vrshoot: libs/vorbis/sharedbook.c annotate

vrshoot

annotate libs/vorbis/sharedbook.c @ 0:b2f14e535253

initial commit

author	John Tsiombikas <nuclear@member.fsf.org>
date	Sat, 01 Feb 2014 19:58:19 +0200
parents
children

rev	line source
nuclear@0	1 /********************************************************************
nuclear@0	2 * *
nuclear@0	3 * THIS FILE IS PART OF THE OggVorbis SOFTWARE CODEC SOURCE CODE. *
nuclear@0	4 * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS *
nuclear@0	5 * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE *
nuclear@0	6 * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. *
nuclear@0	7 * *
nuclear@0	8 * THE OggVorbis SOURCE CODE IS (C) COPYRIGHT 1994-2009 *
nuclear@0	9 * by the Xiph.Org Foundation http://www.xiph.org/ *
nuclear@0	10 * *
nuclear@0	11 ********************************************************************
nuclear@0	12
nuclear@0	13 function: basic shared codebook operations
nuclear@0	14 last mod: $Id: sharedbook.c 17030 2010-03-25 06:52:55Z xiphmont $
nuclear@0	15
nuclear@0	16 ********************************************************************/
nuclear@0	17
nuclear@0	18 #include <stdlib.h>
nuclear@0	19 #include <math.h>
nuclear@0	20 #include <string.h>
nuclear@0	21 #include <ogg/ogg.h>
nuclear@0	22 #include "os.h"
nuclear@0	23 #include "misc.h"
nuclear@0	24 #include "vorbis/codec.h"
nuclear@0	25 #include "codebook.h"
nuclear@0	26 #include "scales.h"
nuclear@0	27
nuclear@0	28 /** pack/unpack helpers ****************************************/
nuclear@0	29 int _ilog(unsigned int v){
nuclear@0	30 int ret=0;
nuclear@0	31 while(v){
nuclear@0	32 ret++;
nuclear@0	33 v>>=1;
nuclear@0	34 }
nuclear@0	35 return(ret);
nuclear@0	36 }
nuclear@0	37
nuclear@0	38 /* 32 bit float (not IEEE; nonnormalized mantissa +
nuclear@0	39 biased exponent) : neeeeeee eeemmmmm mmmmmmmm mmmmmmmm
nuclear@0	40 Why not IEEE? It's just not that important here. */
nuclear@0	41
nuclear@0	42 #define VQ_FEXP 10
nuclear@0	43 #define VQ_FMAN 21
nuclear@0	44 #define VQ_FEXP_BIAS 768 /* bias toward values smaller than 1. */
nuclear@0	45
nuclear@0	46 /* doesn't currently guard under/overflow */
nuclear@0	47 long _float32_pack(float val){
nuclear@0	48 int sign=0;
nuclear@0	49 long exp;
nuclear@0	50 long mant;
nuclear@0	51 if(val<0){
nuclear@0	52 sign=0x80000000;
nuclear@0	53 val= -val;
nuclear@0	54 }
nuclear@0	55 exp= floor(log(val)/log(2.f)+.001); /+epsilon/
nuclear@0	56 mant=rint(ldexp(val,(VQ_FMAN-1)-exp));
nuclear@0	57 exp=(exp+VQ_FEXP_BIAS)<<VQ_FMAN;
nuclear@0	58
nuclear@0	59 return(sign\|exp\|mant);
nuclear@0	60 }
nuclear@0	61
nuclear@0	62 float _float32_unpack(long val){
nuclear@0	63 double mant=val&0x1fffff;
nuclear@0	64 int sign=val&0x80000000;
nuclear@0	65 long exp =(val&0x7fe00000L)>>VQ_FMAN;
