opencv 2.2.0
/usr/src/RPM/BUILD/libopencv2.2-2.2.0/modules/core/include/opencv2/core/mat.hpp
Go to the documentation of this file.
00001 /*M///////////////////////////////////////////////////////////////////////////////////////
00002 //
00003 //  IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING.
00004 //
00005 //  By downloading, copying, installing or using the software you agree to this license.
00006 //  If you do not agree to this license, do not download, install,
00007 //  copy or use the software.
00008 //
00009 //
00010 //                           License Agreement
00011 //                For Open Source Computer Vision Library
00012 //
00013 // Copyright (C) 2000-2008, Intel Corporation, all rights reserved.
00014 // Copyright (C) 2009, Willow Garage Inc., all rights reserved.
00015 // Third party copyrights are property of their respective owners.
00016 //
00017 // Redistribution and use in source and binary forms, with or without modification,
00018 // are permitted provided that the following conditions are met:
00019 //
00020 //   * Redistribution's of source code must retain the above copyright notice,
00021 //     this list of conditions and the following disclaimer.
00022 //
00023 //   * Redistribution's in binary form must reproduce the above copyright notice,
00024 //     this list of conditions and the following disclaimer in the documentation
00025 //     and/or other materials provided with the distribution.
00026 //
00027 //   * The name of the copyright holders may not be used to endorse or promote products
00028 //     derived from this software without specific prior written permission.
00029 //
00030 // This software is provided by the copyright holders and contributors "as is" and
00031 // any express or implied warranties, including, but not limited to, the implied
00032 // warranties of merchantability and fitness for a particular purpose are disclaimed.
00033 // In no event shall the Intel Corporation or contributors be liable for any direct,
00034 // indirect, incidental, special, exemplary, or consequential damages
00035 // (including, but not limited to, procurement of substitute goods or services;
00036 // loss of use, data, or profits; or business interruption) however caused
00037 // and on any theory of liability, whether in contract, strict liability,
00038 // or tort (including negligence or otherwise) arising in any way out of
00039 // the use of this software, even if advised of the possibility of such damage.
00040 //
00041 //M*/
00042 
00043 #ifndef __OPENCV_CORE_MATRIX_OPERATIONS_HPP__
00044 #define __OPENCV_CORE_MATRIX_OPERATIONS_HPP__
00045 
00046 #ifndef SKIP_INCLUDES
00047 #include <limits.h>
00048 #include <string.h>
00049 #endif // SKIP_INCLUDES
00050 
00051 #ifdef __cplusplus
00052 
00053 namespace cv
00054 {
00055 
00057 
00058 inline Mat::Mat()
00059     : flags(0), dims(0), rows(0), cols(0), data(0), refcount(0),
00060     datastart(0), dataend(0), datalimit(0), allocator(0), size(&rows)
00061 {
00062 }
00063 
00064 inline Mat::Mat(int _rows, int _cols, int _type)
00065     : flags(0), dims(0), rows(0), cols(0), data(0), refcount(0),
00066     datastart(0), dataend(0), datalimit(0), allocator(0), size(&rows)
00067 {
00068     create(_rows, _cols, _type);
00069 }
00070 
00071 inline Mat::Mat(int _rows, int _cols, int _type, const Scalar& _s)
00072     : flags(0), dims(0), rows(0), cols(0), data(0), refcount(0),
00073     datastart(0), dataend(0), datalimit(0), allocator(0), size(&rows)
00074 {
00075     create(_rows, _cols, _type);
00076     *this = _s;
00077 }
00078 
00079 inline Mat::Mat(Size _sz, int _type)
00080     : flags(0), dims(0), rows(0), cols(0), data(0), refcount(0),
00081     datastart(0), dataend(0), datalimit(0), allocator(0), size(&rows)
00082 {
00083     create( _sz.height, _sz.width, _type );
00084 }
00085     
00086 inline Mat::Mat(Size _sz, int _type, const Scalar& _s)
00087     : flags(0), dims(0), rows(0), cols(0), data(0), refcount(0),
00088     datastart(0), dataend(0), datalimit(0), allocator(0), size(&rows)
00089 {
00090     create(_sz.height, _sz.width, _type);
00091     *this = _s;
00092 }
00093     
00094 inline Mat::Mat(int _dims, const int* _sz, int _type)
00095     : flags(0), dims(0), rows(0), cols(0), data(0), refcount(0),
00096     datastart(0), dataend(0), datalimit(0), allocator(0), size(&rows)
00097 {
00098     create(_dims, _sz, _type);
00099 }
00100 
00101 inline Mat::Mat(int _dims, const int* _sz, int _type, const Scalar& _s)
00102     : flags(0), dims(0), rows(0), cols(0), data(0), refcount(0),
00103     datastart(0), dataend(0), datalimit(0), allocator(0), size(&rows)
00104 {
00105     create(_dims, _sz, _type);
00106     *this = _s;
00107 }    
00108 
00109 inline Mat::Mat(const Mat& m)
00110     : flags(m.flags), dims(m.dims), rows(m.rows), cols(m.cols), data(m.data),
00111     refcount(m.refcount), datastart(m.datastart), dataend(m.dataend),
00112     datalimit(m.datalimit), allocator(m.allocator), size(&rows)
00113 {
00114     if( refcount )
00115         CV_XADD(refcount, 1);
00116     if( m.dims <= 2 )
00117     {
00118         step[0] = m.step[0]; step[1] = m.step[1];
00119     }
00120     else
00121     {
00122         dims = 0;
00123         copySize(m);
00124     }
00125 }
00126 
00127 inline Mat::Mat(int _rows, int _cols, int _type, void* _data, size_t _step)
00128     : flags(MAGIC_VAL + (_type & TYPE_MASK)), dims(2), rows(_rows), cols(_cols),
00129     data((uchar*)_data), refcount(0), datastart((uchar*)_data), dataend(0),
00130     datalimit(0), allocator(0), size(&rows)
00131 {
00132     size_t esz = CV_ELEM_SIZE(_type), minstep = cols*esz;
00133     if( _step == AUTO_STEP )
00134     {
00135         _step = minstep;
00136         flags |= CONTINUOUS_FLAG;
00137     }
00138     else
00139     {
00140         if( rows == 1 ) _step = minstep;
00141         CV_DbgAssert( _step >= minstep );
00142         flags |= _step == minstep ? CONTINUOUS_FLAG : 0;
00143     }
00144     step[0] = _step; step[1] = esz;
00145     datalimit = datastart + _step*rows;
00146     dataend = datalimit - _step + minstep;
00147 }
00148 
00149 inline Mat::Mat(Size _sz, int _type, void* _data, size_t _step)
00150     : flags(MAGIC_VAL + (_type & TYPE_MASK)), dims(2), rows(_sz.height), cols(_sz.width),
00151     data((uchar*)_data), refcount(0), datastart((uchar*)_data), dataend(0),
00152     datalimit(0), allocator(0), size(&rows)
00153 {
00154     size_t esz = CV_ELEM_SIZE(_type), minstep = cols*esz;
00155     if( _step == AUTO_STEP )
00156     {
00157         _step = minstep;
00158         flags |= CONTINUOUS_FLAG;
00159     }
00160     else
00161     {
00162         if( rows == 1 ) _step = minstep;
00163         CV_DbgAssert( _step >= minstep );
00164         flags |= _step == minstep ? CONTINUOUS_FLAG : 0;
00165     }
00166     step[0] = _step; step[1] = esz;
00167     datalimit = datastart + _step*rows;
00168     dataend = datalimit - _step + minstep;
00169 }
00170 
00171 
00172 inline Mat::Mat(const CvMat* m, bool copyData)
00173     : flags(MAGIC_VAL + (m->type & (CV_MAT_TYPE_MASK|CV_MAT_CONT_FLAG))),
00174     dims(2), rows(m->rows), cols(m->cols), data(m->data.ptr), refcount(0),
00175     datastart(m->data.ptr), allocator(0), size(&rows)
00176 {
00177     if( !copyData )
00178     {
00179         size_t esz = CV_ELEM_SIZE(m->type), minstep = cols*esz, _step = m->step;
00180         if( _step == 0 )
00181             _step = minstep;
00182         datalimit = datastart + _step*rows;
00183         dataend = datalimit - _step + minstep;
00184         step[0] = _step; step[1] = esz;
00185     }
00186     else
00187     {
00188         data = datastart = dataend = 0;
00189         Mat(m->rows, m->cols, m->type, m->data.ptr, m->step).copyTo(*this);
00190     }
00191 }
00192 
00193 template<typename _Tp> inline Mat::Mat(const vector<_Tp>& vec, bool copyData)
00194     : flags(MAGIC_VAL | DataType<_Tp>::type | CV_MAT_CONT_FLAG),
00195     dims(2), rows((int)vec.size()), cols(1), data(0), refcount(0),
00196     datastart(0), dataend(0), allocator(0), size(&rows)
00197 {
00198     if(vec.empty())
00199         return;
00200     if( !copyData )
00201     {
00202         step[0] = step[1] = sizeof(_Tp);
00203         data = datastart = (uchar*)&vec[0];
00204         datalimit = dataend = datastart + rows*step[0];
00205     }
00206     else
00207         Mat((int)vec.size(), 1, DataType<_Tp>::type, (uchar*)&vec[0]).copyTo(*this);
00208 }
00209     
00210     
00211 template<typename _Tp, int n> inline Mat::Mat(const Vec<_Tp, n>& vec, bool copyData)
00212     : flags(MAGIC_VAL | DataType<_Tp>::type | CV_MAT_CONT_FLAG),
00213     dims(2), rows(n), cols(1), data(0), refcount(0),
00214     datastart(0), dataend(0), allocator(0), size(&rows)
00215 {
00216     if( !copyData )
00217     {
00218         step[0] = step[1] = sizeof(_Tp);
00219         data = datastart = (uchar*)vec.val;
00220         datalimit = dataend = datastart + rows*step[0];
00221     }
00222     else
00223         Mat(n, 1, DataType<_Tp>::type, (void*)vec.val).copyTo(*this);
00224 }
00225 
00226 
00227 template<typename _Tp, int m, int n> inline Mat::Mat(const Matx<_Tp,m,n>& M, bool copyData)
00228     : flags(MAGIC_VAL | DataType<_Tp>::type | CV_MAT_CONT_FLAG),
00229     dims(2), rows(m), cols(n), data(0), refcount(0),
00230     datastart(0), dataend(0), allocator(0), size(&rows)
00231 {
00232     if( !copyData )
00233     {
00234         step[0] = cols*sizeof(_Tp);
00235         step[1] = sizeof(_Tp);
00236         data = datastart = (uchar*)M.val;
00237         datalimit = dataend = datastart + rows*step[0];
00238     }
00239     else
00240         Mat(m, n, DataType<_Tp>::type, (uchar*)M.val).copyTo(*this);    
00241 }
00242 
00243     
00244 template<typename _Tp> inline Mat::Mat(const Point_<_Tp>& pt, bool copyData)
00245     : flags(MAGIC_VAL | DataType<_Tp>::type | CV_MAT_CONT_FLAG),
00246     dims(2), rows(2), cols(1), data(0), refcount(0),
00247     datastart(0), dataend(0), allocator(0), size(&rows)
00248 {
00249     if( !copyData )
00250     {
00251         step[0] = step[1] = sizeof(_Tp);
00252         data = datastart = (uchar*)&pt.x;
00253         datalimit = dataend = datastart + rows*step[0];
00254     }
00255     else
00256     {
00257         create(2, 1, DataType<_Tp>::type);
00258         ((_Tp*)data)[0] = pt.x;
00259         ((_Tp*)data)[1] = pt.y;
00260     }
00261 }
00262     
00263 
00264 template<typename _Tp> inline Mat::Mat(const Point3_<_Tp>& pt, bool copyData)
00265     : flags(MAGIC_VAL | DataType<_Tp>::type | CV_MAT_CONT_FLAG),
00266     dims(2), rows(3), cols(1), data(0), refcount(0),
00267     datastart(0), dataend(0), allocator(0), size(&rows)
00268 {
00269     if( !copyData )
00270     {
00271         step[0] = step[1] = sizeof(_Tp);
00272         data = datastart = (uchar*)&pt.x;
00273         datalimit = dataend = datastart + rows*step[0];
00274     }
00275     else
00276     {
00277         create(3, 1, DataType<_Tp>::type);
00278         ((_Tp*)data)[0] = pt.x;
00279         ((_Tp*)data)[1] = pt.y;
00280         ((_Tp*)data)[2] = pt.z;
00281     }
00282 }
00283 
00284     
00285 template<typename _Tp> inline Mat::Mat(const MatCommaInitializer_<_Tp>& commaInitializer)
00286     : flags(MAGIC_VAL | DataType<_Tp>::type | CV_MAT_CONT_FLAG),
00287     dims(0), rows(0), cols(0), data(0), refcount(0),
00288     datastart(0), dataend(0), allocator(0), size(&rows)
00289 {
00290     *this = *commaInitializer;
00291 }
00292     
00293 inline Mat::~Mat()
