Exemplo n.º 1
0
/* decides between modes, dispatches to the appropriate mapping. */
int vorbis_analysis(vorbis_block *vb, ogg_packet *op){
  int                   ret;

  vb->glue_bits=0;
  vb->time_bits=0;
  vb->floor_bits=0;
  vb->res_bits=0;

  /* first things first.  Make sure encode is ready */
  oggpack_reset(&vb->opb);
  
  /* we only have one mapping type (0), and we let the mapping code
     itself figure out what soft mode to use.  This allows easier
     bitrate management */

  if((ret=_mapping_P[0]->forward(vb)))
    return(ret);

  if(op){
    if(vorbis_bitrate_managed(vb))
      /* The app is using a bitmanaged mode... but not using the
         bitrate management interface. */
      return(OV_EINVAL);
    
    op->packet=oggpack_get_buffer(&vb->opb);
    op->bytes=oggpack_bytes(&vb->opb);
    op->b_o_s=0;
    op->e_o_s=vb->eofflag;
    op->granulepos=vb->granulepos;
    op->packetno=vb->sequence; /* for sake of completeness */
  }
  return(0);
}
Exemplo n.º 2
0
static int mapping0_forward(vorbis_block *vb){
  vorbis_dsp_state      *vd=vb->vd;
  vorbis_info           *vi=vd->vi;
  codec_setup_info      *ci=vi->codec_setup;
  private_state         *b=vb->vd->backend_state;
  vorbis_block_internal *vbi=(vorbis_block_internal *)vb->internal;
  int                    n=vb->pcmend;
  int i,j,k;

  int    *nonzero    = alloca(sizeof(*nonzero)*vi->channels);
  float  **gmdct     = _vorbis_block_alloc(vb,vi->channels*sizeof(*gmdct));
  int    **ilogmaskch= _vorbis_block_alloc(vb,vi->channels*sizeof(*ilogmaskch));
  int ***floor_posts = _vorbis_block_alloc(vb,vi->channels*sizeof(*floor_posts));
  
  float global_ampmax=vbi->ampmax;
  float *local_ampmax=alloca(sizeof(*local_ampmax)*vi->channels);
  int blocktype=vbi->blocktype;

  int modenumber=vb->W;
  vorbis_info_mapping0 *info=ci->map_param[modenumber];
  vorbis_look_psy *psy_look=
    b->psy+blocktype+(vb->W?2:0);

  vb->mode=modenumber;

  for(i=0;i<vi->channels;i++){
    float scale=4.f/n;
    float scale_dB;

    float *pcm     =vb->pcm[i]; 
    float *logfft  =pcm;

    gmdct[i]=_vorbis_block_alloc(vb,n/2*sizeof(**gmdct));

    scale_dB=todB(&scale) + .345; /* + .345 is a hack; the original
                                     todB estimation used on IEEE 754
                                     compliant machines had a bug that
                                     returned dB values about a third
                                     of a decibel too high.  The bug
                                     was harmless because tunings
                                     implicitly took that into
                                     account.  However, fixing the bug
                                     in the estimator requires
                                     changing all the tunings as well.
                                     For now, it's easier to sync
                                     things back up here, and
                                     recalibrate the tunings in the
                                     next major model upgrade. */

#if 0
    if(vi->channels==2)
      if(i==0)
	_analysis_output("pcmL",seq,pcm,n,0,0,total-n/2);
      else
	_analysis_output("pcmR",seq,pcm,n,0,0,total-n/2);
#endif
  
    /* window the PCM data */
    _vorbis_apply_window(pcm,b->window,ci->blocksizes,vb->lW,vb->W,vb->nW);

#if 0
    if(vi->channels==2)
      if(i==0)
	_analysis_output("windowedL",seq,pcm,n,0,0,total-n/2);
      else
	_analysis_output("windowedR",seq,pcm,n,0,0,total-n/2);
#endif

    /* transform the PCM data */
    /* only MDCT right now.... */
    mdct_forward(b->transform[vb->W][0],pcm,gmdct[i]);
    
