D-Modem/pjproject-2.11.1/third_party/ilbc/createCB.c



   /******************************************************************

       iLBC Speech Coder ANSI-C Source Code

       createCB.c

       Copyright (C) The Internet Society (2004).
       All Rights Reserved.

   ******************************************************************/


   #include "iLBC_define.h"
   #include "constants.h"
   #include <string.h>
   #include <math.h>

   /*----------------------------------------------------------------*
    *  Construct an additional codebook vector by filtering the
    *  initial codebook buffer. This vector is then used to expand
    *  the codebook with an additional section.
    *---------------------------------------------------------------*/

   void filteredCBvecs(
       float *cbvectors,   /* (o) Codebook vectors for the
                                  higher section */
       float *mem,         /* (i) Buffer to create codebook
                                  vector from */
       int lMem        /* (i) Length of buffer */
   ){
       int j, k;
       float *pp, *pp1;
       float tempbuff2[CB_MEML+CB_FILTERLEN];
       float *pos;

       memset(tempbuff2, 0, (CB_HALFFILTERLEN-1)*sizeof(float));
       memcpy(&tempbuff2[CB_HALFFILTERLEN-1], mem, lMem*sizeof(float));
       memset(&tempbuff2[lMem+CB_HALFFILTERLEN-1], 0,
           (CB_HALFFILTERLEN+1)*sizeof(float));

       /* Create codebook vector for higher section by filtering */

       /* do filtering */
       pos=cbvectors;
       memset(pos, 0, lMem*sizeof(float));
       for (k=0; k<lMem; k++) {
           pp=&tempbuff2[k];
           pp1=&cbfiltersTbl[CB_FILTERLEN-1];
           for (j=0;j<CB_FILTERLEN;j++) {
               (*pos)+=(*pp++)*(*pp1--);
           }
           pos++;
       }
   }

   /*----------------------------------------------------------------*
    *  Search the augmented part of the codebook to find the best
    *  measure.
    *----------------------------------------------------------------*/


   void searchAugmentedCB(
       int low,        /* (i) Start index for the search */
       int high,           /* (i) End index for the search */
       int stage,          /* (i) Current stage */
       int startIndex,     /* (i) Codebook index for the first
                                  aug vector */
       float *target,      /* (i) Target vector for encoding */
       float *buffer,      /* (i) Pointer to the end of the buffer for
                                  augmented codebook construction */
       float *max_measure, /* (i/o) Currently maximum measure */
       int *best_index,/* (o) Currently the best index */
       float *gain,    /* (o) Currently the best gain */
       float *energy,      /* (o) Energy of augmented codebook
                                  vectors */
       float *invenergy/* (o) Inv energy of augmented codebook
                                  vectors */
   ) {
       int icount, ilow, j, tmpIndex;
       float *pp, *ppo, *ppi, *ppe, crossDot, alfa;
       float weighted, measure, nrjRecursive;
       float ftmp;

       /* Compute the energy for the first (low-5)
          noninterpolated samples */
       nrjRecursive = (float) 0.0;
       pp = buffer - low + 1;
       for (j=0; j<(low-5); j++) {
           nrjRecursive += ( (*pp)*(*pp) );
           pp++;
       }
       ppe = buffer - low;


       for (icount=low; icount<=high; icount++) {

           /* Index of the codebook vector used for retrieving
              energy values */
           tmpIndex = startIndex+icount-20;

           ilow = icount-4;

           /* Update the energy recursively to save complexity */
           nrjRecursive = nrjRecursive + (*ppe)*(*ppe);
           ppe--;
           energy[tmpIndex] = nrjRecursive;

           /* Compute cross dot product for the first (low-5)
              samples */


           crossDot = (float) 0.0;
           pp = buffer-icount;
           for (j=0; j<ilow; j++) {
               crossDot += target[j]*(*pp++);
           }

           /* interpolation */
           alfa = (float) 0.2;
           ppo = buffer-4;
           ppi = buffer-icount-4;
           for (j=ilow; j<icount; j++) {
               weighted = ((float)1.0-alfa)*(*ppo)+alfa*(*ppi);
               ppo++;
               ppi++;
               energy[tmpIndex] += weighted*weighted;
               crossDot += target[j]*weighted;
               alfa += (float)0.2;
           }

