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41 
42 #ifndef _CXCORE_TYPES_H_
43 #define _CXCORE_TYPES_H_
44 
45 #if !defined _CRT_SECURE_NO_DEPRECATE && _MSC_VER > 1300
46 #define _CRT_SECURE_NO_DEPRECATE /* to avoid multiple Visual Studio 2005 warnings */
47 #endif
48 
49 #ifndef SKIP_INCLUDES
50   #include <assert.h>
51   #include <stdlib.h>
52   #include <string.h>
53   #include <float.h>
54 
55   #if defined __ICL
56     #define CV_ICC   __ICL
57   #elif defined __ICC
58     #define CV_ICC   __ICC
59   #elif defined __ECL
60     #define CV_ICC   __ECL
61   #elif defined __ECC
62     #define CV_ICC   __ECC
63   #endif
64 
65   #if defined WIN32 && (!defined WIN64 || defined EM64T) && \
66       (_MSC_VER >= 1400 || defined CV_ICC) \
67       || (defined __SSE2__ && defined __GNUC__ && __GNUC__ >= 4)
68     #include <emmintrin.h>
69     #define CV_SSE2 1
70   #else
71     #define CV_SSE2 0
72   #endif
73 
74   #if defined __BORLANDC__
75     #include <fastmath.h>
76   #elif defined WIN64 && !defined EM64T && defined CV_ICC
77     #include <mathimf.h>
78   #else
79     #include <math.h>
80   #endif
81 
82   #ifdef HAVE_IPL
83       #ifndef __IPL_H__
84           #if defined WIN32 || defined WIN64
85               #include <ipl.h>
86           #else
87               #include <ipl/ipl.h>
88           #endif
89       #endif
90   #elif defined __IPL_H__
91       #define HAVE_IPL
92   #endif
93 #endif // SKIP_INCLUDES
94 
95 #if defined WIN32 || defined WIN64
96     #define CV_CDECL __cdecl
97     #define CV_STDCALL __stdcall
98 #else
99     #define CV_CDECL
100     #define CV_STDCALL
101 #endif
102 
103 #ifndef CV_EXTERN_C
104     #ifdef __cplusplus
105         #define CV_EXTERN_C extern "C"
106         #define CV_DEFAULT(val) = val
107     #else
108         #define CV_EXTERN_C
109         #define CV_DEFAULT(val)
110     #endif
111 #endif
112 
113 #ifndef CV_EXTERN_C_FUNCPTR
114     #ifdef __cplusplus
115         #define CV_EXTERN_C_FUNCPTR(x) extern "C" { typedef x; }
116     #else
117         #define CV_EXTERN_C_FUNCPTR(x) typedef x
118     #endif
119 #endif
120 
121 #ifndef CV_INLINE
122 #if defined __cplusplus
123     #define CV_INLINE inline
124 #elif (defined WIN32 || defined WIN64) && !defined __GNUC__
125     #define CV_INLINE __inline
126 #else
127     #define CV_INLINE static
128 #endif
129 #endif /* CV_INLINE */
130 
131 #if (defined WIN32 || defined WIN64) && defined CVAPI_EXPORTS
132     #define CV_EXPORTS __declspec(dllexport)
133 #else
134     #define CV_EXPORTS
135 #endif
136 
137 #ifndef CVAPI
138     #define CVAPI(rettype) CV_EXTERN_C CV_EXPORTS rettype CV_CDECL
139 #endif
140 
141 #if defined _MSC_VER || defined __BORLANDC__
142 typedef __int64 int64;
143 typedef unsigned __int64 uint64;
144 #else
145 typedef long long int64;
146 typedef unsigned long long uint64;
147 #endif
148 
149 #ifndef HAVE_IPL
150 typedef unsigned char uchar;
151 typedef unsigned short ushort;
152 #endif
153 
154 typedef signed char schar;
155 
156 /* CvArr* is used to pass arbitrary
157  * array-like data structures
158  * into functions where the particular
159  * array type is recognized at runtime:
160  */
161 typedef void CvArr;
162 
163 typedef union Cv32suf
164 {
165     int i;
166     unsigned u;
167     float f;
168 }
169 Cv32suf;
170 
171 typedef union Cv64suf
172 {
173     int64 i;
174     uint64 u;
175     double f;
176 }
177 Cv64suf;
178 
179 /****************************************************************************************\
180 *                             Common macros and inline functions                         *
181 \****************************************************************************************/
182 
183 #define CV_PI   3.1415926535897932384626433832795
184 #define CV_LOG2 0.69314718055994530941723212145818
185 
186 #define CV_SWAP(a,b,t) ((t) = (a), (a) = (b), (b) = (t))
187 
188 #ifndef MIN
189 #define MIN(a,b)  ((a) > (b) ? (b) : (a))
190 #endif
191 
192 #ifndef MAX
193 #define MAX(a,b)  ((a) < (b) ? (b) : (a))
194 #endif
195 
196 /* min & max without jumps */
197 #define  CV_IMIN(a, b)  ((a) ^ (((a)^(b)) & (((a) < (b)) - 1)))
198 
199 #define  CV_IMAX(a, b)  ((a) ^ (((a)^(b)) & (((a) > (b)) - 1)))
200 
201 /* absolute value without jumps */
202 #ifndef __cplusplus
203 #define  CV_IABS(a)     (((a) ^ ((a) < 0 ? -1 : 0)) - ((a) < 0 ? -1 : 0))
204 #else
205 #define  CV_IABS(a)     abs(a)
206 #endif
207 #define  CV_CMP(a,b)    (((a) > (b)) - ((a) < (b)))
208 #define  CV_SIGN(a)     CV_CMP((a),0)
209 
cvRound(double value)210 CV_INLINE  int  cvRound( double value )
211 {
212 #if CV_SSE2
213     __m128d t = _mm_load_sd( &value );
214     return _mm_cvtsd_si32(t);
215 #elif defined WIN32 && !defined WIN64 && defined _MSC_VER
216     int t;
217     __asm
218     {
219         fld value;
220         fistp t;
221     }
222     return t;
223 #elif (defined HAVE_LRINT) || (defined WIN64 && !defined EM64T && defined CV_ICC)
224     return (int)lrint(value);
225 #else
226     /*
227      the algorithm was taken from Agner Fog's optimization guide
228      at http://www.agner.org/assem
229      */
230     Cv64suf temp;
231     temp.f = value + 6755399441055744.0;
232     return (int)temp.u;
233 #endif
234 }
235 
236 
cvFloor(double value)237 CV_INLINE  int  cvFloor( double value )
238 {
239 #if CV_SSE2
240     __m128d t = _mm_load_sd( &value );
241     int i = _mm_cvtsd_si32(t);
242     return i - _mm_movemask_pd(_mm_cmplt_sd(t,_mm_cvtsi32_sd(t,i)));
243 #else
244     int temp = cvRound(value);
245     Cv32suf diff;
246     diff.f = (float)(value - temp);
247     return temp - (diff.i < 0);
248 #endif
249 }
250 
251 
cvCeil(double value)252 CV_INLINE  int  cvCeil( double value )
253 {
254 #if CV_SSE2
255     __m128d t = _mm_load_sd( &value );
256     int i = _mm_cvtsd_si32(t);
257     return i + _mm_movemask_pd(_mm_cmplt_sd(_mm_cvtsi32_sd(t,i),t));
258 #else
259     int temp = cvRound(value);
260     Cv32suf diff;
261     diff.f = (float)(temp - value);
262     return temp + (diff.i < 0);
263 #endif
264 }
265 
266 #define cvInvSqrt(value) ((float)(1./sqrt(value)))
267 #define cvSqrt(value)  ((float)sqrt(value))
268 
cvIsNaN(double value)269 CV_INLINE int cvIsNaN( double value )
270 {
271 #if 1/*defined _MSC_VER || defined __BORLANDC__
272     return _isnan(value);
273 #elif defined __GNUC__
274     return isnan(value);
275 #else*/
276     Cv64suf ieee754;
277     ieee754.f = value;
278     return ((unsigned)(ieee754.u >> 32) & 0x7fffffff) +
279            ((unsigned)ieee754.u != 0) > 0x7ff00000;
280 #endif
281 }
282 
283 
cvIsInf(double value)284 CV_INLINE int cvIsInf( double value )
285 {
286 #if 1/*defined _MSC_VER || defined __BORLANDC__
287     return !_finite(value);
288 #elif defined __GNUC__
289     return isinf(value);
290 #else*/
291     Cv64suf ieee754;
292     ieee754.f = value;
293     return ((unsigned)(ieee754.u >> 32) & 0x7fffffff) == 0x7ff00000 &&
294            (unsigned)ieee754.u == 0;
295 #endif
296 }
297 
298 
299 /*************** Random number generation *******************/
300 
301 typedef uint64 CvRNG;
302 
303 CV_INLINE CvRNG cvRNG( int64 seed CV_DEFAULT(-1))
304 {
305     CvRNG rng = seed ? (uint64)seed : (uint64)(int64)-1;
306     return rng;
307 }
308 
309 /* Return random 32-bit unsigned integer: */
cvRandInt(CvRNG * rng)310 CV_INLINE unsigned cvRandInt( CvRNG* rng )
311 {
312     uint64 temp = *rng;
313     temp = (uint64)(unsigned)temp*1554115554 + (temp >> 32);
314     *rng = temp;
315     return (unsigned)temp;
316 }
317 
318 /* Returns random floating-point number between 0 and 1: */
cvRandReal(CvRNG * rng)319 CV_INLINE double cvRandReal( CvRNG* rng )
320 {
321     return cvRandInt(rng)*2.3283064365386962890625e-10 /* 2^-32 */;
322 }
323 
324 /****************************************************************************************\
325 *                                  Image type (IplImage)                                 *
326 \****************************************************************************************/
327 
328 #ifndef HAVE_IPL
329 
330 /*
331  * The following definitions (until #endif)
332  * is an extract from IPL headers.