nuclear@0	66 if(sign)mant= -mant;
nuclear@0	67 return(ldexp(mant,exp-(VQ_FMAN-1)-VQ_FEXP_BIAS));
nuclear@0	68 }
nuclear@0	69
nuclear@0	70 /* given a list of word lengths, generate a list of codewords. Works
nuclear@0	71 for length ordered or unordered, always assigns the lowest valued
nuclear@0	72 codewords first. Extended to handle unused entries (length 0) */
nuclear@0	73 ogg_uint32_t _make_words(long l,long n,long sparsecount){
nuclear@0	74 long i,j,count=0;
nuclear@0	75 ogg_uint32_t marker[33];
nuclear@0	76 ogg_uint32_t r=_ogg_malloc((sparsecount?sparsecount:n)sizeof(*r));
nuclear@0	77 memset(marker,0,sizeof(marker));
nuclear@0	78
nuclear@0	79 for(i=0;i<n;i++){
nuclear@0	80 long length=l[i];
nuclear@0	81 if(length>0){
nuclear@0	82 ogg_uint32_t entry=marker[length];
nuclear@0	83
nuclear@0	84 /* when we claim a node for an entry, we also claim the nodes
nuclear@0	85 below it (pruning off the imagined tree that may have dangled
nuclear@0	86 from it) as well as blocking the use of any nodes directly
nuclear@0	87 above for leaves */
nuclear@0	88
nuclear@0	89 /* update ourself */
nuclear@0	90 if(length<32 && (entry>>length)){
nuclear@0	91 /* error condition; the lengths must specify an overpopulated tree */
nuclear@0	92 _ogg_free(r);
nuclear@0	93 return(NULL);
nuclear@0	94 }
nuclear@0	95 r[count++]=entry;
nuclear@0	96
nuclear@0	97 /* Look to see if the next shorter marker points to the node
nuclear@0	98 above. if so, update it and repeat. */
nuclear@0	99 {
nuclear@0	100 for(j=length;j>0;j--){
nuclear@0	101
nuclear@0	102 if(marker[j]&1){
nuclear@0	103 /* have to jump branches */
nuclear@0	104 if(j==1)
nuclear@0	105 marker[1]++;
nuclear@0	106 else
nuclear@0	107 marker[j]=marker[j-1]<<1;
nuclear@0	108 break; /* invariant says next upper marker would already
nuclear@0	109 have been moved if it was on the same path */
nuclear@0	110 }
nuclear@0	111 marker[j]++;
nuclear@0	112 }
nuclear@0	113 }
nuclear@0	114
nuclear@0	115 /* prune the tree; the implicit invariant says all the longer
nuclear@0	116 markers were dangling from our just-taken node. Dangle them
nuclear@0	117 from our new node. */
nuclear@0	118 for(j=length+1;j<33;j++)
nuclear@0	119 if((marker[j]>>1) == entry){
nuclear@0	120 entry=marker[j];
nuclear@0	121 marker[j]=marker[j-1]<<1;
nuclear@0	122 }else
nuclear@0	123 break;
nuclear@0	124 }else
nuclear@0	125 if(sparsecount==0)count++;
nuclear@0	126 }
nuclear@0	127
nuclear@0	128 /* sanity check the huffman tree; an underpopulated tree must be
nuclear@0	129 rejected. The only exception is the one-node pseudo-nil tree,
nuclear@0	130 which appears to be underpopulated because the tree doesn't
nuclear@0	131 really exist; there's only one possible 'codeword' or zero bits,
nuclear@0	132 but the above tree-gen code doesn't mark that. */