00294 {
00295     release();
00296     if( step.p != step.buf )
00297         fastFree(step.p);
00298 }
00299 
00300 inline Mat& Mat::operator = (const Mat& m)
00301 {
00302     if( this != &m )
00303     {
00304         if( m.refcount )
00305             CV_XADD(m.refcount, 1);
00306         release();
00307         flags = m.flags;
00308         if( dims <= 2 && m.dims <= 2 )
00309         {
00310             dims = m.dims;
00311             rows = m.rows;
00312             cols = m.cols;
00313             step[0] = m.step[0];
00314             step[1] = m.step[1];
00315         }
00316         else
00317             copySize(m);
00318         data = m.data;
00319         datastart = m.datastart;
00320         dataend = m.dataend;
00321         datalimit = m.datalimit;
00322         refcount = m.refcount;
00323         allocator = m.allocator;
00324     }
00325     return *this;
00326 }
00327     
00328 inline Mat Mat::row(int y) const { return Mat(*this, Range(y, y+1), Range::all()); }
00329 inline Mat Mat::col(int x) const { return Mat(*this, Range::all(), Range(x, x+1)); }
00330 inline Mat Mat::rowRange(int startrow, int endrow) const
00331     { return Mat(*this, Range(startrow, endrow), Range::all()); }
00332 inline Mat Mat::rowRange(const Range& r) const
00333     { return Mat(*this, r, Range::all()); }
00334 inline Mat Mat::colRange(int startcol, int endcol) const
00335     { return Mat(*this, Range::all(), Range(startcol, endcol)); }
00336 inline Mat Mat::colRange(const Range& r) const
00337     { return Mat(*this, Range::all(), r); }
00338 
00339 inline Mat Mat::diag(const Mat& d)
00340 {
00341     Mat m(d.rows, d.rows, d.type(), Scalar(0)), md = m.diag();
00342     d.copyTo(md);
00343     return m;
00344 }
00345 
00346 inline Mat Mat::clone() const
00347 {
00348     Mat m;
00349     copyTo(m);
00350     return m;
00351 }
00352 
00353 inline void Mat::assignTo( Mat& m, int type ) const
00354 {
00355     if( type < 0 )
00356         m = *this;
00357     else
00358         convertTo(m, type);
00359 }
00360 
00361 inline void Mat::create(int _rows, int _cols, int _type)
00362 {
00363     _type &= TYPE_MASK;
00364     if( dims <= 2 && rows == _rows && cols == _cols && type() == _type && data )
00365         return;
00366     int sz[] = {_rows, _cols};
00367     create(2, sz, _type);
00368 }
00369 
00370 inline void Mat::create(Size _sz, int _type)
00371 {
00372     create(_sz.height, _sz.width, _type);
00373 }
00374 
00375 inline void Mat::addref()
00376 { if( refcount ) CV_XADD(refcount, 1); }
00377 
00378 inline void Mat::release()
00379 {
00380     if( refcount && CV_XADD(refcount, -1) == 1 )
00381         deallocate();
00382     data = datastart = dataend = datalimit = 0;
00383     size.p[0] = 0;
00384     refcount = 0;
00385 }
00386 
00387 inline Mat Mat::operator()( Range rowRange, Range colRange ) const
00388 {
00389     return Mat(*this, rowRange, colRange);
00390 }
00391     
00392 inline Mat Mat::operator()( const Rect& roi ) const
00393 { return Mat(*this, roi); }
00394 
00395 inline Mat Mat::operator()(const Range* ranges) const
00396 {
00397     return Mat(*this, ranges);
00398 }    
00399     
00400 inline Mat::operator CvMat() const
00401 {
00402     CV_DbgAssert(dims <= 2);
00403     CvMat m = cvMat(rows, dims == 1 ? 1 : cols, type(), data);
00404     m.step = (int)step[0];
00405     m.type = (m.type & ~CONTINUOUS_FLAG) | (flags & CONTINUOUS_FLAG);
00406     return m;
00407 }
00408 
00409 inline bool Mat::isContinuous() const { return (flags & CONTINUOUS_FLAG) != 0; }
00410 inline bool Mat::isSubmatrix() const { return (flags & SUBMATRIX_FLAG) != 0; }
00411 inline size_t Mat::elemSize() const { return dims > 0 ? step.p[dims-1] : 0; }
00412 inline size_t Mat::elemSize1() const { return CV_ELEM_SIZE1(flags); }
00413 inline int Mat::type() const { return CV_MAT_TYPE(flags); }
00414 inline int Mat::depth() const { return CV_MAT_DEPTH(flags); }
00415 inline int Mat::channels() const { return CV_MAT_CN(flags); }
00416 inline size_t Mat::step1(int i) const { return step.p[i]/elemSize1(); }
00417 inline bool Mat::empty() const { return data == 0 || total() == 0; }
00418 inline size_t Mat::total() const
00419 {
00420     if( dims <= 2 )
00421         return rows*cols;
00422     size_t p = 1;
00423     for( int i = 0; i < dims; i++ )
00424         p *= size[i];
00425     return p;
00426 }
00427 
00428 inline uchar* Mat::ptr(int y)
00429 {
00430     CV_DbgAssert( data && dims >= 1 && (unsigned)y < (unsigned)size.p[0] );
00431     return data + step.p[0]*y;
00432 }
00433 
00434 inline const uchar* Mat::ptr(int y) const
00435 {
00436     CV_DbgAssert( data && dims >= 1 && (unsigned)y < (unsigned)size.p[0] );
00437     return data + step.p[0]*y;
00438 }
00439 
00440 template<typename _Tp> inline _Tp* Mat::ptr(int y)
00441 {
00442     CV_DbgAssert( data && dims >= 1 && (unsigned)y < (unsigned)size.p[0] );
00443     return (_Tp*)(data + step.p[0]*y);
00444 }
00445 
00446 template<typename _Tp> inline const _Tp* Mat::ptr(int y) const
00447 {
00448     CV_DbgAssert( dims >= 1 && data && (unsigned)y < (unsigned)size.p[0] );
00449     return (const _Tp*)(data + step.p[0]*y);
00450 }
00451 
00452     
00453 inline uchar* Mat::ptr(int i0, int i1)
00454 {
00455     CV_DbgAssert( dims >= 2 && data &&
00456                   (unsigned)i0 < (unsigned)size.p[0] &&
00457                   (unsigned)i1 < (unsigned)size.p[1] );
00458     return data + i0*step.p[0] + i1*step.p[1];
00459 }
00460 
00461 inline const uchar* Mat::ptr(int i0, int i1) const
00462 {
00463     CV_DbgAssert( dims >= 2 && data &&
00464                  (unsigned)i0 < (unsigned)size.p[0] &&
00465                  (unsigned)i1 < (unsigned)size.p[1] );
00466     return data + i0*step.p[0] + i1*step.p[1];
00467 }
00468 
00469 inline uchar* Mat::ptr(int i0, int i1, int i2)
00470 {
00471     CV_DbgAssert( dims >= 3 && data &&
00472                   (unsigned)i0 < (unsigned)size.p[0] &&
00473                   (unsigned)i1 < (unsigned)size.p[1] &&
00474                   (unsigned)i2 < (unsigned)size.p[2] );
00475     return data + i0*step.p[0] + i1*step.p[1] + i2*step.p[2];
00476 }
00477 
00478 inline const uchar* Mat::ptr(int i0, int i1, int i2) const
00479 {
00480     CV_DbgAssert( dims >= 3 && data &&
00481                   (unsigned)i0 < (unsigned)size.p[0] &&
00482                   (unsigned)i1 < (unsigned)size.p[1] &&
00483                   (unsigned)i2 < (unsigned)size.p[2] );
00484     return data + i0*step.p[0] + i1*step.p[1] + i2*step.p[2];
00485 }
00486 
00487 inline uchar* Mat::ptr(const int* idx)
00488 {    
00489     int i, d = dims;
00490     uchar* p = data;
00491     CV_DbgAssert( d >= 1 && p );
00492     for( i = 0; i < d; i++ )
00493     {
00494         CV_DbgAssert( (unsigned)idx[i] < (unsigned)size.p[i] );
00495         p += idx[i]*step.p[i];
00496     }
00497     return p;
00498 }
00499 
00500 inline const uchar* Mat::ptr(const int* idx) const
00501 {
00502     int i, d = dims;
00503     uchar* p = data;
00504     CV_DbgAssert( d >= 1 && p );
00505     for( i = 0; i < d; i++ )
00506     {
00507         CV_DbgAssert( (unsigned)idx[i] < (unsigned)size.p[i] );
00508         p += idx[i]*step.p[i];
00509     }
00510     return p;
00511 }    
00512     
00513 template<typename _Tp> inline _Tp& Mat::at(int i0, int i1)
00514 {
00515     CV_DbgAssert( dims <= 2 && data && (unsigned)i0 < (unsigned)size.p[0] &&
00516         (unsigned)(i1*DataType<_Tp>::channels) < (unsigned)(size.p[1]*channels()) &&
00517         CV_ELEM_SIZE1(DataType<_Tp>::depth) == elemSize1());
00518     return ((_Tp*)(data + step.p[0]*i0))[i1];
00519 }
00520 
00521 template<typename _Tp> inline const _Tp& Mat::at(int i0, int i1) const
00522 {
00523     CV_DbgAssert( dims <= 2 && data && (unsigned)i0 < (unsigned)size.p[0] &&
00524         (unsigned)(i1*DataType<_Tp>::channels) < (unsigned)(size.p[1]*channels()) &&
00525         CV_ELEM_SIZE1(DataType<_Tp>::depth) == elemSize1());
00526     return ((const _Tp*)(data + step.p[0]*i0))[i1];
00527 }
00528     
00529 template<typename _Tp> inline _Tp& Mat::at(Point pt)
00530 {
00531     CV_DbgAssert( dims <= 2 && data && (unsigned)pt.y < (unsigned)size.p[0] &&
00532         (unsigned)(pt.x*DataType<_Tp>::channels) < (unsigned)(size.p[1]*channels()) &&
00533         CV_ELEM_SIZE1(DataType<_Tp>::depth) == elemSize1());
00534     return ((_Tp*)(data + step.p[0]*pt.y))[pt.x];
00535 }
00536 
00537 template<typename _Tp> inline const _Tp& Mat::at(Point pt) const
00538 {
00539     CV_DbgAssert( dims <= 2 && data && (unsigned)pt.y < (unsigned)size.p[0] &&
00540         (unsigned)(pt.x*DataType<_Tp>::channels) < (unsigned)(size.p[1]*channels()) &&
00541         CV_ELEM_SIZE1(DataType<_Tp>::depth) == elemSize1());
00542     return ((const _Tp*)(data + step.p[0]*pt.y))[pt.x];
00543 }
00544 
00545 template<typename _Tp> inline _Tp& Mat::at(int i0)
00546 {
00547     CV_DbgAssert( dims <= 2 && data && (size.p[0] == 1 || size.p[1] == 1) &&
00548                  (unsigned)i0 < (unsigned)(size.p[0] + size.p[1] - 1) &&
00549                  elemSize() == CV_ELEM_SIZE(DataType<_Tp>::type) );
00550     return *(_Tp*)(data + step.p[size.p[0]==1]*i0);
00551 }
00552     
00553 template<typename _Tp> inline const _Tp& Mat::at(int i0) const
00554 {
00555     CV_DbgAssert( dims <= 2 && data && (size.p[0] == 1 || size.p[1] == 1) &&
00556                  (unsigned)i0 < (unsigned)(size.p[0] + size.p[1] - 1) &&
00557                  elemSize() == CV_ELEM_SIZE(DataType<_Tp>::type) );
00558     return *(_Tp*)(data + step.p[size.p[0]==1]*i0);
00559 }
00560     
00561 template<typename _Tp> inline _Tp& Mat::at(int i0, int i1, int i2)
00562 {
00563     CV_DbgAssert( elemSize() == CV_ELEM_SIZE(DataType<_Tp>::type) );
00564     return *(_Tp*)ptr(i0, i1, i2);
00565 }
00566 template<typename _Tp> inline const _Tp& Mat::at(int i0, int i1, int i2) const
00567 {
00568     CV_DbgAssert( elemSize() == CV_ELEM_SIZE(DataType<_Tp>::type) );
00569     return *(const _Tp*)ptr(i0, i1, i2);
00570 }
00571 template<typename _Tp> inline _Tp& Mat::at(const int* idx)
00572 {
00573     CV_DbgAssert( elemSize() == CV_ELEM_SIZE(DataType<_Tp>::type) );
00574     return *(_Tp*)ptr(idx);
00575 }
00576 template<typename _Tp> inline const _Tp& Mat::at(const int* idx) const
00577 {
00578     CV_DbgAssert( elemSize() == CV_ELEM_SIZE(DataType<_Tp>::type) );
00579     return *(const _Tp*)ptr(idx);
00580 }
00581     
00582     
00583 template<typename _Tp> inline MatConstIterator_<_Tp> Mat::begin() const
00584 {
00585     CV_DbgAssert( elemSize() == sizeof(_Tp) );
00586     return MatConstIterator_<_Tp>((const Mat_<_Tp>*)this);
00587 }
00588 
00589 template<typename _Tp> inline MatConstIterator_<_Tp> Mat::end() const
00590 {
00591     CV_DbgAssert( elemSize() == sizeof(_Tp) );
00592     MatConstIterator_<_Tp> it((const Mat_<_Tp>*)this);
00593     it += total();
00594     return it;
00595 }
00596 
00597 template<typename _Tp> inline MatIterator_<_Tp> Mat::begin()
00598 {
00599     CV_DbgAssert( elemSize() == sizeof(_Tp) );
00600     return MatIterator_<_Tp>((Mat_<_Tp>*)this);
00601 }
00602 
00603 template<typename _Tp> inline MatIterator_<_Tp> Mat::end()
00604 {
00605     CV_DbgAssert( elemSize() == sizeof(_Tp) );
00606     MatIterator_<_Tp> it((Mat_<_Tp>*)this);
00607     it += total();
00608     return it;
00609 }
00610 
00611     
00612 template<typename _Tp> inline void Mat::copyTo(vector<_Tp>& v) const
00613 {
00614     int n = checkVector(DataType<_Tp>::channels);
00615     if( empty() || n == 0 )
00616     {
