ref: b677ab0c5909942bf8946e9e9bd148dea7dae718
dir: /sys/src/cmd/audio/libvorbis/mapping0.c/
/********************************************************************
* *
* THIS FILE IS PART OF THE OggVorbis SOFTWARE CODEC SOURCE CODE. *
* USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS *
* GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE *
* IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. *
* *
* THE OggVorbis SOURCE CODE IS (C) COPYRIGHT 1994-2002 *
* by the XIPHOPHORUS Company http://www.xiph.org/ *
* *
********************************************************************
function: channel mapping 0 implementation
last mod: $Id: mapping0.c,v 1.53 2002/07/13 06:12:46 xiphmont Exp $
********************************************************************/
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <math.h>
#include <ogg/ogg.h>
#include "vorbis/codec.h"
#include "codec_internal.h"
#include "codebook.h"
#include "window.h"
#include "registry.h"
#include "psy.h"
#include "misc.h"
/* simplistic, wasteful way of doing this (unique lookup for each
mode/submapping); there should be a central repository for
identical lookups. That will require minor work, so I'm putting it
off as low priority.
Why a lookup for each backend in a given mode? Because the
blocksize is set by the mode, and low backend lookups may require
parameters from other areas of the mode/mapping */
static void mapping0_free_info(vorbis_info_mapping *i){
vorbis_info_mapping0 *info=(vorbis_info_mapping0 *)i;
if(info){
memset(info,0,sizeof(*info));
_ogg_free(info);
}
}
static int ilog(unsigned int v){
int ret=0;
if(v)--v;
while(v){
ret++;
v>>=1;
}
return(ret);
}
static void mapping0_pack(vorbis_info *vi,vorbis_info_mapping *vm,
oggpack_buffer *opb){
int i;
vorbis_info_mapping0 *info=(vorbis_info_mapping0 *)vm;
/* another 'we meant to do it this way' hack... up to beta 4, we
packed 4 binary zeros here to signify one submapping in use. We
now redefine that to mean four bitflags that indicate use of
deeper features; bit0:submappings, bit1:coupling,
bit2,3:reserved. This is backward compatable with all actual uses
of the beta code. */
if(info->submaps>1){
oggpack_write(opb,1,1);
oggpack_write(opb,info->submaps-1,4);
}else
oggpack_write(opb,0,1);
if(info->coupling_steps>0){
oggpack_write(opb,1,1);
oggpack_write(opb,info->coupling_steps-1,8);
for(i=0;i<info->coupling_steps;i++){
oggpack_write(opb,info->coupling_mag[i],ilog(vi->channels));
oggpack_write(opb,info->coupling_ang[i],ilog(vi->channels));
}
}else
oggpack_write(opb,0,1);
oggpack_write(opb,0,2); /* 2,3:reserved */
/* we don't write the channel submappings if we only have one... */
if(info->submaps>1){
for(i=0;i<vi->channels;i++)
oggpack_write(opb,info->chmuxlist[i],4);
}
for(i=0;i<info->submaps;i++){
oggpack_write(opb,0,8); /* time submap unused */
oggpack_write(opb,info->floorsubmap[i],8);
oggpack_write(opb,info->residuesubmap[i],8);
}
}
/* also responsible for range checking */
static vorbis_info_mapping *mapping0_unpack(vorbis_info *vi,oggpack_buffer *opb){
int i;
vorbis_info_mapping0 *info=_ogg_calloc(1,sizeof(*info));
codec_setup_info *ci=vi->codec_setup;
memset(info,0,sizeof(*info));
if(oggpack_read(opb,1))
info->submaps=oggpack_read(opb,4)+1;
else
info->submaps=1;
if(oggpack_read(opb,1)){
info->coupling_steps=oggpack_read(opb,8)+1;
for(i=0;i<info->coupling_steps;i++){
int testM=info->coupling_mag[i]=oggpack_read(opb,ilog(vi->channels));
