common_audio/vad/vad_sp.c - src.git - Git at Google

 /*
  *  Copyright (c) 2012 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/vad/vad_sp.h"

 #include "rtc_base/checks.h"
 #include "common_audio/signal_processing/include/signal_processing_library.h"
 #include "common_audio/vad/vad_core.h"

 // Allpass filter coefficients, upper and lower, in Q13.
 // Upper: 0.64, Lower: 0.17.
 static const int16_t kAllPassCoefsQ13[2] = { 5243, 1392 };  // Q13.
 static const int16_t kSmoothingDown = 6553;  // 0.2 in Q15.
 static const int16_t kSmoothingUp = 32439;  // 0.99 in Q15.

 // TODO(bjornv): Move this function to vad_filterbank.c.
 // Downsampling filter based on splitting filter and allpass functions.
 void WebRtcVad_Downsampling(const int16_t* signal_in,
                             int16_t* signal_out,
                             int32_t* filter_state,
                             size_t in_length) {
   int16_t tmp16_1 = 0, tmp16_2 = 0;
   int32_t tmp32_1 = filter_state[0];
   int32_t tmp32_2 = filter_state[1];
   size_t n = 0;
   // Downsampling by 2 gives half length.
   size_t half_length = (in_length >> 1);

   // Filter coefficients in Q13, filter state in Q0.
   for (n = 0; n < half_length; n++) {
     // All-pass filtering upper branch.
     tmp16_1 = (int16_t) ((tmp32_1 >> 1) +
         ((kAllPassCoefsQ13[0] * *signal_in) >> 14));
     *signal_out = tmp16_1;
     tmp32_1 = (int32_t)(*signal_in++) - ((kAllPassCoefsQ13[0] * tmp16_1) >> 12);

     // All-pass filtering lower branch.
     tmp16_2 = (int16_t) ((tmp32_2 >> 1) +
         ((kAllPassCoefsQ13[1] * *signal_in) >> 14));
     *signal_out++ += tmp16_2;
     tmp32_2 = (int32_t)(*signal_in++) - ((kAllPassCoefsQ13[1] * tmp16_2) >> 12);
   }
   // Store the filter states.
   filter_state[0] = tmp32_1;
   filter_state[1] = tmp32_2;
 }

 // Inserts |feature_value| into |low_value_vector|, if it is one of the 16
 // smallest values the last 100 frames. Then calculates and returns the median
 // of the five smallest values.
 int16_t WebRtcVad_FindMinimum(VadInstT* self,
                               int16_t feature_value,
                               int channel) {
   int i = 0, j = 0;
   int position = -1;
   // Offset to beginning of the 16 minimum values in memory.
   const int offset = (channel << 4);
   int16_t current_median = 1600;
   int16_t alpha = 0;
   int32_t tmp32 = 0;
   // Pointer to memory for the 16 minimum values and the age of each value of
   // the |channel|.
   int16_t* age = &self->index_vector[offset];
   int16_t* smallest_values = &self->low_value_vector[offset];

   RTC_DCHECK_LT(channel, kNumChannels);

   // Each value in |smallest_values| is getting 1 loop older. Update |age|, and
   // remove old values.
   for (i = 0; i < 16; i++) {
     if (age[i] != 100) {
       age[i]++;
     } else {
       // Too old value. Remove from memory and shift larger values downwards.
       for (j = i; j < 16; j++) {
         smallest_values[j] = smallest_values[j + 1];
         age[j] = age[j + 1];
       }
       age[15] = 101;
       smallest_values[15] = 10000;
     }
   }

