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fix plugins using libcolors
[cinelerra_cv/ct.git] / mpeg2enc / quantize.c
blobf8a437c145ed61b97906a7b0ef3fc1a8c344e848
1 /* quantize.c, quantization / inverse quantization */
2
3 /* Copyright (C) 1996, MPEG Software Simulation Group. All Rights Reserved. */
4
5 /*
6 * Disclaimer of Warranty
7 *
8 * These software programs are available to the user without any license fee or
9 * royalty on an "as is" basis. The MPEG Software Simulation Group disclaims
10 * any and all warranties, whether express, implied, or statuary, including any
11 * implied warranties or merchantability or of fitness for a particular
12 * purpose. In no event shall the copyright-holder be liable for any
13 * incidental, punitive, or consequential damages of any kind whatsoever
14 * arising from the use of these programs.
15 *
16 * This disclaimer of warranty extends to the user of these programs and user's
17 * customers, employees, agents, transferees, successors, and assigns.
18 *
19 * The MPEG Software Simulation Group does not represent or warrant that the
20 * programs furnished hereunder are free of infringement of any third-party
21 * patents.
22 *
23 * Commercial implementations of MPEG-1 and MPEG-2 video, including shareware,
24 * are subject to royalty fees to patent holders. Many of these patents are
25 * general enough such that they are unavoidable regardless of implementation
26 * design.
27 *
28 */
29
30 #include "config.h"
31 #include <stdio.h>
32 #include <math.h>
33 #include <fenv.h>
34 #include "global.h"
35 #include "cpu_accel.h"
36 #include "simd.h"
37 #include "fastintfns.h"
38
39
40 /* Global function pointers for SIMD-dependent functions */
41 int (*pquant_non_intra)(pict_data_s *picture, int16_t *src, int16_t *dst,
42 int mquant, int *nonsat_mquant);
43 int (*pquant_weight_coeff_sum)(int16_t *blk, uint16_t*i_quant_mat );
44
45 /* Local functions pointers for SIMD-dependent functions */
46
47 static void (*piquant_non_intra_m1)(int16_t *src, int16_t *dst, uint16_t *quant_mat);
48
49
50 static int quant_weight_coeff_sum( int16_t *blk, uint16_t * i_quant_mat );
51 static void iquant_non_intra_m1(int16_t *src, int16_t *dst, uint16_t *quant_mat);
52
53
54 /*
55 Initialise quantization routines.
56 Currently just setting up MMX routines if available...
57 */
58
59 void init_quantizer_hv()
60 {
61 int flags;
62 flags = cpu_accel();
63 #ifdef X86_CPU
64 if( (flags & ACCEL_X86_MMX) != 0 ) /* MMX CPU */
65 {
66 if(verbose) fprintf( stderr, "SETTING " );
67 if( (flags & ACCEL_X86_3DNOW) != 0 )
68 {
69 if(verbose) fprintf( stderr, "3DNOW and ");
70 pquant_non_intra = quant_non_intra_hv_3dnow;
71 }
72 /*
73 * else if ( (flags & ACCEL_X86_MMXEXT) != 0 )
74 * {
75 * if(verbose) fprintf( stderr, "SSE and ");
76 * pquant_non_intra = quant_non_intra_hv_sse;
77 * }
78 */
79 else
80 {
81 pquant_non_intra = quant_non_intra_hv;
82 }
83
84 if ( (flags & ACCEL_X86_MMXEXT) != 0 )
85 {
86 if(verbose) fprintf( stderr, "EXTENDED MMX");
87 pquant_weight_coeff_sum = quant_weight_coeff_sum_mmx;
88 piquant_non_intra_m1 = iquant_non_intra_m1_sse;
89 }
90 else
91 {
92 if(verbose) fprintf( stderr, "MMX");
93 pquant_weight_coeff_sum = quant_weight_coeff_sum_mmx;
94 piquant_non_intra_m1 = iquant_non_intra_m1_mmx;
95 }
96 if(verbose) fprintf( stderr, " for QUANTIZER!\n");
97 }
98 else
99 #endif
100 {
101 pquant_non_intra = quant_non_intra_hv;
102 pquant_weight_coeff_sum = quant_weight_coeff_sum;
103 piquant_non_intra_m1 = iquant_non_intra_m1;
104 }
105 }
106
107 /*
108 *
109 * Computes the next quantisation up. Used to avoid saturation
110 * in macroblock coefficients - common in MPEG-1 - which causes
111 * nasty artefacts.
112 *
113 * NOTE: Does no range checking...
114 *
115 */
116
117
118 int next_larger_quant_hv( pict_data_s *picture, int quant )
119 {
120 if( picture->q_scale_type )
121 {
122 if( map_non_linear_mquant_hv[quant]+1 > 31 )
123 return quant;
124 else
125 return non_linear_mquant_table_hv[map_non_linear_mquant_hv[quant]+1];
126 }
127 else
128 {
129 if( quant+2 > 31 )
130 return quant;
131 else
132 return quant+2;
133 }
134
135 }
136
137 /*
138 * Quantisation for intra blocks using Test Model 5 quantization
139 *
140 * this quantizer has a bias of 1/8 stepsize towards zero
141 * (except for the DC coefficient)
142 *
143 PRECONDITION: src dst point to *disinct* memory buffers...
144 of block_count *adjact* int16_t[64] arrays...