    /* FFT yields more accurate tonal estimation (not phase sensitive) */
    drft_forward(&b->fft_look[vb->W],pcm);
    logfft[0]=scale_dB+todB(pcm)  + .345; /* + .345 is a hack; the
                                     original todB estimation used on
                                     IEEE 754 compliant machines had a
                                     bug that returned dB values about
                                     a third of a decibel too high.
                                     The bug was harmless because
                                     tunings implicitly took that into
                                     account.  However, fixing the bug
                                     in the estimator requires
                                     changing all the tunings as well.
                                     For now, it's easier to sync
                                     things back up here, and
                                     recalibrate the tunings in the
                                     next major model upgrade. */
    local_ampmax[i]=logfft[0];
    for(j=1;j<n-1;j+=2){
      float temp=pcm[j]*pcm[j]+pcm[j+1]*pcm[j+1];
      temp=logfft[(j+1)>>1]=scale_dB+.5f*todB(&temp)  + .345; /* +
                                     .345 is a hack; the original todB
                                     estimation used on IEEE 754
                                     compliant machines had a bug that
                                     returned dB values about a third
                                     of a decibel too high.  The bug
                                     was harmless because tunings
                                     implicitly took that into
                                     account.  However, fixing the bug
                                     in the estimator requires
                                     changing all the tunings as well.
                                     For now, it's easier to sync
                                     things back up here, and
                                     recalibrate the tunings in the
                                     next major model upgrade. */
      if(temp>local_ampmax[i])local_ampmax[i]=temp;
    }

    if(local_ampmax[i]>0.f)local_ampmax[i]=0.f;
    if(local_ampmax[i]>global_ampmax)global_ampmax=local_ampmax[i];

#if 0
    if(vi->channels==2){
      if(i==0){
	_analysis_output("fftL",seq,logfft,n/2,1,0,0);
      }else{
	_analysis_output("fftR",seq,logfft,n/2,1,0,0);
      }
    }
#endif

  }
  
  {
    float   *noise        = _vorbis_block_alloc(vb,n/2*sizeof(*noise));
    float   *tone         = _vorbis_block_alloc(vb,n/2*sizeof(*tone));
    
    for(i=0;i<vi->channels;i++){
      /* the encoder setup assumes that all the modes used by any
	 specific bitrate tweaking use the same floor */
      
      int submap=info->chmuxlist[i];
      
      /* the following makes things clearer to *me* anyway */
      float *mdct    =gmdct[i];
      float *logfft  =vb->pcm[i];
      
      float *logmdct =logfft+n/2;
      float *logmask =logfft;

      vb->mode=modenumber;

      floor_posts[i]=_vorbis_block_alloc(vb,PACKETBLOBS*sizeof(**floor_posts));
      memset(floor_posts[i],0,sizeof(**floor_posts)*PACKETBLOBS);
      
      for(j=0;j<n/2;j++)
	logmdct[j]=todB(mdct+j)  + .345; /* + .345 is a hack; the original
                                     todB estimation used on IEEE 754
                                     compliant machines had a bug that
                                     returned dB values about a third
                                     of a decibel too high.  The bug
                                     was harmless because tunings
                                     implicitly took that into
                                     account.  However, fixing the bug
                                     in the estimator requires
                                     changing all the tunings as well.
                                     For now, it's easier to sync
                                     things back up here, and
                                     recalibrate the tunings in the
                                     next major model upgrade. */

#if 0
      if(vi->channels==2){
	if(i==0)
	  _analysis_output("mdctL",seq,logmdct,n/2,1,0,0);
	else
	  _analysis_output("mdctR",seq,logmdct,n/2,1,0,0);
      }else{
	_analysis_output("mdct",seq,logmdct,n/2,1,0,0);
      }
#endif 
      
      /* first step; noise masking.  Not only does 'noise masking'
         give us curves from which we can decide how much resolution
         to give noise parts of the spectrum, it also implicitly hands
         us a tonality estimate (the larger the value in the
         'noise_depth' vector, the more tonal that area is) */

      _vp_noisemask(psy_look,
		    logmdct,
		    noise); /* noise does not have by-frequency offset
                               bias applied yet */
#if 0
      if(vi->channels==2){
	if(i==0)
	  _analysis_output("noiseL",seq,noise,n/2,1,0,0);
	else
	  _analysis_output("noiseR",seq,noise,n/2,1,0,0);
      }
#endif

      /* second step: 'all the other crap'; all the stuff that isn't
         computed/fit for bitrate management goes in the second psy
         vector.  This includes tone masking, peak limiting and ATH */

      _vp_tonemask(psy_look,
		   logfft,
		   tone,
		   global_ampmax,
		   local_ampmax[i]);

#if 0
      if(vi->channels==2){
	if(i==0)
	  _analysis_output("toneL",seq,tone,n/2,1,0,0);
	else
	  _analysis_output("toneR",seq,tone,n/2,1,0,0);
      }
#endif

      /* third step; we offset the noise vectors, overlay tone
	 masking.  We then do a floor1-specific line fit.  If we're
	 performing bitrate management, the line fit is performed
	 multiple times for up/down tweakage on demand. */