00617         v.clear();
00618         return;
00619     }
00620     CV_Assert( n > 0 );
00621     v.resize(n);
00622     Mat temp(dims, size.p, DataType<_Tp>::type, &v[0]);
00623     convertTo(temp, DataType<_Tp>::type);
00624 }    
00625     
00626 template<typename _Tp> inline Mat::operator vector<_Tp>() const
00627 {
00628     vector<_Tp> v;
00629     copyTo(v);
00630     return v;
00631 }
00632 
00633 template<typename _Tp, int n> inline Mat::operator Vec<_Tp, n>() const
00634 {
00635     CV_Assert( data && dims <= 2 && (rows == 1 || cols == 1) &&
00636                rows + cols - 1 == n && channels() == 1 );
00637     
00638     if( isContinuous() && type() == DataType<_Tp>::type )
00639         return Vec<_Tp, n>((_Tp*)data);
00640     Vec<_Tp, n> v; Mat tmp(rows, cols, DataType<_Tp>::type, v.val);
00641     convertTo(tmp, tmp.type());
00642     return v;
00643 }
00644     
00645 template<typename _Tp, int m, int n> inline Mat::operator Matx<_Tp, m, n>() const
00646 {
00647     CV_Assert( data && dims <= 2 && rows == m && cols == n && channels() == 1 );
00648     
00649     if( isContinuous() && type() == DataType<_Tp>::type )
00650         return Matx<_Tp, m, n>((_Tp*)data);
00651     Matx<_Tp, m, n> mtx; Mat tmp(rows, cols, DataType<_Tp>::type, mtx.val);
00652     convertTo(tmp, tmp.type());
00653     return mtx;
00654 }
00655 
00656 
00657 template<typename _Tp> inline void Mat::push_back(const _Tp& elem)
00658 {
00659     CV_Assert(DataType<_Tp>::type == type() && cols == 1
00660               /* && dims == 2 (cols == 1 implies dims == 2) */);
00661     uchar* tmp = dataend + step[0];
00662     if( !isSubmatrix() && isContinuous() && tmp <= datalimit )
00663     {
00664         *(_Tp*)(data + (size.p[0]++)*step.p[0]) = elem;
00665         dataend = tmp;
00666     }
00667     else
00668         push_back_(&elem);
00669 }
00670     
00671 template<typename _Tp> inline void Mat::push_back(const Mat_<_Tp>& m)
00672 {
00673     push_back((const Mat&)m);
00674 }    
00675     
00676 inline Mat::MSize::MSize(int* _p) : p(_p) {}
00677 inline Size Mat::MSize::operator()() const
00678 {
00679     CV_DbgAssert(p[-1] <= 2); 
00680     return Size(p[1], p[0]);
00681 }
00682 inline const int& Mat::MSize::operator[](int i) const { return p[i]; }
00683 inline int& Mat::MSize::operator[](int i) { return p[i]; }
00684 inline Mat::MSize::operator const int*() const { return p; }
00685 
00686 inline bool Mat::MSize::operator == (const MSize& sz) const
00687 {
00688     int d = p[-1], dsz = sz.p[-1];
00689     if( d != dsz )
00690         return false;
00691     if( d == 2 )
00692         return p[0] == sz.p[0] && p[1] == sz.p[1];
00693     
00694     for( int i = 0; i < d; i++ )
00695         if( p[i] != sz.p[i] )
00696             return false;
00697     return true;
00698 }    
00699 
00700 inline bool Mat::MSize::operator != (const MSize& sz) const
00701 {
00702     return !(*this == sz);
00703 }
00704     
00705 inline Mat::MStep::MStep() { p = buf; p[0] = p[1] = 0; }
00706 inline Mat::MStep::MStep(size_t s) { p = buf; p[0] = s; p[1] = 0; }
00707 inline const size_t& Mat::MStep::operator[](int i) const { return p[i]; }
00708 inline size_t& Mat::MStep::operator[](int i) { return p[i]; }
00709 inline Mat::MStep::operator size_t() const
00710 {
00711     CV_DbgAssert( p == buf );
00712     return buf[0];
00713 }
00714 inline Mat::MStep& Mat::MStep::operator = (size_t s)
00715 {
00716     CV_DbgAssert( p == buf );
00717     buf[0] = s;
00718     return *this;
00719 }
00720     
00721 static inline Mat cvarrToMatND(const CvArr* arr, bool copyData=false, int coiMode=0)
00722 {
00723     return cvarrToMat(arr, copyData, true, coiMode);
00724 }
00725 
00727 
00728 inline SVD::SVD() {}
00729 inline SVD::SVD( const Mat& m, int flags ) { operator ()(m, flags); }
00730 inline void SVD::solveZ( const Mat& m, Mat& dst )
00731 {
00732     SVD svd(m);
00733     svd.vt.row(svd.vt.rows-1).reshape(1,svd.vt.cols).copyTo(dst);
00734 }
00735 
00736 template<typename _Tp, int m, int n, int nm> inline void
00737     SVD::compute( const Matx<_Tp, m, n>& a, Matx<_Tp, nm, 1>& w, Matx<_Tp, m, nm>& u, Matx<_Tp, n, nm>& vt )
00738 {
00739     assert( nm == MIN(m, n));
00740     Mat _a(a, false), _u(u, false), _w(w, false), _vt(vt, false);
00741     SVD::compute(_a, _w, _u, _vt);
00742     CV_Assert(_w.data == (uchar*)&w.val[0] && _u.data == (uchar*)&u.val[0] && _vt.data == (uchar*)&vt.val[0]);
00743 }
00744     
00745 template<typename _Tp, int m, int n, int nm> inline void
00746 SVD::compute( const Matx<_Tp, m, n>& a, Matx<_Tp, nm, 1>& w )
00747 {
00748     assert( nm == MIN(m, n));
00749     Mat _a(a, false), _w(w, false);
00750     SVD::compute(_a, _w);
00751     CV_Assert(_w.data == (uchar*)&w.val[0]);
00752 }
00753     
00754 template<typename _Tp, int m, int n, int nm, int nb> inline void
00755 SVD::backSubst( const Matx<_Tp, nm, 1>& w, const Matx<_Tp, m, nm>& u,
00756                 const Matx<_Tp, n, nm>& vt, const Matx<_Tp, m, nb>& rhs,
00757                 Matx<_Tp, n, nb>& dst )
00758 {
00759     assert( nm == MIN(m, n));
00760     Mat _u(u, false), _w(w, false), _vt(vt, false), _rhs(rhs, false), _dst(dst, false);
00761     SVD::backSubst(_w, _u, _vt, _rhs, _dst);
00762     CV_Assert(_dst.data == (uchar*)&dst.val[0]);
00763 }
00764     
00766 
00767 template<typename _Tp> inline Mat_<_Tp>::Mat_()
00768     : Mat() { flags = (flags & ~CV_MAT_TYPE_MASK) | DataType<_Tp>::type; }
00769     
00770 template<typename _Tp> inline Mat_<_Tp>::Mat_(int _rows, int _cols)
00771     : Mat(_rows, _cols, DataType<_Tp>::type) {}
00772 
00773 template<typename _Tp> inline Mat_<_Tp>::Mat_(int _rows, int _cols, const _Tp& value)
00774     : Mat(_rows, _cols, DataType<_Tp>::type) { *this = value; }
00775 
00776 template<typename _Tp> inline Mat_<_Tp>::Mat_(Size _sz)
00777     : Mat(_sz.height, _sz.width, DataType<_Tp>::type) {}
00778     
00779 template<typename _Tp> inline Mat_<_Tp>::Mat_(Size _sz, const _Tp& value)
00780     : Mat(_sz.height, _sz.width, DataType<_Tp>::type) { *this = value; }
00781     
00782 template<typename _Tp> inline Mat_<_Tp>::Mat_(int _dims, const int* _sz)
00783     : Mat(_dims, _sz, DataType<_Tp>::type) {}
00784     
00785 template<typename _Tp> inline Mat_<_Tp>::Mat_(int _dims, const int* _sz, const _Tp& _s)
00786     : Mat(_dims, _sz, DataType<_Tp>::type, Scalar(_s)) {}
00787     
00788 template<typename _Tp> inline Mat_<_Tp>::Mat_(const Mat_<_Tp>& m, const Range* ranges)
00789     : Mat(m, ranges) {}
00790     
00791 template<typename _Tp> inline Mat_<_Tp>::Mat_(const Mat& m)
00792     : Mat() { flags = (flags & ~CV_MAT_TYPE_MASK) | DataType<_Tp>::type; *this = m; }
00793 
00794 template<typename _Tp> inline Mat_<_Tp>::Mat_(const Mat_& m)
00795     : Mat(m) {}
00796 
00797 template<typename _Tp> inline Mat_<_Tp>::Mat_(int _rows, int _cols, _Tp* _data, size_t steps)
00798     : Mat(_rows, _cols, DataType<_Tp>::type, _data, steps) {}
00799 
00800 template<typename _Tp> inline Mat_<_Tp>::Mat_(const Mat_& m, const Range& rowRange, const Range& colRange)
00801     : Mat(m, rowRange, colRange) {}
00802 
00803 template<typename _Tp> inline Mat_<_Tp>::Mat_(const Mat_& m, const Rect& roi)
00804     : Mat(m, roi) {}
00805 
00806 template<typename _Tp> template<int n> inline
00807     Mat_<_Tp>::Mat_(const Vec<typename DataType<_Tp>::channel_type, n>& vec, bool copyData)
00808     : Mat(n/DataType<_Tp>::channels, 1, DataType<_Tp>::type, (void*)&vec)
00809 {
00810     CV_Assert(n%DataType<_Tp>::channels == 0);
00811     if( copyData )
00812         *this = clone();
00813 }
00814 
00815 template<typename _Tp> template<int m, int n> inline
00816     Mat_<_Tp>::Mat_(const Matx<typename DataType<_Tp>::channel_type,m,n>& M, bool copyData)
00817     : Mat(m, n/DataType<_Tp>::channels, DataType<_Tp>::type, (void*)&M)
00818 {
00819     CV_Assert(n % DataType<_Tp>::channels == 0);
00820     if( copyData )
00821         *this = clone();
00822 }
00823     
00824 template<typename _Tp> inline Mat_<_Tp>::Mat_(const Point_<typename DataType<_Tp>::channel_type>& pt, bool copyData)
00825     : Mat(2/DataType<_Tp>::channels, 1, DataType<_Tp>::type, (void*)&pt)
00826 {
00827     CV_Assert(2 % DataType<_Tp>::channels == 0);
00828     if( copyData )
00829         *this = clone();
00830 }
00831 
00832 template<typename _Tp> inline Mat_<_Tp>::Mat_(const Point3_<typename DataType<_Tp>::channel_type>& pt, bool copyData)
00833     : Mat(3/DataType<_Tp>::channels, 1, DataType<_Tp>::type, (void*)&pt)
00834 {
00835     CV_Assert(3 % DataType<_Tp>::channels == 0);
00836     if( copyData )
00837         *this = clone();
00838 }
00839 
00840 template<typename _Tp> inline Mat_<_Tp>::Mat_(const MatCommaInitializer_<_Tp>& commaInitializer)
00841     : Mat(commaInitializer) {}
00842     
00843 template<typename _Tp> inline Mat_<_Tp>::Mat_(const vector<_Tp>& vec, bool copyData)
00844     : Mat(vec, copyData) {}
00845 
00846 template<typename _Tp> inline Mat_<_Tp>& Mat_<_Tp>::operator = (const Mat& m)
00847 {
00848     if( DataType<_Tp>::type == m.type() )
00849     {
00850         Mat::operator = (m);
00851         return *this;
00852     }
00853     if( DataType<_Tp>::depth == m.depth() )
00854     {
00855         return (*this = m.reshape(DataType<_Tp>::channels, m.dims, 0));
00856     }
00857     CV_DbgAssert(DataType<_Tp>::channels == m.channels());
00858     m.convertTo(*this, type());
00859     return *this;
00860 }
00861 
00862 template<typename _Tp> inline Mat_<_Tp>& Mat_<_Tp>::operator = (const Mat_& m)
00863 {
00864     Mat::operator=(m);
00865     return *this;
00866 }
00867 
00868 template<typename _Tp> inline Mat_<_Tp>& Mat_<_Tp>::operator = (const _Tp& s)
00869 {
00870     typedef typename DataType<_Tp>::vec_type VT;
00871     Mat::operator=(Scalar((const VT&)s));
00872     return *this;
00873 }
00874     
00875 
00876 template<typename _Tp> inline void Mat_<_Tp>::create(int _rows, int _cols)
00877 {
00878     Mat::create(_rows, _cols, DataType<_Tp>::type);
00879 }
00880 
00881 template<typename _Tp> inline void Mat_<_Tp>::create(Size _sz)
00882 {
00883     Mat::create(_sz, DataType<_Tp>::type);
00884 }
00885 
00886 template<typename _Tp> inline void Mat_<_Tp>::create(int _dims, const int* _sz)
00887 {
00888     Mat::create(_dims, _sz, DataType<_Tp>::type);
00889 }    
00890     
00891     
00892 template<typename _Tp> inline Mat_<_Tp> Mat_<_Tp>::cross(const Mat_& m) const
00893 { return Mat_<_Tp>(Mat::cross(m)); }
00894 
00895 template<typename _Tp> template<typename T2> inline Mat_<_Tp>::operator Mat_<T2>() const
00896 { return Mat_<T2>(*this); }
00897 
00898 template<typename _Tp> inline Mat_<_Tp> Mat_<_Tp>::row(int y) const
00899 { return Mat_(*this, Range(y, y+1), Range::all()); }
00900 template<typename _Tp> inline Mat_<_Tp> Mat_<_Tp>::col(int x) const
00901 { return Mat_(*this, Range::all(), Range(x, x+1)); }
00902 template<typename _Tp> inline Mat_<_Tp> Mat_<_Tp>::diag(int d) const
00903 { return Mat_(Mat::diag(d)); }
00904 template<typename _Tp> inline Mat_<_Tp> Mat_<_Tp>::clone() const
00905 { return Mat_(Mat::clone()); }
00906 
00907 template<typename _Tp> inline size_t Mat_<_Tp>::elemSize() const
00908 {
00909     CV_DbgAssert( Mat::elemSize() == sizeof(_Tp) );
00910     return sizeof(_Tp);
00911 }
00912 
00913 template<typename _Tp> inline size_t Mat_<_Tp>::elemSize1() const
00914 {
00915     CV_DbgAssert( Mat::elemSize1() == sizeof(_Tp)/DataType<_Tp>::channels );
00916     return sizeof(_Tp)/DataType<_Tp>::channels;
00917 }
00918 template<typename _Tp> inline int Mat_<_Tp>::type() const
