/* * Copyright (c) 2017 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 "api/array_view.h" #include "modules/audio_processing/aec3/erle_estimator.h" #include "test/gtest.h" namespace webrtc { namespace { constexpr int kLowFrequencyLimit = kFftLengthBy2 / 2; constexpr float kMaxErleLf = 8.f; constexpr float kMaxErleHf = 1.5f; constexpr float kMinErle = 1.0f; constexpr float kTrueErle = 10.f; constexpr float kTrueErleOnsets = 1.0f; void VerifyErleBands(rtc::ArrayView erle, float reference_lf, float reference_hf) { std::for_each( erle.begin(), erle.begin() + kLowFrequencyLimit, [reference_lf](float a) { EXPECT_NEAR(reference_lf, a, 0.001); }); std::for_each( erle.begin() + kLowFrequencyLimit, erle.end(), [reference_hf](float a) { EXPECT_NEAR(reference_hf, a, 0.001); }); } void VerifyErle(rtc::ArrayView erle, float erle_time_domain, float reference_lf, float reference_hf) { VerifyErleBands(erle, reference_lf, reference_hf); EXPECT_NEAR(reference_lf, erle_time_domain, 0.5); } void FormFarendFrame(std::array* X2, std::array* E2, std::array* Y2, float erle) { X2->fill(500 * 1000.f * 1000.f); E2->fill(1000.f * 1000.f); Y2->fill(erle * (*E2)[0]); } void FormNearendFrame(std::array* X2, std::array* E2, std::array* Y2) { X2->fill(0.f); Y2->fill(500.f * 1000.f * 1000.f); E2->fill((*Y2)[0]); } } // namespace TEST(ErleEstimator, VerifyErleIncreaseAndHold) { std::array X2; std::array E2; std::array Y2; ErleEstimator estimator(kMinErle, kMaxErleLf, kMaxErleHf); // Verifies that the ERLE estimate is properly increased to higher values. FormFarendFrame(&X2, &E2, &Y2, kTrueErle); for (size_t k = 0; k < 200; ++k) { estimator.Update(X2, Y2, E2, true, true); } VerifyErle(estimator.Erle(), std::pow(2.f, estimator.ErleTimeDomainLog2()), kMaxErleLf, kMaxErleHf); FormNearendFrame(&X2, &E2, &Y2); // Verifies that the ERLE is not immediately decreased during nearend // activity. for (size_t k = 0; k < 50; ++k) { estimator.Update(X2, Y2, E2, true, true); } VerifyErle(estimator.Erle(), std::pow(2.f, estimator.ErleTimeDomainLog2()), kMaxErleLf, kMaxErleHf); } TEST(ErleEstimator, VerifyErleTrackingOnOnsets) { std::array X2; std::array E2; std::array Y2; ErleEstimator estimator(kMinErle, kMaxErleLf, kMaxErleHf); for (size_t burst = 0; burst < 20; ++burst) { FormFarendFrame(&X2, &E2, &Y2, kTrueErleOnsets); for (size_t k = 0; k < 10; ++k) { estimator.Update(X2, Y2, E2, true, true); } FormFarendFrame(&X2, &E2, &Y2, kTrueErle); for (size_t k = 0; k < 200; ++k) { estimator.Update(X2, Y2, E2, true, true); } FormNearendFrame(&X2, &E2, &Y2); for (size_t k = 0; k < 300; ++k) { estimator.Update(X2, Y2, E2, true, true); } } VerifyErleBands(estimator.ErleOnsets(), kMinErle, kMinErle); FormNearendFrame(&X2, &E2, &Y2); for (size_t k = 0; k < 1000; k++) { estimator.Update(X2, Y2, E2, true, true); } // Verifies that during ne activity, Erle converges to the Erle for onsets. VerifyErle(estimator.Erle(), std::pow(2.f, estimator.ErleTimeDomainLog2()), kMinErle, kMinErle); } TEST(ErleEstimator, VerifyNoErleUpdateDuringLowActivity) { std::array X2; std::array E2; std::array Y2; ErleEstimator estimator(kMinErle, kMaxErleLf, kMaxErleHf); // Verifies that the ERLE estimate is is not updated for low-level render // signals. X2.fill(1000.f * 1000.f); Y2.fill(10 * E2[0]); for (size_t k = 0; k < 200; ++k) { estimator.Update(X2, Y2, E2, true, true); } VerifyErle(estimator.Erle(), std::pow(2.f, estimator.ErleTimeDomainLog2()), kMinErle, kMinErle); } } // namespace webrtc