common_audio/smoothing_filter.cc - src - Git at Google

 /*
  *  Copyright (c) 2016 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 "common_audio/smoothing_filter.h"

 #include <math.h>

 #include <cmath>

 #include "rtc_base/checks.h"
 #include "rtc_base/time_utils.h"

 namespace webrtc {

 SmoothingFilterImpl::SmoothingFilterImpl(int init_time_ms)
     : init_time_ms_(init_time_ms),
       // Duing the initalization time, we use an increasing alpha. Specifically,
       //   alpha(n) = exp(-powf(init_factor_, n)),
       // where `init_factor_` is chosen such that
       //   alpha(init_time_ms_) = exp(-1.0f / init_time_ms_),
       init_factor_(init_time_ms_ == 0
                        ? 0.0f
                        : powf(init_time_ms_, -1.0f / init_time_ms_)),
       // `init_const_` is to a factor to help the calculation during
       // initialization phase.
       init_const_(init_time_ms_ == 0
                       ? 0.0f
                       : init_time_ms_ -
                             powf(init_time_ms_, 1.0f - 1.0f / init_time_ms_)) {
   UpdateAlpha(init_time_ms_);
 }

 SmoothingFilterImpl::~SmoothingFilterImpl() = default;

 void SmoothingFilterImpl::AddSample(float sample) {
   const int64_t now_ms = rtc::TimeMillis();

   if (!init_end_time_ms_) {
     // This is equivalent to assuming the filter has been receiving the same
     // value as the first sample since time -infinity.
     state_ = last_sample_ = sample;
     init_end_time_ms_ = now_ms + init_time_ms_;
     last_state_time_ms_ = now_ms;
     return;
   }

   ExtrapolateLastSample(now_ms);
   last_sample_ = sample;
 }

 absl::optional<float> SmoothingFilterImpl::GetAverage() {
   if (!init_end_time_ms_) {
     // `init_end_time_ms_` undefined since we have not received any sample.
     return absl::nullopt;
   }
   ExtrapolateLastSample(rtc::TimeMillis());
   return state_;
 }

 bool SmoothingFilterImpl::SetTimeConstantMs(int time_constant_ms) {
   if (!init_end_time_ms_ || last_state_time_ms_ < *init_end_time_ms_) {
     return false;
   }
   UpdateAlpha(time_constant_ms);
   return true;
 }

 void SmoothingFilterImpl::UpdateAlpha(int time_constant_ms) {
   alpha_ = time_constant_ms == 0 ? 0.0f : std::exp(-1.0f / time_constant_ms);
 }

 void SmoothingFilterImpl::ExtrapolateLastSample(int64_t time_ms) {
   RTC_DCHECK_GE(time_ms, last_state_time_ms_);
   RTC_DCHECK(init_end_time_ms_);

   float multiplier = 0.0f;

   if (time_ms <= *init_end_time_ms_) {
     // Current update is to be made during initialization phase.
     // We update the state as if the `alpha` has been increased according
     //   alpha(n) = exp(-powf(init_factor_, n)),
     // where n is the time (in millisecond) since the first sample received.
     // With algebraic derivation as shown in the Appendix, we can find that the
     // state can be updated in a similar manner as if alpha is a constant,
     // except for a different multiplier.
     if (init_time_ms_ == 0) {
       // This means `init_factor_` = 0.
       multiplier = 0.0f;
     } else if (init_time_ms_ == 1) {
       // This means `init_factor_` = 1.
       multiplier = std::exp(last_state_time_ms_ - time_ms);
     } else {
       multiplier = std::exp(
           -(powf(init_factor_, last_state_time_ms_ - *init_end_time_ms_) -
             powf(init_factor_, time_ms - *init_end_time_ms_)) /
           init_const_);
     }
   } else {
     if (last_state_time_ms_ < *init_end_time_ms_) {
       // The latest state update was made during initialization phase.
       // We first extrapolate to the initialization time.
       ExtrapolateLastSample(*init_end_time_ms_);
       // Then extrapolate the rest by the following.
     }
     multiplier = powf(alpha_, time_ms - last_state_time_ms_);
   }

   state_ = multiplier * state_ + (1.0f - multiplier) * last_sample_;
   last_state_time_ms_ = time_ms;
 }

