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1 /*M///////////////////////////////////////////////////////////////////////////////////////
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11 //                For Open Source Computer Vision Library
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41 #include "_cvaux.h"
42 
43 //*F///////////////////////////////////////////////////////////////////////////////////////
44 //    Name: icvImgToObs_DCT_8u32f_C1R
45 //    Purpose: The function takes as input an image and returns the sequnce of observations
46 //             to be used with an embedded HMM; Each observation is top-left block of DCT
47 //             coefficient matrix.
48 //    Context:
49 //    Parameters: img     - pointer to the original image ROI
50 //                imgStep - full row width of the image in bytes
51 //                roi     - width and height of ROI in pixels
52 //                obs     - pointer to resultant observation vectors
53 //                dctSize - size of the block for which DCT is calculated
54 //                obsSize - size of top-left block of DCT coeffs matrix, which is treated
55 //                          as observation. Each observation vector consists of
56 //                          obsSize.width * obsSize.height floats.
57 //                          The following conditions should be satisfied:
58 //                          0 < objSize.width <= dctSize.width,
59 //                          0 < objSize.height <= dctSize.height.
60 //                delta   - dctBlocks are overlapped and this parameter specifies horizontal
61 //                          and vertical shift.
62 //    Returns:
63 //      CV_NO_ERR or error code
64 //    Notes:
65 //      The algorithm is following:
66 //          1. First, number of observation vectors per row and per column are calculated:
67 //
68 //             Nx = floor((roi.width - dctSize.width + delta.width)/delta.width);
69 //             Ny = floor((roi.height - dctSize.height + delta.height)/delta.height);
70 //
71 //             So, total number of observation vectors is Nx*Ny, and total size of
72 //             array obs must be >= Nx*Ny*obsSize.width*obsSize.height*sizeof(float).
73 //          2. Observation vectors are calculated in the following loop
74 //               ( actual implementation may be different ), where
75 //               I[x1:x2,y1:y2] means block of pixels from source image with
76 //               x1 <= x < x2, y1 <= y < y2,
77 //               D[x1:x2,y1:y2] means sub matrix of DCT matrix D.
78 //               O[x,y] means observation vector that corresponds to position
79 //               (x*delta.width,y*delta.height) in the source image
80 //               ( all indices are counted from 0 ).
81 //
82 //               for( y = 0; y < Ny; y++ )
83 //               {
84 //                   for( x = 0; x < Nx; x++ )
85 //                   {
86 //                       D = DCT(I[x*delta.width : x*delta.width + dctSize.width,
87 //                                  y*delta.height : y*delta.height + dctSize.height]);
88 //                       O[x,y] = D[0:obsSize.width, 0:obsSize.height];
89 //                   }
90 //               }
91 //F*/
92 
93 /*comment out the following line to make DCT be calculated in floating-point arithmetics*/
94 //#define _CV_INT_DCT
95 
96 /* for integer DCT only */
97 #define DCT_SCALE  15
98 
99 #ifdef _CV_INT_DCT
100 typedef int work_t;
101 
102 #define  DESCALE      CV_DESCALE
103 #define  SCALE(x)     CV_FLT_TO_FIX((x),DCT_SCALE)
104 #else
105 typedef float work_t;
106 
107 #define  DESCALE(x,n) (float)(x)
108 #define  SCALE(x)     (float)(x)
109 #endif
110 
111 /* calculate dct transform matrix */
112 static void icvCalcDCTMatrix( work_t * cfs, int n );
113 
114 #define  MAX_DCT_SIZE  32
115 
116 static CvStatus CV_STDCALL
icvImgToObs_DCT_8u32f_C1R(uchar * img,int imgStep,CvSize roi,float * obs,CvSize dctSize,CvSize obsSize,CvSize delta)117 icvImgToObs_DCT_8u32f_C1R( uchar * img, int imgStep, CvSize roi,
118                            float *obs, CvSize dctSize,