333  * Copyright (c) 1995 Intel Corporation.
334  */
335 #define IPL_DEPTH_SIGN 0x80000000
336 
337 #define IPL_DEPTH_1U     1
338 #define IPL_DEPTH_8U     8
339 #define IPL_DEPTH_16U   16
340 #define IPL_DEPTH_32F   32
341 
342 #define IPL_DEPTH_8S  (IPL_DEPTH_SIGN| 8)
343 #define IPL_DEPTH_16S (IPL_DEPTH_SIGN|16)
344 #define IPL_DEPTH_32S (IPL_DEPTH_SIGN|32)
345 
346 #define IPL_DATA_ORDER_PIXEL  0
347 #define IPL_DATA_ORDER_PLANE  1
348 
349 #define IPL_ORIGIN_TL 0
350 #define IPL_ORIGIN_BL 1
351 
352 #define IPL_ALIGN_4BYTES   4
353 #define IPL_ALIGN_8BYTES   8
354 #define IPL_ALIGN_16BYTES 16
355 #define IPL_ALIGN_32BYTES 32
356 
357 #define IPL_ALIGN_DWORD   IPL_ALIGN_4BYTES
358 #define IPL_ALIGN_QWORD   IPL_ALIGN_8BYTES
359 
360 #define IPL_BORDER_CONSTANT   0
361 #define IPL_BORDER_REPLICATE  1
362 #define IPL_BORDER_REFLECT    2
363 #define IPL_BORDER_WRAP       3
364 
365 typedef struct _IplImage
366 {
367     int  nSize;             /* sizeof(IplImage) */
368     int  ID;                /* version (=0)*/
369     int  nChannels;         /* Most of OpenCV functions support 1,2,3 or 4 channels */
370     int  alphaChannel;      /* Ignored by OpenCV */
371     int  depth;             /* Pixel depth in bits: IPL_DEPTH_8U, IPL_DEPTH_8S, IPL_DEPTH_16S,
372                                IPL_DEPTH_32S, IPL_DEPTH_32F and IPL_DEPTH_64F are supported.  */
373     char colorModel[4];     /* Ignored by OpenCV */
374     char channelSeq[4];     /* ditto */
375     int  dataOrder;         /* 0 - interleaved color channels, 1 - separate color channels.
376                                cvCreateImage can only create interleaved images */
377     int  origin;            /* 0 - top-left origin,
378                                1 - bottom-left origin (Windows bitmaps style).  */
379     int  align;             /* Alignment of image rows (4 or 8).
380                                OpenCV ignores it and uses widthStep instead.    */
381     int  width;             /* Image width in pixels.                           */
382     int  height;            /* Image height in pixels.                          */
383     struct _IplROI *roi;    /* Image ROI. If NULL, the whole image is selected. */
384     struct _IplImage *maskROI;      /* Must be NULL. */
385     void  *imageId;                 /* "           " */
386     struct _IplTileInfo *tileInfo;  /* "           " */
387     int  imageSize;         /* Image data size in bytes
388                                (==image->height*image->widthStep
389                                in case of interleaved data)*/
390     char *imageData;        /* Pointer to aligned image data.         */
391     int  widthStep;         /* Size of aligned image row in bytes.    */
392     int  BorderMode[4];     /* Ignored by OpenCV.                     */
393     int  BorderConst[4];    /* Ditto.                                 */
394     char *imageDataOrigin;  /* Pointer to very origin of image data
395                                (not necessarily aligned) -
396                                needed for correct deallocation */
397 }
398 IplImage;
399 
400 typedef struct _IplTileInfo IplTileInfo;
401 
402 typedef struct _IplROI
403 {
404     int  coi; /* 0 - no COI (all channels are selected), 1 - 0th channel is selected ...*/
405     int  xOffset;
406     int  yOffset;
407     int  width;
408     int  height;
409 }
410 IplROI;
411 
412 typedef struct _IplConvKernel
413 {
414     int  nCols;
415     int  nRows;
416     int  anchorX;
417     int  anchorY;
418     int *values;
419     int  nShiftR;
420 }
421 IplConvKernel;
422 
423 typedef struct _IplConvKernelFP
424 {
425     int  nCols;
426     int  nRows;
427     int  anchorX;
428     int  anchorY;
429     float *values;
430 }
431 IplConvKernelFP;
432 
433 #define IPL_IMAGE_HEADER 1
434 #define IPL_IMAGE_DATA   2
435 #define IPL_IMAGE_ROI    4
436 
437 #endif/*HAVE_IPL*/
438 
439 /* extra border mode */
440 #define IPL_BORDER_REFLECT_101    4
441 
442 #define IPL_IMAGE_MAGIC_VAL  ((int)sizeof(IplImage))
443 #define CV_TYPE_NAME_IMAGE "opencv-image"
444 
445 #define CV_IS_IMAGE_HDR(img) \
446     ((img) != NULL && ((const IplImage*)(img))->nSize == sizeof(IplImage))
447 
448 #define CV_IS_IMAGE(img) \
449     (CV_IS_IMAGE_HDR(img) && ((IplImage*)img)->imageData != NULL)
450 
451 /* for storing double-precision
452    floating point data in IplImage's */
453 #define IPL_DEPTH_64F  64
454 
455 /* get reference to pixel at (col,row),
456    for multi-channel images (col) should be multiplied by number of channels */
457 #define CV_IMAGE_ELEM( image, elemtype, row, col )       \
458     (((elemtype*)((image)->imageData + (image)->widthStep*(row)))[(col)])
459 
460 /****************************************************************************************\
461 *                                  Matrix type (CvMat)                                   *
462 \****************************************************************************************/
463 
464 #define CV_CN_MAX     64
465 #define CV_CN_SHIFT   3
466 #define CV_DEPTH_MAX  (1 << CV_CN_SHIFT)
467 
468 #define CV_8U   0
469 #define CV_8S   1
470 #define CV_16U  2
471 #define CV_16S  3
472 #define CV_32S  4
473 #define CV_32F  5
474 #define CV_64F  6
475 #define CV_USRTYPE1 7
476 
477 #define CV_MAKETYPE(depth,cn) ((depth) + (((cn)-1) << CV_CN_SHIFT))
478 #define CV_MAKE_TYPE CV_MAKETYPE
479 
480 #define CV_8UC1 CV_MAKETYPE(CV_8U,1)
481 #define CV_8UC2 CV_MAKETYPE(CV_8U,2)
482 #define CV_8UC3 CV_MAKETYPE(CV_8U,3)
483 #define CV_8UC4 CV_MAKETYPE(CV_8U,4)
484 #define CV_8UC(n) CV_MAKETYPE(CV_8U,(n))
485 
486 #define CV_8SC1 CV_MAKETYPE(CV_8S,1)
487 #define CV_8SC2 CV_MAKETYPE(CV_8S,2)
488 #define CV_8SC3 CV_MAKETYPE(CV_8S,3)
489 #define CV_8SC4 CV_MAKETYPE(CV_8S,4)
490 #define CV_8SC(n) CV_MAKETYPE(CV_8S,(n))
491 
492 #define CV_16UC1 CV_MAKETYPE(CV_16U,1)
493 #define CV_16UC2 CV_MAKETYPE(CV_16U,2)
494 #define CV_16UC3 CV_MAKETYPE(CV_16U,3)
495 #define CV_16UC4 CV_MAKETYPE(CV_16U,4)
496 #define CV_16UC(n) CV_MAKETYPE(CV_16U,(n))
497 
498 #define CV_16SC1 CV_MAKETYPE(CV_16S,1)
499 #define CV_16SC2 CV_MAKETYPE(CV_16S,2)
500 #define CV_16SC3 CV_MAKETYPE(CV_16S,3)
501 #define CV_16SC4 CV_MAKETYPE(CV_16S,4)
502 #define CV_16SC(n) CV_MAKETYPE(CV_16S,(n))
503 
504 #define CV_32SC1 CV_MAKETYPE(CV_32S,1)
505 #define CV_32SC2 CV_MAKETYPE(CV_32S,2)
506 #define CV_32SC3 CV_MAKETYPE(CV_32S,3)
507 #define CV_32SC4 CV_MAKETYPE(CV_32S,4)
508 #define CV_32SC(n) CV_MAKETYPE(CV_32S,(n))
509 
510 #define CV_32FC1 CV_MAKETYPE(CV_32F,1)
511 #define CV_32FC2 CV_MAKETYPE(CV_32F,2)
512 #define CV_32FC3 CV_MAKETYPE(CV_32F,3)
513 #define CV_32FC4 CV_MAKETYPE(CV_32F,4)
514 #define CV_32FC(n) CV_MAKETYPE(CV_32F,(n))
515 
516 #define CV_64FC1 CV_MAKETYPE(CV_64F,1)
517 #define CV_64FC2 CV_MAKETYPE(CV_64F,2)
518 #define CV_64FC3 CV_MAKETYPE(CV_64F,3)
519 #define CV_64FC4 CV_MAKETYPE(CV_64F,4)
520 #define CV_64FC(n) CV_MAKETYPE(CV_64F,(n))
521 
522 #define CV_AUTO_STEP  0x7fffffff
523 #define CV_WHOLE_ARR  cvSlice( 0, 0x3fffffff )
524 
525 #define CV_MAT_CN_MASK          ((CV_CN_MAX - 1) << CV_CN_SHIFT)
526 #define CV_MAT_CN(flags)        ((((flags) & CV_MAT_CN_MASK) >> CV_CN_SHIFT) + 1)
527 #define CV_MAT_DEPTH_MASK       (CV_DEPTH_MAX - 1)
528 #define CV_MAT_DEPTH(flags)     ((flags) & CV_MAT_DEPTH_MASK)
529 #define CV_MAT_TYPE_MASK        (CV_DEPTH_MAX*CV_CN_MAX - 1)