   // Check if |feature_value| is smaller than any of the values in
   // |smallest_values|. If so, find the |position| where to insert the new value
   // (|feature_value|).
   if (feature_value < smallest_values[7]) {
     if (feature_value < smallest_values[3]) {
       if (feature_value < smallest_values[1]) {
         if (feature_value < smallest_values[0]) {
           position = 0;
         } else {
           position = 1;
         }
       } else if (feature_value < smallest_values[2]) {
         position = 2;
       } else {
         position = 3;
       }
     } else if (feature_value < smallest_values[5]) {
       if (feature_value < smallest_values[4]) {
         position = 4;
       } else {
         position = 5;
       }
     } else if (feature_value < smallest_values[6]) {
       position = 6;
     } else {
       position = 7;
     }
   } else if (feature_value < smallest_values[15]) {
     if (feature_value < smallest_values[11]) {
       if (feature_value < smallest_values[9]) {
         if (feature_value < smallest_values[8]) {
           position = 8;
         } else {
           position = 9;
         }
       } else if (feature_value < smallest_values[10]) {
         position = 10;
       } else {
         position = 11;
       }
     } else if (feature_value < smallest_values[13]) {
       if (feature_value < smallest_values[12]) {
         position = 12;
       } else {
         position = 13;
       }
     } else if (feature_value < smallest_values[14]) {
       position = 14;
     } else {
       position = 15;
     }
   }

   // If we have detected a new small value, insert it at the correct position
   // and shift larger values up.
   if (position > -1) {
     for (i = 15; i > position; i--) {
       smallest_values[i] = smallest_values[i - 1];
       age[i] = age[i - 1];
     }
     smallest_values[position] = feature_value;
     age[position] = 1;
   }

   // Get |current_median|.
   if (self->frame_counter > 2) {
     current_median = smallest_values[2];
   } else if (self->frame_counter > 0) {
     current_median = smallest_values[0];
   }

   // Smooth the median value.
   if (self->frame_counter > 0) {
     if (current_median < self->mean_value[channel]) {
       alpha = kSmoothingDown;  // 0.2 in Q15.
     } else {
       alpha = kSmoothingUp;  // 0.99 in Q15.
     }
   }
   tmp32 = (alpha + 1) * self->mean_value[channel];
   tmp32 += (WEBRTC_SPL_WORD16_MAX - alpha) * current_median;
   tmp32 += 16384;
   self->mean_value[channel] = (int16_t) (tmp32 >> 15);

   return self->mean_value[channel];
 }
	/*
	* Copyright (c) 2012 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/vad/vad_sp.h"

	#include "rtc_base/checks.h"
	#include "common_audio/signal_processing/include/signal_processing_library.h"
	#include "common_audio/vad/vad_core.h"

	// Allpass filter coefficients, upper and lower, in Q13.
	// Upper: 0.64, Lower: 0.17.
	static const int16_t kAllPassCoefsQ13[2] = { 5243, 1392 }; // Q13.
	static const int16_t kSmoothingDown = 6553; // 0.2 in Q15.
	static const int16_t kSmoothingUp = 32439; // 0.99 in Q15.

	// TODO(bjornv): Move this function to vad_filterbank.c.
	// Downsampling filter based on splitting filter and allpass functions.
	void WebRtcVad_Downsampling(const int16_t* signal_in,
	int16_t* signal_out,
	int32_t* filter_state,
	size_t in_length) {
	int16_t tmp16_1 = 0, tmp16_2 = 0;
	int32_t tmp32_1 = filter_state[0];
	int32_t tmp32_2 = filter_state[1];
	size_t n = 0;
	// Downsampling by 2 gives half length.
	size_t half_length = (in_length >> 1);

	// Filter coefficients in Q13, filter state in Q0.
	for (n = 0; n < half_length; n++) {
	// All-pass filtering upper branch.
	tmp16_1 = (int16_t) ((tmp32_1 >> 1) +
	((kAllPassCoefsQ13[0] * *signal_in) >> 14));
	*signal_out = tmp16_1;
	tmp32_1 = (int32_t)(signal_in++) - ((kAllPassCoefsQ13[0] tmp16_1) >> 12);

	// All-pass filtering lower branch.
	tmp16_2 = (int16_t) ((tmp32_2 >> 1) +
	((kAllPassCoefsQ13[1] * *signal_in) >> 14));
	*signal_out++ += tmp16_2;
	tmp32_2 = (int32_t)(signal_in++) - ((kAllPassCoefsQ13[1] tmp16_2) >> 12);
	}
	// Store the filter states.
	filter_state[0] = tmp32_1;
	filter_state[1] = tmp32_2;
	}