 }  // namespace webrtc

 // Appendix: derivation of extrapolation during initialization phase.
 // (LaTeX syntax)
 // Assuming
 //   \begin{align}
 //     y(n) &= \alpha_{n-1} y(n-1) + \left(1 - \alpha_{n-1}\right) x(m) \\*
 //          &= \left(\prod_{i=m}^{n-1} \alpha_i\right) y(m) +
 //             \left(1 - \prod_{i=m}^{n-1} \alpha_i \right) x(m)
 //   \end{align}
 // Taking $\alpha_{n} = \exp(-\gamma^n)$, $\gamma$ denotes init\_factor\_, the
 // multiplier becomes
 //   \begin{align}
 //     \prod_{i=m}^{n-1} \alpha_i
 //     &= \exp\left(-\sum_{i=m}^{n-1} \gamma^i \right) \\*
 //     &= \begin{cases}
 //          \exp\left(-\frac{\gamma^m - \gamma^n}{1 - \gamma} \right)
 //          & \gamma \neq 1 \\*
 //          m-n & \gamma = 1
 //        \end{cases}
 //   \end{align}
 // We know $\gamma = T^{-\frac{1}{T}}$, where $T$ denotes init\_time\_ms\_. Then
 // $1 - \gamma$ approaches zero when $T$ increases. This can cause numerical
 // difficulties. We multiply $T$ (if $T > 0$) to both numerator and denominator
 // in the fraction. See.
 //   \begin{align}
 //     \frac{\gamma^m - \gamma^n}{1 - \gamma}
 //     &= \frac{T^\frac{T-m}{T} - T^\frac{T-n}{T}}{T - T^{1-\frac{1}{T}}}
 //   \end{align}
	/*
	* Copyright (c) 2016 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 "common_audio/smoothing_filter.h"

	#include <math.h>

	#include <cmath>

	#include "rtc_base/checks.h"
	#include "rtc_base/time_utils.h"

	namespace webrtc {

	SmoothingFilterImpl::SmoothingFilterImpl(int init_time_ms)
	: init_time_ms_(init_time_ms),
	// Duing the initalization time, we use an increasing alpha. Specifically,
	// alpha(n) = exp(-powf(init_factor_, n)),
	// where `init_factor_` is chosen such that
	// alpha(init_time_ms_) = exp(-1.0f / init_time_ms_),
	init_factor_(init_time_ms_ == 0
	? 0.0f
	: powf(init_time_ms_, -1.0f / init_time_ms_)),
	// `init_const_` is to a factor to help the calculation during
	// initialization phase.
	init_const_(init_time_ms_ == 0
	? 0.0f
	: init_time_ms_ -
	powf(init_time_ms_, 1.0f - 1.0f / init_time_ms_)) {
	UpdateAlpha(init_time_ms_);
	}

	SmoothingFilterImpl::~SmoothingFilterImpl() = default;

	void SmoothingFilterImpl::AddSample(float sample) {
	const int64_t now_ms = rtc::TimeMillis();

	if (!init_end_time_ms_) {
	// This is equivalent to assuming the filter has been receiving the same
	// value as the first sample since time -infinity.
	state_ = last_sample_ = sample;
	init_end_time_ms_ = now_ms + init_time_ms_;
	last_state_time_ms_ = now_ms;
	return;
	}