530 #define CV_MAT_TYPE(flags)      ((flags) & CV_MAT_TYPE_MASK)
531 #define CV_MAT_CONT_FLAG_SHIFT  14
532 #define CV_MAT_CONT_FLAG        (1 << CV_MAT_CONT_FLAG_SHIFT)
533 #define CV_IS_MAT_CONT(flags)   ((flags) & CV_MAT_CONT_FLAG)
534 #define CV_IS_CONT_MAT          CV_IS_MAT_CONT
535 #define CV_MAT_TEMP_FLAG_SHIFT  15
536 #define CV_MAT_TEMP_FLAG        (1 << CV_MAT_TEMP_FLAG_SHIFT)
537 #define CV_IS_TEMP_MAT(flags)   ((flags) & CV_MAT_TEMP_FLAG)
538 
539 #define CV_MAGIC_MASK       0xFFFF0000
540 #define CV_MAT_MAGIC_VAL    0x42420000
541 #define CV_TYPE_NAME_MAT    "opencv-matrix"
542 
543 typedef struct CvMat
544 {
545     int type;
546     int step;
547 
548     /* for internal use only */
549     int* refcount;
550     int hdr_refcount;
551 
552     union
553     {
554         uchar* ptr;
555         short* s;
556         int* i;
557         float* fl;
558         double* db;
559     } data;
560 
561 #ifdef __cplusplus
562     union
563     {
564         int rows;
565         int height;
566     };
567 
568     union
569     {
570         int cols;
571         int width;
572     };
573 #else
574     int rows;
575     int cols;
576 #endif
577 
578 }
579 CvMat;
580 
581 
582 #define CV_IS_MAT_HDR(mat) \
583     ((mat) != NULL && \
584     (((const CvMat*)(mat))->type & CV_MAGIC_MASK) == CV_MAT_MAGIC_VAL && \
585     ((const CvMat*)(mat))->cols > 0 && ((const CvMat*)(mat))->rows > 0)
586 
587 #define CV_IS_MAT(mat) \
588     (CV_IS_MAT_HDR(mat) && ((const CvMat*)(mat))->data.ptr != NULL)
589 
590 #define CV_IS_MASK_ARR(mat) \
591     (((mat)->type & (CV_MAT_TYPE_MASK & ~CV_8SC1)) == 0)
592 
593 #define CV_ARE_TYPES_EQ(mat1, mat2) \
594     ((((mat1)->type ^ (mat2)->type) & CV_MAT_TYPE_MASK) == 0)
595 
596 #define CV_ARE_CNS_EQ(mat1, mat2) \
597     ((((mat1)->type ^ (mat2)->type) & CV_MAT_CN_MASK) == 0)
598 
599 #define CV_ARE_DEPTHS_EQ(mat1, mat2) \
600     ((((mat1)->type ^ (mat2)->type) & CV_MAT_DEPTH_MASK) == 0)
601 
602 #define CV_ARE_SIZES_EQ(mat1, mat2) \
603     ((mat1)->rows == (mat2)->rows && (mat1)->cols == (mat2)->cols)
604 
605 #define CV_IS_MAT_CONST(mat)  \
606     (((mat)->rows|(mat)->cols) == 1)
607 
608 /* Size of each channel item,
609    0x124489 = 1000 0100 0100 0010 0010 0001 0001 ~ array of sizeof(arr_type_elem) */
610 #define CV_ELEM_SIZE1(type) \
611     ((((sizeof(size_t)<<28)|0x8442211) >> CV_MAT_DEPTH(type)*4) & 15)
612 
613 /* 0x3a50 = 11 10 10 01 01 00 00 ~ array of log2(sizeof(arr_type_elem)) */
614 #define CV_ELEM_SIZE(type) \
615     (CV_MAT_CN(type) << ((((sizeof(size_t)/4+1)*16384|0x3a50) >> CV_MAT_DEPTH(type)*2) & 3))
616 
617 /* Inline constructor. No data is allocated internally!!!
618  * (Use together with cvCreateData, or use cvCreateMat instead to
619  * get a matrix with allocated data):
620  */
cvMat(int rows,int cols,int type,void * data CV_DEFAULT (NULL))621 CV_INLINE CvMat cvMat( int rows, int cols, int type, void* data CV_DEFAULT(NULL))
622 {
623     CvMat m;
624 
625     assert( (unsigned)CV_MAT_DEPTH(type) <= CV_64F );
626     type = CV_MAT_TYPE(type);
627     m.type = CV_MAT_MAGIC_VAL | CV_MAT_CONT_FLAG | type;
628     m.cols = cols;
629     m.rows = rows;
630     m.step = rows > 1 ? m.cols*CV_ELEM_SIZE(type) : 0;
631     m.data.ptr = (uchar*)data;
632     m.refcount = NULL;
633     m.hdr_refcount = 0;
634 
635     return m;
636 }
637 
638 
639 #define CV_MAT_ELEM_PTR_FAST( mat, row, col, pix_size )  \
640     (assert( (unsigned)(row) < (unsigned)(mat).rows &&   \
641              (unsigned)(col) < (unsigned)(mat).cols ),   \
642      (mat).data.ptr + (size_t)(mat).step*(row) + (pix_size)*(col))
643 
644 #define CV_MAT_ELEM_PTR( mat, row, col )                 \
645     CV_MAT_ELEM_PTR_FAST( mat, row, col, CV_ELEM_SIZE((mat).type) )
646 
647 #define CV_MAT_ELEM( mat, elemtype, row, col )           \
648     (*(elemtype*)CV_MAT_ELEM_PTR_FAST( mat, row, col, sizeof(elemtype)))
649 
650 
cvmGet(const CvMat * mat,int row,int col)651 CV_INLINE  double  cvmGet( const CvMat* mat, int row, int col )
652 {
653     int type;
654 
655     type = CV_MAT_TYPE(mat->type);
656     assert( (unsigned)row < (unsigned)mat->rows &&
657             (unsigned)col < (unsigned)mat->cols );
658 
659     if( type == CV_32FC1 )
660         return ((float*)(mat->data.ptr + (size_t)mat->step*row))[col];
661     else
662     {
663         assert( type == CV_64FC1 );
664         return ((double*)(mat->data.ptr + (size_t)mat->step*row))[col];
665     }
666 }
667 
668 
cvmSet(CvMat * mat,int row,int col,double value)669 CV_INLINE  void  cvmSet( CvMat* mat, int row, int col, double value )
670 {
671     int type;
672     type = CV_MAT_TYPE(mat->type);
673     assert( (unsigned)row < (unsigned)mat->rows &&
674             (unsigned)col < (unsigned)mat->cols );
675 
676     if( type == CV_32FC1 )
677         ((float*)(mat->data.ptr + (size_t)mat->step*row))[col] = (float)value;
678     else
679     {
680         assert( type == CV_64FC1 );
681         ((double*)(mat->data.ptr + (size_t)mat->step*row))[col] = (double)value;
682     }
683 }
684 
685 
cvCvToIplDepth(int type)686 CV_INLINE int cvCvToIplDepth( int type )
687 {
688     int depth = CV_MAT_DEPTH(type);
689     return CV_ELEM_SIZE1(depth)*8 | (depth == CV_8S || depth == CV_16S ||
690            depth == CV_32S ? IPL_DEPTH_SIGN : 0);
691 }
692 
693 
694 /****************************************************************************************\
695 *                       Multi-dimensional dense array (CvMatND)                          *
696 \****************************************************************************************/
697 
698 #define CV_MATND_MAGIC_VAL    0x42430000
699 #define CV_TYPE_NAME_MATND    "opencv-nd-matrix"
700 
701 #define CV_MAX_DIM            32
702 #define CV_MAX_DIM_HEAP       (1 << 16)
703 
704 typedef struct CvMatND
705 {
706     int type;
707     int dims;
708 
709     int* refcount;
710     int hdr_refcount;
711 
712     union
713     {
714         uchar* ptr;
715         float* fl;
716         double* db;
717         int* i;
718         short* s;
719     } data;
720 
721     struct
722     {
723         int size;
724         int step;
725     }
726     dim[CV_MAX_DIM];
727 }
728 CvMatND;
729 
730 #define CV_IS_MATND_HDR(mat) \
731     ((mat) != NULL && (((const CvMatND*)(mat))->type & CV_MAGIC_MASK) == CV_MATND_MAGIC_VAL)
732 
733 #define CV_IS_MATND(mat) \
734     (CV_IS_MATND_HDR(mat) && ((const CvMatND*)(mat))->data.ptr != NULL)
735 
736 
737 /****************************************************************************************\
738 *                      Multi-dimensional sparse array (CvSparseMat)                      *
739 \****************************************************************************************/
740 
741 #define CV_SPARSE_MAT_MAGIC_VAL    0x42440000
742 #define CV_TYPE_NAME_SPARSE_MAT    "opencv-sparse-matrix"
743 
744 struct CvSet;
745 
746 typedef struct CvSparseMat
747 {
748     int type;
749     int dims;
750     int* refcount;
751     int hdr_refcount;
752 
753     struct CvSet* heap;
754     void** hashtable;
755     int hashsize;
756     int valoffset;
757     int idxoffset;
758     int size[CV_MAX_DIM];
759 }
760 CvSparseMat;
761 
762 #define CV_IS_SPARSE_MAT_HDR(mat) \
763     ((mat) != NULL && \
764     (((const CvSparseMat*)(mat))->type & CV_MAGIC_MASK) == CV_SPARSE_MAT_MAGIC_VAL)
765 
766 #define CV_IS_SPARSE_MAT(mat) \