int testA=info->coupling_ang[i]=oggpack_read(opb,ilog(vi->channels));
if(testM<0 ||
testA<0 ||
testM==testA ||
testM>=vi->channels ||
testA>=vi->channels) goto err_out;
}
}
if(oggpack_read(opb,2)>0)goto err_out; /* 2,3:reserved */
if(info->submaps>1){
for(i=0;i<vi->channels;i++){
info->chmuxlist[i]=oggpack_read(opb,4);
if(info->chmuxlist[i]>=info->submaps)goto err_out;
}
}
for(i=0;i<info->submaps;i++){
oggpack_read(opb,8); /* time submap unused */
info->floorsubmap[i]=oggpack_read(opb,8);
if(info->floorsubmap[i]>=ci->floors)goto err_out;
info->residuesubmap[i]=oggpack_read(opb,8);
if(info->residuesubmap[i]>=ci->residues)goto err_out;
}
return info;
err_out:
mapping0_free_info(info);
return(NULL);
}
#include "os.h"
#include "lpc.h"
#include "lsp.h"
#include "envelope.h"
#include "mdct.h"
#include "psy.h"
#include "scales.h"
#if 0
static long seq=0;
static ogg_int64_t total=0;
static float FLOOR1_fromdB_LOOKUP[256]={
1.0649863e-07F, 1.1341951e-07F, 1.2079015e-07F, 1.2863978e-07F,
1.3699951e-07F, 1.4590251e-07F, 1.5538408e-07F, 1.6548181e-07F,
1.7623575e-07F, 1.8768855e-07F, 1.9988561e-07F, 2.128753e-07F,
2.2670913e-07F, 2.4144197e-07F, 2.5713223e-07F, 2.7384213e-07F,
2.9163793e-07F, 3.1059021e-07F, 3.3077411e-07F, 3.5226968e-07F,
3.7516214e-07F, 3.9954229e-07F, 4.2550680e-07F, 4.5315863e-07F,
4.8260743e-07F, 5.1396998e-07F, 5.4737065e-07F, 5.8294187e-07F,
6.2082472e-07F, 6.6116941e-07F, 7.0413592e-07F, 7.4989464e-07F,
7.9862701e-07F, 8.5052630e-07F, 9.0579828e-07F, 9.6466216e-07F,
1.0273513e-06F, 1.0941144e-06F, 1.1652161e-06F, 1.2409384e-06F,
1.3215816e-06F, 1.4074654e-06F, 1.4989305e-06F, 1.5963394e-06F,
1.7000785e-06F, 1.8105592e-06F, 1.9282195e-06F, 2.0535261e-06F,
2.1869758e-06F, 2.3290978e-06F, 2.4804557e-06F, 2.6416497e-06F,
2.8133190e-06F, 2.9961443e-06F, 3.1908506e-06F, 3.3982101e-06F,
3.6190449e-06F, 3.8542308e-06F, 4.1047004e-06F, 4.3714470e-06F,
4.6555282e-06F, 4.9580707e-06F, 5.2802740e-06F, 5.6234160e-06F,
5.9888572e-06F, 6.3780469e-06F, 6.7925283e-06F, 7.2339451e-06F,
7.7040476e-06F, 8.2047000e-06F, 8.7378876e-06F, 9.3057248e-06F,
9.9104632e-06F, 1.0554501e-05F, 1.1240392e-05F, 1.1970856e-05F,
1.2748789e-05F, 1.3577278e-05F, 1.4459606e-05F, 1.5399272e-05F,
1.6400004e-05F, 1.7465768e-05F, 1.8600792e-05F, 1.9809576e-05F,
2.1096914e-05F, 2.2467911e-05F, 2.3928002e-05F, 2.5482978e-05F,
2.7139006e-05F, 2.8902651e-05F, 3.0780908e-05F, 3.2781225e-05F,
3.4911534e-05F, 3.7180282e-05F, 3.9596466e-05F, 4.2169667e-05F,
4.4910090e-05F, 4.7828601e-05F, 5.0936773e-05F, 5.4246931e-05F,
5.7772202e-05F, 6.1526565e-05F, 6.5524908e-05F, 6.9783085e-05F,
7.4317983e-05F, 7.9147585e-05F, 8.4291040e-05F, 8.9768747e-05F,
9.5602426e-05F, 0.00010181521F, 0.00010843174F, 0.00011547824F,
0.00012298267F, 0.00013097477F, 0.00013948625F, 0.00014855085F,
0.00015820453F, 0.00016848555F, 0.00017943469F, 0.00019109536F,
0.00020351382F, 0.00021673929F, 0.00023082423F, 0.00024582449F,
0.00026179955F, 0.00027881276F, 0.00029693158F, 0.00031622787F,
0.00033677814F, 0.00035866388F, 0.00038197188F, 0.00040679456F,
0.00043323036F, 0.00046138411F, 0.00049136745F, 0.00052329927F,
0.00055730621F, 0.00059352311F, 0.00063209358F, 0.00067317058F,
0.00071691700F, 0.00076350630F, 0.00081312324F, 0.00086596457F,
0.00092223983F, 0.00098217216F, 0.0010459992F, 0.0011139742F,
0.0011863665F, 0.0012634633F, 0.0013455702F, 0.0014330129F,
0.0015261382F, 0.0016253153F, 0.0017309374F, 0.0018434235F,
0.0019632195F, 0.0020908006F, 0.0022266726F, 0.0023713743F,