	ExtrapolateLastSample(now_ms);
	last_sample_ = sample;
	}

	absl::optional<float> SmoothingFilterImpl::GetAverage() {
	if (!init_end_time_ms_) {
	// `init_end_time_ms_` undefined since we have not received any sample.
	return absl::nullopt;
	}
	ExtrapolateLastSample(rtc::TimeMillis());
	return state_;
	}

	bool SmoothingFilterImpl::SetTimeConstantMs(int time_constant_ms) {
	if (!init_end_time_ms_ \|\| last_state_time_ms_ < *init_end_time_ms_) {
	return false;
	}
	UpdateAlpha(time_constant_ms);
	return true;
	}

	void SmoothingFilterImpl::UpdateAlpha(int time_constant_ms) {
	alpha_ = time_constant_ms == 0 ? 0.0f : std::exp(-1.0f / time_constant_ms);
	}

	void SmoothingFilterImpl::ExtrapolateLastSample(int64_t time_ms) {
	RTC_DCHECK_GE(time_ms, last_state_time_ms_);
	RTC_DCHECK(init_end_time_ms_);

	float multiplier = 0.0f;

	if (time_ms <= *init_end_time_ms_) {
	// Current update is to be made during initialization phase.
	// We update the state as if the `alpha` has been increased according
	// alpha(n) = exp(-powf(init_factor_, n)),
	// where n is the time (in millisecond) since the first sample received.
	// With algebraic derivation as shown in the Appendix, we can find that the
	// state can be updated in a similar manner as if alpha is a constant,
	// except for a different multiplier.
	if (init_time_ms_ == 0) {
	// This means `init_factor_` = 0.
	multiplier = 0.0f;
	} else if (init_time_ms_ == 1) {
	// This means `init_factor_` = 1.
	multiplier = std::exp(last_state_time_ms_ - time_ms);
	} else {
	multiplier = std::exp(
	-(powf(init_factor_, last_state_time_ms_ - *init_end_time_ms_) -
	powf(init_factor_, time_ms - *init_end_time_ms_)) /
	init_const_);
	}
	} else {
	if (last_state_time_ms_ < *init_end_time_ms_) {
	// The latest state update was made during initialization phase.
	// We first extrapolate to the initialization time.
	ExtrapolateLastSample(*init_end_time_ms_);
	// Then extrapolate the rest by the following.
	}
	multiplier = powf(alpha_, time_ms - last_state_time_ms_);
	}

	state_ = multiplier * state_ + (1.0f - multiplier) * last_sample_;
	last_state_time_ms_ = time_ms;
	}

	} // namespace webrtc

	// Appendix: derivation of extrapolation during initialization phase.
	// (LaTeX syntax)
	// Assuming
	// \begin{align}
	// y(n) &= \alpha_{n-1} y(n-1) + \left(1 - \alpha_{n-1}\right) x(m) \\*
	// &= \left(\prod_{i=m}^{n-1} \alpha_i\right) y(m) +
	// \left(1 - \prod_{i=m}^{n-1} \alpha_i \right) x(m)
	// \end{align}
	// Taking $\alpha_{n} = \exp(-\gamma^n)$, $\gamma$ denotes init\_factor\_, the
	// multiplier becomes
	// \begin{align}
	// \prod_{i=m}^{n-1} \alpha_i
	// &= \exp\left(-\sum_{i=m}^{n-1} \gamma^i \right) \\*
	// &= \begin{cases}
	// \exp\left(-\frac{\gamma^m - \gamma^n}{1 - \gamma} \right)
	// & \gamma \neq 1 \\*
	// m-n & \gamma = 1
	// \end{cases}
	// \end{align}
	// We know $\gamma = T^{-\frac{1}{T}}$, where $T$ denotes init\_time\_ms\_. Then
	// $1 - \gamma$ approaches zero when $T$ increases. This can cause numerical
	// difficulties. We multiply $T$ (if $T > 0$) to both numerator and denominator
	// in the fraction. See.
	// \begin{align}
	// \frac{\gamma^m - \gamma^n}{1 - \gamma}
	// &= \frac{T^\frac{T-m}{T} - T^\frac{T-n}{T}}{T - T^{1-\frac{1}{T}}}
	// \end{align}