pns.c - platform/external/faad - Git at Google

 /************************* MPEG-4 AAC Audio Decoder **************************
  *                                                                           *
 "This software module was originally developed by
 AT&T, Dolby Laboratories, Fraunhofer Gesellschaft IIS in the course of
 development of the MPEG-2 AAC/MPEG-4 Audio standard ISO/IEC 13818-7,
 14496-1,2 and 3. This software module is an implementation of a part of one or more
 MPEG-2 AAC/MPEG-4 Audio tools as specified by the MPEG-2 AAC/MPEG-4
 Audio standard. ISO/IEC  gives users of the MPEG-2 AAC/MPEG-4 Audio
 standards free license to this software module or modifications thereof for use in
 hardware or software products claiming conformance to the MPEG-2 AAC/MPEG-4
 Audio  standards. Those intending to use this software module in hardware or
 software products are advised that this use may infringe existing patents.
 The original developer of this software module and his/her company, the subsequent
 editors and their companies, and ISO/IEC have no liability for use of this software
 module or modifications thereof in an implementation. Copyright is not released for
 non MPEG-2 AAC/MPEG-4 Audio conforming products. The original developer
 retains full right to use the code for his/her  own purpose, assign or donate the
 code to a third party and to inhibit third party from using the code for non
 MPEG-2 AAC/MPEG-4 Audio conforming products. This copyright notice must
 be included in all copies or derivative works."
 Copyright(c)1996.
  *                                                                           *
  ****************************************************************************/
 /*
  * $Id: pns.c,v 1.6 2002/01/11 00:55:17 wmaycisco Exp $
  */

 #include "all.h"


 #define MEAN_NRG 1.5625e+18      /* Theory: (2^31)^2 / 3 = 1.537228e+18 */

 static void random2(long *seed)
 {
     *seed = (1664525L * *seed) + 1013904223L;  /* Numerical recipes */
 }


 static void gen_rand_vector(float *spec, int size, long *state)
 /* Noise generator, generating vector with unity energy */
 {
     int i;
     float s, norm, nrg= 0.0;

     norm = 1.0f / (float)sqrt( size * MEAN_NRG );

     for (i=0; i<size; i++)
     {
         random2(state);
         spec[i] = (float)(*state * norm);
         nrg += spec[i] * spec[i];
     }

     s = 1.0f / (float)sqrt( nrg );
     for (i=0; i<size; i++)
         spec[i] *= s;
 }


 /*
  * if (noise correlated) {
  *   restore saved left channel random generator state
  *   generate random values
  * } else {
  *   save current random generator state
  *   generate random values
  * }
  * scale according to scalefactor
  *
  * Important: needs to be called left channel, then right channel
  *            for each channel pair
  */

 void pns(faacDecHandle hDecoder, MC_Info *mip, Info *info, int widx, int ch,
          byte *group, byte *cb_map, int *factors,
          int *lpflag, Float *coef[Chans] )
 {
     Ch_Info *cip = &mip->ch_info[ch];
     Float   *spec, *fp, scale;
     int     cb, corr_flag, sfb, n, nn, b, bb, nband;
     int   *band;
     long    *nsp;

     /* store original predictor flags when left channel of a channel pair */
     if ((cip->cpe  &&  cip->ch_is_left  &&  info->islong))
         for (sfb=0; sfb<info->sfb_per_sbk[0]; sfb++)
             hDecoder->lp_store[sfb+1] = lpflag[sfb+1];

     /* restore original predictor flags when right channel of a channel pair */
     if ((cip->cpe  &&  !cip->ch_is_left  &&  info->islong))
         for (sfb=0; sfb<info->sfb_per_sbk[0]; sfb++)
             lpflag[sfb+1] = hDecoder->lp_store[sfb+1];

     spec = coef[ ch ];
     nsp = hDecoder->noise_state_save;

     /* PNS goes by group */
     bb = 0;
     for (b = 0; b < info->nsbk; ) {
         nband = info->sfb_per_sbk[b];
         band = info->sbk_sfb_top[b];

         b = *group++;       /* b = index of last sbk in group */
         for (; bb < b; bb++) {  /* bb = sbk index */
             n = 0;
             for (sfb = 0; sfb < nband; sfb++){
                 nn = band[sfb]; /* band is offset table, nn is last coef in band */
                 cb = cb_map[sfb];
                 if (cb == NOISE_HCB  ||  cb == NOISE_HCB+100) {
                     /* found noise  substitution code book */

