opencv/modules/calib3d/test/test_cameracalibration.cpp
Andrey Kamaev 2a6fb2867e Remove all using directives for STL namespace and members
Made all STL usages explicit to be able automatically find all usages of
particular class or function.
2013-02-25 15:04:17 +04:00

1876 lines
71 KiB
C++

/*M///////////////////////////////////////////////////////////////////////////////////////
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#include "test_precomp.hpp"
#include <limits>
using namespace std;
using namespace cv;
#if 0
class CV_ProjectPointsTest : public cvtest::ArrayTest
{
public:
CV_ProjectPointsTest();
protected:
int read_params( CvFileStorage* fs );
void fill_array( int test_case_idx, int i, int j, Mat& arr );
int prepare_test_case( int test_case_idx );
void get_test_array_types_and_sizes( int test_case_idx, vector<vector<Size> >& sizes, vector<vector<int> >& types );
double get_success_error_level( int test_case_idx, int i, int j );
void run_func();
void prepare_to_validation( int );
bool calc_jacobians;
};
CV_ProjectPointsTest::CV_ProjectPointsTest()
: cvtest::ArrayTest( "3d-ProjectPoints", "cvProjectPoints2", "" )
{
test_array[INPUT].push_back(NULL); // rotation vector
test_array[OUTPUT].push_back(NULL); // rotation matrix
test_array[OUTPUT].push_back(NULL); // jacobian (J)
test_array[OUTPUT].push_back(NULL); // rotation vector (backward transform result)
test_array[OUTPUT].push_back(NULL); // inverse transform jacobian (J1)
test_array[OUTPUT].push_back(NULL); // J*J1 (or J1*J) == I(3x3)
test_array[REF_OUTPUT].push_back(NULL);
test_array[REF_OUTPUT].push_back(NULL);
test_array[REF_OUTPUT].push_back(NULL);
test_array[REF_OUTPUT].push_back(NULL);
test_array[REF_OUTPUT].push_back(NULL);
element_wise_relative_error = false;
calc_jacobians = false;
}
int CV_ProjectPointsTest::read_params( CvFileStorage* fs )
{
int code = cvtest::ArrayTest::read_params( fs );
return code;
}
void CV_ProjectPointsTest::get_test_array_types_and_sizes(
int /*test_case_idx*/, vector<vector<Size> >& sizes, vector<vector<int> >& types )
{
RNG& rng = ts->get_rng();
int depth = cvtest::randInt(rng) % 2 == 0 ? CV_32F : CV_64F;
int i, code;
code = cvtest::randInt(rng) % 3;
types[INPUT][0] = CV_MAKETYPE(depth, 1);
if( code == 0 )
{
sizes[INPUT][0] = cvSize(1,1);
types[INPUT][0] = CV_MAKETYPE(depth, 3);
}
else if( code == 1 )
sizes[INPUT][0] = cvSize(3,1);
else
sizes[INPUT][0] = cvSize(1,3);
sizes[OUTPUT][0] = cvSize(3, 3);
types[OUTPUT][0] = CV_MAKETYPE(depth, 1);
types[OUTPUT][1] = CV_MAKETYPE(depth, 1);
if( cvtest::randInt(rng) % 2 )
sizes[OUTPUT][1] = cvSize(3,9);
else
sizes[OUTPUT][1] = cvSize(9,3);
types[OUTPUT][2] = types[INPUT][0];
sizes[OUTPUT][2] = sizes[INPUT][0];
types[OUTPUT][3] = types[OUTPUT][1];
sizes[OUTPUT][3] = cvSize(sizes[OUTPUT][1].height, sizes[OUTPUT][1].width);
types[OUTPUT][4] = types[OUTPUT][1];
sizes[OUTPUT][4] = cvSize(3,3);
calc_jacobians = 1;//cvtest::randInt(rng) % 3 != 0;
if( !calc_jacobians )
sizes[OUTPUT][1] = sizes[OUTPUT][3] = sizes[OUTPUT][4] = cvSize(0,0);
for( i = 0; i < 5; i++ )
{
types[REF_OUTPUT][i] = types[OUTPUT][i];
sizes[REF_OUTPUT][i] = sizes[OUTPUT][i];
}
}
double CV_ProjectPointsTest::get_success_error_level( int /*test_case_idx*/, int /*i*/, int j )
{
return j == 4 ? 1e-2 : 1e-2;
}
void CV_ProjectPointsTest::fill_array( int /*test_case_idx*/, int /*i*/, int /*j*/, CvMat* arr )
{
double r[3], theta0, theta1, f;
CvMat _r = cvMat( arr->rows, arr->cols, CV_MAKETYPE(CV_64F,CV_MAT_CN(arr->type)), r );
RNG& rng = ts->get_rng();
r[0] = cvtest::randReal(rng)*CV_PI*2;
r[1] = cvtest::randReal(rng)*CV_PI*2;
r[2] = cvtest::randReal(rng)*CV_PI*2;
theta0 = sqrt(r[0]*r[0] + r[1]*r[1] + r[2]*r[2]);
theta1 = fmod(theta0, CV_PI*2);
if( theta1 > CV_PI )
theta1 = -(CV_PI*2 - theta1);
f = theta1/(theta0 ? theta0 : 1);
r[0] *= f;
r[1] *= f;
r[2] *= f;
cvTsConvert( &_r, arr );
}
int CV_ProjectPointsTest::prepare_test_case( int test_case_idx )
{
int code = cvtest::ArrayTest::prepare_test_case( test_case_idx );
return code;
}
void CV_ProjectPointsTest::run_func()
{
CvMat *v2m_jac = 0, *m2v_jac = 0;
if( calc_jacobians )
{
v2m_jac = &test_mat[OUTPUT][1];
m2v_jac = &test_mat[OUTPUT][3];
}
cvProjectPoints2( &test_mat[INPUT][0], &test_mat[OUTPUT][0], v2m_jac );
cvProjectPoints2( &test_mat[OUTPUT][0], &test_mat[OUTPUT][2], m2v_jac );
}
void CV_ProjectPointsTest::prepare_to_validation( int /*test_case_idx*/ )
{
const CvMat* vec = &test_mat[INPUT][0];
CvMat* m = &test_mat[REF_OUTPUT][0];
CvMat* vec2 = &test_mat[REF_OUTPUT][2];
CvMat* v2m_jac = 0, *m2v_jac = 0;
double theta0, theta1;
if( calc_jacobians )
{
v2m_jac = &test_mat[REF_OUTPUT][1];
m2v_jac = &test_mat[REF_OUTPUT][3];
}
cvTsProjectPoints( vec, m, v2m_jac );
cvTsProjectPoints( m, vec2, m2v_jac );
cvTsCopy( vec, vec2 );
theta0 = cvNorm( vec2, 0, CV_L2 );
theta1 = fmod( theta0, CV_PI*2 );
if( theta1 > CV_PI )
theta1 = -(CV_PI*2 - theta1);
cvScale( vec2, vec2, theta1/(theta0 ? theta0 : 1) );
if( calc_jacobians )
{
//cvInvert( v2m_jac, m2v_jac, CV_SVD );
if( cvNorm(&test_mat[OUTPUT][3],0,CV_C) < 1000 )
{
cvTsGEMM( &test_mat[OUTPUT][1], &test_mat[OUTPUT][3],
1, 0, 0, &test_mat[OUTPUT][4],
v2m_jac->rows == 3 ? 0 : CV_GEMM_A_T + CV_GEMM_B_T );
}
else
{
cvTsSetIdentity( &test_mat[OUTPUT][4], cvScalarAll(1.) );
cvTsCopy( &test_mat[REF_OUTPUT][2], &test_mat[OUTPUT][2] );
}
cvTsSetIdentity( &test_mat[REF_OUTPUT][4], cvScalarAll(1.) );
}
}
CV_ProjectPointsTest ProjectPoints_test;
#endif
// --------------------------------- CV_CameraCalibrationTest --------------------------------------------
class CV_CameraCalibrationTest : public cvtest::BaseTest
{
public:
CV_CameraCalibrationTest();
~CV_CameraCalibrationTest();
void clear();
protected:
int compare(double* val, double* refVal, int len,
double eps, const char* paramName);
virtual void calibrate( int imageCount, int* pointCounts,
CvSize imageSize, CvPoint2D64f* imagePoints, CvPoint3D64f* objectPoints,
double* distortionCoeffs, double* cameraMatrix, double* translationVectors,
double* rotationMatrices, int flags ) = 0;
virtual void project( int pointCount, CvPoint3D64f* objectPoints,
double* rotationMatrix, double* translationVector,
double* cameraMatrix, double* distortion, CvPoint2D64f* imagePoints ) = 0;
void run(int);
};
CV_CameraCalibrationTest::CV_CameraCalibrationTest()
{
}
CV_CameraCalibrationTest::~CV_CameraCalibrationTest()
{
clear();
}
void CV_CameraCalibrationTest::clear()
{
cvtest::BaseTest::clear();
}
int CV_CameraCalibrationTest::compare(double* val, double* ref_val, int len,
double eps, const char* param_name )
{
return cvtest::cmpEps2_64f( ts, val, ref_val, len, eps, param_name );
}
void CV_CameraCalibrationTest::run( int start_from )
{
int code = cvtest::TS::OK;
char filepath[200];
char filename[200];
CvSize imageSize;
CvSize etalonSize;
int numImages;
CvPoint2D64f* imagePoints;
CvPoint3D64f* objectPoints;
CvPoint2D64f* reprojectPoints;
double* transVects;
double* rotMatrs;
double* goodTransVects;
double* goodRotMatrs;
double cameraMatrix[3*3];
double distortion[5]={0,0,0,0,0};
double goodDistortion[4];
int* numbers;
FILE* file = 0;
FILE* datafile = 0;
int i,j;
int currImage;
int currPoint;
int calibFlags;
char i_dat_file[100];
int numPoints;
int numTests;
int currTest;
imagePoints = 0;
objectPoints = 0;
reprojectPoints = 0;
numbers = 0;
transVects = 0;
rotMatrs = 0;
goodTransVects = 0;
goodRotMatrs = 0;
int progress = 0;
int values_read = -1;