nuclear@0	133 if(sparsecount != 1){
nuclear@0	134 for(i=1;i<33;i++)
nuclear@0	135 if(marker[i] & (0xffffffffUL>>(32-i))){
nuclear@0	136 _ogg_free(r);
nuclear@0	137 return(NULL);
nuclear@0	138 }
nuclear@0	139 }
nuclear@0	140
nuclear@0	141 /* bitreverse the words because our bitwise packer/unpacker is LSb
nuclear@0	142 endian */
nuclear@0	143 for(i=0,count=0;i<n;i++){
nuclear@0	144 ogg_uint32_t temp=0;
nuclear@0	145 for(j=0;j<l[i];j++){
nuclear@0	146 temp<<=1;
nuclear@0	147 temp\|=(r[count]>>j)&1;
nuclear@0	148 }
nuclear@0	149
nuclear@0	150 if(sparsecount){
nuclear@0	151 if(l[i])
nuclear@0	152 r[count++]=temp;
nuclear@0	153 }else
nuclear@0	154 r[count++]=temp;
nuclear@0	155 }
nuclear@0	156
nuclear@0	157 return(r);
nuclear@0	158 }
nuclear@0	159
nuclear@0	160 /* there might be a straightforward one-line way to do the below
nuclear@0	161 that's portable and totally safe against roundoff, but I haven't
nuclear@0	162 thought of it. Therefore, we opt on the side of caution */
nuclear@0	163 long _book_maptype1_quantvals(const static_codebook *b){
nuclear@0	164 long vals=floor(pow((float)b->entries,1.f/b->dim));
nuclear@0	165
nuclear@0	166 /* the above should be reliable, but we'll not assume that FP is
nuclear@0	167 ever reliable when bitstream sync is at stake; verify via integer
nuclear@0	168 means that vals really is the greatest value of dim for which
nuclear@0	169 vals^b->bim <= b->entries */
nuclear@0	170 /* treat the above as an initial guess */
nuclear@0	171 while(1){
nuclear@0	172 long acc=1;
nuclear@0	173 long acc1=1;
nuclear@0	174 int i;
nuclear@0	175 for(i=0;i<b->dim;i++){
nuclear@0	176 acc*=vals;
nuclear@0	177 acc1*=vals+1;
nuclear@0	178 }
nuclear@0	179 if(acc<=b->entries && acc1>b->entries){
nuclear@0	180 return(vals);
nuclear@0	181 }else{
nuclear@0	182 if(acc>b->entries){
nuclear@0	183 vals--;
nuclear@0	184 }else{
nuclear@0	185 vals++;
nuclear@0	186 }
nuclear@0	187 }
nuclear@0	188 }
nuclear@0	189 }
nuclear@0	190
nuclear@0	191 /* unpack the quantized list of values for encode/decode ***********/
nuclear@0	192 /* we need to deal with two map types: in map type 1, the values are
nuclear@0	193 generated algorithmically (each column of the vector counts through
nuclear@0	194 the values in the quant vector). in map type 2, all the values came
nuclear@0	195 in in an explicit list. Both value lists must be unpacked */
nuclear@0	196 float _book_unquantize(const static_codebook b,int n,int *sparsemap){
nuclear@0	197 long j,k,count=0;
nuclear@0	198 if(b->maptype==1 \|\| b->maptype==2){
nuclear@0	199 int quantvals;
nuclear@0	200 float mindel=_float32_unpack(b->q_min);
nuclear@0	201 float delta=_float32_unpack(b->q_delta);
nuclear@0	202 float r=_ogg_calloc(nb->dim,sizeof(*r));