                     /* disable prediction (only important for long blocks) */
                     if (info->islong)  lpflag[1+sfb] = 0;

                     /* determine left/right correlation */
                     corr_flag = (cb != NOISE_HCB);

                     /* reconstruct noise substituted values */
                     /* generate random noise */
                     fp = spec + n;
                     if (corr_flag)  {
                         /* Start with stored state */
                         gen_rand_vector( fp, nn-n, nsp+sfb );
                     } else {
                         /* Store current state and go */
                         nsp[sfb] = hDecoder->cur_noise_state;
                         gen_rand_vector( fp, nn-n, &hDecoder->cur_noise_state );
                     }

                     /* scale to target energy */
                     scale = (float)pow( 2.0, 0.25*(factors[sfb]) );
                     for (; n < nn; n++) {   /* n is coef index */
                         *fp++ *= scale;
                     }
                 }
                 n = nn;
             }
             spec += info->bins_per_sbk[bb];
             factors += nband;
         }
         nsp += info->sfb_per_sbk[bb-1];
         cb_map += info->sfb_per_sbk[bb-1];
     }
 }


 /********************************************************************************
  *** FUNCTION: predict_pns_reset()                                              *
  ***                                        *
  ***    carry out predictor reset for PNS scalefactor bands (long blocks)       *
  ***                                        *
  ********************************************************************************/
 void predict_pns_reset(Info* info, PRED_STATUS *psp, byte *cb_map)
 {
     int    nband, sfb, i, top;
     int    *band;

     if (info->islong) {

         nband = info->sfb_per_sbk[0];
         band = info->sbk_sfb_top[0];

         for (i=0,sfb=0; sfb<nband; sfb++)  {

             top = band[sfb];
             if (cb_map[sfb] == NOISE_HCB  ||  cb_map[sfb] == NOISE_HCB+100) {
                 for (; i<top; i++)
                     reset_pred_state(&psp[i]);
             }
             i = top;
         }

     } /* end islong */
 }
	/*********************** MPEG-4 AAC Audio Decoder ************************
	* *
	"This software module was originally developed by
	AT&T, Dolby Laboratories, Fraunhofer Gesellschaft IIS in the course of
	development of the MPEG-2 AAC/MPEG-4 Audio standard ISO/IEC 13818-7,
	14496-1,2 and 3. This software module is an implementation of a part of one or more
	MPEG-2 AAC/MPEG-4 Audio tools as specified by the MPEG-2 AAC/MPEG-4
	Audio standard. ISO/IEC gives users of the MPEG-2 AAC/MPEG-4 Audio
	standards free license to this software module or modifications thereof for use in
	hardware or software products claiming conformance to the MPEG-2 AAC/MPEG-4
	Audio standards. Those intending to use this software module in hardware or
	software products are advised that this use may infringe existing patents.
	The original developer of this software module and his/her company, the subsequent
	editors and their companies, and ISO/IEC have no liability for use of this software
	module or modifications thereof in an implementation. Copyright is not released for
	non MPEG-2 AAC/MPEG-4 Audio conforming products. The original developer
	retains full right to use the code for his/her own purpose, assign or donate the
	code to a third party and to inhibit third party from using the code for non
	MPEG-2 AAC/MPEG-4 Audio conforming products. This copyright notice must
	be included in all copies or derivative works."
	Copyright(c)1996.
	* *
	****************************************************************************/
	/*
	* $Id: pns.c,v 1.6 2002/01/11 00:55:17 wmaycisco Exp $
	*/

	#include "all.h"


