trunk/src/common_audio/signal_processing/resample_fractional.c - vendor/opensource/webrtc - Git at Google

 /*
  *  Copyright (c) 2011 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.
  */


 /*
  * This file contains the resampling functions between 48, 44, 32 and 24 kHz.
  * The description headers can be found in signal_processing_library.h
  *
  */

 #include "signal_processing_library.h"

 // interpolation coefficients
 static const WebRtc_Word16 kCoefficients48To32[2][8] = {
         {778, -2050, 1087, 23285, 12903, -3783, 441, 222},
         {222, 441, -3783, 12903, 23285, 1087, -2050, 778}
 };

 static const WebRtc_Word16 kCoefficients32To24[3][8] = {
         {767, -2362, 2434, 24406, 10620, -3838, 721, 90},
         {386, -381, -2646, 19062, 19062, -2646, -381, 386},
         {90, 721, -3838, 10620, 24406, 2434, -2362, 767}
 };

 static const WebRtc_Word16 kCoefficients44To32[4][9] = {
         {117, -669, 2245, -6183, 26267, 13529, -3245, 845, -138},
         {-101, 612, -2283, 8532, 29790, -5138, 1789, -524, 91},
         {50, -292, 1016, -3064, 32010, 3933, -1147, 315, -53},
         {-156, 974, -3863, 18603, 21691, -6246, 2353, -712, 126}
 };

 //   Resampling ratio: 2/3
 // input:  WebRtc_Word32 (normalized, not saturated) :: size 3 * K
 // output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) :: size 2 * K
 //      K: number of blocks

 void WebRtcSpl_Resample48khzTo32khz(const WebRtc_Word32 *In, WebRtc_Word32 *Out,
                                     const WebRtc_Word32 K)
 {
     /////////////////////////////////////////////////////////////
     // Filter operation:
     //
     // Perform resampling (3 input samples -> 2 output samples);
     // process in sub blocks of size 3 samples.
     WebRtc_Word32 tmp;
     WebRtc_Word32 m;

     for (m = 0; m < K; m++)
     {
         tmp = 1 << 14;
         tmp += kCoefficients48To32[0][0] * In[0];
         tmp += kCoefficients48To32[0][1] * In[1];
         tmp += kCoefficients48To32[0][2] * In[2];
         tmp += kCoefficients48To32[0][3] * In[3];
         tmp += kCoefficients48To32[0][4] * In[4];
         tmp += kCoefficients48To32[0][5] * In[5];
         tmp += kCoefficients48To32[0][6] * In[6];
         tmp += kCoefficients48To32[0][7] * In[7];
         Out[0] = tmp;

         tmp = 1 << 14;
         tmp += kCoefficients48To32[1][0] * In[1];
         tmp += kCoefficients48To32[1][1] * In[2];
         tmp += kCoefficients48To32[1][2] * In[3];
         tmp += kCoefficients48To32[1][3] * In[4];
         tmp += kCoefficients48To32[1][4] * In[5];
         tmp += kCoefficients48To32[1][5] * In[6];
         tmp += kCoefficients48To32[1][6] * In[7];
         tmp += kCoefficients48To32[1][7] * In[8];
         Out[1] = tmp;

         // update pointers
         In += 3;
         Out += 2;
     }
 }

 //   Resampling ratio: 3/4
 // input:  WebRtc_Word32 (normalized, not saturated) :: size 4 * K
 // output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) :: size 3 * K
 //      K: number of blocks

 void WebRtcSpl_Resample32khzTo24khz(const WebRtc_Word32 *In, WebRtc_Word32 *Out,
                                     const WebRtc_Word32 K)
 {
     /////////////////////////////////////////////////////////////
     // Filter operation:
     //
     // Perform resampling (4 input samples -> 3 output samples);
     // process in sub blocks of size 4 samples.
     WebRtc_Word32 m;
     WebRtc_Word32 tmp;

     for (m = 0; m < K; m++)
     {
         tmp = 1 << 14;
         tmp += kCoefficients32To24[0][0] * In[0];
         tmp += kCoefficients32To24[0][1] * In[1];
         tmp += kCoefficients32To24[0][2] * In[2];
         tmp += kCoefficients32To24[0][3] * In[3];
         tmp += kCoefficients32To24[0][4] * In[4];
         tmp += kCoefficients32To24[0][5] * In[5];
         tmp += kCoefficients32To24[0][6] * In[6];
         tmp += kCoefficients32To24[0][7] * In[7];
         Out[0] = tmp;

