
	bf.AimAt(AzimuthToSphericalPoint(bf.away_radians_ / 2.f));
	EXPECT_EQ(2u, bf.interf_angles_radians_.size());
	EXPECT_FLOAT_EQ(-bf.away_radians_ / 2.f, bf.interf_angles_radians_[0]);
	EXPECT_FLOAT_EQ(3.f * bf.away_radians_ / 2.f, bf.interf_angles_radians_[1]);
	}
	}

	// TODO(peah): Investigate why the nonlinear_beamformer.cc causes a DCHECK in
	// this setup.
	TEST(BeamformerBitExactnessTest,
	DISABLED_Stereo8kHz_ArrayGeometry1_TargetDirection1) {
	const float kOutputReference[] = {0.001318f, -0.001091f, 0.000990f,
	0.001318f, -0.001091f, 0.000990f};

	RunBitExactnessTest(AudioProcessing::kSampleRate8kHz, CreateArrayGeometry(1),
	TargetDirection1, kOutputReference);
	}

	TEST(BeamformerBitExactnessTest,
	Stereo16kHz_ArrayGeometry1_TargetDirection1) {
	const float kOutputReference[] = {-0.000077f, -0.000147f, -0.000138f,
	-0.000077f, -0.000147f, -0.000138f};

	RunBitExactnessTest(AudioProcessing::kSampleRate16kHz, CreateArrayGeometry(1),
	TargetDirection1, kOutputReference);
	}

	TEST(BeamformerBitExactnessTest,
	Stereo32kHz_ArrayGeometry1_TargetDirection1) {
	const float kOutputReference[] = {-0.000061f, -0.000061f, -0.000061f,
	-0.000061f, -0.000061f, -0.000061f};

	RunBitExactnessTest(AudioProcessing::kSampleRate32kHz, CreateArrayGeometry(1),
	TargetDirection1, kOutputReference);
	}

	TEST(BeamformerBitExactnessTest,
	Stereo48kHz_ArrayGeometry1_TargetDirection1) {
	const float kOutputReference[] = {0.000450f, 0.000436f, 0.000433f,
	0.000450f, 0.000436f, 0.000433f};

	RunBitExactnessTest(AudioProcessing::kSampleRate48kHz, CreateArrayGeometry(1),
	TargetDirection1, kOutputReference);
	}

	// TODO(peah): Investigate why the nonlinear_beamformer.cc causes a DCHECK in
	// this setup.
	TEST(BeamformerBitExactnessTest,
	DISABLED_Stereo8kHz_ArrayGeometry1_TargetDirection2) {
	const float kOutputReference[] = {0.001144f, -0.001026f, 0.001074f,
	-0.016205f, -0.007324f, -0.015656f};

	RunBitExactnessTest(AudioProcessing::kSampleRate8kHz, CreateArrayGeometry(1),
	TargetDirection2, kOutputReference);
	}

	TEST(BeamformerBitExactnessTest,
	Stereo16kHz_ArrayGeometry1_TargetDirection2) {
	const float kOutputReference[] = {0.000221f, -0.000249f, 0.000140f,
	0.000221f, -0.000249f, 0.000140f};

	RunBitExactnessTest(AudioProcessing::kSampleRate16kHz, CreateArrayGeometry(1),
	TargetDirection2, kOutputReference);
	}

	TEST(BeamformerBitExactnessTest,
	Stereo32kHz_ArrayGeometry1_TargetDirection2) {
	const float kOutputReference[] = {0.000763f, -0.000336f, 0.000549f,
	0.000763f, -0.000336f, 0.000549f};

	RunBitExactnessTest(AudioProcessing::kSampleRate32kHz, CreateArrayGeometry(1),
	TargetDirection2, kOutputReference);
	}

	TEST(BeamformerBitExactnessTest,
	Stereo48kHz_ArrayGeometry1_TargetDirection2) {
	const float kOutputReference[] = {-0.000004f, -0.000494f, 0.000255f,
	-0.000004f, -0.000494f, 0.000255f};

	RunBitExactnessTest(AudioProcessing::kSampleRate48kHz, CreateArrayGeometry(1),
	TargetDirection2, kOutputReference);
	}

	TEST(BeamformerBitExactnessTest,
	Stereo8kHz_ArrayGeometry2_TargetDirection2) {
	const float kOutputReference[] = {-0.000914f, 0.002170f, -0.002382f,
	-0.000914f, 0.002170f, -0.002382f};

	RunBitExactnessTest(AudioProcessing::kSampleRate8kHz, CreateArrayGeometry(2),
	TargetDirection2, kOutputReference);
	}

	TEST(BeamformerBitExactnessTest,
	Stereo16kHz_ArrayGeometry2_TargetDirection2) {
	const float kOutputReference[] = {0.000179f, -0.000179f, 0.000081f,
	0.000179f, -0.000179f, 0.000081f};

	RunBitExactnessTest(AudioProcessing::kSampleRate16kHz, CreateArrayGeometry(2),
	TargetDirection2, kOutputReference);
	}

	TEST(BeamformerBitExactnessTest,
	Stereo32kHz_ArrayGeometry2_TargetDirection2) {
	const float kOutputReference[] = {0.000549f, -0.000214f, 0.000366f,
	0.000549f, -0.000214f, 0.000366f};

	RunBitExactnessTest(AudioProcessing::kSampleRate32kHz, CreateArrayGeometry(2),
	TargetDirection2, kOutputReference);
	}

	TEST(BeamformerBitExactnessTest,
	Stereo48kHz_ArrayGeometry2_TargetDirection2) {
	const float kOutputReference[] = {0.000019f, -0.000310f, 0.000182f,
	0.000019f, -0.000310f, 0.000182f};

	RunBitExactnessTest(AudioProcessing::kSampleRate48kHz, CreateArrayGeometry(2),
	TargetDirection2, kOutputReference);
	}

	// TODO(peah): Investigate why the nonlinear_beamformer.cc causes a DCHECK in
	// this setup.
	TEST(BeamformerBitExactnessTest,
	DISABLED_Stereo16kHz_ArrayGeometry3_TargetDirection1) {
	const float kOutputReference[] = {-0.000161f, 0.000171f, -0.000096f,
	0.001007f, 0.000427f, 0.000977f};

	RunBitExactnessTest(AudioProcessing::kSampleRate16kHz, CreateArrayGeometry(3),
	TargetDirection1, kOutputReference);
	}

	} // namespace webrtc