145 *
146 * RETURN: 1 If non-zero coefficients left after quantisaiont 0 otherwise
147 */
148
149 void quant_intra_hv(
150 pict_data_s *picture,
151 int16_t *src,
152 int16_t *dst,
153 int mquant,
154 int *nonsat_mquant
155 )
156 {
157 int16_t *psrc,*pbuf;
158 int i,comp;
159 int x, y, d;
160 int clipping;
161 int clipvalue = dctsatlim;
162 uint16_t *quant_mat = intra_q_tbl[mquant] /* intra_q */;
163
164
165 /* Inspired by suggestion by Juan. Quantize a little harder if we clip...
166 */
167
168 do
169 {
170 clipping = 0;
171 pbuf = dst;
172 psrc = src;
173 for( comp = 0; comp<block_count && !clipping; ++comp )
174 {
175 x = psrc[0];
176 d = 8>>picture->dc_prec; /* intra_dc_mult */
177 pbuf[0] = (x>=0) ? (x+(d>>1))/d : -((-x+(d>>1))/d); /* round(x/d) */
178
179
180 for (i=1; i<64 ; i++)
181 {
182 x = psrc[i];
183 d = quant_mat[i];
184 /* RJ: save one divide operation */
185 y = ((abs(x) << 5)+ ((3 * quant_mat[i]) >> 2)) / (quant_mat[i] << 1);
186 if ( y > clipvalue )
187 {
188 clipping = 1;
189 mquant = next_larger_quant_hv( picture, mquant );
190 quant_mat = intra_q_tbl[mquant];
191 break;
192 }
193
194 pbuf[i] = intsamesign(x,y);
195 }
196 pbuf += 64;
197 psrc += 64;
198 }
199
200 } while( clipping );
201 *nonsat_mquant = mquant;
202 }
203
204
205 /*
206 * Quantisation matrix weighted Coefficient sum fixed-point
207 * integer with low 16 bits fractional...
208 * To be used for rate control as a measure of dct block
209 * complexity...
210 *
211 */
212
213 int quant_weight_coeff_sum( int16_t *blk, uint16_t * i_quant_mat )
214 {
215 int i;
216 int sum = 0;
217 for( i = 0; i < 64; i+=2 )
218 {
219 sum += abs((int)blk[i]) * (i_quant_mat[i]) + abs((int)blk[i+1]) * (i_quant_mat[i+1]);
220 }
221 return sum;
222 /* In case you're wondering typical average coeff_sum's for a rather
223 noisy video are around 20.0. */
224 }
225
226
227
228 /*
229 * Quantisation for non-intra blocks using Test Model 5 quantization
230 *
231 * this quantizer has a bias of 1/8 stepsize towards zero
232 * (except for the DC coefficient)
233 *
234 * A.Stevens 2000: The above comment is nonsense. Only the intra quantiser does
235 * this. This one just truncates with a modest bias of 1/(4*quant_matrix_scale)
236 * to 1.
237 *
238 * PRECONDITION: src dst point to *disinct* memory buffers...
239 * of block_count *adjacent* int16_t[64] arrays...
240 *
241 * RETURN: A bit-mask of block_count bits indicating non-zero blocks (a 1).
242 *
243 * TODO: A candidate for use of efficient abs and "intsamesign". If only gcc understood
244 * PPro conditional moves...
245 */
246
247 int quant_non_intra_hv(
248 pict_data_s *picture,
249 int16_t *src, int16_t *dst,
250 int mquant,
251 int *nonsat_mquant)
252 {
253 int i;
254 int x, y, d;
255 int nzflag;
256 int coeff_count;
257 int clipvalue = dctsatlim;
258 int flags = 0;
259 int saturated = 0;
260 uint16_t *quant_mat = inter_q_tbl[mquant]/* inter_q */;
261
262 coeff_count = 64*block_count;
263 flags = 0;
264 nzflag = 0;
265 for (i=0; i<coeff_count; ++i)
266 {
267 restart:
268 if( (i%64) == 0 )
269 {
270 nzflag = (nzflag<<1) | !!flags;
271 flags = 0;
272
273 }
274 /* RJ: save one divide operation */
275
276 x = abs( ((int)src[i]) ) /*(src[i] >= 0 ? src[i] : -src[i])*/ ;
277 d = (int)quant_mat[(i&63)];
278 /* A.Stevens 2000: Given the math of non-intra frame
279 quantisation / inverse quantisation I always though the
280 funny little foudning factor was bogus. It seems to be
281 the encoder needs less bits if you simply divide!