         tmp = 1 << 14;
         tmp += kCoefficients32To24[1][0] * In[1];
         tmp += kCoefficients32To24[1][1] * In[2];
         tmp += kCoefficients32To24[1][2] * In[3];
         tmp += kCoefficients32To24[1][3] * In[4];
         tmp += kCoefficients32To24[1][4] * In[5];
         tmp += kCoefficients32To24[1][5] * In[6];
         tmp += kCoefficients32To24[1][6] * In[7];
         tmp += kCoefficients32To24[1][7] * In[8];
         Out[1] = tmp;

         tmp = 1 << 14;
         tmp += kCoefficients32To24[2][0] * In[2];
         tmp += kCoefficients32To24[2][1] * In[3];
         tmp += kCoefficients32To24[2][2] * In[4];
         tmp += kCoefficients32To24[2][3] * In[5];
         tmp += kCoefficients32To24[2][4] * In[6];
         tmp += kCoefficients32To24[2][5] * In[7];
         tmp += kCoefficients32To24[2][6] * In[8];
         tmp += kCoefficients32To24[2][7] * In[9];
         Out[2] = tmp;

         // update pointers
         In += 4;
         Out += 3;
     }
 }

 //
 // fractional resampling filters
 //   Fout = 11/16 * Fin
 //   Fout =  8/11 * Fin
 //

 // compute two inner-products and store them to output array
 static void WebRtcSpl_ResampDotProduct(const WebRtc_Word32 *in1, const WebRtc_Word32 *in2,
                                const WebRtc_Word16 *coef_ptr, WebRtc_Word32 *out1,
                                WebRtc_Word32 *out2)
 {
     WebRtc_Word32 tmp1 = 16384;
     WebRtc_Word32 tmp2 = 16384;
     WebRtc_Word16 coef;

     coef = coef_ptr[0];
     tmp1 += coef * in1[0];
     tmp2 += coef * in2[-0];

     coef = coef_ptr[1];
     tmp1 += coef * in1[1];
     tmp2 += coef * in2[-1];

     coef = coef_ptr[2];
     tmp1 += coef * in1[2];
     tmp2 += coef * in2[-2];

     coef = coef_ptr[3];
     tmp1 += coef * in1[3];
     tmp2 += coef * in2[-3];

     coef = coef_ptr[4];
     tmp1 += coef * in1[4];
     tmp2 += coef * in2[-4];

     coef = coef_ptr[5];
     tmp1 += coef * in1[5];
     tmp2 += coef * in2[-5];

     coef = coef_ptr[6];
     tmp1 += coef * in1[6];
     tmp2 += coef * in2[-6];

     coef = coef_ptr[7];
     tmp1 += coef * in1[7];
     tmp2 += coef * in2[-7];

     coef = coef_ptr[8];
     *out1 = tmp1 + coef * in1[8];
     *out2 = tmp2 + coef * in2[-8];
 }

 //   Resampling ratio: 8/11
 // input:  WebRtc_Word32 (normalized, not saturated) :: size 11 * K
 // output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) :: size  8 * K
 //      K: number of blocks

 void WebRtcSpl_Resample44khzTo32khz(const WebRtc_Word32 *In, WebRtc_Word32 *Out,
                                     const WebRtc_Word32 K)
 {
     /////////////////////////////////////////////////////////////
     // Filter operation:
     //
     // Perform resampling (11 input samples -> 8 output samples);
     // process in sub blocks of size 11 samples.
     WebRtc_Word32 tmp;
     WebRtc_Word32 m;

     for (m = 0; m < K; m++)
     {
         tmp = 1 << 14;

         // first output sample
         Out[0] = ((WebRtc_Word32)In[3] << 15) + tmp;

         // sum and accumulate filter coefficients and input samples
         tmp += kCoefficients44To32[3][0] * In[5];
         tmp += kCoefficients44To32[3][1] * In[6];
         tmp += kCoefficients44To32[3][2] * In[7];
         tmp += kCoefficients44To32[3][3] * In[8];
         tmp += kCoefficients44To32[3][4] * In[9];
         tmp += kCoefficients44To32[3][5] * In[10];
         tmp += kCoefficients44To32[3][6] * In[11];
         tmp += kCoefficients44To32[3][7] * In[12];
         tmp += kCoefficients44To32[3][8] * In[13];
         Out[4] = tmp;

         // sum and accumulate filter coefficients and input samples
         WebRtcSpl_ResampDotProduct(&In[0], &In[17], kCoefficients44To32[0], &Out[1], &Out[7]);

         // sum and accumulate filter coefficients and input samples
         WebRtcSpl_ResampDotProduct(&In[2], &In[15], kCoefficients44To32[1], &Out[2], &Out[6]);

         // sum and accumulate filter coefficients and input samples
         WebRtcSpl_ResampDotProduct(&In[3], &In[14], kCoefficients44To32[2], &Out[3], &Out[5]);