nuclear@0	203
nuclear@0	204 /* maptype 1 and 2 both use a quantized value vector, but
nuclear@0	205 different sizes */
nuclear@0	206 switch(b->maptype){
nuclear@0	207 case 1:
nuclear@0	208 /* most of the time, entries%dimensions == 0, but we need to be
nuclear@0	209 well defined. We define that the possible vales at each
nuclear@0	210 scalar is values == entries/dim. If entries%dim != 0, we'll
nuclear@0	211 have 'too few' values (values*dim<entries), which means that
nuclear@0	212 we'll have 'left over' entries; left over entries use zeroed
nuclear@0	213 values (and are wasted). So don't generate codebooks like
nuclear@0	214 that */
nuclear@0	215 quantvals=_book_maptype1_quantvals(b);
nuclear@0	216 for(j=0;j<b->entries;j++){
nuclear@0	217 if((sparsemap && b->lengthlist[j]) \|\| !sparsemap){
nuclear@0	218 float last=0.f;
nuclear@0	219 int indexdiv=1;
nuclear@0	220 for(k=0;k<b->dim;k++){
nuclear@0	221 int index= (j/indexdiv)%quantvals;
nuclear@0	222 float val=b->quantlist[index];
nuclear@0	223 val=fabs(val)*delta+mindel+last;
nuclear@0	224 if(b->q_sequencep)last=val;
nuclear@0	225 if(sparsemap)
nuclear@0	226 r[sparsemap[count]*b->dim+k]=val;
nuclear@0	227 else
nuclear@0	228 r[count*b->dim+k]=val;
nuclear@0	229 indexdiv*=quantvals;
nuclear@0	230 }
nuclear@0	231 count++;
nuclear@0	232 }
nuclear@0	233
nuclear@0	234 }
nuclear@0	235 break;
nuclear@0	236 case 2:
nuclear@0	237 for(j=0;j<b->entries;j++){
nuclear@0	238 if((sparsemap && b->lengthlist[j]) \|\| !sparsemap){
nuclear@0	239 float last=0.f;
nuclear@0	240
nuclear@0	241 for(k=0;k<b->dim;k++){
nuclear@0	242 float val=b->quantlist[j*b->dim+k];
nuclear@0	243 val=fabs(val)*delta+mindel+last;
nuclear@0	244 if(b->q_sequencep)last=val;
nuclear@0	245 if(sparsemap)
nuclear@0	246 r[sparsemap[count]*b->dim+k]=val;
nuclear@0	247 else
nuclear@0	248 r[count*b->dim+k]=val;
nuclear@0	249 }
nuclear@0	250 count++;
nuclear@0	251 }
nuclear@0	252 }
nuclear@0	253 break;
nuclear@0	254 }
nuclear@0	255
nuclear@0	256 return(r);
nuclear@0	257 }
nuclear@0	258 return(NULL);
nuclear@0	259 }
nuclear@0	260
nuclear@0	261 void vorbis_staticbook_destroy(static_codebook *b){
nuclear@0	262 if(b->allocedp){
nuclear@0	263 if(b->quantlist)_ogg_free(b->quantlist);
nuclear@0	264 if(b->lengthlist)_ogg_free(b->lengthlist);
nuclear@0	265 memset(b,0,sizeof(*b));
nuclear@0	266 _ogg_free(b);
nuclear@0	267 } /* otherwise, it is in static memory */
nuclear@0	268 }
nuclear@0	269
nuclear@0	270 void vorbis_book_clear(codebook *b){
nuclear@0	271 /* static book is not cleared; we're likely called on the lookup and
nuclear@0	272 the static codebook belongs to the info struct */
nuclear@0	273 if(b->valuelist)_ogg_free(b->valuelist);
nuclear@0	274 if(b->codelist)_ogg_free(b->codelist);
nuclear@0	275
