/*M///////////////////////////////////////////////////////////////////////////////////////
//
// IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING.
//
// By downloading, copying, installing or using the software you agree to this license.
// If you do not agree to this license, do not download, install,
// copy or use the software.
//
//
// Intel License Agreement
// For Open Source Computer Vision Library
//
// Copyright (C) 2000, Intel Corporation, all rights reserved.
// Third party copyrights are property of their respective owners.
//
// Redistribution and use in source and binary forms, with or without modification,
// are permitted provided that the following conditions are met:
//
// * Redistribution's of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
//
// * Redistribution's in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
//
// * The name of Intel Corporation may not be used to endorse or promote products
// derived from this software without specific prior written permission.
//
// This software is provided by the copyright holders and contributors "as is" and
// any express or implied warranties, including, but not limited to, the implied
// warranties of merchantability and fitness for a particular purpose are disclaimed.
// In no event shall the Intel Corporation or contributors be liable for any direct,
// indirect, incidental, special, exemplary, or consequential damages
// (including, but not limited to, procurement of substitute goods or services;
// loss of use, data, or profits; or business interruption) however caused
// and on any theory of liability, whether in contract, strict liability,
// or tort (including negligence or otherwise) arising in any way out of
// the use of this software, even if advised of the possibility of such damage.
//
//M*/
#include "_cvaux.h"
// temporarily remove it from build
#if 0 && ((_MSC_VER>=1200) || defined __BORLANDC__)
double CvMAT::get( const uchar* ptr, int type, int coi )
{
double t = 0;
assert( (unsigned)coi < (unsigned)CV_MAT_CN(type) );
switch( CV_MAT_DEPTH(type) )
{
case CV_8U:
t = ((uchar*)ptr)[coi];
break;
case CV_8S:
t = ((char*)ptr)[coi];
break;
case CV_16S:
t = ((short*)ptr)[coi];
break;
case CV_32S:
t = ((int*)ptr)[coi];
break;
case CV_32F:
t = ((float*)ptr)[coi];
break;
case CV_64F:
t = ((double*)ptr)[coi];
break;
}
return t;
}
void CvMAT::set( uchar* ptr, int type, int coi, double d )
{
int i;
assert( (unsigned)coi < (unsigned)CV_MAT_CN(type) );
switch( CV_MAT_DEPTH(type))
{
case CV_8U:
i = cvRound(d);
((uchar*)ptr)[coi] = CV_CAST_8U(i);
break;
case CV_8S:
i = cvRound(d);
((char*)ptr)[coi] = CV_CAST_8S(i);
break;
case CV_16S:
i = cvRound(d);
((short*)ptr)[coi] = CV_CAST_16S(i);
break;
case CV_32S:
i = cvRound(d);
((int*)ptr)[coi] = CV_CAST_32S(i);
break;
case CV_32F:
((float*)ptr)[coi] = (float)d;
break;
case CV_64F:
((double*)ptr)[coi] = d;
break;
}
}
void CvMAT::set( uchar* ptr, int type, int coi, int i )
{