sprintf( filepath, "%scameracalibration/", ts->get_data_path().c_str() );
sprintf( filename, "%sdatafiles.txt", filepath );
datafile = fopen( filename, "r" );
if( datafile == 0 )
{
ts->printf( cvtest::TS::LOG, "Could not open file with list of test files: %s\n", filename );
code = cvtest::TS::FAIL_MISSING_TEST_DATA;
goto _exit_;
}
values_read = fscanf(datafile,"%d",&numTests);
CV_Assert(values_read == 1);
for( currTest = start_from; currTest < numTests; currTest++ )
{
values_read = fscanf(datafile,"%s",i_dat_file);
CV_Assert(values_read == 1);
sprintf(filename, "%s%s", filepath, i_dat_file);
file = fopen(filename,"r");
ts->update_context( this, currTest, true );
if( file == 0 )
{
ts->printf( cvtest::TS::LOG,
"Can't open current test file: %s\n",filename);
if( numTests == 1 )
{
code = cvtest::TS::FAIL_MISSING_TEST_DATA;
goto _exit_;
}
continue; // if there is more than one test, just skip the test
}
values_read = fscanf(file,"%d %d\n",&(imageSize.width),&(imageSize.height));
CV_Assert(values_read == 2);
if( imageSize.width <= 0 || imageSize.height <= 0 )
{
ts->printf( cvtest::TS::LOG, "Image size in test file is incorrect\n" );
code = cvtest::TS::FAIL_INVALID_TEST_DATA;
goto _exit_;
}
/* Read etalon size */
values_read = fscanf(file,"%d %d\n",&(etalonSize.width),&(etalonSize.height));
CV_Assert(values_read == 2);
if( etalonSize.width <= 0 || etalonSize.height <= 0 )
{
ts->printf( cvtest::TS::LOG, "Pattern size in test file is incorrect\n" );
code = cvtest::TS::FAIL_INVALID_TEST_DATA;
goto _exit_;
}
numPoints = etalonSize.width * etalonSize.height;
/* Read number of images */
values_read = fscanf(file,"%d\n",&numImages);
CV_Assert(values_read == 1);
if( numImages <=0 )
{
ts->printf( cvtest::TS::LOG, "Number of images in test file is incorrect\n");
code = cvtest::TS::FAIL_INVALID_TEST_DATA;
goto _exit_;
}
/* Need to allocate memory */
imagePoints = (CvPoint2D64f*)cvAlloc( numPoints *
numImages * sizeof(CvPoint2D64f));
objectPoints = (CvPoint3D64f*)cvAlloc( numPoints *
numImages * sizeof(CvPoint3D64f));
reprojectPoints = (CvPoint2D64f*)cvAlloc( numPoints *
numImages * sizeof(CvPoint2D64f));
/* Alloc memory for numbers */
numbers = (int*)cvAlloc( numImages * sizeof(int));
/* Fill it by numbers of points of each image*/
for( currImage = 0; currImage < numImages; currImage++ )
{
numbers[currImage] = etalonSize.width * etalonSize.height;
}
/* Allocate memory for translate vectors and rotmatrixs*/
transVects = (double*)cvAlloc(3 * 1 * numImages * sizeof(double));
rotMatrs = (double*)cvAlloc(3 * 3 * numImages * sizeof(double));
goodTransVects = (double*)cvAlloc(3 * 1 * numImages * sizeof(double));
goodRotMatrs = (double*)cvAlloc(3 * 3 * numImages * sizeof(double));
/* Read object points */
i = 0;/* shift for current point */
for( currImage = 0; currImage < numImages; currImage++ )
{
for( currPoint = 0; currPoint < numPoints; currPoint++ )
{
double x,y,z;
values_read = fscanf(file,"%lf %lf %lf\n",&x,&y,&z);
CV_Assert(values_read == 3);
(objectPoints+i)->x = x;
(objectPoints+i)->y = y;
(objectPoints+i)->z = z;
i++;
}
}
/* Read image points */
i = 0;/* shift for current point */
for( currImage = 0; currImage < numImages; currImage++ )
{
for( currPoint = 0; currPoint < numPoints; currPoint++ )
{
double x,y;
values_read = fscanf(file,"%lf %lf\n",&x,&y);
CV_Assert(values_read == 2);
(imagePoints+i)->x = x;
(imagePoints+i)->y = y;
i++;
}
}
/* Read good data computed before */
/* Focal lengths */
double goodFcx,goodFcy;
values_read = fscanf(file,"%lf %lf",&goodFcx,&goodFcy);
CV_Assert(values_read == 2);
/* Principal points */
double goodCx,goodCy;
values_read = fscanf(file,"%lf %lf",&goodCx,&goodCy);
CV_Assert(values_read == 2);
/* Read distortion */
values_read = fscanf(file,"%lf",goodDistortion+0); CV_Assert(values_read == 1);
values_read = fscanf(file,"%lf",goodDistortion+1); CV_Assert(values_read == 1);
values_read = fscanf(file,"%lf",goodDistortion+2); CV_Assert(values_read == 1);
values_read = fscanf(file,"%lf",goodDistortion+3); CV_Assert(values_read == 1);
/* Read good Rot matrixes */
for( currImage = 0; currImage < numImages; currImage++ )
{
for( i = 0; i < 3; i++ )
for( j = 0; j < 3; j++ )
{
values_read = fscanf(file, "%lf", goodRotMatrs + currImage * 9 + j * 3 + i);
CV_Assert(values_read == 1);
}
}
/* Read good Trans vectors */
for( currImage = 0; currImage < numImages; currImage++ )
{
for( i = 0; i < 3; i++ )
{
values_read = fscanf(file, "%lf", goodTransVects + currImage * 3 + i);
CV_Assert(values_read == 1);
}
}
calibFlags = 0
// + CV_CALIB_FIX_PRINCIPAL_POINT
// + CV_CALIB_ZERO_TANGENT_DIST
// + CV_CALIB_FIX_ASPECT_RATIO
// + CV_CALIB_USE_INTRINSIC_GUESS
+ CV_CALIB_FIX_K3
+ CV_CALIB_FIX_K4+CV_CALIB_FIX_K5
+ CV_CALIB_FIX_K6
;
memset( cameraMatrix, 0, 9*sizeof(cameraMatrix[0]) );
cameraMatrix[0] = cameraMatrix[4] = 807.;
cameraMatrix[2] = (imageSize.width - 1)*0.5;
cameraMatrix[5] = (imageSize.height - 1)*0.5;
cameraMatrix[8] = 1.;
/* Now we can calibrate camera */
calibrate( numImages,
numbers,
imageSize,
imagePoints,
objectPoints,
distortion,
cameraMatrix,
transVects,
rotMatrs,
calibFlags );
/* ---- Reproject points to the image ---- */
for( currImage = 0; currImage < numImages; currImage++ )
{
int nPoints = etalonSize.width * etalonSize.height;
project( nPoints,
objectPoints + currImage * nPoints,
rotMatrs + currImage * 9,
transVects + currImage * 3,
cameraMatrix,
distortion,
reprojectPoints + currImage * nPoints);
}
/* ----- Compute reprojection error ----- */
i = 0;
double dx,dy;
double rx,ry;
double meanDx,meanDy;
double maxDx = 0.0;
double maxDy = 0.0;
meanDx = 0;
meanDy = 0;
for( currImage = 0; currImage < numImages; currImage++ )
{
for( currPoint = 0; currPoint < etalonSize.width * etalonSize.height; currPoint++ )
{
rx = reprojectPoints[i].x;
ry = reprojectPoints[i].y;
dx = rx - imagePoints[i].x;
dy = ry - imagePoints[i].y;
meanDx += dx;
meanDy += dy;
dx = fabs(dx);
dy = fabs(dy);
if( dx > maxDx )
maxDx = dx;
if( dy > maxDy )
maxDy = dy;
i++;
}
}
meanDx /= numImages * etalonSize.width * etalonSize.height;
meanDy /= numImages * etalonSize.width * etalonSize.height;
/* ========= Compare parameters ========= */
/* ----- Compare focal lengths ----- */
code = compare(cameraMatrix+0,&goodFcx,1,0.1,"fx");
if( code < 0 )
goto _exit_;
code = compare(cameraMatrix+4,&goodFcy,1,0.1,"fy");
if( code < 0 )
goto _exit_;
/* ----- Compare principal points ----- */
code = compare(cameraMatrix+2,&goodCx,1,0.1,"cx");
if( code < 0 )
goto _exit_;
code = compare(cameraMatrix+5,&goodCy,1,0.1,"cy");
if( code < 0 )
goto _exit_;
/* ----- Compare distortion ----- */
code = compare(distortion,goodDistortion,4,0.1,"[k1,k2,p1,p2]");
if( code < 0 )
goto _exit_;
/* ----- Compare rot matrixs ----- */
code = compare(rotMatrs,goodRotMatrs, 9*numImages,0.05,"rotation matrices");
if( code < 0 )
goto _exit_;
/* ----- Compare rot matrixs ----- */
code = compare(transVects,goodTransVects, 3*numImages,0.1,"translation vectors");
if( code < 0 )
goto _exit_;
if( maxDx > 1.0 )
{
ts->printf( cvtest::TS::LOG,
"Error in reprojection maxDx=%f > 1.0\n",maxDx);
code = cvtest::TS::FAIL_BAD_ACCURACY; goto _exit_;
}
if( maxDy > 1.0 )
{
ts->printf( cvtest::TS::LOG,
"Error in reprojection maxDy=%f > 1.0\n",maxDy);
code = cvtest::TS::FAIL_BAD_ACCURACY; goto _exit_;
}
progress = update_progress( progress, currTest, numTests, 0 );
cvFree(&imagePoints);
cvFree(&objectPoints);
cvFree(&reprojectPoints);
cvFree(&numbers);
