/********************************************************************
* *
* 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 1994-2015 *
* by the Xiph.Org Foundation http://www.xiph.org/ *
* *
********************************************************************
function: basic shared codebook operations
last mod: $Id: sharedbook.c 19457 2015-03-03 00:15:29Z giles $
********************************************************************/
#include <stdlib.h>
#include <math.h>
#include <string.h>
#include <ogg/ogg.h>
#include "os.h"
#include "misc.h"
#include "vorbis/codec.h"
#include "codebook.h"
#include "scales.h"
/**** pack/unpack helpers ******************************************/
int ov_ilog(ogg_uint32_t v){
int ret;
for(ret=0;v;ret++)v>>=1;
return ret;
}
/* 32 bit float (not IEEE; nonnormalized mantissa +
biased exponent) : neeeeeee eeemmmmm mmmmmmmm mmmmmmmm
Why not IEEE? It's just not that important here. */
#define VQ_FEXP 10
#define VQ_FMAN 21
#define VQ_FEXP_BIAS 768 /* bias toward values smaller than 1. */
/* doesn't currently guard under/overflow */
long _float32_pack(float val){
int sign=0;
long exp;
long mant;
if(val<0){
sign=0x80000000;
val= -val;
}
exp= floor(log(val)/log(2.f)+.001); //+epsilon
mant=rint(ldexp(val,(VQ_FMAN-1)-exp));
exp=(exp+VQ_FEXP_BIAS)<<VQ_FMAN;
return(sign|exp|mant);
}
float _float32_unpack(long val){
double mant=val&0x1fffff;
int sign=val&0x80000000;
long exp =(val&0x7fe00000L)>>VQ_FMAN;
if(sign)mant= -mant;
return(ldexp(mant,exp-(VQ_FMAN-1)-VQ_FEXP_BIAS));
}
/* given a list of word lengths, generate a list of codewords. Works
for length ordered or unordered, always assigns the lowest valued
codewords first. Extended to handle unused entries (length 0) */
ogg_uint32_t *_make_words(char *l,long n,long sparsecount){
long i,j,count=0;
ogg_uint32_t marker[33];
ogg_uint32_t *r=_ogg_malloc((sparsecount?sparsecount:n)*sizeof(*r));
memset(marker,0,sizeof(marker));
for(i=0;i<n;i++){
long length=l[i];
if(length>0){
ogg_uint32_t entry=marker[length];
/* when we claim a node for an entry, we also claim the nodes
below it (pruning off the imagined tree that may have dangled
from it) as well as blocking the use of any nodes directly
above for leaves */
/* update ourself */
if(length<32 && (entry>>length)){
/* error condition; the lengths must specify an overpopulated tree */
_ogg_free(r);
return(NULL);
}
r[count++]=entry;
/* Look to see if the next shorter marker points to the node
above. if so, update it and repeat. */
{
for(j=length;j>0;j--){
if(marker[j]&1){
/* have to jump branches */
if(j==1)
marker[1]++;
else
marker[j]=marker[j-1]<<1;
break; /* invariant says next upper marker would already
have been moved if it was on the same path */
}
marker[j]++;
}
}
/* prune the tree; the implicit invariant says all the longer
markers were dangling from our just-taken node. Dangle them
from our *new* node. */
for(j=length+1;j<33;j++)
if((marker[j]>>1) == entry){
entry=marker[j];
marker[j]=marker[j-1]<<1;
}else
break;
}else
if(sparsecount==0)count++;
}
/* any underpopulated tree must be rejected. */
/* Single-entry codebooks are a retconned extension to the spec.