00919 {
00920     CV_DbgAssert( Mat::type() == DataType<_Tp>::type );
00921     return DataType<_Tp>::type;
00922 }
00923 template<typename _Tp> inline int Mat_<_Tp>::depth() const
00924 {
00925     CV_DbgAssert( Mat::depth() == DataType<_Tp>::depth );
00926     return DataType<_Tp>::depth;
00927 }
00928 template<typename _Tp> inline int Mat_<_Tp>::channels() const
00929 {
00930     CV_DbgAssert( Mat::channels() == DataType<_Tp>::channels );
00931     return DataType<_Tp>::channels;
00932 }
00933 template<typename _Tp> inline size_t Mat_<_Tp>::stepT(int i) const { return step.p[i]/elemSize(); }
00934 template<typename _Tp> inline size_t Mat_<_Tp>::step1(int i) const { return step.p[i]/elemSize1(); }
00935 
00936 template<typename _Tp> inline Mat_<_Tp> Mat_<_Tp>::reshape(int _rows) const
00937 { return Mat_<_Tp>(Mat::reshape(0,_rows)); }
00938 
00939 template<typename _Tp> inline Mat_<_Tp>& Mat_<_Tp>::adjustROI( int dtop, int dbottom, int dleft, int dright )
00940 { return (Mat_<_Tp>&)(Mat::adjustROI(dtop, dbottom, dleft, dright));  }
00941 
00942 template<typename _Tp> inline Mat_<_Tp> Mat_<_Tp>::operator()( const Range& rowRange, const Range& colRange ) const
00943 { return Mat_<_Tp>(*this, rowRange, colRange); }
00944 
00945 template<typename _Tp> inline Mat_<_Tp> Mat_<_Tp>::operator()( const Rect& roi ) const
00946 { return Mat_<_Tp>(*this, roi); }
00947 
00948 template<typename _Tp> inline Mat_<_Tp> Mat_<_Tp>::operator()( const Range* ranges ) const
00949 { return Mat_<_Tp>(*this, ranges); }    
00950     
00951 template<typename _Tp> inline _Tp* Mat_<_Tp>::operator [](int y)
00952 { return (_Tp*)ptr(y); }
00953 template<typename _Tp> inline const _Tp* Mat_<_Tp>::operator [](int y) const
00954 { return (const _Tp*)ptr(y); }
00955 
00956 template<typename _Tp> inline _Tp& Mat_<_Tp>::operator ()(int i0, int i1)
00957 {
00958     CV_DbgAssert( dims <= 2 && data &&
00959                   (unsigned)i0 < (unsigned)size.p[0] &&
00960                   (unsigned)i1 < (unsigned)size.p[1] &&
00961                   type() == DataType<_Tp>::type );
00962     return ((_Tp*)(data + step.p[0]*i0))[i1];
00963 }
00964 
00965 template<typename _Tp> inline const _Tp& Mat_<_Tp>::operator ()(int i0, int i1) const
00966 {
00967     CV_DbgAssert( dims <= 2 && data &&
00968                   (unsigned)i0 < (unsigned)size.p[0] &&
00969                   (unsigned)i1 < (unsigned)size.p[1] &&
00970                   type() == DataType<_Tp>::type );
00971     return ((const _Tp*)(data + step.p[0]*i0))[i1];
00972 }
00973 
00974 template<typename _Tp> inline _Tp& Mat_<_Tp>::operator ()(Point pt)
00975 {
00976     CV_DbgAssert( dims <= 2 && data &&
00977                   (unsigned)pt.y < (unsigned)size.p[0] &&
00978                   (unsigned)pt.x < (unsigned)size.p[1] &&
00979                   type() == DataType<_Tp>::type );
00980     return ((_Tp*)(data + step.p[0]*pt.y))[pt.x];
00981 }
00982 
00983 template<typename _Tp> inline const _Tp& Mat_<_Tp>::operator ()(Point pt) const
00984 {
00985     CV_DbgAssert( dims <= 2 && data &&
00986                   (unsigned)pt.y < (unsigned)size.p[0] &&
00987                   (unsigned)pt.x < (unsigned)size.p[1] &&
00988                  type() == DataType<_Tp>::type );
00989     return ((const _Tp*)(data + step.p[0]*pt.y))[pt.x];
00990 }
00991 
00992 template<typename _Tp> inline _Tp& Mat_<_Tp>::operator ()(const int* idx)
00993 {
00994     return Mat::at<_Tp>(idx);
00995 }
00996 
00997 template<typename _Tp> inline const _Tp& Mat_<_Tp>::operator ()(const int* idx) const
00998 {
00999     return Mat::at<_Tp>(idx);
01000 }
01001 
01002 template<typename _Tp> inline _Tp& Mat_<_Tp>::operator ()(int i0)
01003 {
01004     return this->at<_Tp>(i0);
01005 }
01006 
01007 template<typename _Tp> inline const _Tp& Mat_<_Tp>::operator ()(int i0) const
01008 {
01009     return this->at<_Tp>(i0);
01010 }    
01011 
01012 template<typename _Tp> inline _Tp& Mat_<_Tp>::operator ()(int i0, int i1, int i2)
01013 {
01014     return this->at<_Tp>(i0, i1, i2);
01015 }
01016 
01017 template<typename _Tp> inline const _Tp& Mat_<_Tp>::operator ()(int i0, int i1, int i2) const
01018 {
01019     return this->at<_Tp>(i0, i1, i2);
01020 }    
01021     
01022     
01023 template<typename _Tp> inline Mat_<_Tp>::operator vector<_Tp>() const
01024 {
01025     vector<_Tp> v;
01026     copyTo(v);
01027     return v;
01028 }
01029 
01030 template<typename _Tp> template<int n> inline Mat_<_Tp>::operator Vec<typename DataType<_Tp>::channel_type, n>() const
01031 {
01032     CV_Assert(n % DataType<_Tp>::channels == 0);
01033     return this->Mat::operator Vec<typename DataType<_Tp>::channel_type, n>();
01034 }
01035 
01036 template<typename _Tp> template<int m, int n> inline Mat_<_Tp>::operator Matx<typename DataType<_Tp>::channel_type, m, n>() const
01037 {
01038     CV_Assert(n % DataType<_Tp>::channels == 0);
01039     return this->Mat::operator Matx<typename DataType<_Tp>::channel_type, m, n>();
01040 }    
01041 
01042 template<typename T1, typename T2, typename Op> inline void
01043 process( const Mat_<T1>& m1, Mat_<T2>& m2, Op op )
01044 {
01045     int y, x, rows = m1.rows, cols = m1.cols;
01046     int c1 = m1.channels(), c2 = m2.channels();
01047 
01048     CV_DbgAssert( m1.size() == m2.size() );
01049 
01050     for( y = 0; y < rows; y++ )
01051     {
01052         const T1* src = m1[y];
01053         T2* dst = m2[y];
01054 
01055         for( x = 0; x < cols; x++ )
01056             dst[x] = op(src[x]);
01057     }
01058 }
01059 
01060 template<typename T1, typename T2, typename T3, typename Op> inline void
01061 process( const Mat_<T1>& m1, const Mat_<T2>& m2, Mat_<T3>& m3, Op op )
01062 {
01063     int y, x, rows = m1.rows, cols = m1.cols;
01064 
01065     CV_DbgAssert( m1.size() == m2.size() );
01066 
01067     for( y = 0; y < rows; y++ )
01068     {
01069         const T1* src1 = m1[y];
01070         const T2* src2 = m2[y];
01071         T3* dst = m3[y];
01072 
01073         for( x = 0; x < cols; x++ )
01074             dst[x] = op( src1[x], src2[x] );
01075     }
01076 }
01077 
01079 
01080 class CV_EXPORTS MatOp
01081 {    
01082 public:
01083     MatOp() {};
01084     virtual ~MatOp() {};
01085     
01086     virtual bool elementWise(const MatExpr& expr) const;
01087     virtual void assign(const MatExpr& expr, Mat& m, int type=-1) const = 0;
01088     virtual void roi(const MatExpr& expr, const Range& rowRange,
01089                      const Range& colRange, MatExpr& res) const;
01090     virtual void diag(const MatExpr& expr, int d, MatExpr& res) const;
01091     virtual void augAssignAdd(const MatExpr& expr, Mat& m) const;
01092     virtual void augAssignSubtract(const MatExpr& expr, Mat& m) const;
01093     virtual void augAssignMultiply(const MatExpr& expr, Mat& m) const;
01094     virtual void augAssignDivide(const MatExpr& expr, Mat& m) const;
01095     virtual void augAssignAnd(const MatExpr& expr, Mat& m) const;
01096     virtual void augAssignOr(const MatExpr& expr, Mat& m) const;
01097     virtual void augAssignXor(const MatExpr& expr, Mat& m) const;
01098     
01099     virtual void add(const MatExpr& expr1, const MatExpr& expr2, MatExpr& res) const;
01100     virtual void add(const MatExpr& expr1, const Scalar& s, MatExpr& res) const;
01101     
01102     virtual void subtract(const MatExpr& expr1, const MatExpr& expr2, MatExpr& res) const;
01103     virtual void subtract(const Scalar& s, const MatExpr& expr, MatExpr& res) const;
01104     
01105     virtual void multiply(const MatExpr& expr1, const MatExpr& expr2, MatExpr& res, double scale=1) const;
01106     virtual void multiply(const MatExpr& expr1, double s, MatExpr& res) const;
01107     
01108     virtual void divide(const MatExpr& expr1, const MatExpr& expr2, MatExpr& res, double scale=1) const;
01109     virtual void divide(double s, const MatExpr& expr, MatExpr& res) const;
01110         
01111     virtual void abs(const MatExpr& expr, MatExpr& res) const;
01112     
01113     virtual void transpose(const MatExpr& expr, MatExpr& res) const;
01114     virtual void matmul(const MatExpr& expr1, const MatExpr& expr2, MatExpr& res) const;
01115     virtual void invert(const MatExpr& expr, int method, MatExpr& res) const;
01116 };
01117 
01118     
01119 class CV_EXPORTS MatExpr
01120 {
01121 public:
01122     MatExpr() : op(0), flags(0), a(Mat()), b(Mat()), c(Mat()), alpha(0), beta(0), s(Scalar()) {}
01123     MatExpr(const MatOp* _op, int _flags, const Mat& _a=Mat(), const Mat& _b=Mat(),
01124             const Mat& _c=Mat(), double _alpha=1, double _beta=1, const Scalar& _s=Scalar())
01125         : op(_op), flags(_flags), a(_a), b(_b), c(_c), alpha(_alpha), beta(_beta), s(_s) {}
01126     explicit MatExpr(const Mat& m);
01127     operator Mat() const
01128     {
01129         Mat m;
01130         op->assign(*this, m);
01131         return m;
01132     }
01133     
01134     template<typename _Tp> operator Mat_<_Tp>() const
01135     {
01136         Mat_<_Tp> m;
01137         op->assign(*this, m, DataType<_Tp>::type);
01138         return m;
01139     }
01140     
01141     MatExpr row(int y) const;
01142     MatExpr col(int x) const;
01143     MatExpr diag(int d=0) const;
01144     MatExpr operator()( const Range& rowRange, const Range& colRange ) const;
01145     MatExpr operator()( const Rect& roi ) const;
01146     
01147     Mat cross(const Mat& m) const;
01148     double dot(const Mat& m) const;
01149     
01150     MatExpr t() const;
01151     MatExpr inv(int method = DECOMP_LU) const;
01152     MatExpr mul(const MatExpr& e, double scale=1) const;
01153     MatExpr mul(const Mat& m, double scale=1) const;
01154     
01155     const MatOp* op;
01156     int flags;
01157     
01158     Mat a, b, c;
01159     double alpha, beta;
01160     Scalar s;
01161 };
01162     
01163 
01164 CV_EXPORTS MatExpr operator + (const Mat& a, const Mat& b);
01165 CV_EXPORTS MatExpr operator + (const Mat& a, const Scalar& s);
01166 CV_EXPORTS MatExpr operator + (const Scalar& s, const Mat& a);
01167 CV_EXPORTS MatExpr operator + (const MatExpr& e, const Mat& m);
01168 CV_EXPORTS MatExpr operator + (const Mat& m, const MatExpr& e);
01169 CV_EXPORTS MatExpr operator + (const MatExpr& e, const Scalar& s);
01170 CV_EXPORTS MatExpr operator + (const Scalar& s, const MatExpr& e);
01171 CV_EXPORTS MatExpr operator + (const MatExpr& e1, const MatExpr& e2);
01172 
01173 CV_EXPORTS MatExpr operator - (const Mat& a, const Mat& b);
01174 CV_EXPORTS MatExpr operator - (const Mat& a, const Scalar& s);
01175 CV_EXPORTS MatExpr operator - (const Scalar& s, const Mat& a);
01176 CV_EXPORTS MatExpr operator - (const MatExpr& e, const Mat& m);
01177 CV_EXPORTS MatExpr operator - (const Mat& m, const MatExpr& e);
01178 CV_EXPORTS MatExpr operator - (const MatExpr& e, const Scalar& s);
01179 CV_EXPORTS MatExpr operator - (const Scalar& s, const MatExpr& e);
01180 CV_EXPORTS MatExpr operator - (const MatExpr& e1, const MatExpr& e2);
01181 
01182 CV_EXPORTS MatExpr operator - (const Mat& m);
01183 CV_EXPORTS MatExpr operator - (const MatExpr& e);
01184 
01185 CV_EXPORTS MatExpr operator * (const Mat& a, const Mat& b);
01186 CV_EXPORTS MatExpr operator * (const Mat& a, double s);
01187 CV_EXPORTS MatExpr operator * (double s, const Mat& a);
01188 CV_EXPORTS MatExpr operator * (const MatExpr& e, const Mat& m);
01189 CV_EXPORTS MatExpr operator * (const Mat& m, const MatExpr& e);
01190 CV_EXPORTS MatExpr operator * (const MatExpr& e, double s);