767     CV_IS_SPARSE_MAT_HDR(mat)
768 
769 /**************** iteration through a sparse array *****************/
770 
771 typedef struct CvSparseNode
772 {
773     unsigned hashval;
774     struct CvSparseNode* next;
775 }
776 CvSparseNode;
777 
778 typedef struct CvSparseMatIterator
779 {
780     CvSparseMat* mat;
781     CvSparseNode* node;
782     int curidx;
783 }
784 CvSparseMatIterator;
785 
786 #define CV_NODE_VAL(mat,node)   ((void*)((uchar*)(node) + (mat)->valoffset))
787 #define CV_NODE_IDX(mat,node)   ((int*)((uchar*)(node) + (mat)->idxoffset))
788 
789 /****************************************************************************************\
790 *                                         Histogram                                      *
791 \****************************************************************************************/
792 
793 typedef int CvHistType;
794 
795 #define CV_HIST_MAGIC_VAL     0x42450000
796 #define CV_HIST_UNIFORM_FLAG  (1 << 10)
797 
798 /* indicates whether bin ranges are set already or not */
799 #define CV_HIST_RANGES_FLAG   (1 << 11)
800 
801 #define CV_HIST_ARRAY         0
802 #define CV_HIST_SPARSE        1
803 #define CV_HIST_TREE          CV_HIST_SPARSE
804 
805 /* should be used as a parameter only,
806    it turns to CV_HIST_UNIFORM_FLAG of hist->type */
807 #define CV_HIST_UNIFORM       1
808 
809 typedef struct CvHistogram
810 {
811     int     type;
812     CvArr*  bins;
813     float   thresh[CV_MAX_DIM][2];  /* For uniform histograms.                      */
814     float** thresh2;                /* For non-uniform histograms.                  */
815     CvMatND mat;                    /* Embedded matrix header for array histograms. */
816 }
817 CvHistogram;
818 
819 #define CV_IS_HIST( hist ) \
820     ((hist) != NULL  && \
821      (((CvHistogram*)(hist))->type & CV_MAGIC_MASK) == CV_HIST_MAGIC_VAL && \
822      (hist)->bins != NULL)
823 
824 #define CV_IS_UNIFORM_HIST( hist ) \
825     (((hist)->type & CV_HIST_UNIFORM_FLAG) != 0)
826 
827 #define CV_IS_SPARSE_HIST( hist ) \
828     CV_IS_SPARSE_MAT((hist)->bins)
829 
830 #define CV_HIST_HAS_RANGES( hist ) \
831     (((hist)->type & CV_HIST_RANGES_FLAG) != 0)
832 
833 /****************************************************************************************\
834 *                      Other supplementary data type definitions                         *
835 \****************************************************************************************/
836 
837 /*************************************** CvRect *****************************************/
838 
839 typedef struct CvRect
840 {
841     int x;
842     int y;
843     int width;
844     int height;
845 }
846 CvRect;
847 
cvRect(int x,int y,int width,int height)848 CV_INLINE  CvRect  cvRect( int x, int y, int width, int height )
849 {
850     CvRect r;
851 
852     r.x = x;
853     r.y = y;
854     r.width = width;
855     r.height = height;
856 
857     return r;
858 }
859 
860 
cvRectToROI(CvRect rect,int coi)861 CV_INLINE  IplROI  cvRectToROI( CvRect rect, int coi )
862 {
863     IplROI roi;
864     roi.xOffset = rect.x;
865     roi.yOffset = rect.y;
866     roi.width = rect.width;
867     roi.height = rect.height;
868     roi.coi = coi;
869 
870     return roi;
871 }
872 
873 
cvROIToRect(IplROI roi)874 CV_INLINE  CvRect  cvROIToRect( IplROI roi )
875 {
876     return cvRect( roi.xOffset, roi.yOffset, roi.width, roi.height );
877 }
878 
879 /*********************************** CvTermCriteria *************************************/
880 
881 #define CV_TERMCRIT_ITER    1
882 #define CV_TERMCRIT_NUMBER  CV_TERMCRIT_ITER
883 #define CV_TERMCRIT_EPS     2
884 
885 typedef struct CvTermCriteria
886 {
887     int    type;  /* may be combination of
888                      CV_TERMCRIT_ITER
889                      CV_TERMCRIT_EPS */
890     int    max_iter;
891     double epsilon;
892 }
893 CvTermCriteria;
894 
cvTermCriteria(int type,int max_iter,double epsilon)895 CV_INLINE  CvTermCriteria  cvTermCriteria( int type, int max_iter, double epsilon )
896 {
897     CvTermCriteria t;
898 
899     t.type = type;
900     t.max_iter = max_iter;
901     t.epsilon = (float)epsilon;
902 
903     return t;
904 }
905 
906 
907 /******************************* CvPoint and variants ***********************************/
908 
909 typedef struct CvPoint
910 {
911     int x;
912     int y;
913 }
914 CvPoint;
915 
916 
cvPoint(int x,int y)917 CV_INLINE  CvPoint  cvPoint( int x, int y )
918 {
919     CvPoint p;
920 
921     p.x = x;
922     p.y = y;
923 
924     return p;
925 }
926 
927 
928 typedef struct CvPoint2D32f
929 {
930     float x;
931     float y;
932 }
933 CvPoint2D32f;
934 
935 
cvPoint2D32f(double x,double y)936 CV_INLINE  CvPoint2D32f  cvPoint2D32f( double x, double y )
937 {
938     CvPoint2D32f p;
939 
940     p.x = (float)x;
941     p.y = (float)y;
942 
943     return p;
944 }
945 
946 
cvPointTo32f(CvPoint point)947 CV_INLINE  CvPoint2D32f  cvPointTo32f( CvPoint point )
948 {
949     return cvPoint2D32f( (float)point.x, (float)point.y );
950 }
951 
952 
cvPointFrom32f(CvPoint2D32f point)953 CV_INLINE  CvPoint  cvPointFrom32f( CvPoint2D32f point )
954 {
955     CvPoint ipt;
956     ipt.x = cvRound(point.x);
957     ipt.y = cvRound(point.y);
958 
959     return ipt;
960 }
961 
962 
963 typedef struct CvPoint3D32f
964 {
965     float x;
966     float y;
967     float z;
968 }
969 CvPoint3D32f;
970 
971 
cvPoint3D32f(double x,double y,double z)972 CV_INLINE  CvPoint3D32f  cvPoint3D32f( double x, double y, double z )
973 {
974     CvPoint3D32f p;
975 
976     p.x = (float)x;
977     p.y = (float)y;
978     p.z = (float)z;
979 
980     return p;
981 }
982 
983 
984 typedef struct CvPoint2D64f
985 {
986     double x;
987     double y;
988 }
989 CvPoint2D64f;
990 
991 
cvPoint2D64f(double x,double y)992 CV_INLINE  CvPoint2D64f  cvPoint2D64f( double x, double y )
993 {
994     CvPoint2D64f p;
995 
996     p.x = x;
997     p.y = y;
998 
999     return p;
1000 }
1001 
1002 
1003 typedef struct CvPoint3D64f
1004 {
1005     double x;
1006     double y;
1007     double z;
1008 }
1009 CvPoint3D64f;
1010 
1011 
cvPoint3D64f(double x,double y,double z)1012 CV_INLINE  CvPoint3D64f  cvPoint3D64f( double x, double y, double z )
1013 {
1014     CvPoint3D64f p;
1015 
1016     p.x = x;
1017     p.y = y;
1018     p.z = z;
1019 
1020     return p;
1021 }
1022 
1023 
1024 /******************************** CvSize's & CvBox **************************************/
1025 
1026 typedef struct
1027 {
1028     int width;
1029     int height;
1030 }
1031 CvSize;
1032 
cvSize(int width,int height)1033 CV_INLINE  CvSize  cvSize( int width, int height )
1034 {
1035     CvSize s;
1036 
1037     s.width = width;
1038     s.height = height;
1039 
1040     return s;
1041 }
1042 
1043 typedef struct CvSize2D32f
1044 {
1045     float width;
1046     float height;
1047 }
1048 CvSize2D32f;
1049 
1050 
cvSize2D32f(double width,double height)1051 CV_INLINE  CvSize2D32f  cvSize2D32f( double width, double height )
1052 {
1053     CvSize2D32f s;
1054 
1055     s.width = (float)width;
1056     s.height = (float)height;
1057 
1058     return s;
1059 }
1060 
1061 typedef struct CvBox2D
1062 {
1063     CvPoint2D32f center;  /* Center of the box.                          */
1064     CvSize2D32f  size;    /* Box width and length.                       */
