modules/audio_coding/neteq/histogram.cc - src - Git at Google

 /*
  *  Copyright (c) 2019 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 "modules/audio_coding/neteq/histogram.h"

 #include <algorithm>
 #include <cstdlib>
 #include <numeric>

 #include "absl/types/optional.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/numerics/safe_conversions.h"

 namespace webrtc {

 Histogram::Histogram(size_t num_buckets,
                      int forget_factor,
                      absl::optional<double> start_forget_weight)
     : buckets_(num_buckets, 0),
       forget_factor_(0),
       base_forget_factor_(forget_factor),
       add_count_(0),
       start_forget_weight_(start_forget_weight) {
   RTC_DCHECK_LT(base_forget_factor_, 1 << 15);
 }

 Histogram::~Histogram() {}

 // Each element in the vector is first multiplied by the forgetting factor
 // `forget_factor_`. Then the vector element indicated by `iat_packets` is then
 // increased (additive) by 1 - `forget_factor_`. This way, the probability of
 // `value` is slightly increased, while the sum of the histogram remains
 // constant (=1).
 // Due to inaccuracies in the fixed-point arithmetic, the histogram may no
 // longer sum up to 1 (in Q30) after the update. To correct this, a correction
 // term is added or subtracted from the first element (or elements) of the
 // vector.
 // The forgetting factor `forget_factor_` is also updated. When the DelayManager
 // is reset, the factor is set to 0 to facilitate rapid convergence in the
 // beginning. With each update of the histogram, the factor is increased towards
 // the steady-state value `base_forget_factor_`.
 void Histogram::Add(int value) {
   RTC_DCHECK(value >= 0);
   RTC_DCHECK(value < static_cast<int>(buckets_.size()));
   int vector_sum = 0;  // Sum up the vector elements as they are processed.
   // Multiply each element in `buckets_` with `forget_factor_`.
   for (int& bucket : buckets_) {
     bucket = (static_cast<int64_t>(bucket) * forget_factor_) >> 15;
     vector_sum += bucket;
   }

   // Increase the probability for the currently observed inter-arrival time
   // by 1 - `forget_factor_`. The factor is in Q15, `buckets_` in Q30.
   // Thus, left-shift 15 steps to obtain result in Q30.
   buckets_[value] += (32768 - forget_factor_) << 15;
   vector_sum += (32768 - forget_factor_) << 15;  // Add to vector sum.

   // `buckets_` should sum up to 1 (in Q30), but it may not due to
   // fixed-point rounding errors.
   vector_sum -= 1 << 30;  // Should be zero. Compensate if not.
   if (vector_sum != 0) {
     // Modify a few values early in `buckets_`.
     int flip_sign = vector_sum > 0 ? -1 : 1;
     for (int& bucket : buckets_) {
       // Add/subtract 1/16 of the element, but not more than `vector_sum`.
       int correction = flip_sign * std::min(std::abs(vector_sum), bucket >> 4);
       bucket += correction;
       vector_sum += correction;
       if (std::abs(vector_sum) == 0) {
         break;
       }
     }
   }
   RTC_DCHECK(vector_sum == 0);  // Verify that the above is correct.

   ++add_count_;

   // Update `forget_factor_` (changes only during the first seconds after a
   // reset). The factor converges to `base_forget_factor_`.
   if (start_forget_weight_) {
     if (forget_factor_ != base_forget_factor_) {
       int old_forget_factor = forget_factor_;
       int forget_factor =
           (1 << 15) * (1 - start_forget_weight_.value() / (add_count_ + 1));
       forget_factor_ =
           std::max(0, std::min(base_forget_factor_, forget_factor));
       // The histogram is updated recursively by forgetting the old histogram
       // with `forget_factor_` and adding a new sample multiplied by |1 -
       // forget_factor_|. We need to make sure that the effective weight on the
       // new sample is no smaller than those on the old samples, i.e., to
       // satisfy the following DCHECK.
       RTC_DCHECK_GE((1 << 15) - forget_factor_,
                     ((1 << 15) - old_forget_factor) * forget_factor_ >> 15);
     }
   } else {
     forget_factor_ += (base_forget_factor_ - forget_factor_ + 3) >> 2;
   }
 }