nuclear@0	276 if(b->dec_index)_ogg_free(b->dec_index);
nuclear@0	277 if(b->dec_codelengths)_ogg_free(b->dec_codelengths);
nuclear@0	278 if(b->dec_firsttable)_ogg_free(b->dec_firsttable);
nuclear@0	279
nuclear@0	280 memset(b,0,sizeof(*b));
nuclear@0	281 }
nuclear@0	282
nuclear@0	283 int vorbis_book_init_encode(codebook c,const static_codebook s){
nuclear@0	284
nuclear@0	285 memset(c,0,sizeof(*c));
nuclear@0	286 c->c=s;
nuclear@0	287 c->entries=s->entries;
nuclear@0	288 c->used_entries=s->entries;
nuclear@0	289 c->dim=s->dim;
nuclear@0	290 c->codelist=_make_words(s->lengthlist,s->entries,0);
nuclear@0	291 /c->valuelist=_book_unquantize(s,s->entries,NULL);/
nuclear@0	292 c->quantvals=_book_maptype1_quantvals(s);
nuclear@0	293 c->minval=(int)rint(_float32_unpack(s->q_min));
nuclear@0	294 c->delta=(int)rint(_float32_unpack(s->q_delta));
nuclear@0	295
nuclear@0	296 return(0);
nuclear@0	297 }
nuclear@0	298
nuclear@0	299 static ogg_uint32_t bitreverse(ogg_uint32_t x){
nuclear@0	300 x= ((x>>16)&0x0000ffffUL) \| ((x<<16)&0xffff0000UL);
nuclear@0	301 x= ((x>> 8)&0x00ff00ffUL) \| ((x<< 8)&0xff00ff00UL);
nuclear@0	302 x= ((x>> 4)&0x0f0f0f0fUL) \| ((x<< 4)&0xf0f0f0f0UL);
nuclear@0	303 x= ((x>> 2)&0x33333333UL) \| ((x<< 2)&0xccccccccUL);
nuclear@0	304 return((x>> 1)&0x55555555UL) \| ((x<< 1)&0xaaaaaaaaUL);
nuclear@0	305 }
nuclear@0	306
nuclear@0	307 static int sort32a(const void a,const void b){
nuclear@0	308 return ( (ogg_uint32_t )a>(ogg_uint32_t )b)-
nuclear@0	309 ( (ogg_uint32_t )a<(ogg_uint32_t )b);
nuclear@0	310 }
nuclear@0	311
nuclear@0	312 /* decode codebook arrangement is more heavily optimized than encode */
nuclear@0	313 int vorbis_book_init_decode(codebook c,const static_codebook s){
nuclear@0	314 int i,j,n=0,tabn;
nuclear@0	315 int *sortindex;
nuclear@0	316 memset(c,0,sizeof(*c));
nuclear@0	317
nuclear@0	318 /* count actually used entries */
nuclear@0	319 for(i=0;i<s->entries;i++)
nuclear@0	320 if(s->lengthlist[i]>0)
nuclear@0	321 n++;
nuclear@0	322
nuclear@0	323 c->entries=s->entries;
nuclear@0	324 c->used_entries=n;
nuclear@0	325 c->dim=s->dim;
nuclear@0	326
nuclear@0	327 if(n>0){
nuclear@0	328
nuclear@0	329 /* two different remappings go on here.
nuclear@0	330
nuclear@0	331 First, we collapse the likely sparse codebook down only to
nuclear@0	332 actually represented values/words. This collapsing needs to be
nuclear@0	333 indexed as map-valueless books are used to encode original entry
nuclear@0	334 positions as integers.
nuclear@0	335
nuclear@0	336 Second, we reorder all vectors, including the entry index above,
nuclear@0	337 by sorted bitreversed codeword to allow treeless decode. */
nuclear@0	338
nuclear@0	339 /* perform sort */
nuclear@0	340 ogg_uint32_t *codes=_make_words(s->lengthlist,s->entries,c->used_entries);