282 */
283
284 y = (x<<4) / (d) /* (32*x + (d>>1))/(d*2*mquant)*/ ;
285 if ( y > clipvalue )
286 {
287 if( saturated )
288 {
289 y = clipvalue;
290 }
291 else
292 {
293 int new_mquant = next_larger_quant_hv( picture, mquant );
294 if( new_mquant != mquant )
295 {
296 mquant = new_mquant;
297 quant_mat = inter_q_tbl[mquant];
298 }
299 else
300 {
301 saturated = 1;
302 }
303 i=0;
304 nzflag =0;
305 goto restart;
306 }
307 }
308 dst[i] = intsamesign(src[i], y) /* (src[i] >= 0 ? y : -y) */;
309 flags |= dst[i];
310 }
311 nzflag = (nzflag<<1) | !!flags;
312
313 *nonsat_mquant = mquant;
314 return nzflag;
315 }
316
317 /* MPEG-1 inverse quantization */
318 static void iquant1_intra(int16_t *src, int16_t *dst, int dc_prec, int mquant)
319 {
320 int i, val;
321 uint16_t *quant_mat = intra_q;
322
323 dst[0] = src[0] << (3-dc_prec);
324 for (i=1; i<64; i++)
325 {
326 val = (int)(src[i]*quant_mat[i]*mquant)/16;
327
328 /* mismatch control */
329 if ((val&1)==0 && val!=0)
330 val+= (val>0) ? -1 : 1;
331
332 /* saturation */
333 dst[i] = (val>2047) ? 2047 : ((val<-2048) ? -2048 : val);
334 }
335 }
336
337
338 /* MPEG-2 inverse quantization */
339 void iquant_intra(int16_t *src, int16_t *dst, int dc_prec, int mquant)
340 {
341 int i, val, sum;
342
343 if ( mpeg1 )
344 iquant1_intra(src,dst,dc_prec, mquant);
345 else
346 {
347 sum = dst[0] = src[0] << (3-dc_prec);
348 for (i=1; i<64; i++)
349 {
350 val = (int)(src[i]*intra_q[i]*mquant)/16;
351 sum+= dst[i] = (val>2047) ? 2047 : ((val<-2048) ? -2048 : val);
352 }
353
354 /* mismatch control */
355 if ((sum&1)==0)
356 dst[63]^= 1;
357 }
358 }
359
360
361 static void iquant_non_intra_m1(int16_t *src, int16_t *dst, uint16_t *quant_mat)
362 {
363 int i, val;
364
365 #ifndef ORIGINAL_CODE
366
367 for (i=0; i<64; i++)
368 {
369 val = src[i];
370 if (val!=0)
371 {
372 val = (int)((2*val+(val>0 ? 1 : -1))*quant_mat[i])/32;
373
374 /* mismatch control */
375 if ((val&1)==0 && val!=0)
376 val+= (val>0) ? -1 : 1;
377 }
378
379 /* saturation */
380 dst[i] = (val>2047) ? 2047 : ((val<-2048) ? -2048 : val);
381 }
382 #else
383
384 for (i=0; i<64; i++)
385 {
386 val = abs(src[i]);
387 if (val!=0)
388 {
389 val = ((val+val+1)*quant_mat[i]) >> 5;
390 /* mismatch control */
391 val -= (~(val&1))&(val!=0);
392 val = fastmin(val, 2047); /* Saturation */
393 }
394 dst[i] = intsamesign(src[i],val);
395
396 }
397
398 #endif
399 }
400
401
402
403
404 void iquant_non_intra(int16_t *src, int16_t *dst, int mquant )
405 {
406 int i, val, sum;
407 uint16_t *quant_mat;
408
409 if ( mpeg1 )
410 (*piquant_non_intra_m1)(src,dst,inter_q_tbl[mquant]);
411 else
412 {
413 sum = 0;
414 #ifdef ORIGINAL_CODE
415
416 for (i=0; i<64; i++)
417 {
418 val = src[i];
419 if (val!=0)
420
421 val = (int)((2*val+(val>0 ? 1 : -1))*inter_q[i]*mquant)/32;
422 sum+= dst[i] = (val>2047) ? 2047 : ((val<-2048) ? -2048 : val);
423 }
424 #else
425 quant_mat = inter_q_tbl[mquant];
426 for (i=0; i<64; i++)
427 {
428 val = src[i];
429 if( val != 0 )
430 {
431 val = abs(val);
432 val = (int)((val+val+1)*quant_mat[i])>>5;
433 val = intmin( val, 2047);
434 sum += val;
435 }
436 dst[i] = intsamesign(src[i],val);
437 }
438 #endif
439
440 /* mismatch control */
441 if ((sum&1)==0)
442 dst[63]^= 1;
443 }
444 }
445
446 void iquantize( pict_data_s *picture )
447 {
448 int j,k;
449 int16_t (*qblocks)[64] = picture->qblocks;
450 for (k=0; k<mb_per_pict; k++)
451 {
452 if (picture->mbinfo[k].mb_type & MB_INTRA)
453 for (j=0; j<block_count; j++)
454 iquant_intra(qblocks[k*block_count+j],
455 qblocks[k*block_count+j],
456 cur_picture.dc_prec,
457 cur_picture.mbinfo[k].mquant);
458 else
459 for (j=0;j<block_count;j++)
460 iquant_non_intra(qblocks[k*block_count+j],
461 qblocks[k*block_count+j],
462 cur_picture.mbinfo[k].mquant);
463 }
464 }
cehtehs branch of CinelerraCV