01191 CV_EXPORTS MatExpr operator * (double s, const MatExpr& e);
01192 CV_EXPORTS MatExpr operator * (const MatExpr& e1, const MatExpr& e2);
01193     
01194 CV_EXPORTS MatExpr operator / (const Mat& a, const Mat& b);
01195 CV_EXPORTS MatExpr operator / (const Mat& a, double s);
01196 CV_EXPORTS MatExpr operator / (double s, const Mat& a);
01197 CV_EXPORTS MatExpr operator / (const MatExpr& e, const Mat& m);
01198 CV_EXPORTS MatExpr operator / (const Mat& m, const MatExpr& e);
01199 CV_EXPORTS MatExpr operator / (const MatExpr& e, double s);
01200 CV_EXPORTS MatExpr operator / (double s, const MatExpr& e);
01201 CV_EXPORTS MatExpr operator / (const MatExpr& e1, const MatExpr& e2);    
01202 
01203 CV_EXPORTS MatExpr operator < (const Mat& a, const Mat& b);
01204 CV_EXPORTS MatExpr operator < (const Mat& a, double s);
01205 CV_EXPORTS MatExpr operator < (double s, const Mat& a);
01206 
01207 CV_EXPORTS MatExpr operator <= (const Mat& a, const Mat& b);
01208 CV_EXPORTS MatExpr operator <= (const Mat& a, double s);
01209 CV_EXPORTS MatExpr operator <= (double s, const Mat& a);
01210 
01211 CV_EXPORTS MatExpr operator == (const Mat& a, const Mat& b);
01212 CV_EXPORTS MatExpr operator == (const Mat& a, double s);
01213 CV_EXPORTS MatExpr operator == (double s, const Mat& a);
01214 
01215 CV_EXPORTS MatExpr operator != (const Mat& a, const Mat& b);
01216 CV_EXPORTS MatExpr operator != (const Mat& a, double s);
01217 CV_EXPORTS MatExpr operator != (double s, const Mat& a);
01218 
01219 CV_EXPORTS MatExpr operator >= (const Mat& a, const Mat& b);
01220 CV_EXPORTS MatExpr operator >= (const Mat& a, double s);
01221 CV_EXPORTS MatExpr operator >= (double s, const Mat& a);
01222 
01223 CV_EXPORTS MatExpr operator > (const Mat& a, const Mat& b);
01224 CV_EXPORTS MatExpr operator > (const Mat& a, double s);
01225 CV_EXPORTS MatExpr operator > (double s, const Mat& a);    
01226     
01227 CV_EXPORTS MatExpr min(const Mat& a, const Mat& b);
01228 CV_EXPORTS MatExpr min(const Mat& a, double s);
01229 CV_EXPORTS MatExpr min(double s, const Mat& a);
01230 
01231 CV_EXPORTS MatExpr max(const Mat& a, const Mat& b);
01232 CV_EXPORTS MatExpr max(const Mat& a, double s);
01233 CV_EXPORTS MatExpr max(double s, const Mat& a);
01234 
01235 template<typename _Tp> static inline MatExpr min(const Mat_<_Tp>& a, const Mat_<_Tp>& b)
01236 {
01237     return cv::min((const Mat&)a, (const Mat&)b);
01238 }
01239 
01240 template<typename _Tp> static inline MatExpr min(const Mat_<_Tp>& a, double s)
01241 {
01242     return cv::min((const Mat&)a, s);
01243 }
01244 
01245 template<typename _Tp> static inline MatExpr min(double s, const Mat_<_Tp>& a)
01246 {
01247     return cv::min((const Mat&)a, s);
01248 }    
01249 
01250 template<typename _Tp> static inline MatExpr max(const Mat_<_Tp>& a, const Mat_<_Tp>& b)
01251 {
01252     return cv::max((const Mat&)a, (const Mat&)b);
01253 }
01254 
01255 template<typename _Tp> static inline MatExpr max(const Mat_<_Tp>& a, double s)
01256 {
01257     return cv::max((const Mat&)a, s);
01258 }
01259 
01260 template<typename _Tp> static inline MatExpr max(double s, const Mat_<_Tp>& a)
01261 {
01262     return cv::max((const Mat&)a, s);
01263 }        
01264     
01265 CV_EXPORTS MatExpr operator & (const Mat& a, const Mat& b);
01266 CV_EXPORTS MatExpr operator & (const Mat& a, const Scalar& s);
01267 CV_EXPORTS MatExpr operator & (const Scalar& s, const Mat& a);
01268 
01269 CV_EXPORTS MatExpr operator | (const Mat& a, const Mat& b);
01270 CV_EXPORTS MatExpr operator | (const Mat& a, const Scalar& s);
01271 CV_EXPORTS MatExpr operator | (const Scalar& s, const Mat& a);
01272 
01273 CV_EXPORTS MatExpr operator ^ (const Mat& a, const Mat& b);
01274 CV_EXPORTS MatExpr operator ^ (const Mat& a, const Scalar& s);
01275 CV_EXPORTS MatExpr operator ^ (const Scalar& s, const Mat& a);
01276 
01277 CV_EXPORTS MatExpr operator ~(const Mat& m);
01278     
01279 CV_EXPORTS MatExpr abs(const Mat& m);
01280 CV_EXPORTS MatExpr abs(const MatExpr& e);
01281     
01282 template<typename _Tp> static inline MatExpr abs(const Mat_<_Tp>& m)
01283 {
01284     return cv::abs((const Mat&)m);
01285 }
01286 
01288     
01289 inline Mat& Mat::operator = (const MatExpr& e)
01290 {
01291     e.op->assign(e, *this);
01292     return *this;
01293 }    
01294 
01295 template<typename _Tp> Mat_<_Tp>& Mat_<_Tp>::operator = (const MatExpr& e)
01296 {
01297     e.op->assign(e, *this, DataType<_Tp>::type);
01298     return *this;
01299 }
01300 
01301 static inline Mat& operator += (const Mat& a, const Mat& b)
01302 {
01303     add(a, b, (Mat&)a);
01304     return (Mat&)a;
01305 }
01306 
01307 static inline Mat& operator += (const Mat& a, const Scalar& s)
01308 {
01309     add(a, s, (Mat&)a);
01310     return (Mat&)a;
01311 }    
01312 
01313 template<typename _Tp> static inline
01314 Mat_<_Tp>& operator += (const Mat_<_Tp>& a, const Mat_<_Tp>& b)
01315 {
01316     add(a, b, (Mat&)a);
01317     return (Mat_<_Tp>&)a;
01318 }
01319 
01320 template<typename _Tp> static inline
01321 Mat_<_Tp>& operator += (const Mat_<_Tp>& a, const Scalar& s)
01322 {
01323     add(a, s, (Mat&)a);
01324     return (Mat_<_Tp>&)a;
01325 }    
01326 
01327 static inline Mat& operator += (const Mat& a, const MatExpr& b)
01328 {
01329     b.op->augAssignAdd(b, (Mat&)a); 
01330     return (Mat&)a;
01331 }
01332 
01333 template<typename _Tp> static inline
01334 Mat_<_Tp>& operator += (const Mat_<_Tp>& a, const MatExpr& b)
01335 {
01336     b.op->augAssignAdd(b, (Mat&)a);
01337     return (Mat_<_Tp>&)a;
01338 }
01339     
01340 static inline Mat& operator -= (const Mat& a, const Mat& b)
01341 {
01342     subtract(a, b, (Mat&)a);
01343     return (Mat&)a;
01344 }
01345 
01346 static inline Mat& operator -= (const Mat& a, const Scalar& s)
01347 {
01348     subtract(a, s, (Mat&)a);
01349     return (Mat&)a;
01350 }    
01351 
01352 template<typename _Tp> static inline
01353 Mat_<_Tp>& operator -= (const Mat_<_Tp>& a, const Mat_<_Tp>& b)
01354 {
01355     subtract(a, b, (Mat&)a);
01356     return (Mat_<_Tp>&)a;
01357 }
01358 
01359 template<typename _Tp> static inline
01360 Mat_<_Tp>& operator -= (const Mat_<_Tp>& a, const Scalar& s)
01361 {
01362     subtract(a, s, (Mat&)a);
01363     return (Mat_<_Tp>&)a;
01364 }    
01365 
01366 static inline Mat& operator -= (const Mat& a, const MatExpr& b)
01367 {
01368     b.op->augAssignSubtract(b, (Mat&)a); 
01369     return (Mat&)a;
01370 }
01371 
01372 template<typename _Tp> static inline
01373 Mat_<_Tp>& operator -= (const Mat_<_Tp>& a, const MatExpr& b)
01374 {
01375     b.op->augAssignSubtract(b, (Mat&)a);
01376     return (Mat_<_Tp>&)a;
01377 }    
01378 
01379 static inline Mat& operator *= (const Mat& a, const Mat& b)
01380 {
01381     gemm(a, b, 1, Mat(), 0, (Mat&)a, 0);
01382     return (Mat&)a;
01383 }
01384 
01385 static inline Mat& operator *= (const Mat& a, double s)
01386 {
01387     a.convertTo((Mat&)a, -1, s);
01388     return (Mat&)a;
01389 }    
01390 
01391 template<typename _Tp> static inline
01392 Mat_<_Tp>& operator *= (const Mat_<_Tp>& a, const Mat_<_Tp>& b)
01393 {
01394     gemm(a, b, 1, Mat(), 0, (Mat&)a, 0);
01395     return (Mat_<_Tp>&)a;
01396 }
01397 
01398 template<typename _Tp> static inline
01399 Mat_<_Tp>& operator *= (const Mat_<_Tp>& a, double s)
01400 {
01401     a.convertTo((Mat&)a, -1, s);
01402     return (Mat_<_Tp>&)a;
01403 }    
01404 
01405 static inline Mat& operator *= (const Mat& a, const MatExpr& b)
01406 {
01407     b.op->augAssignMultiply(b, (Mat&)a); 
01408     return (Mat&)a;
01409 }
01410 
01411 template<typename _Tp> static inline
01412 Mat_<_Tp>& operator *= (const Mat_<_Tp>& a, const MatExpr& b)
01413 {
01414     b.op->augAssignMultiply(b, (Mat&)a);
01415     return (Mat_<_Tp>&)a;
01416 }    
01417     
01418 static inline Mat& operator /= (const Mat& a, const Mat& b)
01419 {
01420     divide(a, b, (Mat&)a);
01421     return (Mat&)a;
01422 }
01423 
01424 static inline Mat& operator /= (const Mat& a, double s)
01425 {
01426     a.convertTo((Mat&)a, -1, 1./s);
01427     return (Mat&)a;
01428 }    
01429 
01430 template<typename _Tp> static inline
01431 Mat_<_Tp>& operator /= (const Mat_<_Tp>& a, const Mat_<_Tp>& b)
01432 {
01433     divide(a, b, (Mat&)a);
01434     return (Mat_<_Tp>&)a;
01435 }
01436 
01437 template<typename _Tp> static inline
01438 Mat_<_Tp>& operator /= (const Mat_<_Tp>& a, double s)
01439 {
01440     a.convertTo((Mat&)a, -1, 1./s);
01441     return (Mat_<_Tp>&)a;
01442 }    
01443 
01444 static inline Mat& operator /= (const Mat& a, const MatExpr& b)
01445 {
01446     b.op->augAssignDivide(b, (Mat&)a); 
01447     return (Mat&)a;
01448 }
01449 
01450 template<typename _Tp> static inline
01451 Mat_<_Tp>& operator /= (const Mat_<_Tp>& a, const MatExpr& b)
01452 {
01453     b.op->augAssignDivide(b, (Mat&)a);
01454     return (Mat_<_Tp>&)a;
01455 }
01456 
01458 
01459 static inline Mat& operator &= (const Mat& a, const Mat& b)
01460 {
01461     bitwise_and(a, b, (Mat&)a);
01462     return (Mat&)a;
01463 }
01464 
01465 static inline Mat& operator &= (const Mat& a, const Scalar& s)
01466 {
01467     bitwise_and(a, s, (Mat&)a);
01468     return (Mat&)a;
01469 }    
01470 
01471 template<typename _Tp> static inline Mat_<_Tp>&
01472 operator &= (const Mat_<_Tp>& a, const Mat_<_Tp>& b)
01473 {
01474     bitwise_and(a, b, (Mat&)a);
01475     return (Mat_<_Tp>&)a;
01476 }    
01477 
01478 template<typename _Tp> static inline Mat_<_Tp>&
01479 operator &= (const Mat_<_Tp>& a, const Scalar& s)
01480 {
01481     bitwise_and(a, s, (Mat&)a);
01482     return (Mat_<_Tp>&)a;
01483 }        
01484     
01485 static inline Mat& operator |= (const Mat& a, const Mat& b)
01486 {
01487     bitwise_or(a, b, (Mat&)a);
01488     return (Mat&)a;
01489 }
01490 
01491 static inline Mat& operator |= (const Mat& a, const Scalar& s)
01492 {
01493     bitwise_or(a, s, (Mat&)a);
01494     return (Mat&)a;
01495 }    
01496 
01497 template<typename _Tp> static inline Mat_<_Tp>&
01498 operator |= (const Mat_<_Tp>& a, const Mat_<_Tp>& b)
01499 {
01500     bitwise_or(a, b, (Mat&)a);
01501     return (Mat_<_Tp>&)a;
01502 }    
01503 
01504 template<typename _Tp> static inline Mat_<_Tp>&
01505 operator |= (const Mat_<_Tp>& a, const Scalar& s)
01506 {
01507     bitwise_or(a, s, (Mat&)a);
01508     return (Mat_<_Tp>&)a;
01509 }        
01510     
01511 static inline Mat& operator ^= (const Mat& a, const Mat& b)
01512 {
01513     bitwise_xor(a, b, (Mat&)a);
01514     return (Mat&)a;
01515 }
01516 
01517 static inline Mat& operator ^= (const Mat& a, const Scalar& s)
01518 {
01519     bitwise_xor(a, s, (Mat&)a);
01520     return (Mat&)a;
01521 }    
01522 
01523 template<typename _Tp> static inline Mat_<_Tp>&
01524 operator ^= (const Mat_<_Tp>& a, const Mat_<_Tp>& b)
01525 {
01526     bitwise_xor(a, b, (Mat&)a);
01527     return (Mat_<_Tp>&)a;
01528 }    
01529 
01530 template<typename _Tp> static inline Mat_<_Tp>&
01531 operator ^= (const Mat_<_Tp>& a, const Scalar& s)
01532 {
01533     bitwise_xor(a, s, (Mat&)a);
01534     return (Mat_<_Tp>&)a;
01535 }        
01536 
01538     
01539 template<typename _Tp> void split(const Mat& src, vector<Mat_<_Tp> >& mv)
01540 { split(src, (vector<Mat>&)mv ); }
01541 
01543     
01544 template<typename _Tp> inline MatExpr Mat_<_Tp>::zeros(int rows, int cols)
01545 {
01546     return Mat::zeros(rows, cols, DataType<_Tp>::type);
01547 }
01548     
01549 template<typename _Tp> inline MatExpr Mat_<_Tp>::zeros(Size sz)
01550 {
01551     return Mat::zeros(sz, DataType<_Tp>::type);
01552 }    
01553     