cvFree(&transVects);
cvFree(&rotMatrs);
cvFree(&goodTransVects);
cvFree(&goodRotMatrs);
fclose(file);
file = 0;
}
_exit_:
if( file )
fclose(file);
if( datafile )
fclose(datafile);
/* Free all allocated memory */
cvFree(&imagePoints);
cvFree(&objectPoints);
cvFree(&reprojectPoints);
cvFree(&numbers);
cvFree(&transVects);
cvFree(&rotMatrs);
cvFree(&goodTransVects);
cvFree(&goodRotMatrs);
if( code < 0 )
ts->set_failed_test_info( code );
}
// --------------------------------- CV_CameraCalibrationTest_C --------------------------------------------
class CV_CameraCalibrationTest_C : public CV_CameraCalibrationTest
{
public:
CV_CameraCalibrationTest_C(){}
protected:
virtual void calibrate( int imageCount, int* pointCounts,
CvSize imageSize, CvPoint2D64f* imagePoints, CvPoint3D64f* objectPoints,
double* distortionCoeffs, double* cameraMatrix, double* translationVectors,
double* rotationMatrices, int flags );
virtual void project( int pointCount, CvPoint3D64f* objectPoints,
double* rotationMatrix, double* translationVector,
double* cameraMatrix, double* distortion, CvPoint2D64f* imagePoints );
};
void CV_CameraCalibrationTest_C::calibrate( int imageCount, int* pointCounts,
CvSize imageSize, CvPoint2D64f* imagePoints, CvPoint3D64f* objectPoints,
double* distortionCoeffs, double* cameraMatrix, double* translationVectors,
double* rotationMatrices, int flags )
{
int i, total = 0;
for( i = 0; i < imageCount; i++ )
total += pointCounts[i];
CvMat _objectPoints = cvMat(1, total, CV_64FC3, objectPoints);
CvMat _imagePoints = cvMat(1, total, CV_64FC2, imagePoints);
CvMat _pointCounts = cvMat(1, imageCount, CV_32S, pointCounts);
CvMat _cameraMatrix = cvMat(3, 3, CV_64F, cameraMatrix);
CvMat _distCoeffs = cvMat(4, 1, CV_64F, distortionCoeffs);
CvMat _rotationMatrices = cvMat(imageCount, 9, CV_64F, rotationMatrices);
CvMat _translationVectors = cvMat(imageCount, 3, CV_64F, translationVectors);
cvCalibrateCamera2(&_objectPoints, &_imagePoints, &_pointCounts, imageSize,
&_cameraMatrix, &_distCoeffs, &_rotationMatrices, &_translationVectors,
flags);
}
void CV_CameraCalibrationTest_C::project( int pointCount, CvPoint3D64f* objectPoints,
double* rotationMatrix, double* translationVector,
double* cameraMatrix, double* distortion, CvPoint2D64f* imagePoints )
{
CvMat _objectPoints = cvMat(1, pointCount, CV_64FC3, objectPoints);
CvMat _imagePoints = cvMat(1, pointCount, CV_64FC2, imagePoints);
CvMat _cameraMatrix = cvMat(3, 3, CV_64F, cameraMatrix);
CvMat _distCoeffs = cvMat(4, 1, CV_64F, distortion);
CvMat _rotationMatrix = cvMat(3, 3, CV_64F, rotationMatrix);
CvMat _translationVector = cvMat(1, 3, CV_64F, translationVector);
cvProjectPoints2(&_objectPoints, &_rotationMatrix, &_translationVector, &_cameraMatrix, &_distCoeffs, &_imagePoints);
}
// --------------------------------- CV_CameraCalibrationTest_CPP --------------------------------------------
class CV_CameraCalibrationTest_CPP : public CV_CameraCalibrationTest
{
public:
CV_CameraCalibrationTest_CPP(){}
protected:
virtual void calibrate( int imageCount, int* pointCounts,
CvSize imageSize, CvPoint2D64f* imagePoints, CvPoint3D64f* objectPoints,
double* distortionCoeffs, double* cameraMatrix, double* translationVectors,
double* rotationMatrices, int flags );
virtual void project( int pointCount, CvPoint3D64f* objectPoints,
double* rotationMatrix, double* translationVector,
double* cameraMatrix, double* distortion, CvPoint2D64f* imagePoints );
};
void CV_CameraCalibrationTest_CPP::calibrate( int imageCount, int* pointCounts,
CvSize _imageSize, CvPoint2D64f* _imagePoints, CvPoint3D64f* _objectPoints,
double* _distortionCoeffs, double* _cameraMatrix, double* translationVectors,
double* rotationMatrices, int flags )
{
vector<vector<Point3f> > objectPoints( imageCount );
vector<vector<Point2f> > imagePoints( imageCount );
Size imageSize = _imageSize;
Mat cameraMatrix, distCoeffs(1,4,CV_64F,Scalar::all(0));
vector<Mat> rvecs, tvecs;
CvPoint3D64f* op = _objectPoints;
CvPoint2D64f* ip = _imagePoints;
vector<vector<Point3f> >::iterator objectPointsIt = objectPoints.begin();
vector<vector<Point2f> >::iterator imagePointsIt = imagePoints.begin();
for( int i = 0; i < imageCount; ++objectPointsIt, ++imagePointsIt, i++ )
{
int num = pointCounts[i];
objectPointsIt->resize( num );
imagePointsIt->resize( num );
vector<Point3f>::iterator oIt = objectPointsIt->begin();
vector<Point2f>::iterator iIt = imagePointsIt->begin();
for( int j = 0; j < num; ++oIt, ++iIt, j++, op++, ip++)
{
oIt->x = (float)op->x, oIt->y = (float)op->y, oIt->z = (float)op->z;
iIt->x = (float)ip->x, iIt->y = (float)ip->y;
}
}
calibrateCamera( objectPoints,
imagePoints,
imageSize,
cameraMatrix,
distCoeffs,
rvecs,
tvecs,
flags );
assert( cameraMatrix.type() == CV_64FC1 );
memcpy( _cameraMatrix, cameraMatrix.data, 9*sizeof(double) );
assert( cameraMatrix.type() == CV_64FC1 );
memcpy( _distortionCoeffs, distCoeffs.data, 4*sizeof(double) );
vector<Mat>::iterator rvecsIt = rvecs.begin();
vector<Mat>::iterator tvecsIt = tvecs.begin();
double *rm = rotationMatrices,
*tm = translationVectors;
assert( rvecsIt->type() == CV_64FC1 );
assert( tvecsIt->type() == CV_64FC1 );
for( int i = 0; i < imageCount; ++rvecsIt, ++tvecsIt, i++, rm+=9, tm+=3 )
{
Mat r9( 3, 3, CV_64FC1 );
Rodrigues( *rvecsIt, r9 );
memcpy( rm, r9.data, 9*sizeof(double) );
memcpy( tm, tvecsIt->data, 3*sizeof(double) );
}
}
void CV_CameraCalibrationTest_CPP::project( int pointCount, CvPoint3D64f* _objectPoints,
double* rotationMatrix, double* translationVector,
double* _cameraMatrix, double* distortion, CvPoint2D64f* _imagePoints )
{
Mat objectPoints( pointCount, 3, CV_64FC1, _objectPoints );
Mat rmat( 3, 3, CV_64FC1, rotationMatrix ),
rvec( 1, 3, CV_64FC1 ),
tvec( 1, 3, CV_64FC1, translationVector );
Mat cameraMatrix( 3, 3, CV_64FC1, _cameraMatrix );
Mat distCoeffs( 1, 4, CV_64FC1, distortion );
vector<Point2f> imagePoints;
Rodrigues( rmat, rvec );
objectPoints.convertTo( objectPoints, CV_32FC1 );
projectPoints( objectPoints, rvec, tvec,
cameraMatrix, distCoeffs, imagePoints );
vector<Point2f>::const_iterator it = imagePoints.begin();
for( int i = 0; it != imagePoints.end(); ++it, i++ )
{
_imagePoints[i] = cvPoint2D64f( it->x, it->y );
}
}
//----------------------------------------- CV_CalibrationMatrixValuesTest --------------------------------
class CV_CalibrationMatrixValuesTest : public cvtest::BaseTest
{
public:
CV_CalibrationMatrixValuesTest() {}
protected:
void run(int);
virtual void calibMatrixValues( const Mat& cameraMatrix, Size imageSize,
double apertureWidth, double apertureHeight, double& fovx, double& fovy, double& focalLength,
Point2d& principalPoint, double& aspectRatio ) = 0;
};
void CV_CalibrationMatrixValuesTest::run(int)
{
int code = cvtest::TS::OK;
const double fcMinVal = 1e-5;
const double fcMaxVal = 1000;
const double apertureMaxVal = 0.01;
RNG rng = ts->get_rng();
double fx, fy, cx, cy, nx, ny;
Mat cameraMatrix( 3, 3, CV_64FC1 );
cameraMatrix.setTo( Scalar(0) );
fx = cameraMatrix.at<double>(0,0) = rng.uniform( fcMinVal, fcMaxVal );
fy = cameraMatrix.at<double>(1,1) = rng.uniform( fcMinVal, fcMaxVal );
cx = cameraMatrix.at<double>(0,2) = rng.uniform( fcMinVal, fcMaxVal );
cy = cameraMatrix.at<double>(1,2) = rng.uniform( fcMinVal, fcMaxVal );
cameraMatrix.at<double>(2,2) = 1;
Size imageSize( 600, 400 );
double apertureWidth = (double)rng * apertureMaxVal,
apertureHeight = (double)rng * apertureMaxVal;