1065     float angle;          /* Angle between the horizontal axis           */
1066                           /* and the first side (i.e. length) in degrees */
1067 }
1068 CvBox2D;
1069 
1070 
1071 /* Line iterator state: */
1072 typedef struct CvLineIterator
1073 {
1074     /* Pointer to the current point: */
1075     uchar* ptr;
1076 
1077     /* Bresenham algorithm state: */
1078     int  err;
1079     int  plus_delta;
1080     int  minus_delta;
1081     int  plus_step;
1082     int  minus_step;
1083 }
1084 CvLineIterator;
1085 
1086 
1087 
1088 /************************************* CvSlice ******************************************/
1089 
1090 typedef struct CvSlice
1091 {
1092     int  start_index, end_index;
1093 }
1094 CvSlice;
1095 
cvSlice(int start,int end)1096 CV_INLINE  CvSlice  cvSlice( int start, int end )
1097 {
1098     CvSlice slice;
1099     slice.start_index = start;
1100     slice.end_index = end;
1101 
1102     return slice;
1103 }
1104 
1105 #define CV_WHOLE_SEQ_END_INDEX 0x3fffffff
1106 #define CV_WHOLE_SEQ  cvSlice(0, CV_WHOLE_SEQ_END_INDEX)
1107 
1108 
1109 /************************************* CvScalar *****************************************/
1110 
1111 typedef struct CvScalar
1112 {
1113     double val[4];
1114 }
1115 CvScalar;
1116 
1117 CV_INLINE  CvScalar  cvScalar( double val0, double val1 CV_DEFAULT(0),
1118                                double val2 CV_DEFAULT(0), double val3 CV_DEFAULT(0))
1119 {
1120     CvScalar scalar;
1121     scalar.val[0] = val0; scalar.val[1] = val1;
1122     scalar.val[2] = val2; scalar.val[3] = val3;
1123     return scalar;
1124 }
1125 
1126 
cvRealScalar(double val0)1127 CV_INLINE  CvScalar  cvRealScalar( double val0 )
1128 {
1129     CvScalar scalar;
1130     scalar.val[0] = val0;
1131     scalar.val[1] = scalar.val[2] = scalar.val[3] = 0;
1132     return scalar;
1133 }
1134 
cvScalarAll(double val0123)1135 CV_INLINE  CvScalar  cvScalarAll( double val0123 )
1136 {
1137     CvScalar scalar;
1138     scalar.val[0] = val0123;
1139     scalar.val[1] = val0123;
1140     scalar.val[2] = val0123;
1141     scalar.val[3] = val0123;
1142     return scalar;
1143 }
1144 
1145 /****************************************************************************************\
1146 *                                   Dynamic Data structures                              *
1147 \****************************************************************************************/
1148 
1149 /******************************** Memory storage ****************************************/
1150 
1151 typedef struct CvMemBlock
1152 {
1153     struct CvMemBlock*  prev;
1154     struct CvMemBlock*  next;
1155 }
1156 CvMemBlock;
1157 
1158 #define CV_STORAGE_MAGIC_VAL    0x42890000
1159 
1160 typedef struct CvMemStorage
1161 {
1162     int signature;
1163     CvMemBlock* bottom;           /* First allocated block.                   */
1164     CvMemBlock* top;              /* Current memory block - top of the stack. */
1165     struct  CvMemStorage* parent; /* We get new blocks from parent as needed. */
1166     int block_size;               /* Block size.                              */
1167     int free_space;               /* Remaining free space in current block.   */
1168 }
1169 CvMemStorage;
1170 
1171 #define CV_IS_STORAGE(storage)  \
1172     ((storage) != NULL &&       \
1173     (((CvMemStorage*)(storage))->signature & CV_MAGIC_MASK) == CV_STORAGE_MAGIC_VAL)
1174 
1175 
1176 typedef struct CvMemStoragePos
1177 {
1178     CvMemBlock* top;
1179     int free_space;
1180 }
1181 CvMemStoragePos;
1182 
1183 
1184 /*********************************** Sequence *******************************************/
1185 
1186 typedef struct CvSeqBlock
1187 {
1188     struct CvSeqBlock*  prev; /* Previous sequence block.                   */
1189     struct CvSeqBlock*  next; /* Next sequence block.                       */
1190   int    start_index;         /* Index of the first element in the block +  */
1191                               /* sequence->first->start_index.              */
1192     int    count;             /* Number of elements in the block.           */
1193     schar* data;              /* Pointer to the first element of the block. */
1194 }
1195 CvSeqBlock;
1196 
1197 
1198 #define CV_TREE_NODE_FIELDS(node_type)                               \
1199     int       flags;             /* Miscellaneous flags.     */      \
1200     int       header_size;       /* Size of sequence header. */      \
1201     struct    node_type* h_prev; /* Previous sequence.       */      \
1202     struct    node_type* h_next; /* Next sequence.           */      \
1203     struct    node_type* v_prev; /* 2nd previous sequence.   */      \
1204     struct    node_type* v_next  /* 2nd next sequence.       */
1205 
1206 /*
1207    Read/Write sequence.
1208    Elements can be dynamically inserted to or deleted from the sequence.
1209 */
1210 #define CV_SEQUENCE_FIELDS()                                              \
1211     CV_TREE_NODE_FIELDS(CvSeq);                                           \
1212     int       total;          /* Total number of elements.            */  \
1213     int       elem_size;      /* Size of sequence element in bytes.   */  \
1214     schar*    block_max;      /* Maximal bound of the last block.     */  \
1215     schar*    ptr;            /* Current write pointer.               */  \
1216     int       delta_elems;    /* Grow seq this many at a time.        */  \
1217     CvMemStorage* storage;    /* Where the seq is stored.             */  \
1218     CvSeqBlock* free_blocks;  /* Free blocks list.                    */  \
1219     CvSeqBlock* first;        /* Pointer to the first sequence block. */
1220 
1221 typedef struct CvSeq
1222 {
1223     CV_SEQUENCE_FIELDS()
1224 }
1225 CvSeq;
1226 
1227 #define CV_TYPE_NAME_SEQ             "opencv-sequence"
1228 #define CV_TYPE_NAME_SEQ_TREE        "opencv-sequence-tree"
1229 
1230 /*************************************** Set ********************************************/
1231 /*
1232   Set.
1233   Order is not preserved. There can be gaps between sequence elements.
1234   After the element has been inserted it stays in the same place all the time.
1235   The MSB(most-significant or sign bit) of the first field (flags) is 0 iff the element exists.
1236 */
1237 #define CV_SET_ELEM_FIELDS(elem_type)   \
1238     int  flags;                         \
1239     struct elem_type* next_free;
1240 
1241 typedef struct CvSetElem
1242 {
1243     CV_SET_ELEM_FIELDS(CvSetElem)
1244 }
1245 CvSetElem;
1246 
1247 #define CV_SET_FIELDS()      \
1248     CV_SEQUENCE_FIELDS()     \
1249     CvSetElem* free_elems;   \
1250     int active_count;
1251 
1252 typedef struct CvSet
1253 {
1254     CV_SET_FIELDS()
1255 }
1256 CvSet;
1257 
1258 
1259 #define CV_SET_ELEM_IDX_MASK   ((1 << 26) - 1)
1260 #define CV_SET_ELEM_FREE_FLAG  (1 << (sizeof(int)*8-1))
1261 
1262 /* Checks whether the element pointed by ptr belongs to a set or not */
1263 #define CV_IS_SET_ELEM( ptr )  (((CvSetElem*)(ptr))->flags >= 0)
1264 
1265 /************************************* Graph ********************************************/
1266 
1267 /*
1268   We represent a graph as a set of vertices.
1269   Vertices contain their adjacency lists (more exactly, pointers to first incoming or
1270   outcoming edge (or 0 if isolated vertex)). Edges are stored in another set.