They have a single codeword '0' of length 1 that results in an
underpopulated tree. Shield that case from the underformed tree check. */
if(!(count==1 && marker[2]==2)){
for(i=1;i<33;i++)
if(marker[i] & (0xffffffffUL>>(32-i))){
_ogg_free(r);
return(NULL);
}
}
/* bitreverse the words because our bitwise packer/unpacker is LSb
endian */
for(i=0,count=0;i<n;i++){
ogg_uint32_t temp=0;
for(j=0;j<l[i];j++){
temp<<=1;
temp|=(r[count]>>j)&1;
}
if(sparsecount){
if(l[i])
r[count++]=temp;
}else
r[count++]=temp;
}
return(r);
}
/* there might be a straightforward one-line way to do the below
that's portable and totally safe against roundoff, but I haven't
thought of it. Therefore, we opt on the side of caution */
long _book_maptype1_quantvals(const static_codebook *b){
long vals=floor(pow((float)b->entries,1.f/b->dim));
/* the above *should* be reliable, but we'll not assume that FP is
ever reliable when bitstream sync is at stake; verify via integer
means that vals really is the greatest value of dim for which
vals^b->bim <= b->entries */
/* treat the above as an initial guess */
while(1){
long acc=1;
long acc1=1;
int i;
for(i=0;i<b->dim;i++){
acc*=vals;
acc1*=vals+1;
}
if(acc<=b->entries && acc1>b->entries){
return(vals);
}else{
if(acc>b->entries){
vals--;
}else{
vals++;
}
}
}
}
/* unpack the quantized list of values for encode/decode ***********/
/* we need to deal with two map types: in map type 1, the values are
generated algorithmically (each column of the vector counts through
the values in the quant vector). in map type 2, all the values came
in in an explicit list. Both value lists must be unpacked */
float *_book_unquantize(const static_codebook *b,int n,int *sparsemap){
long j,k,count=0;
if(b->maptype==1 || b->maptype==2){
int quantvals;
float mindel=_float32_unpack(b->q_min);
float delta=_float32_unpack(b->q_delta);
float *r=_ogg_calloc(n*b->dim,sizeof(*r));
/* maptype 1 and 2 both use a quantized value vector, but
different sizes */
switch(b->maptype){
case 1:
/* most of the time, entries%dimensions == 0, but we need to be
well defined. We define that the possible vales at each
scalar is values == entries/dim. If entries%dim != 0, we'll
have 'too few' values (values*dim<entries), which means that
we'll have 'left over' entries; left over entries use zeroed
values (and are wasted). So don't generate codebooks like
that */
quantvals=_book_maptype1_quantvals(b);
for(j=0;j<b->entries;j++){
if((sparsemap && b->lengthlist[j]) || !sparsemap){
float last=0.f;
int indexdiv=1;
for(k=0;k<b->dim;k++){
int index= (j/indexdiv)%quantvals;
float val=b->quantlist[index];
val=fabs(val)*delta+mindel+last;
if(b->q_sequencep)last=val;
if(sparsemap)
r[sparsemap[count]*b->dim+k]=val;
else
r[count*b->dim+k]=val;
indexdiv*=quantvals;
}
count++;
}
}
break;
case 2:
for(j=0;j<b->entries;j++){
if((sparsemap && b->lengthlist[j]) || !sparsemap){
float last=0.f;
for(k=0;k<b->dim;k++){
float val=b->quantlist[j*b->dim+k];
val=fabs(val)*delta+mindel+last;
if(b->q_sequencep)last=val;
if(sparsemap)
r[sparsemap[count]*b->dim+k]=val;
else
r[count*b->dim+k]=val;
}
count++;
}
}
break;
}
return(r);
}
return(NULL);
}
void vorbis_staticbook_destroy(static_codebook *b){
if(b->allocedp){
if(b->quantlist)_ogg_free(b->quantlist);
if(b->lengthlist)_ogg_free(b->lengthlist);
memset(b,0,sizeof(*b));
_ogg_free(b);
} /* otherwise, it is in static memory */
}
void vorbis_book_clear(codebook *b){
/* static book is not cleared; we're likely called on the lookup and
the static codebook belongs to the info struct */
if(b->valuelist)_ogg_free(b->valuelist);
if(b->codelist)_ogg_free(b->codelist);
if(b->dec_index)_ogg_free(b->dec_index);
if(b->dec_codelengths)_ogg_free(b->dec_codelengths);
if(b->dec_firsttable)_ogg_free(b->dec_firsttable);
memset(b,0,sizeof(*b));
}
int vorbis_book_init_encode(codebook *c,const static_codebook *s){
memset(c,0,sizeof(*c));
c->c=s;
c->entries=s->entries;
c->used_entries=s->entries;
c->dim=s->dim;
c->codelist=_make_words(s->lengthlist,s->entries,0);
//c->valuelist=_book_unquantize(s,s->entries,NULL);
c->quantvals=_book_maptype1_quantvals(s);
c->minval=(int)rint(_float32_unpack(s->q_min));
c->delta=(int)rint(_float32_unpack(s->q_delta));
return(0);
}
static ogg_uint32_t bitreverse(ogg_uint32_t x){
x= ((x>>16)&0x0000ffffUL) | ((x<<16)&0xffff0000UL);
x= ((x>> 8)&0x00ff00ffUL) | ((x<< 8)&0xff00ff00UL);
x= ((x>> 4)&0x0f0f0f0fUL) | ((x<< 4)&0xf0f0f0f0UL);
x= ((x>> 2)&0x33333333UL) | ((x<< 2)&0xccccccccUL);
return((x>> 1)&0x55555555UL) | ((x<< 1)&0xaaaaaaaaUL);
}
static int sort32a(const void *a,const void *b){
return ( **(ogg_uint32_t **)a>**(ogg_uint32_t **)b)-
( **(ogg_uint32_t **)a<**(ogg_uint32_t **)b);
}
/* decode codebook arrangement is more heavily optimized than encode */
int vorbis_book_init_decode(codebook *c,const static_codebook *s){
int i,j,n=0,tabn;
int *sortindex;
memset(c,0,sizeof(*c));
/* count actually used entries and find max length */
for(i=0;i<s->entries;i++)
if(s->lengthlist[i]>0)
n++;
c->entries=s->entries;
c->used_entries=n;
c->dim=s->dim;
if(n>0){
/* two different remappings go on here.