nuclear@0	341 ogg_uint32_t *codep=alloca(sizeof(codep)*n);
nuclear@0	342
nuclear@0	343 if(codes==NULL)goto err_out;
nuclear@0	344
nuclear@0	345 for(i=0;i<n;i++){
nuclear@0	346 codes[i]=bitreverse(codes[i]);
nuclear@0	347 codep[i]=codes+i;
nuclear@0	348 }
nuclear@0	349
nuclear@0	350 qsort(codep,n,sizeof(*codep),sort32a);
nuclear@0	351
nuclear@0	352 sortindex=alloca(nsizeof(sortindex));
nuclear@0	353 c->codelist=_ogg_malloc(nsizeof(c->codelist));
nuclear@0	354 /* the index is a reverse index */
nuclear@0	355 for(i=0;i<n;i++){
nuclear@0	356 int position=codep[i]-codes;
nuclear@0	357 sortindex[position]=i;
nuclear@0	358 }
nuclear@0	359
nuclear@0	360 for(i=0;i<n;i++)
nuclear@0	361 c->codelist[sortindex[i]]=codes[i];
nuclear@0	362 _ogg_free(codes);
nuclear@0	363
nuclear@0	364
nuclear@0	365 c->valuelist=_book_unquantize(s,n,sortindex);
nuclear@0	366 c->dec_index=_ogg_malloc(nsizeof(c->dec_index));
nuclear@0	367
nuclear@0	368 for(n=0,i=0;i<s->entries;i++)
nuclear@0	369 if(s->lengthlist[i]>0)
nuclear@0	370 c->dec_index[sortindex[n++]]=i;
nuclear@0	371
nuclear@0	372 c->dec_codelengths=_ogg_malloc(nsizeof(c->dec_codelengths));
nuclear@0	373 for(n=0,i=0;i<s->entries;i++)
nuclear@0	374 if(s->lengthlist[i]>0)
nuclear@0	375 c->dec_codelengths[sortindex[n++]]=s->lengthlist[i];
nuclear@0	376
nuclear@0	377 c->dec_firsttablen=_ilog(c->used_entries)-4; /* this is magic */
nuclear@0	378 if(c->dec_firsttablen<5)c->dec_firsttablen=5;
nuclear@0	379 if(c->dec_firsttablen>8)c->dec_firsttablen=8;
nuclear@0	380
nuclear@0	381 tabn=1<<c->dec_firsttablen;
nuclear@0	382 c->dec_firsttable=_ogg_calloc(tabn,sizeof(*c->dec_firsttable));
nuclear@0	383 c->dec_maxlength=0;
nuclear@0	384
nuclear@0	385 for(i=0;i<n;i++){
nuclear@0	386 if(c->dec_maxlength<c->dec_codelengths[i])
nuclear@0	387 c->dec_maxlength=c->dec_codelengths[i];
nuclear@0	388 if(c->dec_codelengths[i]<=c->dec_firsttablen){
nuclear@0	389 ogg_uint32_t orig=bitreverse(c->codelist[i]);
nuclear@0	390 for(j=0;j<(1<<(c->dec_firsttablen-c->dec_codelengths[i]));j++)
nuclear@0	391 c->dec_firsttable[orig\|(j<<c->dec_codelengths[i])]=i+1;
nuclear@0	392 }
nuclear@0	393 }
nuclear@0	394
nuclear@0	395 /* now fill in 'unused' entries in the firsttable with hi/lo search
nuclear@0	396 hints for the non-direct-hits */
nuclear@0	397 {
nuclear@0	398 ogg_uint32_t mask=0xfffffffeUL<<(31-c->dec_firsttablen);
nuclear@0	399 long lo=0,hi=0;
nuclear@0	400
nuclear@0	401 for(i=0;i<tabn;i++){
nuclear@0	402 ogg_uint32_t word=i<<(32-c->dec_firsttablen);
nuclear@0	403 if(c->dec_firsttable[bitreverse(word)]==0){
nuclear@0	404 while((lo+1)<n && c->codelist[lo+1]<=word)lo++;
nuclear@0	405 while( hi<n && word>=(c->codelist[hi]&mask))hi++;
nuclear@0	406
nuclear@0	407 /* we only actually have 15 bits per hint to play with here.