           /* Compute energy and cross dot product for the
              remaining samples */
           pp = buffer - icount;
           for (j=icount; j<SUBL; j++) {
               energy[tmpIndex] += (*pp)*(*pp);
               crossDot += target[j]*(*pp++);
           }

           if (energy[tmpIndex]>0.0) {
               invenergy[tmpIndex]=(float)1.0/(energy[tmpIndex]+EPS);
           } else {
               invenergy[tmpIndex] = (float) 0.0;
           }

           if (stage==0) {
               measure = (float)-10000000.0;

               if (crossDot > 0.0) {
                   measure = crossDot*crossDot*invenergy[tmpIndex];
               }
           }
           else {
               measure = crossDot*crossDot*invenergy[tmpIndex];
           }

           /* check if measure is better */
           ftmp = crossDot*invenergy[tmpIndex];

           if ((measure>*max_measure) && (fabs(ftmp)<CB_MAXGAIN)) {


               *best_index = tmpIndex;
               *max_measure = measure;
               *gain = ftmp;
           }
       }
   }


   /*----------------------------------------------------------------*
    *  Recreate a specific codebook vector from the augmented part.
    *
    *----------------------------------------------------------------*/

   void createAugmentedVec(
       int index,      /* (i) Index for the augmented vector
                              to be created */
       float *buffer,  /* (i) Pointer to the end of the buffer for
                              augmented codebook construction */
       float *cbVec/* (o) The construced codebook vector */
   ) {
       int ilow, j;
       float *pp, *ppo, *ppi, alfa, alfa1, weighted;

       ilow = index-5;

       /* copy the first noninterpolated part */

       pp = buffer-index;
       memcpy(cbVec,pp,sizeof(float)*index);

       /* interpolation */

       alfa1 = (float)0.2;
       alfa = 0.0;
       ppo = buffer-5;
       ppi = buffer-index-5;
       for (j=ilow; j<index; j++) {
           weighted = ((float)1.0-alfa)*(*ppo)+alfa*(*ppi);
           ppo++;
           ppi++;
           cbVec[j] = weighted;
           alfa += alfa1;
       }

       /* copy the second noninterpolated part */

       pp = buffer - index;
       memcpy(cbVec+index,pp,sizeof(float)*(SUBL-index));


   }
initial commit 2021-10-30 02:41:03 +08:00

			`/******************************************************************`

			`iLBC Speech Coder ANSI-C Source Code`

			`createCB.c`

			`Copyright (C) The Internet Society (2004).`
			`All Rights Reserved.`

			`******************************************************************/`





			`#include "iLBC_define.h"`
			`#include "constants.h"`
			`#include <string.h>`
			`#include <math.h>`

			`/----------------------------------------------------------------`
			`* Construct an additional codebook vector by filtering the`
			`* initial codebook buffer. This vector is then used to expand`
			`* the codebook with an additional section.`
			`---------------------------------------------------------------/`

			`void filteredCBvecs(`
			`float cbvectors, / (o) Codebook vectors for the`
			`higher section */`
			`float mem, / (i) Buffer to create codebook`
			`vector from */`
			`int lMem /* (i) Length of buffer */`
			`){`
			`int j, k;`
			`float pp, pp1;`
			`float tempbuff2[CB_MEML+CB_FILTERLEN];`
			`float *pos;`

			`memset(tempbuff2, 0, (CB_HALFFILTERLEN-1)*sizeof(float));`
			`memcpy(&tempbuff2[CB_HALFFILTERLEN-1], mem, lMem*sizeof(float));`
			`memset(&tempbuff2[lMem+CB_HALFFILTERLEN-1], 0,`
			`(CB_HALFFILTERLEN+1)*sizeof(float));`

			`/* Create codebook vector for higher section by filtering */`

			`/* do filtering */`
			`pos=cbvectors;`
			`memset(pos, 0, lMem*sizeof(float));`
			`for (k=0; k<lMem; k++) {`
			`pp=&tempbuff2[k];`
			`pp1=&cbfiltersTbl[CB_FILTERLEN-1];`
			`for (j=0;j<CB_FILTERLEN;j++) {`
			`(pos)+=(pp++)(pp1--);`
			`}`
			`pos++;`
			`}`
			`}`

			`/----------------------------------------------------------------`
			`* Search the augmented part of the codebook to find the best`
			`* measure.`
			`----------------------------------------------------------------/`