1271   There is a singly-linked list of incoming/outcoming edges for each vertex.
1272 
1273   Each edge consists of
1274 
1275      o   Two pointers to the starting and ending vertices
1276          (vtx[0] and vtx[1] respectively).
1277 
1278 	 A graph may be oriented or not. In the latter case, edges between
1279 	 vertex i to vertex j are not distinguished during search operations.
1280 
1281      o   Two pointers to next edges for the starting and ending vertices, where
1282          next[0] points to the next edge in the vtx[0] adjacency list and
1283          next[1] points to the next edge in the vtx[1] adjacency list.
1284 */
1285 #define CV_GRAPH_EDGE_FIELDS()      \
1286     int flags;                      \
1287     float weight;                   \
1288     struct CvGraphEdge* next[2];    \
1289     struct CvGraphVtx* vtx[2];
1290 
1291 
1292 #define CV_GRAPH_VERTEX_FIELDS()    \
1293     int flags;                      \
1294     struct CvGraphEdge* first;
1295 
1296 
1297 typedef struct CvGraphEdge
1298 {
1299     CV_GRAPH_EDGE_FIELDS()
1300 }
1301 CvGraphEdge;
1302 
1303 typedef struct CvGraphVtx
1304 {
1305     CV_GRAPH_VERTEX_FIELDS()
1306 }
1307 CvGraphVtx;
1308 
1309 typedef struct CvGraphVtx2D
1310 {
1311     CV_GRAPH_VERTEX_FIELDS()
1312     CvPoint2D32f* ptr;
1313 }
1314 CvGraphVtx2D;
1315 
1316 /*
1317    Graph is "derived" from the set (this is set a of vertices)
1318    and includes another set (edges)
1319 */
1320 #define  CV_GRAPH_FIELDS()   \
1321     CV_SET_FIELDS()          \
1322     CvSet* edges;
1323 
1324 typedef struct CvGraph
1325 {
1326     CV_GRAPH_FIELDS()
1327 }
1328 CvGraph;
1329 
1330 #define CV_TYPE_NAME_GRAPH "opencv-graph"
1331 
1332 /*********************************** Chain/Countour *************************************/
1333 
1334 typedef struct CvChain
1335 {
1336     CV_SEQUENCE_FIELDS()
1337     CvPoint  origin;
1338 }
1339 CvChain;
1340 
1341 #define CV_CONTOUR_FIELDS()  \
1342     CV_SEQUENCE_FIELDS()     \
1343     CvRect rect;             \
1344     int color;               \
1345     int reserved[3];
1346 
1347 typedef struct CvContour
1348 {
1349     CV_CONTOUR_FIELDS()
1350 }
1351 CvContour;
1352 
1353 typedef CvContour CvPoint2DSeq;
1354 
1355 /****************************************************************************************\
1356 *                                    Sequence types                                      *
1357 \****************************************************************************************/
1358 
1359 #define CV_SEQ_MAGIC_VAL             0x42990000
1360 
1361 #define CV_IS_SEQ(seq) \
1362     ((seq) != NULL && (((CvSeq*)(seq))->flags & CV_MAGIC_MASK) == CV_SEQ_MAGIC_VAL)
1363 
1364 #define CV_SET_MAGIC_VAL             0x42980000
1365 #define CV_IS_SET(set) \
1366     ((set) != NULL && (((CvSeq*)(set))->flags & CV_MAGIC_MASK) == CV_SET_MAGIC_VAL)
1367 
1368 #define CV_SEQ_ELTYPE_BITS           9
1369 #define CV_SEQ_ELTYPE_MASK           ((1 << CV_SEQ_ELTYPE_BITS) - 1)
1370 
1371 #define CV_SEQ_ELTYPE_POINT          CV_32SC2  /* (x,y) */
1372 #define CV_SEQ_ELTYPE_CODE           CV_8UC1   /* freeman code: 0..7 */
1373 #define CV_SEQ_ELTYPE_GENERIC        0
1374 #define CV_SEQ_ELTYPE_PTR            CV_USRTYPE1
1375 #define CV_SEQ_ELTYPE_PPOINT         CV_SEQ_ELTYPE_PTR  /* &(x,y) */
1376 #define CV_SEQ_ELTYPE_INDEX          CV_32SC1  /* #(x,y) */
1377 #define CV_SEQ_ELTYPE_GRAPH_EDGE     0  /* &next_o, &next_d, &vtx_o, &vtx_d */
1378 #define CV_SEQ_ELTYPE_GRAPH_VERTEX   0  /* first_edge, &(x,y) */
1379 #define CV_SEQ_ELTYPE_TRIAN_ATR      0  /* vertex of the binary tree   */
1380 #define CV_SEQ_ELTYPE_CONNECTED_COMP 0  /* connected component  */
1381 #define CV_SEQ_ELTYPE_POINT3D        CV_32FC3  /* (x,y,z)  */
1382 
1383 #define CV_SEQ_KIND_BITS        3
1384 #define CV_SEQ_KIND_MASK        (((1 << CV_SEQ_KIND_BITS) - 1)<<CV_SEQ_ELTYPE_BITS)
1385 
1386 /* types of sequences */
1387 #define CV_SEQ_KIND_GENERIC     (0 << CV_SEQ_ELTYPE_BITS)
1388 #define CV_SEQ_KIND_CURVE       (1 << CV_SEQ_ELTYPE_BITS)
1389 #define CV_SEQ_KIND_BIN_TREE    (2 << CV_SEQ_ELTYPE_BITS)
1390 
1391 /* types of sparse sequences (sets) */
1392 #define CV_SEQ_KIND_GRAPH       (3 << CV_SEQ_ELTYPE_BITS)
1393 #define CV_SEQ_KIND_SUBDIV2D    (4 << CV_SEQ_ELTYPE_BITS)
1394 
1395 #define CV_SEQ_FLAG_SHIFT       (CV_SEQ_KIND_BITS + CV_SEQ_ELTYPE_BITS)
1396 
1397 /* flags for curves */
1398 #define CV_SEQ_FLAG_CLOSED     (1 << CV_SEQ_FLAG_SHIFT)
1399 #define CV_SEQ_FLAG_SIMPLE     (2 << CV_SEQ_FLAG_SHIFT)
1400 #define CV_SEQ_FLAG_CONVEX     (4 << CV_SEQ_FLAG_SHIFT)
1401 #define CV_SEQ_FLAG_HOLE       (8 << CV_SEQ_FLAG_SHIFT)
1402 
1403 /* flags for graphs */
1404 #define CV_GRAPH_FLAG_ORIENTED (1 << CV_SEQ_FLAG_SHIFT)
1405 
1406 #define CV_GRAPH               CV_SEQ_KIND_GRAPH
1407 #define CV_ORIENTED_GRAPH      (CV_SEQ_KIND_GRAPH|CV_GRAPH_FLAG_ORIENTED)
1408 
1409 /* point sets */
1410 #define CV_SEQ_POINT_SET       (CV_SEQ_KIND_GENERIC| CV_SEQ_ELTYPE_POINT)
1411 #define CV_SEQ_POINT3D_SET     (CV_SEQ_KIND_GENERIC| CV_SEQ_ELTYPE_POINT3D)
1412 #define CV_SEQ_POLYLINE        (CV_SEQ_KIND_CURVE  | CV_SEQ_ELTYPE_POINT)
1413 #define CV_SEQ_POLYGON         (CV_SEQ_FLAG_CLOSED | CV_SEQ_POLYLINE )
1414 #define CV_SEQ_CONTOUR         CV_SEQ_POLYGON
1415 #define CV_SEQ_SIMPLE_POLYGON  (CV_SEQ_FLAG_SIMPLE | CV_SEQ_POLYGON  )
1416 
1417 /* chain-coded curves */
1418 #define CV_SEQ_CHAIN           (CV_SEQ_KIND_CURVE  | CV_SEQ_ELTYPE_CODE)
1419 #define CV_SEQ_CHAIN_CONTOUR   (CV_SEQ_FLAG_CLOSED | CV_SEQ_CHAIN)
1420 
1421 /* binary tree for the contour */
1422 #define CV_SEQ_POLYGON_TREE    (CV_SEQ_KIND_BIN_TREE  | CV_SEQ_ELTYPE_TRIAN_ATR)
1423 
1424 /* sequence of the connected components */
1425 #define CV_SEQ_CONNECTED_COMP  (CV_SEQ_KIND_GENERIC  | CV_SEQ_ELTYPE_CONNECTED_COMP)
1426 
1427 /* sequence of the integer numbers */
1428 #define CV_SEQ_INDEX           (CV_SEQ_KIND_GENERIC  | CV_SEQ_ELTYPE_INDEX)
1429 
1430 #define CV_SEQ_ELTYPE( seq )   ((seq)->flags & CV_SEQ_ELTYPE_MASK)
1431 #define CV_SEQ_KIND( seq )     ((seq)->flags & CV_SEQ_KIND_MASK )
1432 
1433 /* flag checking */
1434 #define CV_IS_SEQ_INDEX( seq )      ((CV_SEQ_ELTYPE(seq) == CV_SEQ_ELTYPE_INDEX) && \
1435                                      (CV_SEQ_KIND(seq) == CV_SEQ_KIND_GENERIC))
1436 
1437 #define CV_IS_SEQ_CURVE( seq )      (CV_SEQ_KIND(seq) == CV_SEQ_KIND_CURVE)
1438 #define CV_IS_SEQ_CLOSED( seq )     (((seq)->flags & CV_SEQ_FLAG_CLOSED) != 0)
1439 #define CV_IS_SEQ_CONVEX( seq )     (((seq)->flags & CV_SEQ_FLAG_CONVEX) != 0)
1440 #define CV_IS_SEQ_HOLE( seq )       (((seq)->flags & CV_SEQ_FLAG_HOLE) != 0)
1441 #define CV_IS_SEQ_SIMPLE( seq )     ((((seq)->flags & CV_SEQ_FLAG_SIMPLE) != 0) || \
1442                                     CV_IS_SEQ_CONVEX(seq))
1443 
1444 /* type checking macros */
1445 #define CV_IS_SEQ_POINT_SET( seq ) \
1446     ((CV_SEQ_ELTYPE(seq) == CV_32SC2 || CV_SEQ_ELTYPE(seq) == CV_32FC2))
1447 
1448 #define CV_IS_SEQ_POINT_SUBSET( seq ) \
1449     (CV_IS_SEQ_INDEX( seq ) || CV_SEQ_ELTYPE(seq) == CV_SEQ_ELTYPE_PPOINT)