assert( (unsigned)coi < (unsigned)CV_MAT_CN(type) );
switch( CV_MAT_DEPTH(type))
{
case CV_8U:
((uchar*)ptr)[coi] = CV_CAST_8U(i);
break;
case CV_8S:
((char*)ptr)[coi] = CV_CAST_8S(i);
break;
case CV_16S:
((short*)ptr)[coi] = CV_CAST_16S(i);
break;
case CV_32S:
((int*)ptr)[coi] = i;
break;
case CV_32F:
((float*)ptr)[coi] = (float)i;
break;
case CV_64F:
((double*)ptr)[coi] = (double)i;
break;
}
}
void CvMAT::set( uchar* ptr, int type, double d )
{
int i, cn = CV_MAT_CN(type);
switch( CV_MAT_DEPTH(type))
{
case CV_8U:
i = cvRound(d);
((uchar*)ptr)[0] = CV_CAST_8U(i);
i = cn;
while( --i ) ((uchar*)ptr)[i] = 0;
break;
case CV_8S:
i = cvRound(d);
((char*)ptr)[0] = CV_CAST_8S(i);
i = cn;
while( --i ) ((char*)ptr)[i] = 0;
break;
case CV_16S:
i = cvRound(d);
((short*)ptr)[0] = CV_CAST_16S(i);
i = cn;
while( --i ) ((short*)ptr)[i] = 0;
break;
case CV_32S:
i = cvRound(d);
((int*)ptr)[0] = i;
i = cn;
while( --i ) ((int*)ptr)[i] = 0;
break;
case CV_32F:
((float*)ptr)[0] = (float)d;
i = cn;
while( --i ) ((float*)ptr)[i] = 0;
break;
case CV_64F:
((double*)ptr)[0] = d;
i = cn;
while( --i ) ((double*)ptr)[i] = 0;
break;
}
}
void CvMAT::set( uchar* ptr, int type, int i )
{
int cn = CV_MAT_CN(type);
switch( CV_MAT_DEPTH(type))
{
case CV_8U:
((uchar*)ptr)[0] = CV_CAST_8U(i);
i = cn;
while( --i ) ((uchar*)ptr)[i] = 0;
break;
case CV_8S:
((char*)ptr)[0] = CV_CAST_8S(i);
i = cn;
while( --i ) ((char*)ptr)[i] = 0;
break;
case CV_16S:
((short*)ptr)[0] = CV_CAST_16S(i);
i = cn;
while( --i ) ((short*)ptr)[i] = 0;
break;
case CV_32S:
((int*)ptr)[0] = i;
i = cn;
while( --i ) ((int*)ptr)[i] = 0;
break;
case CV_32F:
((float*)ptr)[0] = (float)i;
i = cn;
while( --i ) ((float*)ptr)[i] = 0;
break;
case CV_64F:
((double*)ptr)[0] = (double)i;
i = cn;
while( --i ) ((double*)ptr)[i] = 0;
break;
}
}
CvMAT::CvMAT( const _CvMAT_T_& mat_t )
{
data.ptr = 0;
type = 0;
refcount = 0;
*this = mat_t;
}
CvMAT::CvMAT( const _CvMAT_ADD_& mat_add )
{
data.ptr = 0;
type = 0;
refcount = 0;
*this = mat_add;
}
CvMAT::CvMAT( const _CvMAT_ADD_EX_& mat_add )
{
data.ptr = 0;
type = 0;
refcount = 0;
*this = mat_add;
}
CvMAT::CvMAT( const _CvMAT_SCALE_& scale_mat )
{
data.ptr = 0;
type = 0;
refcount = 0;
*this = scale_mat;
}
CvMAT::CvMAT( const _CvMAT_SCALE_SHIFT_& scale_shift_mat )
{
data.ptr = 0;
type = 0;
refcount = 0;
*this = scale_shift_mat;
}
CvMAT::CvMAT( const _CvMAT_MUL_& mmul )
{
data.ptr = 0;
type = 0;
refcount = 0;
*this = mmul;
}
CvMAT::CvMAT( const _CvMAT_MUL_ADD_& mmuladd )
{
data.ptr = 0;
type = 0;
refcount = 0;
*this = mmuladd;
}
CvMAT::CvMAT( const _CvMAT_INV_& inv_mat )
{
data.ptr = 0;
type = 0;
refcount = 0;
*this = inv_mat;
}
CvMAT::CvMAT( const _CvMAT_NOT_& not_mat )
{
type = 0;
data.ptr = 0;
refcount = 0;
*this = not_mat;
}
CvMAT::CvMAT( const _CvMAT_UN_LOGIC_& mat_logic )
{
type = 0;
data.ptr = 0;
refcount = 0;
*this = mat_logic;
}
CvMAT::CvMAT( const _CvMAT_LOGIC_& mat_logic )
{
type = 0;
data.ptr = 0;
refcount = 0;
*this = mat_logic;
}
CvMAT::CvMAT( const _CvMAT_COPY_& mat_copy )