			`void searchAugmentedCB(`
			`int low, /* (i) Start index for the search */`
			`int high, /* (i) End index for the search */`
			`int stage, /* (i) Current stage */`
			`int startIndex, /* (i) Codebook index for the first`
			`aug vector */`
			`float target, / (i) Target vector for encoding */`
			`float buffer, / (i) Pointer to the end of the buffer for`
			`augmented codebook construction */`
			`float max_measure, / (i/o) Currently maximum measure */`
			`int best_index,/ (o) Currently the best index */`
			`float gain, / (o) Currently the best gain */`
			`float energy, / (o) Energy of augmented codebook`
			`vectors */`
			`float invenergy/ (o) Inv energy of augmented codebook`
			`vectors */`
			`) {`
			`int icount, ilow, j, tmpIndex;`
			`float pp, ppo, ppi, ppe, crossDot, alfa;`
			`float weighted, measure, nrjRecursive;`
			`float ftmp;`

			`/* Compute the energy for the first (low-5)`
			`noninterpolated samples */`
			`nrjRecursive = (float) 0.0;`
			`pp = buffer - low + 1;`
			`for (j=0; j<(low-5); j++) {`
			`nrjRecursive += ( (pp)(*pp) );`
			`pp++;`
			`}`
			`ppe = buffer - low;`


			`for (icount=low; icount<=high; icount++) {`

			`/* Index of the codebook vector used for retrieving`
			`energy values */`
			`tmpIndex = startIndex+icount-20;`

			`ilow = icount-4;`

			`/* Update the energy recursively to save complexity */`
			`nrjRecursive = nrjRecursive + (ppe)(*ppe);`
			`ppe--;`
			`energy[tmpIndex] = nrjRecursive;`

			`/* Compute cross dot product for the first (low-5)`
			`samples */`





			`crossDot = (float) 0.0;`
			`pp = buffer-icount;`
			`for (j=0; j<ilow; j++) {`
			`crossDot += target[j](pp++);`
			`}`

			`/* interpolation */`
			`alfa = (float) 0.2;`
			`ppo = buffer-4;`
			`ppi = buffer-icount-4;`
			`for (j=ilow; j<icount; j++) {`
			`weighted = ((float)1.0-alfa)(ppo)+alfa(ppi);`
			`ppo++;`
			`ppi++;`
			`energy[tmpIndex] += weighted*weighted;`
			`crossDot += target[j]*weighted;`
			`alfa += (float)0.2;`
			`}`

			`/* Compute energy and cross dot product for the`
			`remaining samples */`
			`pp = buffer - icount;`
			`for (j=icount; j<SUBL; j++) {`
			`energy[tmpIndex] += (pp)(*pp);`
			`crossDot += target[j](pp++);`
			`}`

			`if (energy[tmpIndex]>0.0) {`
			`invenergy[tmpIndex]=(float)1.0/(energy[tmpIndex]+EPS);`
			`} else {`
			`invenergy[tmpIndex] = (float) 0.0;`
			`}`

			`if (stage==0) {`
			`measure = (float)-10000000.0;`

			`if (crossDot > 0.0) {`
			`measure = crossDotcrossDotinvenergy[tmpIndex];`
			`}`
			`}`
			`else {`
			`measure = crossDotcrossDotinvenergy[tmpIndex];`
			`}`

			`/* check if measure is better */`
			`ftmp = crossDot*invenergy[tmpIndex];`

			`if ((measure>*max_measure) && (fabs(ftmp)<CB_MAXGAIN)) {`





			`*best_index = tmpIndex;`
			`*max_measure = measure;`
			`*gain = ftmp;`
			`}`
			`}`
			`}`


			`/----------------------------------------------------------------`
			`* Recreate a specific codebook vector from the augmented part.`
			`*`
			`----------------------------------------------------------------/`

			`void createAugmentedVec(`
			`int index, /* (i) Index for the augmented vector`
			`to be created */`
			`float buffer, / (i) Pointer to the end of the buffer for`
			`augmented codebook construction */`
			`float cbVec/ (o) The construced codebook vector */`
			`) {`
			`int ilow, j;`
			`float pp, ppo, *ppi, alfa, alfa1, weighted;`

			`ilow = index-5;`

			`/* copy the first noninterpolated part */`

			`pp = buffer-index;`
			`memcpy(cbVec,pp,sizeof(float)*index);`

			`/* interpolation */`

			`alfa1 = (float)0.2;`
			`alfa = 0.0;`
			`ppo = buffer-5;`
			`ppi = buffer-index-5;`
			`for (j=ilow; j<index; j++) {`
			`weighted = ((float)1.0-alfa)(ppo)+alfa(ppi);`
			`ppo++;`
			`ppi++;`
			`cbVec[j] = weighted;`
			`alfa += alfa1;`
			`}`

			`/* copy the second noninterpolated part */`

			`pp = buffer - index;`
			`memcpy(cbVec+index,pp,sizeof(float)*(SUBL-index));`





			`}`