 int Histogram::Quantile(int probability) {
   // Find the bucket for which the probability of observing an
   // inter-arrival time larger than or equal to `index` is larger than or
   // equal to `probability`. The sought probability is estimated using
   // the histogram as the reverse cumulant PDF, i.e., the sum of elements from
   // the end up until `index`. Now, since the sum of all elements is 1
   // (in Q30) by definition, and since the solution is often a low value for
   // `iat_index`, it is more efficient to start with `sum` = 1 and subtract
   // elements from the start of the histogram.
   int inverse_probability = (1 << 30) - probability;
   size_t index = 0;        // Start from the beginning of `buckets_`.
   int sum = 1 << 30;       // Assign to 1 in Q30.
   sum -= buckets_[index];

   while ((sum > inverse_probability) && (index < buckets_.size() - 1)) {
     // Subtract the probabilities one by one until the sum is no longer greater
     // than `inverse_probability`.
     ++index;
     sum -= buckets_[index];
   }
   return static_cast<int>(index);
 }

 // Set the histogram vector to an exponentially decaying distribution
 // buckets_[i] = 0.5^(i+1), i = 0, 1, 2, ...
 // buckets_ is in Q30.
 void Histogram::Reset() {
   // Set temp_prob to (slightly more than) 1 in Q14. This ensures that the sum
   // of buckets_ is 1.
   uint16_t temp_prob = 0x4002;  // 16384 + 2 = 100000000000010 binary.
   for (int& bucket : buckets_) {
     temp_prob >>= 1;
     bucket = temp_prob << 16;
   }
   forget_factor_ = 0;  // Adapt the histogram faster for the first few packets.
   add_count_ = 0;
 }

 int Histogram::NumBuckets() const {
   return buckets_.size();
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2019 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 "modules/audio_coding/neteq/histogram.h"

	#include <algorithm>
	#include <cstdlib>
	#include <numeric>

	#include "absl/types/optional.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/numerics/safe_conversions.h"

	namespace webrtc {

	Histogram::Histogram(size_t num_buckets,
	int forget_factor,
	absl::optional<double> start_forget_weight)
	: buckets_(num_buckets, 0),
	forget_factor_(0),
	base_forget_factor_(forget_factor),
	add_count_(0),
	start_forget_weight_(start_forget_weight) {
	RTC_DCHECK_LT(base_forget_factor_, 1 << 15);
	}

	Histogram::~Histogram() {}

	// Each element in the vector is first multiplied by the forgetting factor
	// `forget_factor_`. Then the vector element indicated by `iat_packets` is then
	// increased (additive) by 1 - `forget_factor_`. This way, the probability of
	// `value` is slightly increased, while the sum of the histogram remains
	// constant (=1).
	// Due to inaccuracies in the fixed-point arithmetic, the histogram may no
	// longer sum up to 1 (in Q30) after the update. To correct this, a correction
	// term is added or subtracted from the first element (or elements) of the
	// vector.
	// The forgetting factor `forget_factor_` is also updated. When the DelayManager
	// is reset, the factor is set to 0 to facilitate rapid convergence in the
	// beginning. With each update of the histogram, the factor is increased towards
	// the steady-state value `base_forget_factor_`.
	void Histogram::Add(int value) {
	RTC_DCHECK(value >= 0);
	RTC_DCHECK(value < static_cast<int>(buckets_.size()));
	int vector_sum = 0; // Sum up the vector elements as they are processed.
	// Multiply each element in `buckets_` with `forget_factor_`.
	for (int& bucket : buckets_) {
	bucket = (static_cast<int64_t>(bucket) * forget_factor_) >> 15;
	vector_sum += bucket;
	}

	// Increase the probability for the currently observed inter-arrival time
	// by 1 - `forget_factor_`. The factor is in Q15, `buckets_` in Q30.
	// Thus, left-shift 15 steps to obtain result in Q30.
	buckets_[value] += (32768 - forget_factor_) << 15;
	vector_sum += (32768 - forget_factor_) << 15; // Add to vector sum.