119                            CvSize obsSize, CvSize delta )
120 {
121     /* dct transform matrices: horizontal and vertical */
122     work_t tab_x[MAX_DCT_SIZE * MAX_DCT_SIZE / 2 + 2];
123     work_t tab_y[MAX_DCT_SIZE * MAX_DCT_SIZE / 2 + 2];
124 
125     /* temporary buffers for dct */
126     work_t temp0[MAX_DCT_SIZE * 4];
127     work_t temp1[MAX_DCT_SIZE * 4];
128     work_t *buffer = 0;
129     work_t *buf_limit;
130 
131     double s;
132 
133     int y;
134     int Nx, Ny;
135 
136     int n1 = dctSize.height, m1 = n1 / 2;
137     int n2 = dctSize.width, m2 = n2 / 2;
138 
139     if( !img || !obs )
140         return CV_NULLPTR_ERR;
141 
142     if( roi.width <= 0 || roi.height <= 0 )
143         return CV_BADSIZE_ERR;
144 
145     if( delta.width <= 0 || delta.height <= 0 )
146         return CV_BADRANGE_ERR;
147 
148     if( obsSize.width <= 0 || dctSize.width < obsSize.width ||
149         obsSize.height <= 0 || dctSize.height < obsSize.height )
150         return CV_BADRANGE_ERR;
151 
152     if( dctSize.width > MAX_DCT_SIZE || dctSize.height > MAX_DCT_SIZE )
153         return CV_BADRANGE_ERR;
154 
155     Nx = (roi.width - dctSize.width + delta.width) / delta.width;
156     Ny = (roi.height - dctSize.height + delta.height) / delta.height;
157 
158     if( Nx <= 0 || Ny <= 0 )
159         return CV_BADRANGE_ERR;
160 
161     buffer = (work_t *)cvAlloc( roi.width * obsSize.height * sizeof( buffer[0] ));
162     if( !buffer )
163         return CV_OUTOFMEM_ERR;
164 
165     icvCalcDCTMatrix( tab_x, dctSize.width );
166     icvCalcDCTMatrix( tab_y, dctSize.height );
167 
168     buf_limit = buffer + obsSize.height * roi.width;
169 
170     for( y = 0; y < Ny; y++, img += delta.height * imgStep )
171     {
172         int x, i, j, k;
173         work_t k0 = 0;
174 
175         /* do transfroms for each column. Calc only first obsSize.height DCT coefficients */
176         for( x = 0; x < roi.width; x++ )
177         {
178             float is = 0;
179             work_t *buf = buffer + x;
180             work_t *tab = tab_y + 2;
181 
182             if( n1 & 1 )
183             {
184                 is = img[x + m1 * imgStep];
185                 k0 = ((work_t) is) * tab[-1];
186             }
187 
188             /* first coefficient */
189             for( j = 0; j < m1; j++ )
190             {
191                 float t0 = img[x + j * imgStep];
192                 float t1 = img[x + (n1 - 1 - j) * imgStep];
193                 float t2 = t0 + t1;
194 
195                 t0 -= t1;
196                 temp0[j] = (work_t) t2;
197                 is += t2;
198                 temp1[j] = (work_t) t0;
199             }
200 
201             buf[0] = DESCALE( is * tab[-2], PASS1_SHIFT );
202             if( (buf += roi.width) >= buf_limit )
203                 continue;
204 
205             /* other coefficients */
206             for( ;; )
207             {
208                 s = 0;
209 
210                 for( k = 0; k < m1; k++ )
211                     s += temp1[k] * tab[k];
212 
213                 buf[0] = DESCALE( s, PASS1_SHIFT );
214                 if( (buf += roi.width) >= buf_limit )
215                     break;
216 
217                 tab += m1;
218                 s = 0;
219 
220                 if( n1 & 1 )
221                 {
222                     k0 = -k0;
223                     s = k0;
224                 }
225                 for( k = 0; k < m1; k++ )
226                     s += temp0[k] * tab[k];
227 
228                 buf[0] = DESCALE( s, PASS1_SHIFT );
229                 tab += m1;
230 
231                 if( (buf += roi.width) >= buf_limit )
232                     break;
233             }
234         }
235 
236         k0 = 0;
237 
238         /* do transforms for rows. */
239         for( x = 0; x + dctSize.width <= roi.width; x += delta.width )
240         {
241             for( i = 0; i < obsSize.height; i++ )
242             {
243                 work_t *buf = buffer + x + roi.width * i;
244                 work_t *tab = tab_x + 2;