{
CvMAT* src = (CvMAT*)mat_copy.a;
create( src->height, src->width, src->type );
cvCopy( src, this );
}
CvMAT::CvMAT( const _CvMAT_CVT_& mat_cvt )
{
type = 0;
data.ptr = 0;
refcount = 0;
*this = mat_cvt;
}
CvMAT::CvMAT( const _CvMAT_DOT_OP_& dot_op )
{
data.ptr = 0;
type = 0;
refcount = 0;
*this = dot_op;
}
CvMAT::CvMAT( const _CvMAT_SOLVE_& solve_mat )
{
type = 0;
data.ptr = 0;
refcount = 0;
*this = solve_mat;
}
CvMAT::CvMAT( const _CvMAT_CMP_& cmp_mat )
{
type = 0;
data.ptr = 0;
refcount = 0;
*this = cmp_mat;
}
/****************************************************************************************\
* CvMAT::operator = *
\****************************************************************************************/
CvMAT& CvMAT::operator = ( const _CvMAT_T_& mat_t )
{
CvMAT* src = (CvMAT*)&mat_t.a;
if( !data.ptr )
{
create( src->width, src->height, src->type );
}
cvTranspose( src, this );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_ADD_& mat_add )
{
CvMAT* a = mat_add.a;
CvMAT* b = mat_add.b;
if( !data.ptr )
{
create( a->height, a->width, a->type );
}
if( mat_add.beta == 1 )
{
cvAdd( a, b, this );
return *this;
}
if( mat_add.beta == -1 )
{
cvSub( a, b, this );
return *this;
}
if( CV_MAT_DEPTH(a->type) >= CV_32F && CV_MAT_CN(a->type) <= 2 )
cvScaleAdd( b, cvScalar(mat_add.beta), a, this );
else
cvAddWeighted( a, 1, b, mat_add.beta, 0, this );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_ADD_EX_& mat_add )
{
CvMAT* a = mat_add.a;
CvMAT* b = mat_add.b;
if( !data.ptr )
{
create( a->height, a->width, a->type );
}
cvAddWeighted( a, mat_add.alpha, b, mat_add.beta, mat_add.gamma, this );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_SCALE_& scale_mat )
{
CvMAT* src = scale_mat.a;
if( !data.ptr )
{
create( src->height, src->width, src->type );
}
cvConvertScale( src, this, scale_mat.alpha, 0 );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_SCALE_SHIFT_& scale_shift_mat )
{
CvMAT* src = scale_shift_mat.a;
if( !data.ptr )
{
create( src->height, src->width, src->type );
}
cvConvertScale( src, this, scale_shift_mat.alpha, scale_shift_mat.beta );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_MUL_& mmul )
{
CvMAT* a = mmul.a;
CvMAT* b = mmul.b;
int t_a = mmul.t_ab & 1;
int t_b = (mmul.t_ab & 2) != 0;
int m = (&(a->rows))[t_a];
int n = (&(b->rows))[t_b ^ 1];
/* this(m x n) = (a^o1(t))(m x l) * (b^o2(t))(l x n) */
if( !data.ptr )
{
create( m, n, a->type );
}
if( mmul.alpha == 1 )
{
if( mmul.t_ab == 0 )
{
cvMatMulAdd( a, b, 0, this );
return *this;
}
if( a->data.ptr == b->data.ptr && mmul.t_ab < 3 &&
a->rows == b->rows && a->cols == b->cols &&
a->data.ptr != data.ptr )
{
cvMulTransposed( a, this, mmul.t_ab & 1 );
return *this;
}
}
cvGEMM( a, b, mmul.alpha, 0, 0, this, mmul.t_ab );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_MUL_ADD_& mmuladd )
{
CvMAT* a = mmuladd.a;
CvMAT* b = mmuladd.b;
CvMAT* c = mmuladd.c;
int t_a = mmuladd.t_abc & 1;
int t_b = (mmuladd.t_abc & 2) != 0;
int m = (&(a->rows))[t_a];