         // update pointers
         In += 11;
         Out += 8;
     }
 }
	/*
	* Copyright (c) 2011 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.
	*/


	/*
	* This file contains the resampling functions between 48, 44, 32 and 24 kHz.
	* The description headers can be found in signal_processing_library.h
	*
	*/

	#include "signal_processing_library.h"

	// interpolation coefficients
	static const WebRtc_Word16 kCoefficients48To32[2][8] = {
	{778, -2050, 1087, 23285, 12903, -3783, 441, 222},
	{222, 441, -3783, 12903, 23285, 1087, -2050, 778}
	};

	static const WebRtc_Word16 kCoefficients32To24[3][8] = {
	{767, -2362, 2434, 24406, 10620, -3838, 721, 90},
	{386, -381, -2646, 19062, 19062, -2646, -381, 386},
	{90, 721, -3838, 10620, 24406, 2434, -2362, 767}
	};

	static const WebRtc_Word16 kCoefficients44To32[4][9] = {
	{117, -669, 2245, -6183, 26267, 13529, -3245, 845, -138},
	{-101, 612, -2283, 8532, 29790, -5138, 1789, -524, 91},
	{50, -292, 1016, -3064, 32010, 3933, -1147, 315, -53},
	{-156, 974, -3863, 18603, 21691, -6246, 2353, -712, 126}
	};

	// Resampling ratio: 2/3
	// input: WebRtc_Word32 (normalized, not saturated) :: size 3 * K
	// output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) :: size 2 * K
	// K: number of blocks

	void WebRtcSpl_Resample48khzTo32khz(const WebRtc_Word32 In, WebRtc_Word32 Out,
	const WebRtc_Word32 K)
	{
	/////////////////////////////////////////////////////////////
	// Filter operation:
	//
	// Perform resampling (3 input samples -> 2 output samples);
	// process in sub blocks of size 3 samples.
	WebRtc_Word32 tmp;
	WebRtc_Word32 m;

	for (m = 0; m < K; m++)
	{
	tmp = 1 << 14;
	tmp += kCoefficients48To32[0][0] * In[0];
	tmp += kCoefficients48To32[0][1] * In[1];
	tmp += kCoefficients48To32[0][2] * In[2];
	tmp += kCoefficients48To32[0][3] * In[3];
	tmp += kCoefficients48To32[0][4] * In[4];
	tmp += kCoefficients48To32[0][5] * In[5];
	tmp += kCoefficients48To32[0][6] * In[6];
	tmp += kCoefficients48To32[0][7] * In[7];
	Out[0] = tmp;

	tmp = 1 << 14;
	tmp += kCoefficients48To32[1][0] * In[1];
	tmp += kCoefficients48To32[1][1] * In[2];
	tmp += kCoefficients48To32[1][2] * In[3];
	tmp += kCoefficients48To32[1][3] * In[4];
	tmp += kCoefficients48To32[1][4] * In[5];
	tmp += kCoefficients48To32[1][5] * In[6];
	tmp += kCoefficients48To32[1][6] * In[7];
	tmp += kCoefficients48To32[1][7] * In[8];
	Out[1] = tmp;

	// update pointers
	In += 3;
	Out += 2;
	}
	}

	// Resampling ratio: 3/4
	// input: WebRtc_Word32 (normalized, not saturated) :: size 4 * K
	// output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) :: size 3 * K
	// K: number of blocks

	void WebRtcSpl_Resample32khzTo24khz(const WebRtc_Word32 In, WebRtc_Word32 Out,
	const WebRtc_Word32 K)
	{
	/////////////////////////////////////////////////////////////
	// Filter operation:
	//
	// Perform resampling (4 input samples -> 3 output samples);
	// process in sub blocks of size 4 samples.
	WebRtc_Word32 m;
	WebRtc_Word32 tmp;

	for (m = 0; m < K; m++)
	{
	tmp = 1 << 14;
	tmp += kCoefficients32To24[0][0] * In[0];
	tmp += kCoefficients32To24[0][1] * In[1];
	tmp += kCoefficients32To24[0][2] * In[2];
	tmp += kCoefficients32To24[0][3] * In[3];
	tmp += kCoefficients32To24[0][4] * In[4];
	tmp += kCoefficients32To24[0][5] * In[5];
	tmp += kCoefficients32To24[0][6] * In[6];
	tmp += kCoefficients32To24[0][7] * In[7];
	Out[0] = tmp;