First, we collapse the likely sparse codebook down only to
actually represented values/words. This collapsing needs to be
indexed as map-valueless books are used to encode original entry
positions as integers.
Second, we reorder all vectors, including the entry index above,
by sorted bitreversed codeword to allow treeless decode. */
/* perform sort */
ogg_uint32_t *codes=_make_words(s->lengthlist,s->entries,c->used_entries);
ogg_uint32_t **codep=alloca(sizeof(*codep)*n);
if(codes==NULL)goto err_out;
for(i=0;i<n;i++){
codes[i]=bitreverse(codes[i]);
codep[i]=codes+i;
}
qsort(codep,n,sizeof(*codep),sort32a);
sortindex=alloca(n*sizeof(*sortindex));
c->codelist=_ogg_malloc(n*sizeof(*c->codelist));
/* the index is a reverse index */
for(i=0;i<n;i++){
int position=codep[i]-codes;
sortindex[position]=i;
}
for(i=0;i<n;i++)
c->codelist[sortindex[i]]=codes[i];
_ogg_free(codes);
c->valuelist=_book_unquantize(s,n,sortindex);
c->dec_index=_ogg_malloc(n*sizeof(*c->dec_index));
for(n=0,i=0;i<s->entries;i++)
if(s->lengthlist[i]>0)
c->dec_index[sortindex[n++]]=i;
c->dec_codelengths=_ogg_malloc(n*sizeof(*c->dec_codelengths));
c->dec_maxlength=0;
for(n=0,i=0;i<s->entries;i++)
if(s->lengthlist[i]>0){
c->dec_codelengths[sortindex[n++]]=s->lengthlist[i];
if(s->lengthlist[i]>c->dec_maxlength)
c->dec_maxlength=s->lengthlist[i];
}
if(n==1 && c->dec_maxlength==1){
/* special case the 'single entry codebook' with a single bit
fastpath table (that always returns entry 0 )in order to use
unmodified decode paths. */
c->dec_firsttablen=1;
c->dec_firsttable=_ogg_calloc(2,sizeof(*c->dec_firsttable));
c->dec_firsttable[0]=c->dec_firsttable[1]=1;
}else{
c->dec_firsttablen=ov_ilog(c->used_entries)-4; /* this is magic */
if(c->dec_firsttablen<5)c->dec_firsttablen=5;
if(c->dec_firsttablen>8)c->dec_firsttablen=8;
tabn=1<<c->dec_firsttablen;
c->dec_firsttable=_ogg_calloc(tabn,sizeof(*c->dec_firsttable));
for(i=0;i<n;i++){
if(c->dec_codelengths[i]<=c->dec_firsttablen){
ogg_uint32_t orig=bitreverse(c->codelist[i]);
for(j=0;j<(1<<(c->dec_firsttablen-c->dec_codelengths[i]));j++)
c->dec_firsttable[orig|(j<<c->dec_codelengths[i])]=i+1;
}
}
/* now fill in 'unused' entries in the firsttable with hi/lo search
hints for the non-direct-hits */
{
ogg_uint32_t mask=0xfffffffeUL<<(31-c->dec_firsttablen);
long lo=0,hi=0;
for(i=0;i<tabn;i++){
ogg_uint32_t word=i<<(32-c->dec_firsttablen);
if(c->dec_firsttable[bitreverse(word)]==0){
while((lo+1)<n && c->codelist[lo+1]<=word)lo++;
while( hi<n && word>=(c->codelist[hi]&mask))hi++;
/* we only actually have 15 bits per hint to play with here.