1450 
1451 #define CV_IS_SEQ_POLYLINE( seq )   \
1452     (CV_SEQ_KIND(seq) == CV_SEQ_KIND_CURVE && CV_IS_SEQ_POINT_SET(seq))
1453 
1454 #define CV_IS_SEQ_POLYGON( seq )   \
1455     (CV_IS_SEQ_POLYLINE(seq) && CV_IS_SEQ_CLOSED(seq))
1456 
1457 #define CV_IS_SEQ_CHAIN( seq )   \
1458     (CV_SEQ_KIND(seq) == CV_SEQ_KIND_CURVE && (seq)->elem_size == 1)
1459 
1460 #define CV_IS_SEQ_CONTOUR( seq )   \
1461     (CV_IS_SEQ_CLOSED(seq) && (CV_IS_SEQ_POLYLINE(seq) || CV_IS_SEQ_CHAIN(seq)))
1462 
1463 #define CV_IS_SEQ_CHAIN_CONTOUR( seq ) \
1464     (CV_IS_SEQ_CHAIN( seq ) && CV_IS_SEQ_CLOSED( seq ))
1465 
1466 #define CV_IS_SEQ_POLYGON_TREE( seq ) \
1467     (CV_SEQ_ELTYPE (seq) ==  CV_SEQ_ELTYPE_TRIAN_ATR &&    \
1468     CV_SEQ_KIND( seq ) ==  CV_SEQ_KIND_BIN_TREE )
1469 
1470 #define CV_IS_GRAPH( seq )    \
1471     (CV_IS_SET(seq) && CV_SEQ_KIND((CvSet*)(seq)) == CV_SEQ_KIND_GRAPH)
1472 
1473 #define CV_IS_GRAPH_ORIENTED( seq )   \
1474     (((seq)->flags & CV_GRAPH_FLAG_ORIENTED) != 0)
1475 
1476 #define CV_IS_SUBDIV2D( seq )  \
1477     (CV_IS_SET(seq) && CV_SEQ_KIND((CvSet*)(seq)) == CV_SEQ_KIND_SUBDIV2D)
1478 
1479 /****************************************************************************************/
1480 /*                            Sequence writer & reader                                  */
1481 /****************************************************************************************/
1482 
1483 #define CV_SEQ_WRITER_FIELDS()                                     \
1484     int          header_size;                                      \
1485     CvSeq*       seq;        /* the sequence written */            \
1486     CvSeqBlock*  block;      /* current block */                   \
1487     schar*       ptr;        /* pointer to free space */           \
1488     schar*       block_min;  /* pointer to the beginning of block*/\
1489     schar*       block_max;  /* pointer to the end of block */
1490 
1491 typedef struct CvSeqWriter
1492 {
1493     CV_SEQ_WRITER_FIELDS()
1494 }
1495 CvSeqWriter;
1496 
1497 
1498 #define CV_SEQ_READER_FIELDS()                                      \
1499     int          header_size;                                       \
1500     CvSeq*       seq;        /* sequence, beign read */             \
1501     CvSeqBlock*  block;      /* current block */                    \
1502     schar*       ptr;        /* pointer to element be read next */  \
1503     schar*       block_min;  /* pointer to the beginning of block */\
1504     schar*       block_max;  /* pointer to the end of block */      \
1505     int          delta_index;/* = seq->first->start_index   */      \
1506     schar*       prev_elem;  /* pointer to previous element */
1507 
1508 
1509 typedef struct CvSeqReader
1510 {
1511     CV_SEQ_READER_FIELDS()
1512 }
1513 CvSeqReader;
1514 
1515 /****************************************************************************************/
1516 /*                                Operations on sequences                               */
1517 /****************************************************************************************/
1518 
1519 #define  CV_SEQ_ELEM( seq, elem_type, index )                    \
1520 /* assert gives some guarantee that <seq> parameter is valid */  \
1521 (   assert(sizeof((seq)->first[0]) == sizeof(CvSeqBlock) &&      \
1522     (seq)->elem_size == sizeof(elem_type)),                      \
1523     (elem_type*)((seq)->first && (unsigned)index <               \
1524     (unsigned)((seq)->first->count) ?                            \
1525     (seq)->first->data + (index) * sizeof(elem_type) :           \
1526     cvGetSeqElem( (CvSeq*)(seq), (index) )))
1527 #define CV_GET_SEQ_ELEM( elem_type, seq, index ) CV_SEQ_ELEM( (seq), elem_type, (index) )
1528 
1529 /* Add element to sequence: */
1530 #define CV_WRITE_SEQ_ELEM_VAR( elem_ptr, writer )     \
1531 {                                                     \
1532     if( (writer).ptr >= (writer).block_max )          \
1533     {                                                 \
1534         cvCreateSeqBlock( &writer);                   \
1535     }                                                 \
1536     memcpy((writer).ptr, elem_ptr, (writer).seq->elem_size);\
1537     (writer).ptr += (writer).seq->elem_size;          \
1538 }
1539 
1540 #define CV_WRITE_SEQ_ELEM( elem, writer )             \
1541 {                                                     \
1542     assert( (writer).seq->elem_size == sizeof(elem)); \
1543     if( (writer).ptr >= (writer).block_max )          \
1544     {                                                 \
1545         cvCreateSeqBlock( &writer);                   \
1546     }                                                 \
1547     assert( (writer).ptr <= (writer).block_max - sizeof(elem));\
1548     memcpy((writer).ptr, &(elem), sizeof(elem));      \
1549     (writer).ptr += sizeof(elem);                     \
1550 }
1551 
1552 
1553 /* Move reader position forward: */
1554 #define CV_NEXT_SEQ_ELEM( elem_size, reader )                 \
1555 {                                                             \
1556     if( ((reader).ptr += (elem_size)) >= (reader).block_max ) \
1557     {                                                         \
1558         cvChangeSeqBlock( &(reader), 1 );                     \
1559     }                                                         \
1560 }
1561 
1562 
1563 /* Move reader position backward: */
1564 #define CV_PREV_SEQ_ELEM( elem_size, reader )                \
1565 {                                                            \
1566     if( ((reader).ptr -= (elem_size)) < (reader).block_min ) \
1567     {                                                        \
1568         cvChangeSeqBlock( &(reader), -1 );                   \
1569     }                                                        \
1570 }
1571 
1572 /* Read element and move read position forward: */
1573 #define CV_READ_SEQ_ELEM( elem, reader )                       \
1574 {                                                              \
1575     assert( (reader).seq->elem_size == sizeof(elem));          \
1576     memcpy( &(elem), (reader).ptr, sizeof((elem)));            \
1577     CV_NEXT_SEQ_ELEM( sizeof(elem), reader )                   \
1578 }
1579 
1580 /* Read element and move read position backward: */
1581 #define CV_REV_READ_SEQ_ELEM( elem, reader )                     \
1582 {                                                                \
1583     assert( (reader).seq->elem_size == sizeof(elem));            \
1584     memcpy(&(elem), (reader).ptr, sizeof((elem)));               \
1585     CV_PREV_SEQ_ELEM( sizeof(elem), reader )                     \
1586 }
1587 
1588 
1589 #define CV_READ_CHAIN_POINT( _pt, reader )                              \
1590 {                                                                       \
1591     (_pt) = (reader).pt;                                                \
1592     if( (reader).ptr )                                                  \