double fovx, fovy, focalLength, aspectRatio,
goodFovx, goodFovy, goodFocalLength, goodAspectRatio;
Point2d principalPoint, goodPrincipalPoint;
calibMatrixValues( cameraMatrix, imageSize, apertureWidth, apertureHeight,
fovx, fovy, focalLength, principalPoint, aspectRatio );
// calculate calibration matrix values
goodAspectRatio = fy / fx;
if( apertureWidth != 0.0 && apertureHeight != 0.0 )
{
nx = imageSize.width / apertureWidth;
ny = imageSize.height / apertureHeight;
}
else
{
nx = 1.0;
ny = goodAspectRatio;
}
goodFovx = 2 * atan( imageSize.width / (2 * fx)) * 180.0 / CV_PI;
goodFovy = 2 * atan( imageSize.height / (2 * fy)) * 180.0 / CV_PI;
goodFocalLength = fx / nx;
goodPrincipalPoint.x = cx / nx;
goodPrincipalPoint.y = cy / ny;
// check results
if( fabs(fovx - goodFovx) > FLT_EPSILON )
{
ts->printf( cvtest::TS::LOG, "bad fovx (real=%f, good = %f\n", fovx, goodFovx );
code = cvtest::TS::FAIL_BAD_ACCURACY;
goto _exit_;
}
if( fabs(fovy - goodFovy) > FLT_EPSILON )
{
ts->printf( cvtest::TS::LOG, "bad fovy (real=%f, good = %f\n", fovy, goodFovy );
code = cvtest::TS::FAIL_BAD_ACCURACY;
goto _exit_;
}
if( fabs(focalLength - goodFocalLength) > FLT_EPSILON )
{
ts->printf( cvtest::TS::LOG, "bad focalLength (real=%f, good = %f\n", focalLength, goodFocalLength );
code = cvtest::TS::FAIL_BAD_ACCURACY;
goto _exit_;
}
if( fabs(aspectRatio - goodAspectRatio) > FLT_EPSILON )
{
ts->printf( cvtest::TS::LOG, "bad aspectRatio (real=%f, good = %f\n", aspectRatio, goodAspectRatio );
code = cvtest::TS::FAIL_BAD_ACCURACY;
goto _exit_;
}
if( norm( principalPoint - goodPrincipalPoint ) > FLT_EPSILON )
{
ts->printf( cvtest::TS::LOG, "bad principalPoint\n" );
code = cvtest::TS::FAIL_BAD_ACCURACY;
goto _exit_;
}
_exit_:
RNG& _rng = ts->get_rng();
_rng = rng;
ts->set_failed_test_info( code );
}
//----------------------------------------- CV_CalibrationMatrixValuesTest_C --------------------------------
class CV_CalibrationMatrixValuesTest_C : public CV_CalibrationMatrixValuesTest
{
public:
CV_CalibrationMatrixValuesTest_C(){}
protected:
virtual void calibMatrixValues( const Mat& cameraMatrix, Size imageSize,
double apertureWidth, double apertureHeight, double& fovx, double& fovy, double& focalLength,
Point2d& principalPoint, double& aspectRatio );
};
void CV_CalibrationMatrixValuesTest_C::calibMatrixValues( const Mat& _cameraMatrix, Size imageSize,
double apertureWidth, double apertureHeight,
double& fovx, double& fovy, double& focalLength,
Point2d& principalPoint, double& aspectRatio )
{
CvMat cameraMatrix = _cameraMatrix;
CvPoint2D64f pp;
cvCalibrationMatrixValues( &cameraMatrix, imageSize, apertureWidth, apertureHeight,
&fovx, &fovy, &focalLength, &pp, &aspectRatio );
principalPoint.x = pp.x;
principalPoint.y = pp.y;
}
//----------------------------------------- CV_CalibrationMatrixValuesTest_CPP --------------------------------
class CV_CalibrationMatrixValuesTest_CPP : public CV_CalibrationMatrixValuesTest
{
public:
CV_CalibrationMatrixValuesTest_CPP() {}
protected:
virtual void calibMatrixValues( const Mat& cameraMatrix, Size imageSize,
double apertureWidth, double apertureHeight, double& fovx, double& fovy, double& focalLength,
Point2d& principalPoint, double& aspectRatio );
};
void CV_CalibrationMatrixValuesTest_CPP::calibMatrixValues( const Mat& cameraMatrix, Size imageSize,
double apertureWidth, double apertureHeight,
double& fovx, double& fovy, double& focalLength,
Point2d& principalPoint, double& aspectRatio )
{
calibrationMatrixValues( cameraMatrix, imageSize, apertureWidth, apertureHeight,
fovx, fovy, focalLength, principalPoint, aspectRatio );
}
//----------------------------------------- CV_ProjectPointsTest --------------------------------
void calcdfdx( const vector<vector<Point2f> >& leftF, const vector<vector<Point2f> >& rightF, double eps, Mat& dfdx )
{
const int fdim = 2;
CV_Assert( !leftF.empty() && !rightF.empty() && !leftF[0].empty() && !rightF[0].empty() );
CV_Assert( leftF[0].size() == rightF[0].size() );
CV_Assert( fabs(eps) > std::numeric_limits<double>::epsilon() );
int fcount = (int)leftF[0].size(), xdim = (int)leftF.size();
dfdx.create( fcount*fdim, xdim, CV_64FC1 );
vector<vector<Point2f> >::const_iterator arrLeftIt = leftF.begin();
vector<vector<Point2f> >::const_iterator arrRightIt = rightF.begin();
for( int xi = 0; xi < xdim; xi++, ++arrLeftIt, ++arrRightIt )
{
CV_Assert( (int)arrLeftIt->size() == fcount );
CV_Assert( (int)arrRightIt->size() == fcount );
vector<Point2f>::const_iterator lIt = arrLeftIt->begin();
vector<Point2f>::const_iterator rIt = arrRightIt->begin();
for( int fi = 0; fi < dfdx.rows; fi+=fdim, ++lIt, ++rIt )
{
dfdx.at<double>(fi, xi ) = 0.5 * ((double)(rIt->x - lIt->x)) / eps;
dfdx.at<double>(fi+1, xi ) = 0.5 * ((double)(rIt->y - lIt->y)) / eps;
}
}
}
class CV_ProjectPointsTest : public cvtest::BaseTest
{
public:
CV_ProjectPointsTest() {}
protected:
void run(int);
virtual void project( const Mat& objectPoints,
const Mat& rvec, const Mat& tvec,
const Mat& cameraMatrix,
const Mat& distCoeffs,
vector<Point2f>& imagePoints,
Mat& dpdrot, Mat& dpdt, Mat& dpdf,
Mat& dpdc, Mat& dpddist,
double aspectRatio=0 ) = 0;
};
void CV_ProjectPointsTest::run(int)
{
//typedef float matType;
int code = cvtest::TS::OK;
const int pointCount = 100;
const float zMinVal = 10.0f, zMaxVal = 100.0f,
rMinVal = -0.3f, rMaxVal = 0.3f,
tMinVal = -2.0f, tMaxVal = 2.0f;
const float imgPointErr = 1e-3f,
dEps = 1e-3f;
double err;
Size imgSize( 600, 800 );
Mat_<float> objPoints( pointCount, 3), rvec( 1, 3), rmat, tvec( 1, 3 ), cameraMatrix( 3, 3 ), distCoeffs( 1, 4 ),
leftRvec, rightRvec, leftTvec, rightTvec, leftCameraMatrix, rightCameraMatrix, leftDistCoeffs, rightDistCoeffs;
RNG rng = ts->get_rng();
// generate data
cameraMatrix << 300.f, 0.f, imgSize.width/2.f,
0.f, 300.f, imgSize.height/2.f,
0.f, 0.f, 1.f;
distCoeffs << 0.1, 0.01, 0.001, 0.001;
rvec(0,0) = rng.uniform( rMinVal, rMaxVal );
rvec(0,1) = rng.uniform( rMinVal, rMaxVal );
rvec(0,2) = rng.uniform( rMinVal, rMaxVal );
Rodrigues( rvec, rmat );
tvec(0,0) = rng.uniform( tMinVal, tMaxVal );
tvec(0,1) = rng.uniform( tMinVal, tMaxVal );
tvec(0,2) = rng.uniform( tMinVal, tMaxVal );
for( int y = 0; y < objPoints.rows; y++ )
{
Mat point(1, 3, CV_32FC1, objPoints.ptr(y) );
float z = rng.uniform( zMinVal, zMaxVal );
point.at<float>(0,2) = z;
point.at<float>(0,0) = (rng.uniform(2.f,(float)(imgSize.width-2)) - cameraMatrix(0,2)) / cameraMatrix(0,0) * z;
point.at<float>(0,1) = (rng.uniform(2.f,(float)(imgSize.height-2)) - cameraMatrix(1,2)) / cameraMatrix(1,1) * z;
point = (point - tvec) * rmat;
}
vector<Point2f> imgPoints;
vector<vector<Point2f> > leftImgPoints;
vector<vector<Point2f> > rightImgPoints;
Mat dpdrot, dpdt, dpdf, dpdc, dpddist,
valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist;
project( objPoints, rvec, tvec, cameraMatrix, distCoeffs,
imgPoints, dpdrot, dpdt, dpdf, dpdc, dpddist, 0 );
// calculate and check image points
assert( (int)imgPoints.size() == pointCount );
vector<Point2f>::const_iterator it = imgPoints.begin();
for( int i = 0; i < pointCount; i++, ++it )
{
Point3d p( objPoints(i,0), objPoints(i,1), objPoints(i,2) );
double z = p.x*rmat(2,0) + p.y*rmat(2,1) + p.z*rmat(2,2) + tvec(0,2),
x = (p.x*rmat(0,0) + p.y*rmat(0,1) + p.z*rmat(0,2) + tvec(0,0)) / z,
y = (p.x*rmat(1,0) + p.y*rmat(1,1) + p.z*rmat(1,2) + tvec(0,1)) / z,
r2 = x*x + y*y,
r4 = r2*r2;
Point2f validImgPoint;
double a1 = 2*x*y,