245                 float *obs_limit = obs + obsSize.width;
246 
247                 s = 0;
248 
249                 if( n2 & 1 )
250                 {
251                     s = buf[m2];
252                     k0 = (work_t) (s * tab[-1]);
253                 }
254 
255                 /* first coefficient */
256                 for( j = 0; j < m2; j++ )
257                 {
258                     work_t t0 = buf[j];
259                     work_t t1 = buf[n2 - 1 - j];
260                     work_t t2 = t0 + t1;
261 
262                     t0 -= t1;
263                     temp0[j] = (work_t) t2;
264                     s += t2;
265                     temp1[j] = (work_t) t0;
266                 }
267 
268                 *obs++ = (float) DESCALE( s * tab[-2], PASS2_SHIFT );
269 
270                 if( obs == obs_limit )
271                     continue;
272 
273                 /* other coefficients */
274                 for( ;; )
275                 {
276                     s = 0;
277 
278                     for( k = 0; k < m2; k++ )
279                         s += temp1[k] * tab[k];
280 
281                     obs[0] = (float) DESCALE( s, PASS2_SHIFT );
282                     if( ++obs == obs_limit )
283                         break;
284 
285                     tab += m2;
286 
287                     s = 0;
288 
289                     if( n2 & 1 )
290                     {
291                         k0 = -k0;
292                         s = k0;
293                     }
294                     for( k = 0; k < m2; k++ )
295                         s += temp0[k] * tab[k];
296                     obs[0] = (float) DESCALE( s, PASS2_SHIFT );
297 
298                     tab += m2;
299                     if( ++obs == obs_limit )
300                         break;
301                 }
302             }
303         }
304     }
305 
306     cvFree( &buffer );
307     return CV_NO_ERR;
308 }
309 
310 
311 static CvStatus CV_STDCALL
icvImgToObs_DCT_32f_C1R(float * img,int imgStep,CvSize roi,float * obs,CvSize dctSize,CvSize obsSize,CvSize delta)312 icvImgToObs_DCT_32f_C1R( float * img, int imgStep, CvSize roi,
313                          float *obs, CvSize dctSize,
314                          CvSize obsSize, CvSize delta )
315 {
316     /* dct transform matrices: horizontal and vertical */
317     work_t tab_x[MAX_DCT_SIZE * MAX_DCT_SIZE / 2 + 2];
318     work_t tab_y[MAX_DCT_SIZE * MAX_DCT_SIZE / 2 + 2];
319 
320     /* temporary buffers for dct */
321     work_t temp0[MAX_DCT_SIZE * 4];
322     work_t temp1[MAX_DCT_SIZE * 4];
323     work_t *buffer = 0;
324     work_t *buf_limit;
325 
326     double s;
327 
328     int y;
329     int Nx, Ny;
330 
331     int n1 = dctSize.height, m1 = n1 / 2;
332     int n2 = dctSize.width, m2 = n2 / 2;
333 
334     if( !img || !obs )
335         return CV_NULLPTR_ERR;
336 
337     if( roi.width <= 0 || roi.height <= 0 )
338         return CV_BADSIZE_ERR;
339 
340     if( delta.width <= 0 || delta.height <= 0 )
341         return CV_BADRANGE_ERR;
342 
343     if( obsSize.width <= 0 || dctSize.width < obsSize.width ||
344         obsSize.height <= 0 || dctSize.height < obsSize.height )
345         return CV_BADRANGE_ERR;
346 
347     if( dctSize.width > MAX_DCT_SIZE || dctSize.height > MAX_DCT_SIZE )
348         return CV_BADRANGE_ERR;
349 
350     Nx = (roi.width - dctSize.width + delta.width) / delta.width;
351     Ny = (roi.height - dctSize.height + delta.height) / delta.height;
352 
353     if( Nx <= 0 || Ny <= 0 )
354         return CV_BADRANGE_ERR;
355 
356     buffer = (work_t *)cvAlloc( roi.width * obsSize.height * sizeof( buffer[0] ));
357     if( !buffer )
358         return CV_OUTOFMEM_ERR;
359 
360     icvCalcDCTMatrix( tab_x, dctSize.width );
361     icvCalcDCTMatrix( tab_y, dctSize.height );
362 
363     buf_limit = buffer + obsSize.height * roi.width;
364 
365     imgStep /= sizeof(img[0]);
366 
367     for( y = 0; y < Ny; y++, img += delta.height * imgStep )
368     {
369         int x, i, j, k;
370         work_t k0 = 0;
371 
372         /* do transfroms for each column. Calc only first obsSize.height DCT coefficients */