1593     {                                                                   \
1594         CV_READ_SEQ_ELEM( (reader).code, (reader));                     \
1595         assert( ((reader).code & ~7) == 0 );                            \
1596         (reader).pt.x += (reader).deltas[(int)(reader).code][0];        \
1597         (reader).pt.y += (reader).deltas[(int)(reader).code][1];        \
1598     }                                                                   \
1599 }
1600 
1601 #define CV_CURRENT_POINT( reader )  (*((CvPoint*)((reader).ptr)))
1602 #define CV_PREV_POINT( reader )     (*((CvPoint*)((reader).prev_elem)))
1603 
1604 #define CV_READ_EDGE( pt1, pt2, reader )               \
1605 {                                                      \
1606     assert( sizeof(pt1) == sizeof(CvPoint) &&          \
1607             sizeof(pt2) == sizeof(CvPoint) &&          \
1608             reader.seq->elem_size == sizeof(CvPoint)); \
1609     (pt1) = CV_PREV_POINT( reader );                   \
1610     (pt2) = CV_CURRENT_POINT( reader );                \
1611     (reader).prev_elem = (reader).ptr;                 \
1612     CV_NEXT_SEQ_ELEM( sizeof(CvPoint), (reader));      \
1613 }
1614 
1615 /************ Graph macros ************/
1616 
1617 /* Return next graph edge for given vertex: */
1618 #define  CV_NEXT_GRAPH_EDGE( edge, vertex )                              \
1619      (assert((edge)->vtx[0] == (vertex) || (edge)->vtx[1] == (vertex)),  \
1620       (edge)->next[(edge)->vtx[1] == (vertex)])
1621 
1622 
1623 
1624 /****************************************************************************************\
1625 *             Data structures for persistence (a.k.a serialization) functionality        *
1626 \****************************************************************************************/
1627 
1628 /* "black box" file storage */
1629 typedef struct CvFileStorage CvFileStorage;
1630 
1631 /* Storage flags: */
1632 #define CV_STORAGE_READ          0
1633 #define CV_STORAGE_WRITE         1
1634 #define CV_STORAGE_WRITE_TEXT    CV_STORAGE_WRITE
1635 #define CV_STORAGE_WRITE_BINARY  CV_STORAGE_WRITE
1636 #define CV_STORAGE_APPEND        2
1637 
1638 /* List of attributes: */
1639 typedef struct CvAttrList
1640 {
1641     const char** attr;         /* NULL-terminated array of (attribute_name,attribute_value) pairs. */
1642     struct CvAttrList* next;   /* Pointer to next chunk of the attributes list.                    */
1643 }
1644 CvAttrList;
1645 
cvAttrList(const char ** attr CV_DEFAULT (NULL),CvAttrList * next CV_DEFAULT (NULL))1646 CV_INLINE CvAttrList cvAttrList( const char** attr CV_DEFAULT(NULL),
1647                                  CvAttrList* next CV_DEFAULT(NULL) )
1648 {
1649     CvAttrList l;
1650     l.attr = attr;
1651     l.next = next;
1652 
1653     return l;
1654 }
1655 
1656 struct CvTypeInfo;
1657 
1658 #define CV_NODE_NONE        0
1659 #define CV_NODE_INT         1
1660 #define CV_NODE_INTEGER     CV_NODE_INT
1661 #define CV_NODE_REAL        2
1662 #define CV_NODE_FLOAT       CV_NODE_REAL
1663 #define CV_NODE_STR         3
1664 #define CV_NODE_STRING      CV_NODE_STR
1665 #define CV_NODE_REF         4 /* not used */
1666 #define CV_NODE_SEQ         5
1667 #define CV_NODE_MAP         6
1668 #define CV_NODE_TYPE_MASK   7
1669 
1670 #define CV_NODE_TYPE(flags)  ((flags) & CV_NODE_TYPE_MASK)
1671 
1672 /* file node flags */
1673 #define CV_NODE_FLOW        8 /* Used only for writing structures in YAML format. */
1674 #define CV_NODE_USER        16
1675 #define CV_NODE_EMPTY       32
1676 #define CV_NODE_NAMED       64
1677 
1678 #define CV_NODE_IS_INT(flags)        (CV_NODE_TYPE(flags) == CV_NODE_INT)
1679 #define CV_NODE_IS_REAL(flags)       (CV_NODE_TYPE(flags) == CV_NODE_REAL)
1680 #define CV_NODE_IS_STRING(flags)     (CV_NODE_TYPE(flags) == CV_NODE_STRING)
1681 #define CV_NODE_IS_SEQ(flags)        (CV_NODE_TYPE(flags) == CV_NODE_SEQ)
1682 #define CV_NODE_IS_MAP(flags)        (CV_NODE_TYPE(flags) == CV_NODE_MAP)
1683 #define CV_NODE_IS_COLLECTION(flags) (CV_NODE_TYPE(flags) >= CV_NODE_SEQ)
1684 #define CV_NODE_IS_FLOW(flags)       (((flags) & CV_NODE_FLOW) != 0)
1685 #define CV_NODE_IS_EMPTY(flags)      (((flags) & CV_NODE_EMPTY) != 0)
1686 #define CV_NODE_IS_USER(flags)       (((flags) & CV_NODE_USER) != 0)
1687 #define CV_NODE_HAS_NAME(flags)      (((flags) & CV_NODE_NAMED) != 0)
1688 
1689 #define CV_NODE_SEQ_SIMPLE 256
1690 #define CV_NODE_SEQ_IS_SIMPLE(seq) (((seq)->flags & CV_NODE_SEQ_SIMPLE) != 0)
1691 
1692 typedef struct CvString
1693 {
1694     int len;
1695     char* ptr;
1696 }
1697 CvString;
1698 
1699 /* All the keys (names) of elements in the readed file storage
1700    are stored in the hash to speed up the lookup operations: */
1701 typedef struct CvStringHashNode
1702 {
1703     unsigned hashval;
1704     CvString str;
1705     struct CvStringHashNode* next;
1706 }
1707 CvStringHashNode;
1708 
1709 typedef struct CvGenericHash CvFileNodeHash;
1710 
1711 /* Basic element of the file storage - scalar or collection: */
1712 typedef struct CvFileNode
1713 {
1714     int tag;
1715     struct CvTypeInfo* info; /* type information
1716             (only for user-defined object, for others it is 0) */
1717     union
1718     {
1719         double f; /* scalar floating-point number */
1720         int i;    /* scalar integer number */
1721         CvString str; /* text string */
1722         CvSeq* seq; /* sequence (ordered collection of file nodes) */
1723         CvFileNodeHash* map; /* map (collection of named file nodes) */
1724     } data;
1725 }
1726 CvFileNode;
1727 
1728 #ifdef __cplusplus
1729 extern "C" {
1730 #endif
1731 typedef int (CV_CDECL *CvIsInstanceFunc)( const void* struct_ptr );
1732 typedef void (CV_CDECL *CvReleaseFunc)( void** struct_dblptr );
1733 typedef void* (CV_CDECL *CvReadFunc)( CvFileStorage* storage, CvFileNode* node );
1734 typedef void (CV_CDECL *CvWriteFunc)( CvFileStorage* storage, const char* name,
1735                                       const void* struct_ptr, CvAttrList attributes );
1736 typedef void* (CV_CDECL *CvCloneFunc)( const void* struct_ptr );
1737 #ifdef __cplusplus
1738 }
1739 #endif
1740 
1741 typedef struct CvTypeInfo
1742 {
1743     int flags;
1744     int header_size;
1745     struct CvTypeInfo* prev;
1746     struct CvTypeInfo* next;
1747     const char* type_name;
1748     CvIsInstanceFunc is_instance;
1749     CvReleaseFunc release;
1750     CvReadFunc read;
1751     CvWriteFunc write;
1752     CvCloneFunc clone;
1753 }
1754 CvTypeInfo;
1755 
1756 
1757 /**** System data types ******/
1758 
1759 typedef struct CvPluginFuncInfo
1760 {
1761     void** func_addr;
1762     void* default_func_addr;
1763     const char* func_names;
1764     int search_modules;
1765     int loaded_from;
1766 }
1767 CvPluginFuncInfo;
1768 
1769 typedef struct CvModuleInfo
1770 {
1771     struct CvModuleInfo* next;
1772     const char* name;
1773     const char* version;
1774     CvPluginFuncInfo* func_tab;
1775 }
1776 CvModuleInfo;
1777 
1778 #endif /*_CXCORE_TYPES_H_*/
1779 
1780 /* End of file. */
1781