01554 template<typename _Tp> inline MatExpr Mat_<_Tp>::ones(int rows, int cols)
01555 {
01556     return Mat::ones(rows, cols, DataType<_Tp>::type);
01557 }
01558 
01559 template<typename _Tp> inline MatExpr Mat_<_Tp>::ones(Size sz)
01560 {
01561     return Mat::ones(sz, DataType<_Tp>::type);
01562 }    
01563     
01564 template<typename _Tp> inline MatExpr Mat_<_Tp>::eye(int rows, int cols)
01565 {
01566     return Mat::eye(rows, cols, DataType<_Tp>::type);
01567 }
01568 
01569 template<typename _Tp> inline MatExpr Mat_<_Tp>::eye(Size sz)
01570 {
01571     return Mat::eye(sz, DataType<_Tp>::type);
01572 }    
01573     
01575 
01576 inline MatConstIterator::MatConstIterator()
01577     : m(0), elemSize(0), ptr(0), sliceStart(0), sliceEnd(0) {}
01578 
01579 inline MatConstIterator::MatConstIterator(const Mat* _m)
01580     : m(_m), elemSize(_m->elemSize()), ptr(0), sliceStart(0), sliceEnd(0)
01581 {
01582     if( m && m->isContinuous() )
01583     {
01584         sliceStart = m->data;
01585         sliceEnd = sliceStart + m->total()*elemSize;
01586     }
01587     seek((const int*)0);
01588 }
01589 
01590 inline MatConstIterator::MatConstIterator(const Mat* _m, int _row, int _col)
01591     : m(_m), elemSize(_m->elemSize()), ptr(0), sliceStart(0), sliceEnd(0)
01592 {
01593     CV_Assert(m && m->dims <= 2);
01594     if( m->isContinuous() )
01595     {
01596         sliceStart = m->data;
01597         sliceEnd = sliceStart + m->total()*elemSize;
01598     }
01599     int idx[]={_row, _col};
01600     seek(idx);
01601 }
01602 
01603 inline MatConstIterator::MatConstIterator(const Mat* _m, Point _pt)
01604     : m(_m), elemSize(_m->elemSize()), ptr(0), sliceStart(0), sliceEnd(0)
01605 {
01606     CV_Assert(m && m->dims <= 2);
01607     if( m->isContinuous() )
01608     {
01609         sliceStart = m->data;
01610         sliceEnd = sliceStart + m->total()*elemSize;
01611     }
01612     int idx[]={_pt.y, _pt.x};
01613     seek(idx);
01614 }
01615     
01616 inline MatConstIterator::MatConstIterator(const MatConstIterator& it)
01617     : m(it.m), elemSize(it.elemSize), ptr(it.ptr), sliceStart(it.sliceStart), sliceEnd(it.sliceEnd)
01618 {}
01619 
01620 inline MatConstIterator& MatConstIterator::operator = (const MatConstIterator& it )
01621 {
01622     m = it.m; elemSize = it.elemSize; ptr = it.ptr;
01623     sliceStart = it.sliceStart; sliceEnd = it.sliceEnd;
01624     return *this;
01625 }
01626 
01627 inline uchar* MatConstIterator::operator *() const { return ptr; }
01628     
01629 inline MatConstIterator& MatConstIterator::operator += (ptrdiff_t ofs)
01630 {
01631     if( !m || ofs == 0 )
01632         return *this;
01633     ptrdiff_t ofsb = ofs*elemSize;
01634     ptr += ofsb;
01635     if( ptr < sliceStart || sliceEnd <= ptr )
01636     {
01637         ptr -= ofsb;
01638         seek(ofs, true);
01639     }
01640     return *this;
01641 }
01642 
01643 inline MatConstIterator& MatConstIterator::operator -= (ptrdiff_t ofs)
01644 { return (*this += -ofs); }
01645 
01646 inline MatConstIterator& MatConstIterator::operator --()
01647 {
01648     if( m && (ptr -= elemSize) < sliceStart )
01649     {
01650         ptr += elemSize;
01651         seek(-1, true); 
01652     }
01653     return *this;
01654 }
01655 
01656 inline MatConstIterator MatConstIterator::operator --(int)
01657 {
01658     MatConstIterator b = *this;
01659     *this += -1;
01660     return b;
01661 }
01662 
01663 inline MatConstIterator& MatConstIterator::operator ++()
01664 {
01665     if( m && (ptr += elemSize) >= sliceEnd )
01666     {
01667         ptr -= elemSize;
01668         seek(1, true); 
01669     }
01670     return *this;
01671 }
01672 
01673 inline MatConstIterator MatConstIterator::operator ++(int)
01674 {
01675     MatConstIterator b = *this;
01676     *this += 1;
01677     return b;
01678 }
01679 
01680 template<typename _Tp> inline MatConstIterator_<_Tp>::MatConstIterator_() {}
01681 
01682 template<typename _Tp> inline MatConstIterator_<_Tp>::MatConstIterator_(const Mat_<_Tp>* _m)
01683     : MatConstIterator(_m) {}
01684 
01685 template<typename _Tp> inline MatConstIterator_<_Tp>::
01686     MatConstIterator_(const Mat_<_Tp>* _m, int _row, int _col)
01687     : MatConstIterator(_m, _row, _col) {}
01688 
01689 template<typename _Tp> inline MatConstIterator_<_Tp>::
01690     MatConstIterator_(const Mat_<_Tp>* _m, Point _pt)
01691     : MatConstIterator(_m, _pt) {}
01692 
01693 template<typename _Tp> inline MatConstIterator_<_Tp>::
01694     MatConstIterator_(const MatConstIterator_& it)
01695     : MatConstIterator(it) {}
01696 
01697 template<typename _Tp> inline MatConstIterator_<_Tp>&
01698     MatConstIterator_<_Tp>::operator = (const MatConstIterator_& it )
01699 {
01700     MatConstIterator::operator = (it);
01701     return *this;
01702 }
01703 
01704 template<typename _Tp> inline _Tp MatConstIterator_<_Tp>::operator *() const { return *(_Tp*)(this->ptr); }
01705 
01706 template<typename _Tp> inline MatConstIterator_<_Tp>& MatConstIterator_<_Tp>::operator += (ptrdiff_t ofs)
01707 {
01708     MatConstIterator::operator += (ofs);
01709     return *this;
01710 }
01711 
01712 template<typename _Tp> inline MatConstIterator_<_Tp>& MatConstIterator_<_Tp>::operator -= (ptrdiff_t ofs)
01713 { return (*this += -ofs); }
01714 
01715 template<typename _Tp> inline MatConstIterator_<_Tp>& MatConstIterator_<_Tp>::operator --()
01716 {
01717     MatConstIterator::operator --();
01718     return *this;
01719 }
01720 
01721 template<typename _Tp> inline MatConstIterator_<_Tp> MatConstIterator_<_Tp>::operator --(int)
01722 {
01723     MatConstIterator_ b = *this;
01724     MatConstIterator::operator --();
01725     return b;
01726 }
01727 
01728 template<typename _Tp> inline MatConstIterator_<_Tp>& MatConstIterator_<_Tp>::operator ++()
01729 {
01730     MatConstIterator::operator ++();
01731     return *this;
01732 }
01733 
01734 template<typename _Tp> inline MatConstIterator_<_Tp> MatConstIterator_<_Tp>::operator ++(int)
01735 {
01736     MatConstIterator_ b = *this;
01737     MatConstIterator::operator ++();
01738     return b;
01739 }
01740 
01741 template<typename _Tp> inline MatIterator_<_Tp>::MatIterator_() : MatConstIterator_<_Tp>() {}
01742 
01743 template<typename _Tp> inline MatIterator_<_Tp>::MatIterator_(Mat_<_Tp>* _m)
01744     : MatConstIterator_<_Tp>(_m) {}
01745 
01746 template<typename _Tp> inline MatIterator_<_Tp>::MatIterator_(Mat_<_Tp>* _m, int _row, int _col)
01747     : MatConstIterator_<_Tp>(_m, _row, _col) {}
01748 
01749 template<typename _Tp> inline MatIterator_<_Tp>::MatIterator_(const Mat_<_Tp>* _m, Point _pt)
01750     : MatConstIterator_<_Tp>(_m, _pt) {}
01751     
01752 template<typename _Tp> inline MatIterator_<_Tp>::MatIterator_(const Mat_<_Tp>* _m, const int* _idx)
01753     : MatConstIterator_<_Tp>(_m, _idx) {}
01754     
01755 template<typename _Tp> inline MatIterator_<_Tp>::MatIterator_(const MatIterator_& it)
01756     : MatConstIterator_<_Tp>(it) {}
01757 
01758 template<typename _Tp> inline MatIterator_<_Tp>& MatIterator_<_Tp>::operator = (const MatIterator_<_Tp>& it )
01759 {
01760     MatConstIterator::operator = (it);
01761     return *this;
01762 }
01763 
01764 template<typename _Tp> inline _Tp& MatIterator_<_Tp>::operator *() const { return *(_Tp*)(this->ptr); }
01765 
01766 template<typename _Tp> inline MatIterator_<_Tp>& MatIterator_<_Tp>::operator += (ptrdiff_t ofs)
01767 {
01768     MatConstIterator::operator += (ofs);
01769     return *this;
01770 }
01771 
01772 template<typename _Tp> inline MatIterator_<_Tp>& MatIterator_<_Tp>::operator -= (ptrdiff_t ofs)
01773 {
01774     MatConstIterator::operator += (-ofs);
01775     return *this;
01776 }
01777 
01778 template<typename _Tp> inline MatIterator_<_Tp>& MatIterator_<_Tp>::operator --()
01779 {
01780     MatConstIterator::operator --();
01781     return *this;
01782 }
01783 
01784 template<typename _Tp> inline MatIterator_<_Tp> MatIterator_<_Tp>::operator --(int)
01785 {
01786     MatIterator_ b = *this;
01787     MatConstIterator::operator --();
01788     return b;
01789 }
01790 
01791 template<typename _Tp> inline MatIterator_<_Tp>& MatIterator_<_Tp>::operator ++()
01792 {
01793     MatConstIterator::operator ++();
01794     return *this;
01795 }
01796 
01797 template<typename _Tp> inline MatIterator_<_Tp> MatIterator_<_Tp>::operator ++(int)
01798 {
01799     MatIterator_ b = *this;
01800     MatConstIterator::operator ++();
01801     return b;
01802 }
01803 
01804 template<typename _Tp> inline Point MatConstIterator_<_Tp>::pos() const
01805 {
01806     if( !m )
01807         return Point();
01808     CV_DbgAssert( m->dims <= 2 );
01809     if( m->isContinuous() )
01810     {
01811         ptrdiff_t ofs = (const _Tp*)ptr - (const _Tp*)m->data;
01812         int y = (int)(ofs / m->cols), x = (int)(ofs - (ptrdiff_t)y*m->cols);
01813         return Point(x, y);
01814     }
01815     else
01816     {
01817         ptrdiff_t ofs = (uchar*)ptr - m->data;
01818         int y = (int)(ofs / m->step), x = (int)((ofs - y*m->step)/sizeof(_Tp));
01819         return Point(x, y);
01820     }
01821 }
01822 
01823 static inline bool
01824 operator == (const MatConstIterator& a, const MatConstIterator& b)
01825 { return a.m == b.m && a.ptr == b.ptr; }
01826 
01827 template<typename _Tp> static inline bool
01828 operator != (const MatConstIterator& a, const MatConstIterator& b)
01829 { return !(a == b); }
01830 
01831 template<typename _Tp> static inline bool
01832 operator == (const MatConstIterator_<_Tp>& a, const MatConstIterator_<_Tp>& b)
01833 { return a.m == b.m && a.ptr == b.ptr; }
01834 
01835 template<typename _Tp> static inline bool
01836 operator != (const MatConstIterator_<_Tp>& a, const MatConstIterator_<_Tp>& b)
01837 { return a.m != b.m || a.ptr != b.ptr; }
01838 
01839 template<typename _Tp> static inline bool
01840 operator == (const MatIterator_<_Tp>& a, const MatIterator_<_Tp>& b)
01841 { return a.m == b.m && a.ptr == b.ptr; }
01842 
01843 template<typename _Tp> static inline bool
01844 operator != (const MatIterator_<_Tp>& a, const MatIterator_<_Tp>& b)
01845 { return a.m != b.m || a.ptr != b.ptr; }    
01846     
01847 static inline bool
01848 operator < (const MatConstIterator& a, const MatConstIterator& b)
01849 { return a.ptr < b.ptr; }
01850 
01851 static inline bool
01852 operator > (const MatConstIterator& a, const MatConstIterator& b)
01853 { return a.ptr > b.ptr; }
01854     
01855 static inline bool
01856 operator <= (const MatConstIterator& a, const MatConstIterator& b)
01857 { return a.ptr <= b.ptr; }
01858 
01859 static inline bool
01860 operator >= (const MatConstIterator& a, const MatConstIterator& b)
01861 { return a.ptr >= b.ptr; }
01862 
01863 CV_EXPORTS ptrdiff_t operator - (const MatConstIterator& b, const MatConstIterator& a);
01864 
01865 static inline MatConstIterator operator + (const MatConstIterator& a, ptrdiff_t ofs)
01866 { MatConstIterator b = a; return b += ofs; }
01867 
01868 static inline MatConstIterator operator + (ptrdiff_t ofs, const MatConstIterator& a)
01869 { MatConstIterator b = a; return b += ofs; }
01870 
01871 static inline MatConstIterator operator - (const MatConstIterator& a, ptrdiff_t ofs)
01872 { MatConstIterator b = a; return b += -ofs; }
01873     
01874 template<typename _Tp> static inline MatConstIterator_<_Tp>
01875 operator + (const MatConstIterator_<_Tp>& a, ptrdiff_t ofs)
01876 { MatConstIterator t = (const MatConstIterator&)a + ofs; return (MatConstIterator_<_Tp>&)t; }
01877 
01878 template<typename _Tp> static inline MatConstIterator_<_Tp>
