/* * Copyright (c) 2018 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 "api/audio/echo_canceller3_config.h" #include #include #include "rtc_base/checks.h" #include "rtc_base/numerics/safe_minmax.h" namespace webrtc { namespace { bool Limit(float* value, float min, float max) { float clamped = rtc::SafeClamp(*value, min, max); clamped = std::isfinite(clamped) ? clamped : min; bool res = *value == clamped; *value = clamped; return res; } bool Limit(size_t* value, size_t min, size_t max) { size_t clamped = rtc::SafeClamp(*value, min, max); bool res = *value == clamped; *value = clamped; return res; } bool Limit(int* value, int min, int max) { int clamped = rtc::SafeClamp(*value, min, max); bool res = *value == clamped; *value = clamped; return res; } bool FloorLimit(size_t* value, size_t min) { size_t clamped = *value >= min ? *value : min; bool res = *value == clamped; *value = clamped; return res; } } // namespace EchoCanceller3Config::EchoCanceller3Config() = default; EchoCanceller3Config::EchoCanceller3Config(const EchoCanceller3Config& e) = default; EchoCanceller3Config& EchoCanceller3Config::operator=( const EchoCanceller3Config& e) = default; EchoCanceller3Config::Delay::Delay() = default; EchoCanceller3Config::Delay::Delay(const EchoCanceller3Config::Delay& e) = default; EchoCanceller3Config::Delay& EchoCanceller3Config::Delay::operator=( const Delay& e) = default; EchoCanceller3Config::EchoModel::EchoModel() = default; EchoCanceller3Config::EchoModel::EchoModel( const EchoCanceller3Config::EchoModel& e) = default; EchoCanceller3Config::EchoModel& EchoCanceller3Config::EchoModel::operator=( const EchoModel& e) = default; EchoCanceller3Config::Suppressor::Suppressor() = default; EchoCanceller3Config::Suppressor::Suppressor( const EchoCanceller3Config::Suppressor& e) = default; EchoCanceller3Config::Suppressor& EchoCanceller3Config::Suppressor::operator=( const Suppressor& e) = default; EchoCanceller3Config::Suppressor::MaskingThresholds::MaskingThresholds( float enr_transparent, float enr_suppress, float emr_transparent) : enr_transparent(enr_transparent), enr_suppress(enr_suppress), emr_transparent(emr_transparent) {} EchoCanceller3Config::Suppressor::MaskingThresholds::MaskingThresholds( const EchoCanceller3Config::Suppressor::MaskingThresholds& e) = default; EchoCanceller3Config::Suppressor::MaskingThresholds& EchoCanceller3Config::Suppressor::MaskingThresholds::operator=( const MaskingThresholds& e) = default; EchoCanceller3Config::Suppressor::Tuning::Tuning(MaskingThresholds mask_lf, MaskingThresholds mask_hf, float max_inc_factor, float max_dec_factor_lf) : mask_lf(mask_lf), mask_hf(mask_hf), max_inc_factor(max_inc_factor), max_dec_factor_lf(max_dec_factor_lf) {} EchoCanceller3Config::Suppressor::Tuning::Tuning( const EchoCanceller3Config::Suppressor::Tuning& e) = default; EchoCanceller3Config::Suppressor::Tuning& EchoCanceller3Config::Suppressor::Tuning::operator=(const Tuning& e) = default; bool EchoCanceller3Config::Validate(EchoCanceller3Config* config) { RTC_DCHECK(config); EchoCanceller3Config* c = config; bool res = true; if (c->delay.down_sampling_factor != 4 && c->delay.down_sampling_factor != 8) { c->delay.down_sampling_factor = 4; res = false; } res = res & Limit(&c->delay.default_delay, 0, 5000); res = res & Limit(&c->delay.num_filters, 0, 5000); res = res & Limit(&c->delay.delay_headroom_samples, 0, 5000); res = res & Limit(&c->delay.hysteresis_limit_blocks, 0, 5000); res = res & Limit(&c->delay.fixed_capture_delay_samples, 0, 5000); res = res & Limit(&c->delay.delay_estimate_smoothing, 0.f, 1.f); res = res & Limit(&c->delay.delay_candidate_detection_threshold, 0.f, 1.f); res = res & Limit(&c->delay.delay_selection_thresholds.initial, 1, 250); res = res & Limit(&c->delay.delay_selection_thresholds.converged, 1, 250); res = res & FloorLimit(&c->filter.refined.length_blocks, 1); res = res & Limit(&c->filter.refined.leakage_converged, 0.f, 1000.f); res = res & Limit(&c->filter.refined.leakage_diverged, 0.f, 1000.f); res = res & Limit(&c->filter.refined.error_floor, 0.f, 1000.f); res = res & Limit(&c->filter.refined.error_ceil, 0.f, 100000000.f); res = res & Limit(&c->filter.refined.noise_gate, 0.f, 100000000.f); res = res & FloorLimit(&c->filter.refined_initial.length_blocks, 1); res = res & Limit(&c->filter.refined_initial.leakage_converged, 0.f, 1000.f); res = res & Limit(&c->filter.refined_initial.leakage_diverged, 0.f, 1000.f); res = res & Limit(&c->filter.refined_initial.error_floor, 0.f, 1000.f); res = res & Limit(&c->filter.refined_initial.error_ceil, 0.f, 100000000.f); res = res & Limit(&c->filter.refined_initial.noise_gate, 0.f, 100000000.f); if (c->filter.refined.length_blocks < c->filter.refined_initial.length_blocks) { c->filter.refined_initial.length_blocks = c->filter.refined.length_blocks; res = false; } res = res & FloorLimit(&c->filter.coarse.length_blocks, 1); res = res & Limit(&c->filter.coarse.rate, 0.f, 1.f); res = res & Limit(&c->filter.coarse.noise_gate, 0.f, 100000000.f); res = res & FloorLimit(&c->filter.coarse_initial.length_blocks, 1); res = res & Limit(&c->filter.coarse_initial.rate, 0.f, 1.f); res = res & Limit(&c->filter.coarse_initial.noise_gate, 0.f, 100000000.f); if (c->filter.coarse.length_blocks < c->filter.coarse_initial.length_blocks) { c->filter.coarse_initial.length_blocks = c->filter.coarse.length_blocks; res = false; } res = res & Limit(&c->filter.config_change_duration_blocks, 0, 100000); res = res & Limit(&c->filter.initial_state_seconds, 0.f, 100.f); res = res & Limit(&c->filter.coarse_reset_hangover_blocks, 0, 250000); res = res & Limit(&c->erle.min, 1.f, 100000.f); res = res & Limit(&c->erle.max_l, 1.f, 100000.f); res = res & Limit(&c->erle.max_h, 1.f, 100000.f); if (c->erle.min > c->erle.max_l || c->erle.min > c->erle.max_h) { c->erle.min = std::min(c->erle.max_l, c->erle.max_h); res = false; } res = res & Limit(&c->erle.num_sections, 1, c->filter.refined.length_blocks); res = res & Limit(&c->ep_strength.default_gain, 0.f, 1000000.f); res = res & Limit(&c->ep_strength.default_len, -1.f, 1.f); res = res & Limit(&c->ep_strength.nearend_len, -1.0f, 1.0f); res = res & Limit(&c->echo_audibility.low_render_limit, 0.f, 32768.f * 32768.f); res = res & Limit(&c->echo_audibility.normal_render_limit, 0.f, 32768.f * 32768.f); res = res & Limit(&c->echo_audibility.floor_power, 0.f, 32768.f * 32768.f); res = res & Limit(&c->echo_audibility.audibility_threshold_lf, 0.f, 32768.f * 32768.f); res = res & Limit(&c->echo_audibility.audibility_threshold_mf, 0.f, 32768.f * 32768.f); res = res & Limit(&c->echo_audibility.audibility_threshold_hf, 0.f, 32768.f * 32768.f); res = res & Limit(&c->render_levels.active_render_limit, 0.f, 32768.f * 32768.f); res = res & Limit(&c->render_levels.poor_excitation_render_limit, 0.f, 32768.f * 32768.f); res = res & Limit(&c->render_levels.poor_excitation_render_limit_ds8, 0.f, 32768.f * 32768.f); res = res & Limit(&c->echo_model.noise_floor_hold, 0, 1000); res = res & Limit(&c->echo_model.min_noise_floor_power, 0, 2000000.f); res = res & Limit(&c->echo_model.stationary_gate_slope, 0, 1000000.f); res = res & Limit(&c->echo_model.noise_gate_power, 0, 1000000.f); res = res & Limit(&c->echo_model.noise_gate_slope, 0, 1000000.f); res = res & Limit(&c->echo_model.render_pre_window_size, 0, 100); res = res & Limit(&c->echo_model.render_post_window_size, 0, 100); res = res & Limit(&c->comfort_noise.noise_floor_dbfs, -200.f, 0.f); res = res & Limit(&c->suppressor.nearend_average_blocks, 1, 5000); res = res & Limit(&c->suppressor.normal_tuning.mask_lf.enr_transparent, 0.f, 100.f); res = res & Limit(&c->suppressor.normal_tuning.mask_lf.enr_suppress, 0.f, 100.f); res = res & Limit(&c->suppressor.normal_tuning.mask_lf.emr_transparent, 0.f, 100.f); res = res & Limit(&c->suppressor.normal_tuning.mask_hf.enr_transparent, 0.f, 100.f); res = res & Limit(&c->suppressor.normal_tuning.mask_hf.enr_suppress, 0.f, 100.f); res = res & Limit(&c->suppressor.normal_tuning.mask_hf.emr_transparent, 0.f, 100.f); res = res & Limit(&c->suppressor.normal_tuning.max_inc_factor, 0.f, 100.f); res = res & Limit(&c->suppressor.normal_tuning.max_dec_factor_lf, 0.f, 100.f); res = res & Limit(&c->suppressor.nearend_tuning.mask_lf.enr_transparent, 0.f, 100.f); res = res & Limit(&c->suppressor.nearend_tuning.mask_lf.enr_suppress, 0.f, 100.f); res = res & Limit(&c->suppressor.nearend_tuning.mask_lf.emr_transparent, 0.f, 100.f); res = res & Limit(&c->suppressor.nearend_tuning.mask_hf.enr_transparent, 0.f, 100.f); res = res & Limit(&c->suppressor.nearend_tuning.mask_hf.enr_suppress, 0.f, 100.f); res = res & Limit(&c->suppressor.nearend_tuning.mask_hf.emr_transparent, 0.f, 100.f); res = res & Limit(&c->suppressor.nearend_tuning.max_inc_factor, 0.f, 100.f); res = res & Limit(&c->suppressor.nearend_tuning.max_dec_factor_lf, 0.f, 100.f); res = res & Limit(&c->suppressor.last_permanent_lf_smoothing_band, 0, 64); res = res & Limit(&c->suppressor.last_lf_smoothing_band, 0, 64); res = res & Limit(&c->suppressor.last_lf_band, 0, 63); res = res & Limit(&c->suppressor.first_hf_band, c->suppressor.last_lf_band + 1, 64); res = res & Limit(&c->suppressor.dominant_nearend_detection.enr_threshold, 0.f, 1000000.f); res = res & Limit(&c->suppressor.dominant_nearend_detection.snr_threshold, 0.f, 1000000.f); res = res & Limit(&c->suppressor.dominant_nearend_detection.hold_duration, 0, 10000); res = res & Limit(&c->suppressor.dominant_nearend_detection.trigger_threshold, 0, 10000); res = res & Limit(&c->suppressor.subband_nearend_detection.nearend_average_blocks, 1, 1024); res = res & Limit(&c->suppressor.subband_nearend_detection.subband1.low, 0, 65); res = res & Limit(&c->suppressor.subband_nearend_detection.subband1.high, c->suppressor.subband_nearend_detection.subband1.low, 65); res = res & Limit(&c->suppressor.subband_nearend_detection.subband2.low, 0, 65); res = res & Limit(&c->suppressor.subband_nearend_detection.subband2.high, c->suppressor.subband_nearend_detection.subband2.low, 65); res = res & Limit(&c->suppressor.subband_nearend_detection.nearend_threshold, 0.f, 1.e24f); res = res & Limit(&c->suppressor.subband_nearend_detection.snr_threshold, 0.f, 1.e24f); res = res & Limit(&c->suppressor.high_bands_suppression.enr_threshold, 0.f, 1000000.f); res = res & Limit(&c->suppressor.high_bands_suppression.max_gain_during_echo, 0.f, 1.f); res = res & Limit(&c->suppressor.high_bands_suppression .anti_howling_activation_threshold, 0.f, 32768.f * 32768.f); res = res & Limit(&c->suppressor.high_bands_suppression.anti_howling_gain, 0.f, 1.f); res = res & Limit(&c->suppressor.floor_first_increase, 0.f, 1000000.f); return res; } } // namespace webrtc