	#define MEAN_NRG 1.5625e+18 /* Theory: (2^31)^2 / 3 = 1.537228e+18 */

	static void random2(long *seed)
	{
	seed = (1664525L seed) + 1013904223L; / Numerical recipes */
	}


	static void gen_rand_vector(float spec, int size, long state)
	/* Noise generator, generating vector with unity energy */
	{
	int i;
	float s, norm, nrg= 0.0;

	norm = 1.0f / (float)sqrt( size * MEAN_NRG );

	for (i=0; i<size; i++)
	{
	random2(state);
	spec[i] = (float)(state norm);
	nrg += spec[i] * spec[i];
	}

	s = 1.0f / (float)sqrt( nrg );
	for (i=0; i<size; i++)
	spec[i] *= s;
	}



	/*
	* if (noise correlated) {
	* restore saved left channel random generator state
	* generate random values
	* } else {
	* save current random generator state
	* generate random values
	* }
	* scale according to scalefactor
	*
	* Important: needs to be called left channel, then right channel
	* for each channel pair
	*/

	void pns(faacDecHandle hDecoder, MC_Info mip, Info info, int widx, int ch,
	byte group, byte cb_map, int *factors,
	int lpflag, Float coef[Chans] )
	{
	Ch_Info *cip = &mip->ch_info[ch];
	Float spec, fp, scale;
	int cb, corr_flag, sfb, n, nn, b, bb, nband;
	int *band;
	long *nsp;

	/* store original predictor flags when left channel of a channel pair */
	if ((cip->cpe && cip->ch_is_left && info->islong))
	for (sfb=0; sfb<info->sfb_per_sbk[0]; sfb++)
	hDecoder->lp_store[sfb+1] = lpflag[sfb+1];

	/* restore original predictor flags when right channel of a channel pair */
	if ((cip->cpe && !cip->ch_is_left && info->islong))
	for (sfb=0; sfb<info->sfb_per_sbk[0]; sfb++)
	lpflag[sfb+1] = hDecoder->lp_store[sfb+1];

	spec = coef[ ch ];
	nsp = hDecoder->noise_state_save;

	/* PNS goes by group */
	bb = 0;
	for (b = 0; b < info->nsbk; ) {
	nband = info->sfb_per_sbk[b];
	band = info->sbk_sfb_top[b];

	b = group++; / b = index of last sbk in group */
	for (; bb < b; bb++) { /* bb = sbk index */
	n = 0;
	for (sfb = 0; sfb < nband; sfb++){
	nn = band[sfb]; /* band is offset table, nn is last coef in band */
	cb = cb_map[sfb];
	if (cb == NOISE_HCB \|\| cb == NOISE_HCB+100) {
	/* found noise substitution code book */

	/* disable prediction (only important for long blocks) */
	if (info->islong) lpflag[1+sfb] = 0;

	/* determine left/right correlation */
	corr_flag = (cb != NOISE_HCB);

	/* reconstruct noise substituted values */
	/* generate random noise */
	fp = spec + n;
	if (corr_flag) {
	/* Start with stored state */
	gen_rand_vector( fp, nn-n, nsp+sfb );
	} else {
	/* Store current state and go */
	nsp[sfb] = hDecoder->cur_noise_state;
	gen_rand_vector( fp, nn-n, &hDecoder->cur_noise_state );
	}

	/* scale to target energy */
	scale = (float)pow( 2.0, 0.25*(factors[sfb]) );
	for (; n < nn; n++) { /* n is coef index */
	fp++ = scale;
	}
	}
	n = nn;
	}
	spec += info->bins_per_sbk[bb];
	factors += nband;
	}
	nsp += info->sfb_per_sbk[bb-1];
	cb_map += info->sfb_per_sbk[bb-1];
	}
	}


	/********************************************************************************
	*** FUNCTION: predict_pns_reset() *
	*** *
	*** carry out predictor reset for PNS scalefactor bands (long blocks) *
	*** *
	********************************************************************************/
	void predict_pns_reset(Info* info, PRED_STATUS psp, byte cb_map)
	{
	int nband, sfb, i, top;
	int *band;

	if (info->islong) {

	nband = info->sfb_per_sbk[0];
	band = info->sbk_sfb_top[0];

	for (i=0,sfb=0; sfb<nband; sfb++) {

	top = band[sfb];
	if (cb_map[sfb] == NOISE_HCB \|\| cb_map[sfb] == NOISE_HCB+100) {
	for (; i<top; i++)
	reset_pred_state(&psp[i]);
	}
	i = top;
	}

	} /* end islong */
	}