01879 operator + (ptrdiff_t ofs, const MatConstIterator_<_Tp>& a)
01880 { MatConstIterator t = (const MatConstIterator&)a + ofs; return (MatConstIterator_<_Tp>&)t; }
01881     
01882 template<typename _Tp> static inline MatConstIterator_<_Tp>
01883 operator - (const MatConstIterator_<_Tp>& a, ptrdiff_t ofs)
01884 { MatConstIterator t = (const MatConstIterator&)a - ofs; return (MatConstIterator_<_Tp>&)t; }
01885 
01886 inline uchar* MatConstIterator::operator [](ptrdiff_t i) const
01887 { return *(*this + i); }
01888     
01889 template<typename _Tp> inline _Tp MatConstIterator_<_Tp>::operator [](ptrdiff_t i) const
01890 { return *(_Tp*)MatConstIterator::operator [](i); }
01891 
01892 template<typename _Tp> static inline MatIterator_<_Tp>
01893 operator + (const MatIterator_<_Tp>& a, ptrdiff_t ofs)
01894 { MatConstIterator t = (const MatConstIterator&)a + ofs; return (MatIterator_<_Tp>&)t; }
01895 
01896 template<typename _Tp> static inline MatIterator_<_Tp>
01897 operator + (ptrdiff_t ofs, const MatIterator_<_Tp>& a)
01898 { MatConstIterator t = (const MatConstIterator&)a + ofs; return (MatIterator_<_Tp>&)t; }
01899 
01900 template<typename _Tp> static inline MatIterator_<_Tp>
01901 operator - (const MatIterator_<_Tp>& a, ptrdiff_t ofs)
01902 { MatConstIterator t = (const MatConstIterator&)a - ofs; return (MatIterator_<_Tp>&)t; }
01903     
01904 template<typename _Tp> inline _Tp& MatIterator_<_Tp>::operator [](ptrdiff_t i) const
01905 { return *(*this + i); }
01906 
01907 template<typename _Tp> inline MatConstIterator_<_Tp> Mat_<_Tp>::begin() const
01908 { return Mat::begin<_Tp>(); }
01909 
01910 template<typename _Tp> inline MatConstIterator_<_Tp> Mat_<_Tp>::end() const
01911 { return Mat::end<_Tp>(); }
01912 
01913 template<typename _Tp> inline MatIterator_<_Tp> Mat_<_Tp>::begin()
01914 { return Mat::begin<_Tp>(); }
01915 
01916 template<typename _Tp> inline MatIterator_<_Tp> Mat_<_Tp>::end()
01917 { return Mat::end<_Tp>(); }
01918 
01919 template<typename _Tp> inline MatCommaInitializer_<_Tp>::MatCommaInitializer_(Mat_<_Tp>* _m) : it(_m) {}
01920 
01921 template<typename _Tp> template<typename T2> inline MatCommaInitializer_<_Tp>&
01922 MatCommaInitializer_<_Tp>::operator , (T2 v)
01923 {
01924     CV_DbgAssert( this->it < ((const Mat_<_Tp>*)this->it.m)->end() );
01925     *this->it = _Tp(v); ++this->it;
01926     return *this;
01927 }
01928 
01929 template<typename _Tp> inline Mat_<_Tp> MatCommaInitializer_<_Tp>::operator *() const
01930 {
01931     CV_DbgAssert( this->it == ((const Mat_<_Tp>*)this->it.m)->end() );
01932     return Mat_<_Tp>(*this->it.m);
01933 }
01934 
01935 template<typename _Tp> inline MatCommaInitializer_<_Tp>::operator Mat_<_Tp>() const
01936 {
01937     CV_DbgAssert( this->it == ((const Mat_<_Tp>*)this->it.m)->end() );
01938     return Mat_<_Tp>(*this->it.m);
01939 }    
01940     
01941 template<typename _Tp, typename T2> static inline MatCommaInitializer_<_Tp>
01942 operator << (const Mat_<_Tp>& m, T2 val)
01943 {
01944     MatCommaInitializer_<_Tp> commaInitializer((Mat_<_Tp>*)&m);
01945     return (commaInitializer, val);
01946 }
01947 
01949 
01950 inline SparseMat::SparseMat()
01951 : flags(MAGIC_VAL), hdr(0)
01952 {
01953 }
01954 
01955 inline SparseMat::SparseMat(int _dims, const int* _sizes, int _type)
01956 : flags(MAGIC_VAL), hdr(0)
01957 {
01958     create(_dims, _sizes, _type);
01959 }
01960 
01961 inline SparseMat::SparseMat(const SparseMat& m)
01962 : flags(m.flags), hdr(m.hdr)
01963 {
01964     addref();
01965 }
01966 
01967 inline SparseMat::~SparseMat()
01968 {
01969     release();
01970 }
01971 
01972 inline SparseMat& SparseMat::operator = (const SparseMat& m)
01973 {
01974     if( this != &m )
01975     {
01976         if( m.hdr )
01977             CV_XADD(&m.hdr->refcount, 1);
01978         release();
01979         flags = m.flags;
01980         hdr = m.hdr;
01981     }
01982     return *this;
01983 }
01984 
01985 inline SparseMat& SparseMat::operator = (const Mat& m)
01986 { return (*this = SparseMat(m)); }
01987 
01988 inline SparseMat SparseMat::clone() const
01989 {
01990     SparseMat temp;
01991     this->copyTo(temp);
01992     return temp;
01993 }
01994 
01995 
01996 inline void SparseMat::assignTo( SparseMat& m, int type ) const
01997 {
01998     if( type < 0 )
01999         m = *this;
02000     else
02001         convertTo(m, type);
02002 }
02003 
02004 inline void SparseMat::addref()
02005 { if( hdr ) CV_XADD(&hdr->refcount, 1); }
02006 
02007 inline void SparseMat::release()
02008 {
02009     if( hdr && CV_XADD(&hdr->refcount, -1) == 1 )
02010         delete hdr;
02011     hdr = 0;
02012 }
02013 
02014 inline size_t SparseMat::elemSize() const
02015 { return CV_ELEM_SIZE(flags); }
02016 
02017 inline size_t SparseMat::elemSize1() const
02018 { return CV_ELEM_SIZE1(flags); }
02019 
02020 inline int SparseMat::type() const
02021 { return CV_MAT_TYPE(flags); }
02022 
02023 inline int SparseMat::depth() const
02024 { return CV_MAT_DEPTH(flags); }
02025 
02026 inline int SparseMat::channels() const
02027 { return CV_MAT_CN(flags); }
02028 
02029 inline const int* SparseMat::size() const
02030 {
02031     return hdr ? hdr->size : 0;
02032 }
02033 
02034 inline int SparseMat::size(int i) const
02035 {
02036     if( hdr )
02037     {
02038         CV_DbgAssert((unsigned)i < (unsigned)hdr->dims);
02039         return hdr->size[i];
02040     }
02041     return 0;
02042 }
02043 
02044 inline int SparseMat::dims() const
02045 {
02046     return hdr ? hdr->dims : 0;
02047 }
02048 
02049 inline size_t SparseMat::nzcount() const
02050 {
02051     return hdr ? hdr->nodeCount : 0;
02052 }
02053 
02054 inline size_t SparseMat::hash(int i0) const
02055 {
02056     return (size_t)i0;
02057 }
02058 
02059 inline size_t SparseMat::hash(int i0, int i1) const
02060 {
02061     return (size_t)(unsigned)i0*HASH_SCALE + (unsigned)i1;
02062 }
02063 
02064 inline size_t SparseMat::hash(int i0, int i1, int i2) const
02065 {
02066     return ((size_t)(unsigned)i0*HASH_SCALE + (unsigned)i1)*HASH_SCALE + (unsigned)i2;
02067 }
02068 
02069 inline size_t SparseMat::hash(const int* idx) const
02070 {
02071     size_t h = (unsigned)idx[0];
02072     if( !hdr )
02073         return 0;
02074     int i, d = hdr->dims;
02075     for( i = 1; i < d; i++ )
02076         h = h*HASH_SCALE + (unsigned)idx[i];
02077     return h;
02078 }
02079 
02080 template<typename _Tp> inline _Tp& SparseMat::ref(int i0, size_t* hashval)
02081 { return *(_Tp*)((SparseMat*)this)->ptr(i0, true, hashval); }
02082     
02083 template<typename _Tp> inline _Tp& SparseMat::ref(int i0, int i1, size_t* hashval)
02084 { return *(_Tp*)((SparseMat*)this)->ptr(i0, i1, true, hashval); }
02085 
02086 template<typename _Tp> inline _Tp& SparseMat::ref(int i0, int i1, int i2, size_t* hashval)
02087 { return *(_Tp*)((SparseMat*)this)->ptr(i0, i1, i2, true, hashval); }
02088 
02089 template<typename _Tp> inline _Tp& SparseMat::ref(const int* idx, size_t* hashval)
02090 { return *(_Tp*)((SparseMat*)this)->ptr(idx, true, hashval); }
02091 
02092 template<typename _Tp> inline _Tp SparseMat::value(int i0, size_t* hashval) const
02093 {
02094     const _Tp* p = (const _Tp*)((SparseMat*)this)->ptr(i0, false, hashval);
02095     return p ? *p : _Tp();
02096 }    
02097     
02098 template<typename _Tp> inline _Tp SparseMat::value(int i0, int i1, size_t* hashval) const
02099 {
02100     const _Tp* p = (const _Tp*)((SparseMat*)this)->ptr(i0, i1, false, hashval);
02101     return p ? *p : _Tp();
02102 }
02103 
02104 template<typename _Tp> inline _Tp SparseMat::value(int i0, int i1, int i2, size_t* hashval) const
02105 {
02106     const _Tp* p = (const _Tp*)((SparseMat*)this)->ptr(i0, i1, i2, false, hashval);
02107     return p ? *p : _Tp();
02108 }
02109 
02110 template<typename _Tp> inline _Tp SparseMat::value(const int* idx, size_t* hashval) const
02111 {
02112     const _Tp* p = (const _Tp*)((SparseMat*)this)->ptr(idx, false, hashval);
02113     return p ? *p : _Tp();
02114 }
02115 
02116 template<typename _Tp> inline const _Tp* SparseMat::find(int i0, size_t* hashval) const
02117 { return (const _Tp*)((SparseMat*)this)->ptr(i0, false, hashval); }
02118     
02119 template<typename _Tp> inline const _Tp* SparseMat::find(int i0, int i1, size_t* hashval) const
02120 { return (const _Tp*)((SparseMat*)this)->ptr(i0, i1, false, hashval); }
02121 
02122 template<typename _Tp> inline const _Tp* SparseMat::find(int i0, int i1, int i2, size_t* hashval) const
02123 { return (const _Tp*)((SparseMat*)this)->ptr(i0, i1, i2, false, hashval); }
02124 
02125 template<typename _Tp> inline const _Tp* SparseMat::find(const int* idx, size_t* hashval) const
02126 { return (const _Tp*)((SparseMat*)this)->ptr(idx, false, hashval); }
02127 
02128 template<typename _Tp> inline _Tp& SparseMat::value(Node* n)
02129 { return *(_Tp*)((uchar*)n + hdr->valueOffset); }
02130 
02131 template<typename _Tp> inline const _Tp& SparseMat::value(const Node* n) const
02132 { return *(const _Tp*)((const uchar*)n + hdr->valueOffset); }
02133 
02134 inline SparseMat::Node* SparseMat::node(size_t nidx)
02135 { return (Node*)&hdr->pool[nidx]; }
02136 
02137 inline const SparseMat::Node* SparseMat::node(size_t nidx) const
02138 { return (const Node*)&hdr->pool[nidx]; }
02139 
02140 inline SparseMatIterator SparseMat::begin()
02141 { return SparseMatIterator(this); }
02142 
02143 inline SparseMatConstIterator SparseMat::begin() const
02144 { return SparseMatConstIterator(this); }
02145 
02146 inline SparseMatIterator SparseMat::end()
02147 { SparseMatIterator it(this); it.seekEnd(); return it; }
02148     
02149 inline SparseMatConstIterator SparseMat::end() const
02150 { SparseMatConstIterator it(this); it.seekEnd(); return it; }
02151     
02152 template<typename _Tp> inline SparseMatIterator_<_Tp> SparseMat::begin()
02153 { return SparseMatIterator_<_Tp>(this); }
02154     
02155 template<typename _Tp> inline SparseMatConstIterator_<_Tp> SparseMat::begin() const
02156 { return SparseMatConstIterator_<_Tp>(this); }
02157     
02158 template<typename _Tp> inline SparseMatIterator_<_Tp> SparseMat::end()
02159 { SparseMatIterator_<_Tp> it(this); it.seekEnd(); return it; }
02160 
02161 template<typename _Tp> inline SparseMatConstIterator_<_Tp> SparseMat::end() const
02162 { SparseMatConstIterator_<_Tp> it(this); it.seekEnd(); return it; }
02163     
02164     
02165 inline SparseMatConstIterator::SparseMatConstIterator()
02166 : m(0), hashidx(0), ptr(0)
02167 {
02168 }
02169 
02170 inline SparseMatConstIterator::SparseMatConstIterator(const SparseMatConstIterator& it)
02171 : m(it.m), hashidx(it.hashidx), ptr(it.ptr)
02172 {
02173 }
02174 
02175 static inline bool operator == (const SparseMatConstIterator& it1, const SparseMatConstIterator& it2)
02176 { return it1.m == it2.m && it1.hashidx == it2.hashidx && it1.ptr == it2.ptr; }
02177 
02178 static inline bool operator != (const SparseMatConstIterator& it1, const SparseMatConstIterator& it2)
02179 { return !(it1 == it2); }
02180 
02181 
02182 inline SparseMatConstIterator& SparseMatConstIterator::operator = (const SparseMatConstIterator& it)
02183 {
02184     if( this != &it )
02185     {
02186         m = it.m;
02187         hashidx = it.hashidx;
02188         ptr = it.ptr;
02189     }
02190     return *this;
02191 }
02192 
02193 template<typename _Tp> inline const _Tp& SparseMatConstIterator::value() const
02194 { return *(_Tp*)ptr; }
02195 
02196 inline const SparseMat::Node* SparseMatConstIterator::node() const
02197 {
02198     return ptr && m && m->hdr ?