0.0025254795F, 0.0026895994F, 0.0028643847F, 0.0030505286F,
0.0032487691F, 0.0034598925F, 0.0036847358F, 0.0039241906F,
0.0041792066F, 0.0044507950F, 0.0047400328F, 0.0050480668F,
0.0053761186F, 0.0057254891F, 0.0060975636F, 0.0064938176F,
0.0069158225F, 0.0073652516F, 0.0078438871F, 0.0083536271F,
0.0088964928F, 0.009474637F, 0.010090352F, 0.010746080F,
0.011444421F, 0.012188144F, 0.012980198F, 0.013823725F,
0.014722068F, 0.015678791F, 0.016697687F, 0.017782797F,
0.018938423F, 0.020169149F, 0.021479854F, 0.022875735F,
0.024362330F, 0.025945531F, 0.027631618F, 0.029427276F,
0.031339626F, 0.033376252F, 0.035545228F, 0.037855157F,
0.040315199F, 0.042935108F, 0.045725273F, 0.048696758F,
0.051861348F, 0.055231591F, 0.058820850F, 0.062643361F,
0.066714279F, 0.071049749F, 0.075666962F, 0.080584227F,
0.085821044F, 0.091398179F, 0.097337747F, 0.10366330F,
0.11039993F, 0.11757434F, 0.12521498F, 0.13335215F,
0.14201813F, 0.15124727F, 0.16107617F, 0.17154380F,
0.18269168F, 0.19456402F, 0.20720788F, 0.22067342F,
0.23501402F, 0.25028656F, 0.26655159F, 0.28387361F,
0.30232132F, 0.32196786F, 0.34289114F, 0.36517414F,
0.38890521F, 0.41417847F, 0.44109412F, 0.46975890F,
0.50028648F, 0.53279791F, 0.56742212F, 0.60429640F,
0.64356699F, 0.68538959F, 0.72993007F, 0.77736504F,
0.82788260F, 0.88168307F, 0.9389798F, 1.F,
};
#endif
extern int *floor1_fit(vorbis_block *vb,vorbis_look_floor *look,
const float *logmdct, /* in */
const float *logmask);
extern int *floor1_interpolate_fit(vorbis_block *vb,vorbis_look_floor *look,
int *A,int *B,
int del);
extern int floor1_encode(vorbis_block *vb,vorbis_look_floor *look,
int *post,int *ilogmask);
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;
backend_lookup_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 = malloc(sizeof(*nonzero)*vi->channels);
float *local_ampmax=malloc(sizeof(*local_ampmax)*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;
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);
#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);
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);
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);
#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. */
_vp_offset_and_mix(psy_look,
noise,
tone,
1,
logmask);
#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) {
free(nonzero);
free(local_ampmax);
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);
#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);
#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=malloc(sizeof(*res_bundle)*vi->channels);
float **couple_bundle=malloc(sizeof(*couple_bundle)*vi->channels);
int *zerobundle=malloc(sizeof(*zerobundle)*vi->channels);
int **sortindex=malloc(sizeof(*sortindex)*vi->channels);
float **mag_memo;
int **mag_sort;
int sortindexes_allocated = 0;
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);
}
memset(sortindex,0,sizeof(*sortindex)*vi->channels);
if(psy_look->vi->normal_channel_p){
sortindexes_allocated = vi->channels;
for(i=0;i<vi->channels;i++){
float *mdct =gmdct[i];
sortindex[i]=malloc(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++){
/* start out our new packet blob with packet type and mode */
/* Encode the packet type */
oggpack_write(&vb->opb,0,1);
/* Encode the modenumber */
/* Encode frame mode, pre,post windowsize, then dispatch */
oggpack_write(&vb->opb,modenumber,b->modebits);
if(vb->W){
oggpack_write(&vb->opb,vb->lW,1);