a2 = r2 + 2*x*x,
a3 = r2 + 2*y*y,
cdist = 1+distCoeffs(0,0)*r2+distCoeffs(0,1)*r4;
validImgPoint.x = static_cast<float>((double)cameraMatrix(0,0)*(x*cdist + (double)distCoeffs(0,2)*a1 + (double)distCoeffs(0,3)*a2)
+ (double)cameraMatrix(0,2));
validImgPoint.y = static_cast<float>((double)cameraMatrix(1,1)*(y*cdist + (double)distCoeffs(0,2)*a3 + distCoeffs(0,3)*a1)
+ (double)cameraMatrix(1,2));
if( fabs(it->x - validImgPoint.x) > imgPointErr ||
fabs(it->y - validImgPoint.y) > imgPointErr )
{
ts->printf( cvtest::TS::LOG, "bad image point\n" );
code = cvtest::TS::FAIL_BAD_ACCURACY;
goto _exit_;
}
}
// check derivatives
// 1. rotation
leftImgPoints.resize(3);
rightImgPoints.resize(3);
for( int i = 0; i < 3; i++ )
{
rvec.copyTo( leftRvec ); leftRvec(0,i) -= dEps;
project( objPoints, leftRvec, tvec, cameraMatrix, distCoeffs,
leftImgPoints[i], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
rvec.copyTo( rightRvec ); rightRvec(0,i) += dEps;
project( objPoints, rightRvec, tvec, cameraMatrix, distCoeffs,
rightImgPoints[i], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
}
calcdfdx( leftImgPoints, rightImgPoints, dEps, valDpdrot );
err = norm( dpdrot, valDpdrot, NORM_INF );
if( err > 3 )
{
ts->printf( cvtest::TS::LOG, "bad dpdrot: too big difference = %g\n", err );
code = cvtest::TS::FAIL_BAD_ACCURACY;
}
// 2. translation
for( int i = 0; i < 3; i++ )
{
tvec.copyTo( leftTvec ); leftTvec(0,i) -= dEps;
project( objPoints, rvec, leftTvec, cameraMatrix, distCoeffs,
leftImgPoints[i], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
tvec.copyTo( rightTvec ); rightTvec(0,i) += dEps;
project( objPoints, rvec, rightTvec, cameraMatrix, distCoeffs,
rightImgPoints[i], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
}
calcdfdx( leftImgPoints, rightImgPoints, dEps, valDpdt );
if( norm( dpdt, valDpdt, NORM_INF ) > 0.2 )
{
ts->printf( cvtest::TS::LOG, "bad dpdtvec\n" );
code = cvtest::TS::FAIL_BAD_ACCURACY;
}
// 3. camera matrix
// 3.1. focus
leftImgPoints.resize(2);
rightImgPoints.resize(2);
cameraMatrix.copyTo( leftCameraMatrix ); leftCameraMatrix(0,0) -= dEps;
project( objPoints, rvec, tvec, leftCameraMatrix, distCoeffs,
leftImgPoints[0], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
cameraMatrix.copyTo( leftCameraMatrix ); leftCameraMatrix(1,1) -= dEps;
project( objPoints, rvec, tvec, leftCameraMatrix, distCoeffs,
leftImgPoints[1], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
cameraMatrix.copyTo( rightCameraMatrix ); rightCameraMatrix(0,0) += dEps;
project( objPoints, rvec, tvec, rightCameraMatrix, distCoeffs,
rightImgPoints[0], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
cameraMatrix.copyTo( rightCameraMatrix ); rightCameraMatrix(1,1) += dEps;
project( objPoints, rvec, tvec, rightCameraMatrix, distCoeffs,
rightImgPoints[1], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
calcdfdx( leftImgPoints, rightImgPoints, dEps, valDpdf );
if ( norm( dpdf, valDpdf ) > 0.2 )
{
ts->printf( cvtest::TS::LOG, "bad dpdf\n" );
code = cvtest::TS::FAIL_BAD_ACCURACY;
}
// 3.2. principal point
leftImgPoints.resize(2);
rightImgPoints.resize(2);
cameraMatrix.copyTo( leftCameraMatrix ); leftCameraMatrix(0,2) -= dEps;
project( objPoints, rvec, tvec, leftCameraMatrix, distCoeffs,
leftImgPoints[0], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
cameraMatrix.copyTo( leftCameraMatrix ); leftCameraMatrix(1,2) -= dEps;
project( objPoints, rvec, tvec, leftCameraMatrix, distCoeffs,
leftImgPoints[1], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
cameraMatrix.copyTo( rightCameraMatrix ); rightCameraMatrix(0,2) += dEps;
project( objPoints, rvec, tvec, rightCameraMatrix, distCoeffs,
rightImgPoints[0], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
cameraMatrix.copyTo( rightCameraMatrix ); rightCameraMatrix(1,2) += dEps;
project( objPoints, rvec, tvec, rightCameraMatrix, distCoeffs,
rightImgPoints[1], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
calcdfdx( leftImgPoints, rightImgPoints, dEps, valDpdc );
if ( norm( dpdc, valDpdc ) > 0.2 )
{
ts->printf( cvtest::TS::LOG, "bad dpdc\n" );
code = cvtest::TS::FAIL_BAD_ACCURACY;
}
// 4. distortion
leftImgPoints.resize(distCoeffs.cols);
rightImgPoints.resize(distCoeffs.cols);
for( int i = 0; i < distCoeffs.cols; i++ )
{
distCoeffs.copyTo( leftDistCoeffs ); leftDistCoeffs(0,i) -= dEps;
project( objPoints, rvec, tvec, cameraMatrix, leftDistCoeffs,
leftImgPoints[i], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
distCoeffs.copyTo( rightDistCoeffs ); rightDistCoeffs(0,i) += dEps;
project( objPoints, rvec, tvec, cameraMatrix, rightDistCoeffs,
rightImgPoints[i], valDpdrot, valDpdt, valDpdf, valDpdc, valDpddist, 0 );
}
calcdfdx( leftImgPoints, rightImgPoints, dEps, valDpddist );
if( norm( dpddist, valDpddist ) > 0.3 )
{
ts->printf( cvtest::TS::LOG, "bad dpddist\n" );
code = cvtest::TS::FAIL_BAD_ACCURACY;
}
_exit_:
RNG& _rng = ts->get_rng();
_rng = rng;
ts->set_failed_test_info( code );
}
//----------------------------------------- CV_ProjectPointsTest_C --------------------------------
class CV_ProjectPointsTest_C : public CV_ProjectPointsTest
{
public:
CV_ProjectPointsTest_C() {}
protected:
virtual void project( const Mat& objectPoints,
const Mat& rvec, const Mat& tvec,
const Mat& cameraMatrix,
const Mat& distCoeffs,
vector<Point2f>& imagePoints,
Mat& dpdrot, Mat& dpdt, Mat& dpdf,
Mat& dpdc, Mat& dpddist,
double aspectRatio=0 );
};
void CV_ProjectPointsTest_C::project( const Mat& opoints, const Mat& rvec, const Mat& tvec,
const Mat& cameraMatrix, const Mat& distCoeffs, vector<Point2f>& ipoints,
Mat& dpdrot, Mat& dpdt, Mat& dpdf, Mat& dpdc, Mat& dpddist, double aspectRatio)
{
int npoints = opoints.cols*opoints.rows*opoints.channels()/3;
ipoints.resize(npoints);
dpdrot.create(npoints*2, 3, CV_64F);
dpdt.create(npoints*2, 3, CV_64F);
dpdf.create(npoints*2, 2, CV_64F);
dpdc.create(npoints*2, 2, CV_64F);
dpddist.create(npoints*2, distCoeffs.rows + distCoeffs.cols - 1, CV_64F);
CvMat _objectPoints = opoints, _imagePoints = Mat(ipoints);
CvMat _rvec = rvec, _tvec = tvec, _cameraMatrix = cameraMatrix, _distCoeffs = distCoeffs;
CvMat _dpdrot = dpdrot, _dpdt = dpdt, _dpdf = dpdf, _dpdc = dpdc, _dpddist = dpddist;
cvProjectPoints2( &_objectPoints, &_rvec, &_tvec, &_cameraMatrix, &_distCoeffs,
&_imagePoints, &_dpdrot, &_dpdt, &_dpdf, &_dpdc, &_dpddist, aspectRatio );
}
//----------------------------------------- CV_ProjectPointsTest_CPP --------------------------------
class CV_ProjectPointsTest_CPP : public CV_ProjectPointsTest
{
public:
CV_ProjectPointsTest_CPP() {}
protected:
virtual void project( const Mat& objectPoints,
const Mat& rvec, const Mat& tvec,
const Mat& cameraMatrix,
const Mat& distCoeffs,
vector<Point2f>& imagePoints,
Mat& dpdrot, Mat& dpdt, Mat& dpdf,
Mat& dpdc, Mat& dpddist,
double aspectRatio=0 );
};
void CV_ProjectPointsTest_CPP::project( const Mat& objectPoints, const Mat& rvec, const Mat& tvec,
const Mat& cameraMatrix, const Mat& distCoeffs, vector<Point2f>& imagePoints,
Mat& dpdrot, Mat& dpdt, Mat& dpdf, Mat& dpdc, Mat& dpddist, double aspectRatio)
{
Mat J;
projectPoints( objectPoints, rvec, tvec, cameraMatrix, distCoeffs, imagePoints, J, aspectRatio);
J.colRange(0, 3).copyTo(dpdrot);
J.colRange(3, 6).copyTo(dpdt);
J.colRange(6, 8).copyTo(dpdf);
J.colRange(8, 10).copyTo(dpdc);
J.colRange(10, J.cols).copyTo(dpddist);
}
///////////////////////////////// Stereo Calibration /////////////////////////////////////