373         for( x = 0; x < roi.width; x++ )
374         {
375             float is = 0;
376             work_t *buf = buffer + x;
377             work_t *tab = tab_y + 2;
378 
379             if( n1 & 1 )
380             {
381                 is = img[x + m1 * imgStep];
382                 k0 = ((work_t) is) * tab[-1];
383             }
384 
385             /* first coefficient */
386             for( j = 0; j < m1; j++ )
387             {
388                 float t0 = img[x + j * imgStep];
389                 float t1 = img[x + (n1 - 1 - j) * imgStep];
390                 float t2 = t0 + t1;
391 
392                 t0 -= t1;
393                 temp0[j] = (work_t) t2;
394                 is += t2;
395                 temp1[j] = (work_t) t0;
396             }
397 
398             buf[0] = DESCALE( is * tab[-2], PASS1_SHIFT );
399             if( (buf += roi.width) >= buf_limit )
400                 continue;
401 
402             /* other coefficients */
403             for( ;; )
404             {
405                 s = 0;
406 
407                 for( k = 0; k < m1; k++ )
408                     s += temp1[k] * tab[k];
409 
410                 buf[0] = DESCALE( s, PASS1_SHIFT );
411                 if( (buf += roi.width) >= buf_limit )
412                     break;
413 
414                 tab += m1;
415                 s = 0;
416 
417                 if( n1 & 1 )
418                 {
419                     k0 = -k0;
420                     s = k0;
421                 }
422                 for( k = 0; k < m1; k++ )
423                     s += temp0[k] * tab[k];
424 
425                 buf[0] = DESCALE( s, PASS1_SHIFT );
426                 tab += m1;
427 
428                 if( (buf += roi.width) >= buf_limit )
429                     break;
430             }
431         }
432 
433         k0 = 0;
434 
435         /* do transforms for rows. */
436         for( x = 0; x + dctSize.width <= roi.width; x += delta.width )
437         {
438             for( i = 0; i < obsSize.height; i++ )
439             {
440                 work_t *buf = buffer + x + roi.width * i;
441                 work_t *tab = tab_x + 2;
442                 float *obs_limit = obs + obsSize.width;
443 
444                 s = 0;
445 
446                 if( n2 & 1 )
447                 {
448                     s = buf[m2];
449                     k0 = (work_t) (s * tab[-1]);
450                 }
451 
452                 /* first coefficient */
453                 for( j = 0; j < m2; j++ )
454                 {
455                     work_t t0 = buf[j];
456                     work_t t1 = buf[n2 - 1 - j];
457                     work_t t2 = t0 + t1;
458 
459                     t0 -= t1;
460                     temp0[j] = (work_t) t2;
461                     s += t2;
462                     temp1[j] = (work_t) t0;
463                 }
464 
465                 *obs++ = (float) DESCALE( s * tab[-2], PASS2_SHIFT );
466 
467                 if( obs == obs_limit )
468                     continue;
469 
470                 /* other coefficients */
471                 for( ;; )
472                 {
473                     s = 0;
474 
475                     for( k = 0; k < m2; k++ )
476                         s += temp1[k] * tab[k];
477 
478                     obs[0] = (float) DESCALE( s, PASS2_SHIFT );
479                     if( ++obs == obs_limit )
480                         break;
481 
482                     tab += m2;
483 
484                     s = 0;
485 
486                     if( n2 & 1 )
487                     {
488                         k0 = -k0;
489                         s = k0;
490                     }
491                     for( k = 0; k < m2; k++ )
492                         s += temp0[k] * tab[k];
493                     obs[0] = (float) DESCALE( s, PASS2_SHIFT );
494 
495                     tab += m2;
496                     if( ++obs == obs_limit )
497                         break;
498                 }
499             }
500         }
501     }
502 
503     cvFree( &buffer );
504     return CV_NO_ERR;