oggpack_write(&vb->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(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(vb,b->residue[resnum],
couple_bundle,NULL,zerobundle,ch_in_bundle,classifications);
}
/* ok, done encoding. Mark this protopacket and prepare next. */
oggpack_writealign(&vb->opb);
vbi->packetblob_markers[k]=oggpack_bytes(&vb->opb);
}
for (i=0;i<sortindexes_allocated;++i)
free(sortindex[i]);
free(res_bundle); free(couple_bundle); free(zerobundle); free(sortindex);
}
#if 0
seq++;
total+=ci->blocksizes[vb->W]/4+ci->blocksizes[vb->nW]/4;
#endif
free(local_ampmax);
free(nonzero);
return(0);
}
static int mapping0_inverse(vorbis_block *vb,vorbis_info_mapping *l){
vorbis_dsp_state *vd=vb->vd;
vorbis_info *vi=vd->vi;
codec_setup_info *ci=vi->codec_setup;
backend_lookup_state *b=vd->backend_state;
vorbis_info_mapping0 *info=(vorbis_info_mapping0 *)l;
int i,j;
long n=vb->pcmend=ci->blocksizes[vb->W];
float **pcmbundle=malloc(sizeof(*pcmbundle)*vi->channels);
int *zerobundle=malloc(sizeof(*zerobundle)*vi->channels);
int *nonzero =malloc(sizeof(*nonzero)*vi->channels);
void **floormemo=malloc(sizeof(*floormemo)*vi->channels);
/* recover the spectral envelope; store it in the PCM vector for now */
for(i=0;i<vi->channels;i++){
int submap=info->chmuxlist[i];
floormemo[i]=_floor_P[ci->floor_type[info->floorsubmap[submap]]]->
inverse1(vb,b->flr[info->floorsubmap[submap]]);
if(floormemo[i])
nonzero[i]=1;
else
nonzero[i]=0;
memset(vb->pcm[i],0,sizeof(*vb->pcm[i])*n/2);
}
/* channel coupling can 'dirty' the nonzero listing */
for(i=0;i<info->coupling_steps;i++){
if(nonzero[info->coupling_mag[i]] ||
nonzero[info->coupling_ang[i]]){
nonzero[info->coupling_mag[i]]=1;
nonzero[info->coupling_ang[i]]=1;
}
}
/* recover the residue into our working vectors */
for(i=0;i<info->submaps;i++){
int ch_in_bundle=0;
for(j=0;j<vi->channels;j++){
if(info->chmuxlist[j]==i){
if(nonzero[j])
zerobundle[ch_in_bundle]=1;
else
zerobundle[ch_in_bundle]=0;
pcmbundle[ch_in_bundle++]=vb->pcm[j];
}
}
_residue_P[ci->residue_type[info->residuesubmap[i]]]->
inverse(vb,b->residue[info->residuesubmap[i]],
pcmbundle,zerobundle,ch_in_bundle);
}
/* channel coupling */
for(i=info->coupling_steps-1;i>=0;i--){
float *pcmM=vb->pcm[info->coupling_mag[i]];
float *pcmA=vb->pcm[info->coupling_ang[i]];
for(j=0;j<n/2;j++){
float mag=pcmM[j];
float ang=pcmA[j];
if(mag>0)
if(ang>0){
pcmM[j]=mag;
pcmA[j]=mag-ang;
}else{
pcmA[j]=mag;
pcmM[j]=mag+ang;
}
else
if(ang>0){
pcmM[j]=mag;
pcmA[j]=mag+ang;
}else{
pcmA[j]=mag;
pcmM[j]=mag-ang;
}
}
}
/* compute and apply spectral envelope */
for(i=0;i<vi->channels;i++){
float *pcm=vb->pcm[i];
int submap=info->chmuxlist[i];
_floor_P[ci->floor_type[info->floorsubmap[submap]]]->
inverse2(vb,b->flr[info->floorsubmap[submap]],
floormemo[i],pcm);
}
/* transform the PCM data; takes PCM vector, vb; modifies PCM vector */
/* only MDCT right now.... */
for(i=0;i<vi->channels;i++){
float *pcm=vb->pcm[i];
mdct_backward(b->transform[vb->W][0],pcm,pcm);
}
/* window the data */
for(i=0;i<vi->channels;i++){
float *pcm=vb->pcm[i];
if(nonzero[i])
_vorbis_apply_window(pcm,b->window,ci->blocksizes,vb->lW,vb->W,vb->nW);
else
for(j=0;j<n;j++)
pcm[j]=0.f;
}
/* all done! */
free(pcmbundle); free(zerobundle); free(nonzero); free(floormemo);
return(0);
}
/* export hooks */
vorbis_func_mapping mapping0_exportbundle={
&mapping0_pack,
&mapping0_unpack,
&mapping0_free_info,
&mapping0_forward,
&mapping0_inverse
};