int n = (&(b->rows))[t_b ^ 1];
/* this(m x n) = (a^o1(t))(m x l) * (b^o2(t))(l x n) */
if( !data.ptr )
{
create( m, n, a->type );
}
if( mmuladd.t_abc == 0 && mmuladd.alpha == 1 && mmuladd.beta == 1 )
cvMatMulAdd( a, b, c, this );
else
cvGEMM( a, b, mmuladd.alpha, c, mmuladd.beta, this, mmuladd.t_abc );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_INV_& inv_mat )
{
CvMAT* src = (CvMAT*)&inv_mat.a;
if( !data.ptr )
{
create( src->height, src->width, src->type );
}
if( inv_mat.method == 0 )
cvInvert( src, this );
else
cvPseudoInv( src, this );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_NOT_& not_mat )
{
CvMAT* src = not_mat.a;
if( !data.ptr )
{
create( src->height, src->width, src->type );
}
cvNot( src, this );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_LOGIC_& mat_logic )
{
CvMAT* a = mat_logic.a;
CvMAT* b = mat_logic.b;
int flags = mat_logic.flags;
_CvMAT_LOGIC_::Op op = mat_logic.op;
if( !data.ptr )
{
create( a->height, a->width, a->type );
}
switch( op )
{
case _CvMAT_LOGIC_::AND:
if( flags == 0 )
cvAnd( a, b, this );
else if( flags == 3 )
{
cvOr( a, b, this );
cvNot( this, this );
}
else if( flags == 1 )
{
if( data.ptr == b->data.ptr )
{
cvNot( b, this );
cvOr( this, a, this );
cvNot( this, this );
}
else
{
cvNot( a, this );
cvAnd( this, b, this );
}
}
else
{
if( data.ptr == a->data.ptr )
{
cvNot( a, this );
cvOr( this, b, this );
cvNot( this, this );
}
else
{
cvNot( b, this );
cvAnd( this, a, this );
}
}
break;
case _CvMAT_LOGIC_::OR:
if( flags == 0 )
cvOr( a, b, this );
else if( flags == 3 )
{
cvAnd( a, b, this );
cvNot( this, this );
}
else if( flags == 1 )
{
if( data.ptr == b->data.ptr )
{
cvNot( b, this );
cvAnd( this, a, this );
cvNot( this, this );
}
else
{
cvNot( a, this );
cvOr( this, b, this );
}
}
else
{
if( data.ptr == a->data.ptr )
{
cvNot( a, this );
cvAnd( this, b, this );
cvNot( this, this );
}
else
{
cvNot( b, this );
cvOr( this, a, this );
}
}
break;
case _CvMAT_LOGIC_::XOR:
cvXor( a, b, this );
if( flags == 1 || flags == 2 )
cvNot( this, this );
break;
}
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_UN_LOGIC_& mat_logic )
{
CvMAT* a = mat_logic.a;
CvScalar scalar = cvScalarAll( mat_logic.alpha );
int flags = mat_logic.flags;
_CvMAT_LOGIC_::Op op = mat_logic.op;
if( !data.ptr )
{
create( a->height, a->width, a->type );
}
switch( op )
{
case _CvMAT_LOGIC_::AND:
if( flags == 0 )
cvAndS( a, scalar, this );
else
{
cvNot( a, this );
cvAndS( this, scalar, this );
}
break;
case _CvMAT_LOGIC_::OR:
if( flags == 0 )
cvOrS( a, scalar, this );
else
{
cvNot( a, this );
cvOrS( this, scalar, this );
}
break;
case _CvMAT_LOGIC_::XOR:
if( flags == 0 )
cvXorS( a, scalar, this );
else
cvXorS( a, ~scalar, this );
break;
}
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_COPY_& mat_copy )
{
CvMAT* src = (CvMAT*)mat_copy.a;
if( !data.ptr )
{
create( src->height, src->width, src->type );
}
if( src != this )
cvCopy( src, this );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_CVT_& mat_cvt )