nuclear@0	408 In order to overflow gracefully (nothing breaks, efficiency
nuclear@0	409 just drops), encode as the difference from the extremes. */
nuclear@0	410 {
nuclear@0	411 unsigned long loval=lo;
nuclear@0	412 unsigned long hival=n-hi;
nuclear@0	413
nuclear@0	414 if(loval>0x7fff)loval=0x7fff;
nuclear@0	415 if(hival>0x7fff)hival=0x7fff;
nuclear@0	416 c->dec_firsttable[bitreverse(word)]=
nuclear@0	417 0x80000000UL \| (loval<<15) \| hival;
nuclear@0	418 }
nuclear@0	419 }
nuclear@0	420 }
nuclear@0	421 }
nuclear@0	422 }
nuclear@0	423
nuclear@0	424 return(0);
nuclear@0	425 err_out:
nuclear@0	426 vorbis_book_clear(c);
nuclear@0	427 return(-1);
nuclear@0	428 }
nuclear@0	429
nuclear@0	430 long vorbis_book_codeword(codebook *book,int entry){
nuclear@0	431 if(book->c) /* only use with encode; decode optimizations are
nuclear@0	432 allowed to break this */
nuclear@0	433 return book->codelist[entry];
nuclear@0	434 return -1;
nuclear@0	435 }
nuclear@0	436
nuclear@0	437 long vorbis_book_codelen(codebook *book,int entry){
nuclear@0	438 if(book->c) /* only use with encode; decode optimizations are
nuclear@0	439 allowed to break this */
nuclear@0	440 return book->c->lengthlist[entry];
nuclear@0	441 return -1;
nuclear@0	442 }
nuclear@0	443
nuclear@0	444 #ifdef _V_SELFTEST
nuclear@0	445
nuclear@0	446 /* Unit tests of the dequantizer; this stuff will be OK
nuclear@0	447 cross-platform, I simply want to be sure that special mapping cases
nuclear@0	448 actually work properly; a bug could go unnoticed for a while */
nuclear@0	449
nuclear@0	450 #include <stdio.h>
nuclear@0	451
nuclear@0	452 /* cases:
nuclear@0	453
nuclear@0	454 no mapping
nuclear@0	455 full, explicit mapping
nuclear@0	456 algorithmic mapping
nuclear@0	457
nuclear@0	458 nonsequential
nuclear@0	459 sequential
nuclear@0	460 */
nuclear@0	461
nuclear@0	462 static long full_quantlist1[]={0,1,2,3, 4,5,6,7, 8,3,6,1};
nuclear@0	463 static long partial_quantlist1[]={0,7,2};
nuclear@0	464
nuclear@0	465 /* no mapping */
nuclear@0	466 static_codebook test1={
nuclear@0	467 4,16,
nuclear@0	468 NULL,
nuclear@0	469 0,
nuclear@0	470 0,0,0,0,
nuclear@0	471 NULL,
nuclear@0	472 0
nuclear@0	473 };
nuclear@0	474 static float *test1_result=NULL;
nuclear@0	475
nuclear@0	476 /* linear, full mapping, nonsequential */
nuclear@0	477 static_codebook test2={
nuclear@0	478 4,3,
nuclear@0	479 NULL,
nuclear@0	480 2,
nuclear@0	481 -533200896,1611661312,4,0,
nuclear@0	482 full_quantlist1,
nuclear@0	483 0
nuclear@0	484 };
nuclear@0	485 static float test2_result[]={-3,-2,-1,0, 1,2,3,4, 5,0,3,-2};
nuclear@0	486
nuclear@0	487 /* linear, full mapping, sequential */
nuclear@0	488 static_codebook test3={
nuclear@0	489 4,3,
nuclear@0	490 NULL,
nuclear@0	491 2,
nuclear@0	492 -533200896,1611661312,4,1,
nuclear@0	493 full_quantlist1,
nuclear@0	494 0
nuclear@0	495 };
nuclear@0	496 static float test3_result[]={-3,-5,-6,-6, 1,3,6,10, 5,5,8,6};
nuclear@0	497
nuclear@0	498 /* linear, algorithmic mapping, nonsequential */