class CV_StereoCalibrationTest : public cvtest::BaseTest
{
public:
CV_StereoCalibrationTest();
~CV_StereoCalibrationTest();
void clear();
protected:
bool checkPandROI( int test_case_idx,
const Mat& M, const Mat& D, const Mat& R,
const Mat& P, Size imgsize, Rect roi );
// covers of tested functions
virtual double calibrateStereoCamera( const vector<vector<Point3f> >& objectPoints,
const vector<vector<Point2f> >& imagePoints1,
const vector<vector<Point2f> >& imagePoints2,
Mat& cameraMatrix1, Mat& distCoeffs1,
Mat& cameraMatrix2, Mat& distCoeffs2,
Size imageSize, Mat& R, Mat& T,
Mat& E, Mat& F, TermCriteria criteria, int flags ) = 0;
virtual void rectify( const Mat& cameraMatrix1, const Mat& distCoeffs1,
const Mat& cameraMatrix2, const Mat& distCoeffs2,
Size imageSize, const Mat& R, const Mat& T,
Mat& R1, Mat& R2, Mat& P1, Mat& P2, Mat& Q,
double alpha, Size newImageSize,
Rect* validPixROI1, Rect* validPixROI2, int flags ) = 0;
virtual bool rectifyUncalibrated( const Mat& points1,
const Mat& points2, const Mat& F, Size imgSize,
Mat& H1, Mat& H2, double threshold=5 ) = 0;
virtual void triangulate( const Mat& P1, const Mat& P2,
const Mat &points1, const Mat &points2,
Mat &points4D ) = 0;
virtual void correct( const Mat& F,
const Mat &points1, const Mat &points2,
Mat &newPoints1, Mat &newPoints2 ) = 0;
void run(int);
};
CV_StereoCalibrationTest::CV_StereoCalibrationTest()
{
}
CV_StereoCalibrationTest::~CV_StereoCalibrationTest()
{
clear();
}
void CV_StereoCalibrationTest::clear()
{
cvtest::BaseTest::clear();
}
bool CV_StereoCalibrationTest::checkPandROI( int test_case_idx, const Mat& M, const Mat& D, const Mat& R,
const Mat& P, Size imgsize, Rect roi )
{
const double eps = 0.05;
const int N = 21;
int x, y, k;
vector<Point2f> pts, upts;
// step 1. check that all the original points belong to the destination image
for( y = 0; y < N; y++ )
for( x = 0; x < N; x++ )
pts.push_back(Point2f((float)x*imgsize.width/(N-1), (float)y*imgsize.height/(N-1)));
undistortPoints(Mat(pts), upts, M, D, R, P );
for( k = 0; k < N*N; k++ )
if( upts[k].x < -imgsize.width*eps || upts[k].x > imgsize.width*(1+eps) ||
upts[k].y < -imgsize.height*eps || upts[k].y > imgsize.height*(1+eps) )
{
ts->printf(cvtest::TS::LOG, "Test #%d. The point (%g, %g) was mapped to (%g, %g) which is out of image\n",
test_case_idx, pts[k].x, pts[k].y, upts[k].x, upts[k].y);
return false;
}
// step 2. check that all the points inside ROI belong to the original source image
Mat temp(imgsize, CV_8U), utemp, map1, map2;
temp = Scalar::all(1);
initUndistortRectifyMap(M, D, R, P, imgsize, CV_16SC2, map1, map2);
remap(temp, utemp, map1, map2, INTER_LINEAR);
if(roi.x < 0 || roi.y < 0 || roi.x + roi.width > imgsize.width || roi.y + roi.height > imgsize.height)
{
ts->printf(cvtest::TS::LOG, "Test #%d. The ROI=(%d, %d, %d, %d) is outside of the imge rectangle\n",
test_case_idx, roi.x, roi.y, roi.width, roi.height);
return false;
}
double s = sum(utemp(roi))[0];
if( s > roi.area() || roi.area() - s > roi.area()*(1-eps) )
{
ts->printf(cvtest::TS::LOG, "Test #%d. The ratio of black pixels inside the valid ROI (~%g%%) is too large\n",
test_case_idx, s*100./roi.area());
return false;
}
return true;
}
void CV_StereoCalibrationTest::run( int )
{
const int ntests = 1;
const double maxReprojErr = 2;
const double maxScanlineDistErr_c = 3;
const double maxScanlineDistErr_uc = 4;
FILE* f = 0;
for(int testcase = 1; testcase <= ntests; testcase++)
{
char filepath[1000];
char buf[1000];
sprintf( filepath, "%sstereo/case%d/stereo_calib.txt", ts->get_data_path().c_str(), testcase );
f = fopen(filepath, "rt");
Size patternSize;
vector<string> imglist;
if( !f || !fgets(buf, sizeof(buf)-3, f) || sscanf(buf, "%d%d", &patternSize.width, &patternSize.height) != 2 )
{
ts->printf( cvtest::TS::LOG, "The file %s can not be opened or has invalid content\n", filepath );
ts->set_failed_test_info( f ? cvtest::TS::FAIL_INVALID_TEST_DATA : cvtest::TS::FAIL_MISSING_TEST_DATA );
return;
}
for(;;)
{
if( !fgets( buf, sizeof(buf)-3, f ))
break;
size_t len = strlen(buf);
while( len > 0 && isspace(buf[len-1]))
buf[--len] = '\0';
if( buf[0] == '#')
continue;
sprintf(filepath, "%sstereo/case%d/%s", ts->get_data_path().c_str(), testcase, buf );
imglist.push_back(string(filepath));
}
fclose(f);
if( imglist.size() == 0 || imglist.size() % 2 != 0 )
{
ts->printf( cvtest::TS::LOG, "The number of images is 0 or an odd number in the case #%d\n", testcase );
ts->set_failed_test_info( cvtest::TS::FAIL_INVALID_TEST_DATA );
return;
}
int nframes = (int)(imglist.size()/2);
int npoints = patternSize.width*patternSize.height;
vector<vector<Point3f> > objpt(nframes);
vector<vector<Point2f> > imgpt1(nframes);
vector<vector<Point2f> > imgpt2(nframes);
Size imgsize;
int total = 0;
for( int i = 0; i < nframes; i++ )
{
Mat left = imread(imglist[i*2]);
Mat right = imread(imglist[i*2+1]);
if(!left.data || !right.data)
{
ts->printf( cvtest::TS::LOG, "Can not load images %s and %s, testcase %d\n",
imglist[i*2].c_str(), imglist[i*2+1].c_str(), testcase );
ts->set_failed_test_info( cvtest::TS::FAIL_MISSING_TEST_DATA );
return;
}
imgsize = left.size();
bool found1 = findChessboardCorners(left, patternSize, imgpt1[i]);
bool found2 = findChessboardCorners(right, patternSize, imgpt2[i]);
if(!found1 || !found2)
{
ts->printf( cvtest::TS::LOG, "The function could not detect boards on the images %s and %s, testcase %d\n",
imglist[i*2].c_str(), imglist[i*2+1].c_str(), testcase );
ts->set_failed_test_info( cvtest::TS::FAIL_INVALID_OUTPUT );
return;
}
total += (int)imgpt1[i].size();
for( int j = 0; j < npoints; j++ )
objpt[i].push_back(Point3f((float)(j%patternSize.width), (float)(j/patternSize.width), 0.f));
}
// rectify (calibrated)
Mat M1 = Mat::eye(3,3,CV_64F), M2 = Mat::eye(3,3,CV_64F), D1(5,1,CV_64F), D2(5,1,CV_64F), R, T, E, F;
M1.at<double>(0,2) = M2.at<double>(0,2)=(imgsize.width-1)*0.5;
M1.at<double>(1,2) = M2.at<double>(1,2)=(imgsize.height-1)*0.5;
D1 = Scalar::all(0);
D2 = Scalar::all(0);
double err = calibrateStereoCamera(objpt, imgpt1, imgpt2, M1, D1, M2, D2, imgsize, R, T, E, F,
TermCriteria(TermCriteria::MAX_ITER+TermCriteria::EPS, 30, 1e-6),
CV_CALIB_SAME_FOCAL_LENGTH
//+ CV_CALIB_FIX_ASPECT_RATIO
+ CV_CALIB_FIX_PRINCIPAL_POINT
+ CV_CALIB_ZERO_TANGENT_DIST
+ CV_CALIB_FIX_K3
+ CV_CALIB_FIX_K4 + CV_CALIB_FIX_K5 //+ CV_CALIB_FIX_K6
);
err /= nframes*npoints;
if( err > maxReprojErr )
{
ts->printf( cvtest::TS::LOG, "The average reprojection error is too big (=%g), testcase %d\n", err, testcase);
ts->set_failed_test_info( cvtest::TS::FAIL_INVALID_OUTPUT );
return;
}
Mat R1, R2, P1, P2, Q;
Rect roi1, roi2;
rectify(M1, D1, M2, D2, imgsize, R, T, R1, R2, P1, P2, Q, 1, imgsize, &roi1, &roi2, 0);
Mat eye33 = Mat::eye(3,3,CV_64F);
Mat R1t = R1.t(), R2t = R2.t();
if( norm(R1t*R1 - eye33) > 0.01 ||
norm(R2t*R2 - eye33) > 0.01 ||
abs(determinant(F)) > 0.01)
{
ts->printf( cvtest::TS::LOG, "The computed (by rectify) R1 and R2 are not orthogonal,"
"or the computed (by calibrate) F is not singular, testcase %d\n", testcase);
ts->set_failed_test_info( cvtest::TS::FAIL_INVALID_OUTPUT );
return;
}
if(!checkPandROI(testcase, M1, D1, R1, P1, imgsize, roi1))
{
ts->set_failed_test_info( cvtest::TS::FAIL_BAD_ACCURACY );
return;
}
if(!checkPandROI(testcase, M2, D2, R2, P2, imgsize, roi2))
{
ts->set_failed_test_info( cvtest::TS::FAIL_BAD_ACCURACY );
return;
}