02199         (const SparseMat::Node*)(ptr - m->hdr->valueOffset) : 0;
02200 }
02201 
02202 inline SparseMatConstIterator SparseMatConstIterator::operator ++(int)
02203 {
02204     SparseMatConstIterator it = *this;
02205     ++*this;
02206     return it;
02207 }
02208 
02209     
02210 inline void SparseMatConstIterator::seekEnd()
02211 {
02212     if( m && m->hdr )
02213     {
02214         hashidx = m->hdr->hashtab.size();
02215         ptr = 0;
02216     }
02217 }
02218     
02219 inline SparseMatIterator::SparseMatIterator()
02220 {}
02221 
02222 inline SparseMatIterator::SparseMatIterator(SparseMat* _m)
02223 : SparseMatConstIterator(_m)
02224 {}
02225 
02226 inline SparseMatIterator::SparseMatIterator(const SparseMatIterator& it)
02227 : SparseMatConstIterator(it)
02228 {
02229 }
02230 
02231 inline SparseMatIterator& SparseMatIterator::operator = (const SparseMatIterator& it)
02232 {
02233     (SparseMatConstIterator&)*this = it;
02234     return *this;
02235 }
02236 
02237 template<typename _Tp> inline _Tp& SparseMatIterator::value() const
02238 { return *(_Tp*)ptr; }
02239 
02240 inline SparseMat::Node* SparseMatIterator::node() const
02241 {
02242     return (SparseMat::Node*)SparseMatConstIterator::node();
02243 }
02244 
02245 inline SparseMatIterator& SparseMatIterator::operator ++()
02246 {
02247     SparseMatConstIterator::operator ++();
02248     return *this;
02249 }
02250 
02251 inline SparseMatIterator SparseMatIterator::operator ++(int)
02252 {
02253     SparseMatIterator it = *this;
02254     ++*this;
02255     return it;
02256 }
02257 
02258 
02259 template<typename _Tp> inline SparseMat_<_Tp>::SparseMat_()
02260 { flags = MAGIC_VAL | DataType<_Tp>::type; }
02261 
02262 template<typename _Tp> inline SparseMat_<_Tp>::SparseMat_(int _dims, const int* _sizes)
02263 : SparseMat(_dims, _sizes, DataType<_Tp>::type)
02264 {}
02265 
02266 template<typename _Tp> inline SparseMat_<_Tp>::SparseMat_(const SparseMat& m)
02267 {
02268     if( m.type() == DataType<_Tp>::type )
02269         *this = (const SparseMat_<_Tp>&)m;
02270     else
02271         m.convertTo(this, DataType<_Tp>::type);
02272 }
02273 
02274 template<typename _Tp> inline SparseMat_<_Tp>::SparseMat_(const SparseMat_<_Tp>& m)
02275 {
02276     this->flags = m.flags;
02277     this->hdr = m.hdr;
02278     if( this->hdr )
02279         CV_XADD(&this->hdr->refcount, 1);
02280 }
02281 
02282 template<typename _Tp> inline SparseMat_<_Tp>::SparseMat_(const Mat& m)
02283 {
02284     SparseMat sm(m);
02285     *this = sm;
02286 }
02287 
02288 template<typename _Tp> inline SparseMat_<_Tp>::SparseMat_(const CvSparseMat* m)
02289 {
02290     SparseMat sm(m);
02291     *this = sm;
02292 }
02293 
02294 template<typename _Tp> inline SparseMat_<_Tp>&
02295 SparseMat_<_Tp>::operator = (const SparseMat_<_Tp>& m)
02296 {
02297     if( this != &m )
02298     {
02299         if( m.hdr ) CV_XADD(&m.hdr->refcount, 1);
02300         release();
02301         flags = m.flags;
02302         hdr = m.hdr;
02303     }
02304     return *this;
02305 }
02306 
02307 template<typename _Tp> inline SparseMat_<_Tp>&
02308 SparseMat_<_Tp>::operator = (const SparseMat& m)
02309 {
02310     if( m.type() == DataType<_Tp>::type )
02311         return (*this = (const SparseMat_<_Tp>&)m);
02312     m.convertTo(*this, DataType<_Tp>::type);
02313     return *this;
02314 }
02315 
02316 template<typename _Tp> inline SparseMat_<_Tp>&
02317 SparseMat_<_Tp>::operator = (const Mat& m)
02318 { return (*this = SparseMat(m)); }
02319 
02320 template<typename _Tp> inline SparseMat_<_Tp>
02321 SparseMat_<_Tp>::clone() const
02322 {
02323     SparseMat_<_Tp> m;
02324     this->copyTo(m);
02325     return m;
02326 }
02327 
02328 template<typename _Tp> inline void
02329 SparseMat_<_Tp>::create(int _dims, const int* _sizes)
02330 {
02331     SparseMat::create(_dims, _sizes, DataType<_Tp>::type);
02332 }
02333 
02334 template<typename _Tp> inline
02335 SparseMat_<_Tp>::operator CvSparseMat*() const
02336 {
02337     return SparseMat::operator CvSparseMat*();
02338 }
02339 
02340 template<typename _Tp> inline int SparseMat_<_Tp>::type() const
02341 { return DataType<_Tp>::type; }
02342 
02343 template<typename _Tp> inline int SparseMat_<_Tp>::depth() const
02344 { return DataType<_Tp>::depth; }
02345 
02346 template<typename _Tp> inline int SparseMat_<_Tp>::channels() const
02347 { return DataType<_Tp>::channels; }
02348 
02349 template<typename _Tp> inline _Tp&
02350 SparseMat_<_Tp>::ref(int i0, size_t* hashval)
02351 { return SparseMat::ref<_Tp>(i0, hashval); }
02352 
02353 template<typename _Tp> inline _Tp
02354 SparseMat_<_Tp>::operator()(int i0, size_t* hashval) const
02355 { return SparseMat::value<_Tp>(i0, hashval); }    
02356     
02357 template<typename _Tp> inline _Tp&
02358 SparseMat_<_Tp>::ref(int i0, int i1, size_t* hashval)
02359 { return SparseMat::ref<_Tp>(i0, i1, hashval); }
02360 
02361 template<typename _Tp> inline _Tp
02362 SparseMat_<_Tp>::operator()(int i0, int i1, size_t* hashval) const
02363 { return SparseMat::value<_Tp>(i0, i1, hashval); }
02364 
02365 template<typename _Tp> inline _Tp&
02366 SparseMat_<_Tp>::ref(int i0, int i1, int i2, size_t* hashval)
02367 { return SparseMat::ref<_Tp>(i0, i1, i2, hashval); }
02368 
02369 template<typename _Tp> inline _Tp
02370 SparseMat_<_Tp>::operator()(int i0, int i1, int i2, size_t* hashval) const
02371 { return SparseMat::value<_Tp>(i0, i1, i2, hashval); }
02372 
02373 template<typename _Tp> inline _Tp&
02374 SparseMat_<_Tp>::ref(const int* idx, size_t* hashval)
02375 { return SparseMat::ref<_Tp>(idx, hashval); }
02376 
02377 template<typename _Tp> inline _Tp
02378 SparseMat_<_Tp>::operator()(const int* idx, size_t* hashval) const
02379 { return SparseMat::value<_Tp>(idx, hashval); }
02380 
02381 template<typename _Tp> inline SparseMatIterator_<_Tp> SparseMat_<_Tp>::begin()
02382 { return SparseMatIterator_<_Tp>(this); }
02383 
02384 template<typename _Tp> inline SparseMatConstIterator_<_Tp> SparseMat_<_Tp>::begin() const
02385 { return SparseMatConstIterator_<_Tp>(this); }
02386 
02387 template<typename _Tp> inline SparseMatIterator_<_Tp> SparseMat_<_Tp>::end()
02388 { SparseMatIterator_<_Tp> it(this); it.seekEnd(); return it; }
02389     
02390 template<typename _Tp> inline SparseMatConstIterator_<_Tp> SparseMat_<_Tp>::end() const
02391 { SparseMatConstIterator_<_Tp> it(this); it.seekEnd(); return it; }
02392 
02393 template<typename _Tp> inline
02394 SparseMatConstIterator_<_Tp>::SparseMatConstIterator_()
02395 {}
02396 
02397 template<typename _Tp> inline
02398 SparseMatConstIterator_<_Tp>::SparseMatConstIterator_(const SparseMat_<_Tp>* _m)
02399 : SparseMatConstIterator(_m)
02400 {}
02401 
02402 template<typename _Tp> inline
02403 SparseMatConstIterator_<_Tp>::SparseMatConstIterator_(const SparseMatConstIterator_<_Tp>& it)
02404 : SparseMatConstIterator(it)
02405 {}
02406 
02407 template<typename _Tp> inline SparseMatConstIterator_<_Tp>&
02408 SparseMatConstIterator_<_Tp>::operator = (const SparseMatConstIterator_<_Tp>& it)
02409 { return ((SparseMatConstIterator&)*this = it); }
02410 
02411 template<typename _Tp> inline const _Tp&
02412 SparseMatConstIterator_<_Tp>::operator *() const
02413 { return *(const _Tp*)this->ptr; }
02414 
02415 template<typename _Tp> inline SparseMatConstIterator_<_Tp>&
02416 SparseMatConstIterator_<_Tp>::operator ++()
02417 {
02418     SparseMatConstIterator::operator ++();
02419     return *this;
02420 }
02421 
02422 template<typename _Tp> inline SparseMatConstIterator_<_Tp>
02423 SparseMatConstIterator_<_Tp>::operator ++(int)
02424 {
02425     SparseMatConstIterator it = *this;
02426     SparseMatConstIterator::operator ++();
02427     return it;
02428 }
02429 
02430 template<typename _Tp> inline
02431 SparseMatIterator_<_Tp>::SparseMatIterator_()
02432 {}
02433 
02434 template<typename _Tp> inline
02435 SparseMatIterator_<_Tp>::SparseMatIterator_(SparseMat_<_Tp>* _m)
02436 : SparseMatConstIterator_<_Tp>(_m)
02437 {}
02438 
02439 template<typename _Tp> inline
02440 SparseMatIterator_<_Tp>::SparseMatIterator_(const SparseMatIterator_<_Tp>& it)
02441 : SparseMatConstIterator_<_Tp>(it)
02442 {}
02443 
02444 template<typename _Tp> inline SparseMatIterator_<_Tp>&
02445 SparseMatIterator_<_Tp>::operator = (const SparseMatIterator_<_Tp>& it)
02446 { return ((SparseMatIterator&)*this = it); }
02447 
02448 template<typename _Tp> inline _Tp&
02449 SparseMatIterator_<_Tp>::operator *() const
02450 { return *(_Tp*)this->ptr; }
02451 
02452 template<typename _Tp> inline SparseMatIterator_<_Tp>&
02453 SparseMatIterator_<_Tp>::operator ++()
02454 {
02455     SparseMatConstIterator::operator ++();
02456     return *this;
02457 }
02458 
02459 template<typename _Tp> inline SparseMatIterator_<_Tp>
02460 SparseMatIterator_<_Tp>::operator ++(int)
02461 {
02462     SparseMatIterator it = *this;
02463     SparseMatConstIterator::operator ++();
02464     return it;
02465 }
02466     
02467 }
02468 
02469 #endif
02470 #endif
 All Classes Namespaces Files Functions Variables Typedefs Enumerations Enumerator Friends Defines