505 }
506 
507 
508 static void
icvCalcDCTMatrix(work_t * cfs,int n)509 icvCalcDCTMatrix( work_t * cfs, int n )
510 {
511     static const double sqrt2 = 1.4142135623730950488016887242097;
512     static const double pi = 3.1415926535897932384626433832795;
513 
514     static const double sincos[16 * 2] = {
515         1.00000000000000000, 0.00000000000000006,
516         0.70710678118654746, 0.70710678118654757,
517         0.49999999999999994, 0.86602540378443871,
518         0.38268343236508978, 0.92387953251128674,
519         0.30901699437494740, 0.95105651629515353,
520         0.25881904510252074, 0.96592582628906831,
521         0.22252093395631439, 0.97492791218182362,
522         0.19509032201612825, 0.98078528040323043,
523         0.17364817766693033, 0.98480775301220802,
524         0.15643446504023087, 0.98768834059513777,
525         0.14231483827328514, 0.98982144188093268,
526         0.13052619222005157, 0.99144486137381038,
527         0.12053668025532305, 0.99270887409805397,
528         0.11196447610330786, 0.99371220989324260,
529         0.10452846326765346, 0.99452189536827329,
530         0.09801714032956060, 0.99518472667219693,
531     };
532 
533 #define ROTATE( c, s, dc, ds ) \
534     {                              \
535         t = c*dc - s*ds;           \
536         s = c*ds + s*dc;           \
537         c = t;                     \
538     }
539 
540 #define WRITE2( j, a, b ) \
541     {                         \
542         cfs[j]   = SCALE(a);  \
543         cfs2[j]  = SCALE(b);  \
544     }
545 
546     double t, scale = 1. / sqrt( (double)n );
547     int i, j, m = n / 2;
548 
549     cfs[0] = SCALE( scale );
550     scale *= sqrt2;
551     cfs[1] = SCALE( scale );
552     cfs += 2 - m;
553 
554     if( n > 1 )
555     {
556         double a0, b0;
557         double da0, db0;
558         work_t *cfs2 = cfs + m * n;
559 
560         if( n <= 16 )
561         {
562             da0 = a0 = sincos[2 * n - 1];
563             db0 = b0 = sincos[2 * n - 2];
564         }
565         else
566         {
567             t = pi / (2 * n);
568             da0 = a0 = cos( t );
569             db0 = b0 = sin( t );
570         }
571 
572         /* other rows */
573         for( i = 1; i <= m; i++ )
574         {
575             double a = a0 * scale;
576             double b = b0 * scale;
577             double da = a0 * a0 - b0 * b0;
578             double db = a0 * b0 + a0 * b0;
579 
580             cfs += m;
581             cfs2 -= m;
582 
583             for( j = 0; j < m; j += 2 )
584             {
585                 WRITE2( j, a, b );
586                 ROTATE( a, b, da, db );
587                 if( j + 1 < m )
588                 {
589                     WRITE2( j + 1, a, -b );
590                     ROTATE( a, b, da, db );
591                 }
592             }
593 
594             ROTATE( a0, b0, da0, db0 );
595         }
596     }
597 #undef ROTATE
598 #undef WRITE2
599 }
600 
601 
602 CV_IMPL void
cvImgToObs_DCT(const void * arr,float * obs,CvSize dctSize,CvSize obsSize,CvSize delta)603 cvImgToObs_DCT( const void* arr, float *obs, CvSize dctSize,
604                 CvSize obsSize, CvSize delta )
605 {
606     CV_FUNCNAME( "cvImgToObs_DCT" );
607 
608     __BEGIN__;
609 
610     CvMat stub, *mat = (CvMat*)arr;
611 
612     CV_CALL( mat = cvGetMat( arr, &stub ));
613 
614     switch( CV_MAT_TYPE( mat->type ))
615     {
616     case CV_8UC1:
617         IPPI_CALL( icvImgToObs_DCT_8u32f_C1R( mat->data.ptr, mat->step,
618                                            cvGetMatSize(mat), obs,
619                                            dctSize, obsSize, delta ));
620         break;
621     case CV_32FC1:
622         IPPI_CALL( icvImgToObs_DCT_32f_C1R( mat->data.fl, mat->step,
623                                            cvGetMatSize(mat), obs,
624                                            dctSize, obsSize, delta ));
625         break;
626     default:
627         CV_ERROR( CV_StsUnsupportedFormat, "" );
628     }
629 
630     __END__;
631 }
632 
633 
634 /* End of file. */
635