	tmp = 1 << 14;
	tmp += kCoefficients32To24[1][0] * In[1];
	tmp += kCoefficients32To24[1][1] * In[2];
	tmp += kCoefficients32To24[1][2] * In[3];
	tmp += kCoefficients32To24[1][3] * In[4];
	tmp += kCoefficients32To24[1][4] * In[5];
	tmp += kCoefficients32To24[1][5] * In[6];
	tmp += kCoefficients32To24[1][6] * In[7];
	tmp += kCoefficients32To24[1][7] * In[8];
	Out[1] = tmp;

	tmp = 1 << 14;
	tmp += kCoefficients32To24[2][0] * In[2];
	tmp += kCoefficients32To24[2][1] * In[3];
	tmp += kCoefficients32To24[2][2] * In[4];
	tmp += kCoefficients32To24[2][3] * In[5];
	tmp += kCoefficients32To24[2][4] * In[6];
	tmp += kCoefficients32To24[2][5] * In[7];
	tmp += kCoefficients32To24[2][6] * In[8];
	tmp += kCoefficients32To24[2][7] * In[9];
	Out[2] = tmp;

	// update pointers
	In += 4;
	Out += 3;
	}
	}

	//
	// fractional resampling filters
	// Fout = 11/16 * Fin
	// Fout = 8/11 * Fin
	//

	// compute two inner-products and store them to output array
	static void WebRtcSpl_ResampDotProduct(const WebRtc_Word32 in1, const WebRtc_Word32 in2,
	const WebRtc_Word16 coef_ptr, WebRtc_Word32 out1,
	WebRtc_Word32 *out2)
	{
	WebRtc_Word32 tmp1 = 16384;
	WebRtc_Word32 tmp2 = 16384;
	WebRtc_Word16 coef;

	coef = coef_ptr[0];
	tmp1 += coef * in1[0];
	tmp2 += coef * in2[-0];

	coef = coef_ptr[1];
	tmp1 += coef * in1[1];
	tmp2 += coef * in2[-1];

	coef = coef_ptr[2];
	tmp1 += coef * in1[2];
	tmp2 += coef * in2[-2];

	coef = coef_ptr[3];
	tmp1 += coef * in1[3];
	tmp2 += coef * in2[-3];

	coef = coef_ptr[4];
	tmp1 += coef * in1[4];
	tmp2 += coef * in2[-4];

	coef = coef_ptr[5];
	tmp1 += coef * in1[5];
	tmp2 += coef * in2[-5];

	coef = coef_ptr[6];
	tmp1 += coef * in1[6];
	tmp2 += coef * in2[-6];

	coef = coef_ptr[7];
	tmp1 += coef * in1[7];
	tmp2 += coef * in2[-7];

	coef = coef_ptr[8];
	out1 = tmp1 + coef in1[8];
	out2 = tmp2 + coef in2[-8];
	}

	// Resampling ratio: 8/11
	// input: WebRtc_Word32 (normalized, not saturated) :: size 11 * K
	// output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) :: size 8 * K
	// K: number of blocks

	void WebRtcSpl_Resample44khzTo32khz(const WebRtc_Word32 In, WebRtc_Word32 Out,
	const WebRtc_Word32 K)
	{
	/////////////////////////////////////////////////////////////
	// Filter operation:
	//
	// Perform resampling (11 input samples -> 8 output samples);
	// process in sub blocks of size 11 samples.
	WebRtc_Word32 tmp;
	WebRtc_Word32 m;

	for (m = 0; m < K; m++)
	{
	tmp = 1 << 14;

	// first output sample
	Out[0] = ((WebRtc_Word32)In[3] << 15) + tmp;

	// sum and accumulate filter coefficients and input samples
	tmp += kCoefficients44To32[3][0] * In[5];
	tmp += kCoefficients44To32[3][1] * In[6];
	tmp += kCoefficients44To32[3][2] * In[7];
	tmp += kCoefficients44To32[3][3] * In[8];
	tmp += kCoefficients44To32[3][4] * In[9];
	tmp += kCoefficients44To32[3][5] * In[10];
	tmp += kCoefficients44To32[3][6] * In[11];
	tmp += kCoefficients44To32[3][7] * In[12];
	tmp += kCoefficients44To32[3][8] * In[13];
	Out[4] = tmp;

	// sum and accumulate filter coefficients and input samples
	WebRtcSpl_ResampDotProduct(&In[0], &In[17], kCoefficients44To32[0], &Out[1], &Out[7]);

	// sum and accumulate filter coefficients and input samples
	WebRtcSpl_ResampDotProduct(&In[2], &In[15], kCoefficients44To32[1], &Out[2], &Out[6]);

	// sum and accumulate filter coefficients and input samples
	WebRtcSpl_ResampDotProduct(&In[3], &In[14], kCoefficients44To32[2], &Out[3], &Out[5]);

	// update pointers
	In += 11;
	Out += 8;
	}
	}