{
CvMAT* src = (CvMAT*)&mat_cvt.a;
if( !data.ptr )
{
int depth = mat_cvt.newdepth;
create( src->height, src->width, depth < 0 ? src->type :
CV_MAT_CN(src->type)|CV_MAT_DEPTH(depth));
}
cvCvtScale( src, this, mat_cvt.scale, mat_cvt.shift );
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_DOT_OP_& dot_op )
{
CvMAT* a = (CvMAT*)&(dot_op.a);
CvMAT* b = dot_op.b;
if( !data.ptr )
{
create( a->height, a->width, a->type );
}
switch( dot_op.op )
{
case '*':
cvMul( a, b, this, dot_op.alpha );
break;
case '/':
if( b != 0 )
cvDiv( a, b, this, dot_op.alpha );
else
cvDiv( 0, a, this, dot_op.alpha );
break;
case 'm':
if( b != 0 )
cvMin( a, b, this );
else
cvMinS( a, dot_op.alpha, this );
break;
case 'M':
if( b != 0 )
cvMax( a, b, this );
else
cvMaxS( a, dot_op.alpha, this );
break;
case 'a':
if( b != 0 )
cvAbsDiff( a, b, this );
else
cvAbsDiffS( a, this, cvScalar(dot_op.alpha) );
break;
default:
assert(0);
}
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_SOLVE_& solve_mat )
{
CvMAT* a = (CvMAT*)(solve_mat.a);
CvMAT* b = (CvMAT*)(solve_mat.b);
if( !data.ptr )
{
create( a->height, b->width, a->type );
}
if( solve_mat.method == 0 )
cvSolve( a, b, this );
else
{
CvMAT temp;
cvInitMatHeader( &temp, a->cols, a->rows, a->type );
cvCreateData( &temp );
cvPseudoInv( a, &temp );
cvMatMul( &temp, b, this );
}
return *this;
}
CvMAT& CvMAT::operator = ( const _CvMAT_CMP_& mat_cmp )
{
CvMAT* a = mat_cmp.a;
CvMAT* b = mat_cmp.b;
if( !data.ptr )
{
create( a->height, a->width, CV_8UC1 );
}
if( b )
cvCmp( a, b, this, mat_cmp.cmp_op );
else
cvCmpS( a, mat_cmp.alpha, this, mat_cmp.cmp_op );
return *this;
}
/****************************************************************************************\
* CvMAT I/O operations *
\****************************************************************************************/
void CvMAT::write( const char* name, FILE* f, const char* fmt )
{
int i, j, w = width * CV_MAT_CN(type);
FILE* out = f ? f : stdout;
if( name )
fprintf( stdout, "%s(%d x %d) =\n\t", name, rows, cols );
for( i = 0; i < rows; i++ )
{
switch( CV_MAT_DEPTH(type))
{
case CV_8U: if( !fmt )
fmt = "%4d";
for( j = 0; j < w; j++ )
fprintf( out, fmt, ((uchar*)(data.ptr + i*step))[j] );
break;
case CV_8S: if( !fmt )
fmt = "%5d";
for( j = 0; j < w; j++ )
fprintf( out, fmt, ((char*)(data.ptr + i*step))[j] );
break;
case CV_16S: if( !fmt )
fmt = "%7d";
for( j = 0; j < w; j++ )
fprintf( out, fmt, ((short*)(data.ptr + i*step))[j] );
break;
case CV_32S: if( !fmt )
fmt = " %08x";
for( j = 0; j < w; j++ )
fprintf( out, fmt, ((int*)(data.ptr + i*step))[j] );
break;
case CV_32F: if( !fmt )
fmt = "%15g";
for( j = 0; j < w; j++ )
fprintf( out, fmt, ((float*)(data.ptr + i*step))[j] );
break;
case CV_64F: if( !fmt )
fmt = "%15g";
for( j = 0; j < w; j++ )
fprintf( out, fmt, ((double*)(data.ptr + i*step))[j] );
break;
}
fprintf( out, "\n%s", i < rows - 1 ? "\t" : "" );
}
fprintf( out, "\n" );
}
#endif /* _MSC_VER || __BORLANDC__ */
/* End of file. */