	// `buckets_` should sum up to 1 (in Q30), but it may not due to
	// fixed-point rounding errors.
	vector_sum -= 1 << 30; // Should be zero. Compensate if not.
	if (vector_sum != 0) {
	// Modify a few values early in `buckets_`.
	int flip_sign = vector_sum > 0 ? -1 : 1;
	for (int& bucket : buckets_) {
	// Add/subtract 1/16 of the element, but not more than `vector_sum`.
	int correction = flip_sign * std::min(std::abs(vector_sum), bucket >> 4);
	bucket += correction;
	vector_sum += correction;
	if (std::abs(vector_sum) == 0) {
	break;
	}
	}
	}
	RTC_DCHECK(vector_sum == 0); // Verify that the above is correct.

	++add_count_;

	// Update `forget_factor_` (changes only during the first seconds after a
	// reset). The factor converges to `base_forget_factor_`.
	if (start_forget_weight_) {
	if (forget_factor_ != base_forget_factor_) {
	int old_forget_factor = forget_factor_;
	int forget_factor =
	(1 << 15) * (1 - start_forget_weight_.value() / (add_count_ + 1));
	forget_factor_ =
	std::max(0, std::min(base_forget_factor_, forget_factor));
	// The histogram is updated recursively by forgetting the old histogram
	// with `forget_factor_` and adding a new sample multiplied by \|1 -
	// forget_factor_\|. We need to make sure that the effective weight on the
	// new sample is no smaller than those on the old samples, i.e., to
	// satisfy the following DCHECK.
	RTC_DCHECK_GE((1 << 15) - forget_factor_,
	((1 << 15) - old_forget_factor) * forget_factor_ >> 15);
	}
	} else {
	forget_factor_ += (base_forget_factor_ - forget_factor_ + 3) >> 2;
	}
	}

	int Histogram::Quantile(int probability) {
	// Find the bucket for which the probability of observing an
	// inter-arrival time larger than or equal to `index` is larger than or
	// equal to `probability`. The sought probability is estimated using
	// the histogram as the reverse cumulant PDF, i.e., the sum of elements from
	// the end up until `index`. Now, since the sum of all elements is 1
	// (in Q30) by definition, and since the solution is often a low value for
	// `iat_index`, it is more efficient to start with `sum` = 1 and subtract
	// elements from the start of the histogram.
	int inverse_probability = (1 << 30) - probability;
	size_t index = 0; // Start from the beginning of `buckets_`.
	int sum = 1 << 30; // Assign to 1 in Q30.
	sum -= buckets_[index];

	while ((sum > inverse_probability) && (index < buckets_.size() - 1)) {
	// Subtract the probabilities one by one until the sum is no longer greater
	// than `inverse_probability`.
	++index;
	sum -= buckets_[index];
	}
	return static_cast<int>(index);
	}

	// Set the histogram vector to an exponentially decaying distribution
	// buckets_[i] = 0.5^(i+1), i = 0, 1, 2, ...
	// buckets_ is in Q30.
	void Histogram::Reset() {
	// Set temp_prob to (slightly more than) 1 in Q14. This ensures that the sum
	// of buckets_ is 1.
	uint16_t temp_prob = 0x4002; // 16384 + 2 = 100000000000010 binary.
	for (int& bucket : buckets_) {
	temp_prob >>= 1;
	bucket = temp_prob << 16;
	}
	forget_factor_ = 0; // Adapt the histogram faster for the first few packets.
	add_count_ = 0;
	}

	int Histogram::NumBuckets() const {
	return buckets_.size();
	}

	} // namespace webrtc