//check that Tx after rectification is equal to distance between cameras
double tx = fabs(P2.at<double>(0, 3) / P2.at<double>(0, 0));
if (fabs(tx - norm(T)) > 1e-5)
{
ts->set_failed_test_info( cvtest::TS::FAIL_BAD_ACCURACY );
return;
}
//check that Q reprojects points before the camera
double testPoint[4] = {0.0, 0.0, 100.0, 1.0};
Mat reprojectedTestPoint = Q * Mat_<double>(4, 1, testPoint);
CV_Assert(reprojectedTestPoint.type() == CV_64FC1);
if( reprojectedTestPoint.at<double>(2) / reprojectedTestPoint.at<double>(3) < 0 )
{
ts->printf( cvtest::TS::LOG, "A point after rectification is reprojected behind the camera, testcase %d\n", testcase);
ts->set_failed_test_info( cvtest::TS::FAIL_INVALID_OUTPUT );
}
//check that Q reprojects the same points as reconstructed by triangulation
const float minCoord = -300.0f;
const float maxCoord = 300.0f;
const float minDisparity = 0.1f;
const float maxDisparity = 600.0f;
const int pointsCount = 500;
const float requiredAccuracy = 1e-3f;
RNG& rng = ts->get_rng();
Mat projectedPoints_1(2, pointsCount, CV_32FC1);
Mat projectedPoints_2(2, pointsCount, CV_32FC1);
Mat disparities(1, pointsCount, CV_32FC1);
rng.fill(projectedPoints_1, RNG::UNIFORM, minCoord, maxCoord);
rng.fill(disparities, RNG::UNIFORM, minDisparity, maxDisparity);
projectedPoints_2.row(0) = projectedPoints_1.row(0) - disparities;
Mat ys_2 = projectedPoints_2.row(1);
projectedPoints_1.row(1).copyTo(ys_2);
Mat points4d;
triangulate(P1, P2, projectedPoints_1, projectedPoints_2, points4d);
Mat homogeneousPoints4d = points4d.t();
const int dimension = 4;
homogeneousPoints4d = homogeneousPoints4d.reshape(dimension);
Mat triangulatedPoints;
convertPointsFromHomogeneous(homogeneousPoints4d, triangulatedPoints);
Mat sparsePoints;
sparsePoints.push_back(projectedPoints_1);
sparsePoints.push_back(disparities);
sparsePoints = sparsePoints.t();
sparsePoints = sparsePoints.reshape(3);
Mat reprojectedPoints;
perspectiveTransform(sparsePoints, reprojectedPoints, Q);
if (norm(triangulatedPoints - reprojectedPoints) / sqrt((double)pointsCount) > requiredAccuracy)
{
ts->printf( cvtest::TS::LOG, "Points reprojected with a matrix Q and points reconstructed by triangulation are different, testcase %d\n", testcase);
ts->set_failed_test_info( cvtest::TS::FAIL_INVALID_OUTPUT );
}
//check correctMatches
const float constraintAccuracy = 1e-5f;
Mat newPoints1, newPoints2;
Mat points1 = projectedPoints_1.t();
points1 = points1.reshape(2, 1);
Mat points2 = projectedPoints_2.t();
points2 = points2.reshape(2, 1);
correctMatches(F, points1, points2, newPoints1, newPoints2);
Mat newHomogeneousPoints1, newHomogeneousPoints2;
convertPointsToHomogeneous(newPoints1, newHomogeneousPoints1);
convertPointsToHomogeneous(newPoints2, newHomogeneousPoints2);
newHomogeneousPoints1 = newHomogeneousPoints1.reshape(1);
newHomogeneousPoints2 = newHomogeneousPoints2.reshape(1);
Mat typedF;
F.convertTo(typedF, newHomogeneousPoints1.type());
for (int i = 0; i < newHomogeneousPoints1.rows; ++i)
{
Mat error = newHomogeneousPoints2.row(i) * typedF * newHomogeneousPoints1.row(i).t();
CV_Assert(error.rows == 1 && error.cols == 1);
if (norm(error) > constraintAccuracy)
{
ts->printf( cvtest::TS::LOG, "Epipolar constraint is violated after correctMatches, testcase %d\n", testcase);
ts->set_failed_test_info( cvtest::TS::FAIL_INVALID_OUTPUT );
}
}
// rectifyUncalibrated
CV_Assert( imgpt1.size() == imgpt2.size() );
Mat _imgpt1( total, 1, CV_32FC2 ), _imgpt2( total, 1, CV_32FC2 );
vector<vector<Point2f> >::const_iterator iit1 = imgpt1.begin();
vector<vector<Point2f> >::const_iterator iit2 = imgpt2.begin();
for( int pi = 0; iit1 != imgpt1.end(); ++iit1, ++iit2 )
{
vector<Point2f>::const_iterator pit1 = iit1->begin();
vector<Point2f>::const_iterator pit2 = iit2->begin();
CV_Assert( iit1->size() == iit2->size() );
for( ; pit1 != iit1->end(); ++pit1, ++pit2, pi++ )
{
_imgpt1.at<Point2f>(pi,0) = Point2f( pit1->x, pit1->y );
_imgpt2.at<Point2f>(pi,0) = Point2f( pit2->x, pit2->y );
}
}
Mat _M1, _M2, _D1, _D2;
vector<Mat> _R1, _R2, _T1, _T2;
calibrateCamera( objpt, imgpt1, imgsize, _M1, _D1, _R1, _T1, 0 );
calibrateCamera( objpt, imgpt2, imgsize, _M2, _D2, _R2, _T1, 0 );
undistortPoints( _imgpt1, _imgpt1, _M1, _D1, Mat(), _M1 );
undistortPoints( _imgpt2, _imgpt2, _M2, _D2, Mat(), _M2 );
Mat matF, _H1, _H2;
matF = findFundamentalMat( _imgpt1, _imgpt2 );
rectifyUncalibrated( _imgpt1, _imgpt2, matF, imgsize, _H1, _H2 );
Mat rectifPoints1, rectifPoints2;
perspectiveTransform( _imgpt1, rectifPoints1, _H1 );
perspectiveTransform( _imgpt2, rectifPoints2, _H2 );
bool verticalStereo = abs(P2.at<double>(0,3)) < abs(P2.at<double>(1,3));
double maxDiff_c = 0, maxDiff_uc = 0;
for( int i = 0, k = 0; i < nframes; i++ )
{
vector<Point2f> temp[2];
undistortPoints(Mat(imgpt1[i]), temp[0], M1, D1, R1, P1);
undistortPoints(Mat(imgpt2[i]), temp[1], M2, D2, R2, P2);
for( int j = 0; j < npoints; j++, k++ )
{
double diff_c = verticalStereo ? abs(temp[0][j].x - temp[1][j].x) : abs(temp[0][j].y - temp[1][j].y);
Point2f d = rectifPoints1.at<Point2f>(k,0) - rectifPoints2.at<Point2f>(k,0);
double diff_uc = verticalStereo ? abs(d.x) : abs(d.y);
maxDiff_c = max(maxDiff_c, diff_c);
maxDiff_uc = max(maxDiff_uc, diff_uc);
if( maxDiff_c > maxScanlineDistErr_c )
{
ts->printf( cvtest::TS::LOG, "The distance between %s coordinates is too big(=%g) (used calibrated stereo), testcase %d\n",
verticalStereo ? "x" : "y", diff_c, testcase);
ts->set_failed_test_info( cvtest::TS::FAIL_BAD_ACCURACY );
return;
}
if( maxDiff_uc > maxScanlineDistErr_uc )
{
ts->printf( cvtest::TS::LOG, "The distance between %s coordinates is too big(=%g) (used uncalibrated stereo), testcase %d\n",
verticalStereo ? "x" : "y", diff_uc, testcase);
ts->set_failed_test_info( cvtest::TS::FAIL_BAD_ACCURACY );
return;
}
}
}
ts->printf( cvtest::TS::LOG, "Testcase %d. Max distance (calibrated) =%g\n"
"Max distance (uncalibrated) =%g\n", testcase, maxDiff_c, maxDiff_uc );
}
}
//-------------------------------- CV_StereoCalibrationTest_C ------------------------------
class CV_StereoCalibrationTest_C : public CV_StereoCalibrationTest
{
public:
CV_StereoCalibrationTest_C() {}
protected:
virtual double calibrateStereoCamera( const vector<vector<Point3f> >& objectPoints,
const vector<vector<Point2f> >& imagePoints1,
const vector<vector<Point2f> >& imagePoints2,
Mat& cameraMatrix1, Mat& distCoeffs1,
Mat& cameraMatrix2, Mat& distCoeffs2,
Size imageSize, Mat& R, Mat& T,
Mat& E, Mat& F, TermCriteria criteria, int flags );
virtual void rectify( const Mat& cameraMatrix1, const Mat& distCoeffs1,
const Mat& cameraMatrix2, const Mat& distCoeffs2,
Size imageSize, const Mat& R, const Mat& T,
Mat& R1, Mat& R2, Mat& P1, Mat& P2, Mat& Q,
double alpha, Size newImageSize,
Rect* validPixROI1, Rect* validPixROI2, int flags );
virtual bool rectifyUncalibrated( const Mat& points1,
const Mat& points2, const Mat& F, Size imgSize,
Mat& H1, Mat& H2, double threshold=5 );
virtual void triangulate( const Mat& P1, const Mat& P2,
const Mat &points1, const Mat &points2,
Mat &points4D );
virtual void correct( const Mat& F,
const Mat &points1, const Mat &points2,
Mat &newPoints1, Mat &newPoints2 );
};
double CV_StereoCalibrationTest_C::calibrateStereoCamera( const vector<vector<Point3f> >& objectPoints,
const vector<vector<Point2f> >& imagePoints1,
const vector<vector<Point2f> >& imagePoints2,
Mat& cameraMatrix1, Mat& distCoeffs1,
Mat& cameraMatrix2, Mat& distCoeffs2,