In order to overflow gracefully (nothing breaks, efficiency
just drops), encode as the difference from the extremes. */
{
unsigned long loval=lo;
unsigned long hival=n-hi;
if(loval>0x7fff)loval=0x7fff;
if(hival>0x7fff)hival=0x7fff;
c->dec_firsttable[bitreverse(word)]=
0x80000000UL | (loval<<15) | hival;
}
}
}
}
}
}
return(0);
err_out:
vorbis_book_clear(c);
return(-1);
}
long vorbis_book_codeword(codebook *book,int entry){
if(book->c) /* only use with encode; decode optimizations are
allowed to break this */
return book->codelist[entry];
return -1;
}
long vorbis_book_codelen(codebook *book,int entry){
if(book->c) /* only use with encode; decode optimizations are
allowed to break this */
return book->c->lengthlist[entry];
return -1;
}
#ifdef _V_SELFTEST
/* Unit tests of the dequantizer; this stuff will be OK
cross-platform, I simply want to be sure that special mapping cases
actually work properly; a bug could go unnoticed for a while */
#include <stdio.h>
/* cases:
no mapping
full, explicit mapping
algorithmic mapping
nonsequential
sequential
*/
static long full_quantlist1[]={0,1,2,3, 4,5,6,7, 8,3,6,1};
static long partial_quantlist1[]={0,7,2};
/* no mapping */
static_codebook test1={
4,16,
NULL,
0,
0,0,0,0,
NULL,
0
};
static float *test1_result=NULL;
/* linear, full mapping, nonsequential */
static_codebook test2={
4,3,
NULL,
2,
-533200896,1611661312,4,0,
full_quantlist1,
0
};
static float test2_result[]={-3,-2,-1,0, 1,2,3,4, 5,0,3,-2};
/* linear, full mapping, sequential */
static_codebook test3={
4,3,
NULL,
2,
-533200896,1611661312,4,1,
full_quantlist1,
0
};
static float test3_result[]={-3,-5,-6,-6, 1,3,6,10, 5,5,8,6};
/* linear, algorithmic mapping, nonsequential */
static_codebook test4={
3,27,
NULL,
1,
-533200896,1611661312,4,0,
partial_quantlist1,
0
};
static float test4_result[]={-3,-3,-3, 4,-3,-3, -1,-3,-3,
-3, 4,-3, 4, 4,-3, -1, 4,-3,
-3,-1,-3, 4,-1,-3, -1,-1,-3,
-3,-3, 4, 4,-3, 4, -1,-3, 4,
-3, 4, 4, 4, 4, 4, -1, 4, 4,
-3,-1, 4, 4,-1, 4, -1,-1, 4,
-3,-3,-1, 4,-3,-1, -1,-3,-1,
-3, 4,-1, 4, 4,-1, -1, 4,-1,
-3,-1,-1, 4,-1,-1, -1,-1,-1};
/* linear, algorithmic mapping, sequential */
static_codebook test5={
3,27,
NULL,
1,
-533200896,1611661312,4,1,
partial_quantlist1,
0
};
static float test5_result[]={-3,-6,-9, 4, 1,-2, -1,-4,-7,
-3, 1,-2, 4, 8, 5, -1, 3, 0,
-3,-4,-7, 4, 3, 0, -1,-2,-5,
-3,-6,-2, 4, 1, 5, -1,-4, 0,
-3, 1, 5, 4, 8,12, -1, 3, 7,
-3,-4, 0, 4, 3, 7, -1,-2, 2,
-3,-6,-7, 4, 1, 0, -1,-4,-5,
-3, 1, 0, 4, 8, 7, -1, 3, 2,
-3,-4,-5, 4, 3, 2, -1,-2,-3};
void run_test(static_codebook *b,float *comp){
float *out=_book_unquantize(b,b->entries,NULL);
int i;
if(comp){
if(!out){
fprintf(stderr,"_book_unquantize incorrectly returned NULL\n");
exit(1);
}
for(i=0;i<b->entries*b->dim;i++)
if(fabs(out[i]-comp[i])>.0001){
fprintf(stderr,"disagreement in unquantized and reference data:\n"
"position %d, %g != %g\n",i,out[i],comp[i]);
exit(1);
}
}else{
if(out){
fprintf(stderr,"_book_unquantize returned a value array: \n"
" correct result should have been NULL\n");
exit(1);
}
}
}
int main(){
/* run the nine dequant tests, and compare to the hand-rolled results */
fprintf(stderr,"Dequant test 1... ");
run_test(&test1,test1_result);
fprintf(stderr,"OK\nDequant test 2... ");
run_test(&test2,test2_result);
fprintf(stderr,"OK\nDequant test 3... ");
run_test(&test3,test3_result);
fprintf(stderr,"OK\nDequant test 4... ");
run_test(&test4,test4_result);
fprintf(stderr,"OK\nDequant test 5... ");
run_test(&test5,test5_result);
fprintf(stderr,"OK\n\n");
return(0);
}
#endif