#if 0
      {
      float aotuv[psy_look->n];
#endif

	_vp_offset_and_mix(psy_look,
			   noise,
			   tone,
			   1,
			   logmask,
			   mdct,
			   logmdct);
	
#if 0
	if(vi->channels==2){
	  if(i==0)
	    _analysis_output("aotuvM1_L",seq,aotuv,psy_look->n,1,1,0);
	  else
	    _analysis_output("aotuvM1_R",seq,aotuv,psy_look->n,1,1,0);
	}
      }
#endif


#if 0
      if(vi->channels==2){
	if(i==0)
	  _analysis_output("mask1L",seq,logmask,n/2,1,0,0);
	else
	  _analysis_output("mask1R",seq,logmask,n/2,1,0,0);
      }
#endif

      /* this algorithm is hardwired to floor 1 for now; abort out if
         we're *not* floor1.  This won't happen unless someone has
         broken the encode setup lib.  Guard it anyway. */
      if(ci->floor_type[info->floorsubmap[submap]]!=1)return(-1);

      floor_posts[i][PACKETBLOBS/2]=
	floor1_fit(vb,b->flr[info->floorsubmap[submap]],
		   logmdct,
		   logmask);
      
      /* are we managing bitrate?  If so, perform two more fits for
         later rate tweaking (fits represent hi/lo) */
      if(vorbis_bitrate_managed(vb) && floor_posts[i][PACKETBLOBS/2]){
	/* higher rate by way of lower noise curve */

	_vp_offset_and_mix(psy_look,
			   noise,
			   tone,
			   2,
			   logmask,
			   mdct,
			   logmdct);

#if 0
	if(vi->channels==2){
	  if(i==0)
	    _analysis_output("mask2L",seq,logmask,n/2,1,0,0);
	  else
	    _analysis_output("mask2R",seq,logmask,n/2,1,0,0);
	}
#endif
	
	floor_posts[i][PACKETBLOBS-1]=
	  floor1_fit(vb,b->flr[info->floorsubmap[submap]],
		     logmdct,
		     logmask);
      
	/* lower rate by way of higher noise curve */
	_vp_offset_and_mix(psy_look,
			   noise,
			   tone,
			   0,
			   logmask,
			   mdct,
			   logmdct);

#if 0
	if(vi->channels==2)
	  if(i==0)
	    _analysis_output("mask0L",seq,logmask,n/2,1,0,0);
	  else
	    _analysis_output("mask0R",seq,logmask,n/2,1,0,0);
#endif

	floor_posts[i][0]=
	  floor1_fit(vb,b->flr[info->floorsubmap[submap]],
		     logmdct,
		     logmask);
	
	/* we also interpolate a range of intermediate curves for
           intermediate rates */
	for(k=1;k<PACKETBLOBS/2;k++)
	  floor_posts[i][k]=
	    floor1_interpolate_fit(vb,b->flr[info->floorsubmap[submap]],
				   floor_posts[i][0],
				   floor_posts[i][PACKETBLOBS/2],
				   k*65536/(PACKETBLOBS/2));
	for(k=PACKETBLOBS/2+1;k<PACKETBLOBS-1;k++)
	  floor_posts[i][k]=
	    floor1_interpolate_fit(vb,b->flr[info->floorsubmap[submap]],
				   floor_posts[i][PACKETBLOBS/2],
				   floor_posts[i][PACKETBLOBS-1],
				   (k-PACKETBLOBS/2)*65536/(PACKETBLOBS/2));
      }
    }
  }
  vbi->ampmax=global_ampmax;

  /*
    the next phases are performed once for vbr-only and PACKETBLOB
    times for bitrate managed modes.
    
    1) encode actual mode being used
    2) encode the floor for each channel, compute coded mask curve/res
    3) normalize and couple.
    4) encode residue
    5) save packet bytes to the packetblob vector
    