	// Inserts \|feature_value\| into \|low_value_vector\|, if it is one of the 16
	// smallest values the last 100 frames. Then calculates and returns the median
	// of the five smallest values.
	int16_t WebRtcVad_FindMinimum(VadInstT* self,
	int16_t feature_value,
	int channel) {
	int i = 0, j = 0;
	int position = -1;
	// Offset to beginning of the 16 minimum values in memory.
	const int offset = (channel << 4);
	int16_t current_median = 1600;
	int16_t alpha = 0;
	int32_t tmp32 = 0;
	// Pointer to memory for the 16 minimum values and the age of each value of
	// the \|channel\|.
	int16_t* age = &self->index_vector[offset];
	int16_t* smallest_values = &self->low_value_vector[offset];

	RTC_DCHECK_LT(channel, kNumChannels);

	// Each value in \|smallest_values\| is getting 1 loop older. Update \|age\|, and
	// remove old values.
	for (i = 0; i < 16; i++) {
	if (age[i] != 100) {
	age[i]++;
	} else {
	// Too old value. Remove from memory and shift larger values downwards.
	for (j = i; j < 16; j++) {
	smallest_values[j] = smallest_values[j + 1];
	age[j] = age[j + 1];
	}
	age[15] = 101;
	smallest_values[15] = 10000;
	}
	}

	// Check if \|feature_value\| is smaller than any of the values in
	// \|smallest_values\|. If so, find the \|position\| where to insert the new value
	// (\|feature_value\|).
	if (feature_value < smallest_values[7]) {
	if (feature_value < smallest_values[3]) {
	if (feature_value < smallest_values[1]) {
	if (feature_value < smallest_values[0]) {
	position = 0;
	} else {
	position = 1;
	}
	} else if (feature_value < smallest_values[2]) {
	position = 2;
	} else {
	position = 3;
	}
	} else if (feature_value < smallest_values[5]) {
	if (feature_value < smallest_values[4]) {
	position = 4;
	} else {
	position = 5;
	}
	} else if (feature_value < smallest_values[6]) {
	position = 6;
	} else {
	position = 7;
	}
	} else if (feature_value < smallest_values[15]) {
	if (feature_value < smallest_values[11]) {
	if (feature_value < smallest_values[9]) {
	if (feature_value < smallest_values[8]) {
	position = 8;
	} else {
	position = 9;
	}
	} else if (feature_value < smallest_values[10]) {
	position = 10;
	} else {
	position = 11;
	}
	} else if (feature_value < smallest_values[13]) {
	if (feature_value < smallest_values[12]) {
	position = 12;
	} else {
	position = 13;
	}
	} else if (feature_value < smallest_values[14]) {
	position = 14;
	} else {
	position = 15;
	}
	}

	// If we have detected a new small value, insert it at the correct position
	// and shift larger values up.
	if (position > -1) {
	for (i = 15; i > position; i--) {
	smallest_values[i] = smallest_values[i - 1];
	age[i] = age[i - 1];
	}
	smallest_values[position] = feature_value;
	age[position] = 1;
	}

	// Get \|current_median\|.
	if (self->frame_counter > 2) {
	current_median = smallest_values[2];
	} else if (self->frame_counter > 0) {
	current_median = smallest_values[0];
	}

	// Smooth the median value.
	if (self->frame_counter > 0) {
	if (current_median < self->mean_value[channel]) {
	alpha = kSmoothingDown; // 0.2 in Q15.
	} else {
	alpha = kSmoothingUp; // 0.99 in Q15.
	}
	}
	tmp32 = (alpha + 1) * self->mean_value[channel];
	tmp32 += (WEBRTC_SPL_WORD16_MAX - alpha) * current_median;
	tmp32 += 16384;
	self->mean_value[channel] = (int16_t) (tmp32 >> 15);

	return self->mean_value[channel];
	}