Size imageSize, Mat& R, Mat& T,
Mat& E, Mat& F, TermCriteria criteria, int flags )
{
cameraMatrix1.create( 3, 3, CV_64F );
cameraMatrix2.create( 3, 3, CV_64F);
distCoeffs1.create( 1, 5, CV_64F);
distCoeffs2.create( 1, 5, CV_64F);
R.create(3, 3, CV_64F);
T.create(3, 1, CV_64F);
E.create(3, 3, CV_64F);
F.create(3, 3, CV_64F);
int nimages = (int)objectPoints.size(), total = 0;
for( int i = 0; i < nimages; i++ )
{
total += (int)objectPoints[i].size();
}
Mat npoints( 1, nimages, CV_32S ),
objPt( 1, total, DataType<Point3f>::type ),
imgPt( 1, total, DataType<Point2f>::type ),
imgPt2( 1, total, DataType<Point2f>::type );
Point2f* imgPtData2 = imgPt2.ptr<Point2f>();
Point3f* objPtData = objPt.ptr<Point3f>();
Point2f* imgPtData = imgPt.ptr<Point2f>();
for( int i = 0, ni = 0, j = 0; i < nimages; i++, j += ni )
{
ni = (int)objectPoints[i].size();
((int*)npoints.data)[i] = ni;
std::copy(objectPoints[i].begin(), objectPoints[i].end(), objPtData + j);
std::copy(imagePoints1[i].begin(), imagePoints1[i].end(), imgPtData + j);
std::copy(imagePoints2[i].begin(), imagePoints2[i].end(), imgPtData2 + j);
}
CvMat _objPt = objPt, _imgPt = imgPt, _imgPt2 = imgPt2, _npoints = npoints;
CvMat _cameraMatrix1 = cameraMatrix1, _distCoeffs1 = distCoeffs1;
CvMat _cameraMatrix2 = cameraMatrix2, _distCoeffs2 = distCoeffs2;
CvMat matR = R, matT = T, matE = E, matF = F;
return cvStereoCalibrate(&_objPt, &_imgPt, &_imgPt2, &_npoints, &_cameraMatrix1,
&_distCoeffs1, &_cameraMatrix2, &_distCoeffs2, imageSize,
&matR, &matT, &matE, &matF, criteria, flags );
}
void CV_StereoCalibrationTest_C::rectify( const Mat& cameraMatrix1, const Mat& distCoeffs1,
const Mat& cameraMatrix2, const Mat& distCoeffs2,
Size imageSize, const Mat& R, const Mat& T,
Mat& R1, Mat& R2, Mat& P1, Mat& P2, Mat& Q,
double alpha, Size newImageSize,
Rect* validPixROI1, Rect* validPixROI2, int flags )
{
int rtype = CV_64F;
R1.create(3, 3, rtype);
R2.create(3, 3, rtype);
P1.create(3, 4, rtype);
P2.create(3, 4, rtype);
Q.create(4, 4, rtype);
CvMat _cameraMatrix1 = cameraMatrix1, _distCoeffs1 = distCoeffs1;
CvMat _cameraMatrix2 = cameraMatrix2, _distCoeffs2 = distCoeffs2;
CvMat matR = R, matT = T, _R1 = R1, _R2 = R2, _P1 = P1, _P2 = P2, matQ = Q;
cvStereoRectify( &_cameraMatrix1, &_cameraMatrix2, &_distCoeffs1, &_distCoeffs2,
imageSize, &matR, &matT, &_R1, &_R2, &_P1, &_P2, &matQ, flags,
alpha, newImageSize, (CvRect*)validPixROI1, (CvRect*)validPixROI2);
}
bool CV_StereoCalibrationTest_C::rectifyUncalibrated( const Mat& points1,
const Mat& points2, const Mat& F, Size imgSize, Mat& H1, Mat& H2, double threshold )
{
H1.create(3, 3, CV_64F);
H2.create(3, 3, CV_64F);
CvMat _pt1 = points1, _pt2 = points2, matF, *pF=0, _H1 = H1, _H2 = H2;
if( F.size() == Size(3, 3) )
pF = &(matF = F);
return cvStereoRectifyUncalibrated(&_pt1, &_pt2, pF, imgSize, &_H1, &_H2, threshold) > 0;
}
void CV_StereoCalibrationTest_C::triangulate( const Mat& P1, const Mat& P2,
const Mat &points1, const Mat &points2,
Mat &points4D )
{
CvMat _P1 = P1, _P2 = P2, _points1 = points1, _points2 = points2;
points4D.create(4, points1.cols, points1.type());
CvMat _points4D = points4D;
cvTriangulatePoints(&_P1, &_P2, &_points1, &_points2, &_points4D);
}
void CV_StereoCalibrationTest_C::correct( const Mat& F,
const Mat &points1, const Mat &points2,
Mat &newPoints1, Mat &newPoints2 )
{
CvMat _F = F, _points1 = points1, _points2 = points2;
newPoints1.create(1, points1.cols, points1.type());
newPoints2.create(1, points2.cols, points2.type());
CvMat _newPoints1 = newPoints1, _newPoints2 = newPoints2;
cvCorrectMatches(&_F, &_points1, &_points2, &_newPoints1, &_newPoints2);
}
//-------------------------------- CV_StereoCalibrationTest_CPP ------------------------------
class CV_StereoCalibrationTest_CPP : public CV_StereoCalibrationTest
{
public:
CV_StereoCalibrationTest_CPP() {}
protected:
virtual double calibrateStereoCamera( const vector<vector<Point3f> >& objectPoints,
const vector<vector<Point2f> >& imagePoints1,
const vector<vector<Point2f> >& imagePoints2,
Mat& cameraMatrix1, Mat& distCoeffs1,
Mat& cameraMatrix2, Mat& distCoeffs2,
Size imageSize, Mat& R, Mat& T,
Mat& E, Mat& F, TermCriteria criteria, int flags );
virtual void rectify( const Mat& cameraMatrix1, const Mat& distCoeffs1,
const Mat& cameraMatrix2, const Mat& distCoeffs2,
Size imageSize, const Mat& R, const Mat& T,
Mat& R1, Mat& R2, Mat& P1, Mat& P2, Mat& Q,
double alpha, Size newImageSize,
Rect* validPixROI1, Rect* validPixROI2, int flags );
virtual bool rectifyUncalibrated( const Mat& points1,
const Mat& points2, const Mat& F, Size imgSize,
Mat& H1, Mat& H2, double threshold=5 );
virtual void triangulate( const Mat& P1, const Mat& P2,
const Mat &points1, const Mat &points2,
Mat &points4D );
virtual void correct( const Mat& F,
const Mat &points1, const Mat &points2,
Mat &newPoints1, Mat &newPoints2 );
};
double CV_StereoCalibrationTest_CPP::calibrateStereoCamera( const vector<vector<Point3f> >& objectPoints,
const vector<vector<Point2f> >& imagePoints1,
const vector<vector<Point2f> >& imagePoints2,
Mat& cameraMatrix1, Mat& distCoeffs1,
Mat& cameraMatrix2, Mat& distCoeffs2,
Size imageSize, Mat& R, Mat& T,
Mat& E, Mat& F, TermCriteria criteria, int flags )
{
return stereoCalibrate( objectPoints, imagePoints1, imagePoints2,
cameraMatrix1, distCoeffs1, cameraMatrix2, distCoeffs2,
imageSize, R, T, E, F, criteria, flags );
}
void CV_StereoCalibrationTest_CPP::rectify( const Mat& cameraMatrix1, const Mat& distCoeffs1,
const Mat& cameraMatrix2, const Mat& distCoeffs2,
Size imageSize, const Mat& R, const Mat& T,
Mat& R1, Mat& R2, Mat& P1, Mat& P2, Mat& Q,
double alpha, Size newImageSize,
Rect* validPixROI1, Rect* validPixROI2, int flags )
{
stereoRectify( cameraMatrix1, distCoeffs1, cameraMatrix2, distCoeffs2,
imageSize, R, T, R1, R2, P1, P2, Q, flags, alpha, newImageSize,validPixROI1, validPixROI2 );
}
bool CV_StereoCalibrationTest_CPP::rectifyUncalibrated( const Mat& points1,
const Mat& points2, const Mat& F, Size imgSize, Mat& H1, Mat& H2, double threshold )
{
return stereoRectifyUncalibrated( points1, points2, F, imgSize, H1, H2, threshold );
}
void CV_StereoCalibrationTest_CPP::triangulate( const Mat& P1, const Mat& P2,
const Mat &points1, const Mat &points2,
Mat &points4D )
{
triangulatePoints(P1, P2, points1, points2, points4D);
}
void CV_StereoCalibrationTest_CPP::correct( const Mat& F,
const Mat &points1, const Mat &points2,
Mat &newPoints1, Mat &newPoints2 )
{
correctMatches(F, points1, points2, newPoints1, newPoints2);
}
///////////////////////////////////////////////////////////////////////////////////////////////////
TEST(Calib3d_CalibrateCamera_C, regression) { CV_CameraCalibrationTest_C test; test.safe_run(); }
TEST(Calib3d_CalibrateCamera_CPP, regression) { CV_CameraCalibrationTest_CPP test; test.safe_run(); }
TEST(Calib3d_CalibrationMatrixValues_C, accuracy) { CV_CalibrationMatrixValuesTest_C test; test.safe_run(); }
TEST(Calib3d_CalibrationMatrixValues_CPP, accuracy) { CV_CalibrationMatrixValuesTest_CPP test; test.safe_run(); }
TEST(Calib3d_ProjectPoints_C, accuracy) { CV_ProjectPointsTest_C test; test.safe_run(); }
TEST(Calib3d_ProjectPoints_CPP, regression) { CV_ProjectPointsTest_CPP test; test.safe_run(); }
TEST(Calib3d_StereoCalibrate_C, regression) { CV_StereoCalibrationTest_C test; test.safe_run(); }
TEST(Calib3d_StereoCalibrate_CPP, regression) { CV_StereoCalibrationTest_CPP test; test.safe_run(); }