nuclear@0	499 static_codebook test4={
nuclear@0	500 3,27,
nuclear@0	501 NULL,
nuclear@0	502 1,
nuclear@0	503 -533200896,1611661312,4,0,
nuclear@0	504 partial_quantlist1,
nuclear@0	505 0
nuclear@0	506 };
nuclear@0	507 static float test4_result[]={-3,-3,-3, 4,-3,-3, -1,-3,-3,
nuclear@0	508 -3, 4,-3, 4, 4,-3, -1, 4,-3,
nuclear@0	509 -3,-1,-3, 4,-1,-3, -1,-1,-3,
nuclear@0	510 -3,-3, 4, 4,-3, 4, -1,-3, 4,
nuclear@0	511 -3, 4, 4, 4, 4, 4, -1, 4, 4,
nuclear@0	512 -3,-1, 4, 4,-1, 4, -1,-1, 4,
nuclear@0	513 -3,-3,-1, 4,-3,-1, -1,-3,-1,
nuclear@0	514 -3, 4,-1, 4, 4,-1, -1, 4,-1,
nuclear@0	515 -3,-1,-1, 4,-1,-1, -1,-1,-1};
nuclear@0	516
nuclear@0	517 /* linear, algorithmic mapping, sequential */
nuclear@0	518 static_codebook test5={
nuclear@0	519 3,27,
nuclear@0	520 NULL,
nuclear@0	521 1,
nuclear@0	522 -533200896,1611661312,4,1,
nuclear@0	523 partial_quantlist1,
nuclear@0	524 0
nuclear@0	525 };
nuclear@0	526 static float test5_result[]={-3,-6,-9, 4, 1,-2, -1,-4,-7,
nuclear@0	527 -3, 1,-2, 4, 8, 5, -1, 3, 0,
nuclear@0	528 -3,-4,-7, 4, 3, 0, -1,-2,-5,
nuclear@0	529 -3,-6,-2, 4, 1, 5, -1,-4, 0,
nuclear@0	530 -3, 1, 5, 4, 8,12, -1, 3, 7,
nuclear@0	531 -3,-4, 0, 4, 3, 7, -1,-2, 2,
nuclear@0	532 -3,-6,-7, 4, 1, 0, -1,-4,-5,
nuclear@0	533 -3, 1, 0, 4, 8, 7, -1, 3, 2,
nuclear@0	534 -3,-4,-5, 4, 3, 2, -1,-2,-3};
nuclear@0	535
nuclear@0	536 void run_test(static_codebook b,float comp){
nuclear@0	537 float *out=_book_unquantize(b,b->entries,NULL);
nuclear@0	538 int i;
nuclear@0	539
nuclear@0	540 if(comp){
nuclear@0	541 if(!out){
nuclear@0	542 fprintf(stderr,"_book_unquantize incorrectly returned NULL\n");
nuclear@0	543 exit(1);
nuclear@0	544 }
nuclear@0	545
nuclear@0	546 for(i=0;i<b->entries*b->dim;i++)
nuclear@0	547 if(fabs(out[i]-comp[i])>.0001){
nuclear@0	548 fprintf(stderr,"disagreement in unquantized and reference data:\n"
nuclear@0	549 "position %d, %g != %g\n",i,out[i],comp[i]);
nuclear@0	550 exit(1);
nuclear@0	551 }
nuclear@0	552
nuclear@0	553 }else{
nuclear@0	554 if(out){
nuclear@0	555 fprintf(stderr,"_book_unquantize returned a value array: \n"
nuclear@0	556 " correct result should have been NULL\n");
nuclear@0	557 exit(1);
nuclear@0	558 }
nuclear@0	559 }
nuclear@0	560 }
nuclear@0	561
nuclear@0	562 int main(){
nuclear@0	563 /* run the nine dequant tests, and compare to the hand-rolled results */
nuclear@0	564 fprintf(stderr,"Dequant test 1... ");
nuclear@0	565 run_test(&test1,test1_result);
nuclear@0	566 fprintf(stderr,"OK\nDequant test 2... ");
nuclear@0	567 run_test(&test2,test2_result);
nuclear@0	568 fprintf(stderr,"OK\nDequant test 3... ");
nuclear@0	569 run_test(&test3,test3_result);
nuclear@0	570 fprintf(stderr,"OK\nDequant test 4... ");
nuclear@0	571 run_test(&test4,test4_result);
nuclear@0	572 fprintf(stderr,"OK\nDequant test 5... ");
nuclear@0	573 run_test(&test5,test5_result);
nuclear@0	574 fprintf(stderr,"OK\n\n");
nuclear@0	575
nuclear@0	576 return(0);
nuclear@0	577 }
nuclear@0	578
nuclear@0	579 #endif