  */

  /* iterate over the many masking curve fits we've created */

  {
    float **res_bundle=alloca(sizeof(*res_bundle)*vi->channels);
    float **couple_bundle=alloca(sizeof(*couple_bundle)*vi->channels);
    int *zerobundle=alloca(sizeof(*zerobundle)*vi->channels);
    int **sortindex=alloca(sizeof(*sortindex)*vi->channels);
    float **mag_memo;
    int **mag_sort;

    if(info->coupling_steps){
      mag_memo=_vp_quantize_couple_memo(vb,
					&ci->psy_g_param,
					psy_look,
					info,
					gmdct);    
      
      mag_sort=_vp_quantize_couple_sort(vb,
					psy_look,
					info,
					mag_memo);    

      hf_reduction(&ci->psy_g_param,
		   psy_look,
		   info,
		   mag_memo);
    }

    memset(sortindex,0,sizeof(*sortindex)*vi->channels);
    if(psy_look->vi->normal_channel_p){
      for(i=0;i<vi->channels;i++){
	float *mdct    =gmdct[i];
	sortindex[i]=alloca(sizeof(**sortindex)*n/2);
	_vp_noise_normalize_sort(psy_look,mdct,sortindex[i]);
      }
    }

    for(k=(vorbis_bitrate_managed(vb)?0:PACKETBLOBS/2);
	k<=(vorbis_bitrate_managed(vb)?PACKETBLOBS-1:PACKETBLOBS/2);
	k++){
      oggpack_buffer *opb=vbi->packetblob[k];

      /* start out our new packet blob with packet type and mode */
      /* Encode the packet type */
      oggpack_write(opb,0,1);
      /* Encode the modenumber */
      /* Encode frame mode, pre,post windowsize, then dispatch */
      oggpack_write(opb,modenumber,b->modebits);
      if(vb->W){
	oggpack_write(opb,vb->lW,1);
	oggpack_write(opb,vb->nW,1);
      }

      /* encode floor, compute masking curve, sep out residue */
      for(i=0;i<vi->channels;i++){
	int submap=info->chmuxlist[i];
	float *mdct    =gmdct[i];
	float *res     =vb->pcm[i];
	int   *ilogmask=ilogmaskch[i]=
	  _vorbis_block_alloc(vb,n/2*sizeof(**gmdct));
      
	nonzero[i]=floor1_encode(opb,vb,b->flr[info->floorsubmap[submap]],
				 floor_posts[i][k],
				 ilogmask);
#if 0
	{
	  char buf[80];
	  sprintf(buf,"maskI%c%d",i?'R':'L',k);
	  float work[n/2];
	  for(j=0;j<n/2;j++)
	    work[j]=FLOOR1_fromdB_LOOKUP[ilogmask[j]];
	  _analysis_output(buf,seq,work,n/2,1,1,0);
	}
#endif
	_vp_remove_floor(psy_look,
			 mdct,
			 ilogmask,
			 res,
			 ci->psy_g_param.sliding_lowpass[vb->W][k]);

	_vp_noise_normalize(psy_look,res,res+n/2,sortindex[i]);

	
#if 0
	{
	  char buf[80];
	  float work[n/2];
	  for(j=0;j<n/2;j++)
	    work[j]=FLOOR1_fromdB_LOOKUP[ilogmask[j]]*(res+n/2)[j];
	  sprintf(buf,"resI%c%d",i?'R':'L',k);
	  _analysis_output(buf,seq,work,n/2,1,1,0);

	}
#endif
      }
      
      /* our iteration is now based on masking curve, not prequant and
	 coupling.  Only one prequant/coupling step */
      
      /* quantize/couple */
      /* incomplete implementation that assumes the tree is all depth
         one, or no tree at all */
      if(info->coupling_steps){
	_vp_couple(k,
		   &ci->psy_g_param,
		   psy_look,
		   info,
		   vb->pcm,
		   mag_memo,
		   mag_sort,
		   ilogmaskch,
		   nonzero,
		   ci->psy_g_param.sliding_lowpass[vb->W][k]);
      }
      
      /* classify and encode by submap */
      for(i=0;i<info->submaps;i++){
	int ch_in_bundle=0;
	long **classifications;
	int resnum=info->residuesubmap[i];

	for(j=0;j<vi->channels;j++){
	  if(info->chmuxlist[j]==i){
	    zerobundle[ch_in_bundle]=0;
	    if(nonzero[j])zerobundle[ch_in_bundle]=1;
	    res_bundle[ch_in_bundle]=vb->pcm[j];
	    couple_bundle[ch_in_bundle++]=vb->pcm[j]+n/2;
	  }
	}
	
	classifications=_residue_P[ci->residue_type[resnum]]->
	  class(vb,b->residue[resnum],couple_bundle,zerobundle,ch_in_bundle);
	
	_residue_P[ci->residue_type[resnum]]->
	  forward(opb,vb,b->residue[resnum],
		  couple_bundle,NULL,zerobundle,ch_in_bundle,classifications);
      }
      
      /* ok, done encoding.  Next protopacket. */
    }
    
  }

#if 0
  seq++;
  total+=ci->blocksizes[vb->W]/4+ci->blocksizes[vb->nW]/4;
#endif
  return(0);
}