/*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 "opencv2/imgproc/imgproc.hpp" #include "opencv2/highgui/highgui.hpp" #include "opencv2/features2d/features2d.hpp" #include "opencv2/legacy/legacy.hpp" #include #include #include #include using namespace std; using namespace cv; string data_path; /****************************************************************************************\ * Functions to evaluate affine covariant detectors and descriptors. * \****************************************************************************************/ static inline Point2f applyHomography( const Mat_& H, const Point2f& pt ) { double z = H(2,0)*pt.x + H(2,1)*pt.y + H(2,2); if( z ) { double w = 1./z; return Point2f( (float)((H(0,0)*pt.x + H(0,1)*pt.y + H(0,2))*w), (float)((H(1,0)*pt.x + H(1,1)*pt.y + H(1,2))*w) ); } return Point2f( numeric_limits::max(), numeric_limits::max() ); } static inline void linearizeHomographyAt( const Mat_& H, const Point2f& pt, Mat_& A ) { A.create(2,2); double p1 = H(0,0)*pt.x + H(0,1)*pt.y + H(0,2), p2 = H(1,0)*pt.x + H(1,1)*pt.y + H(1,2), p3 = H(2,0)*pt.x + H(2,1)*pt.y + H(2,2), p3_2 = p3*p3; if( p3 ) { A(0,0) = H(0,0)/p3 - p1*H(2,0)/p3_2; // fxdx A(0,1) = H(0,1)/p3 - p1*H(2,1)/p3_2; // fxdy A(1,0) = H(1,0)/p3 - p2*H(2,0)/p3_2; // fydx A(1,1) = H(1,1)/p3 - p2*H(2,1)/p3_2; // fydx } else A.setTo(Scalar::all(numeric_limits::max())); } static void calcKeyPointProjections( const vector& src, const Mat_& H, vector& dst ) { if( !src.empty() ) { assert( !H.empty() && H.cols == 3 && H.rows == 3); dst.resize(src.size()); vector::const_iterator srcIt = src.begin(); vector::iterator dstIt = dst.begin(); for( ; srcIt != src.end(); ++srcIt, ++dstIt ) { Point2f dstPt = applyHomography(H, srcIt->pt); float srcSize2 = srcIt->size * srcIt->size; Mat_ M(2, 2); M(0,0) = M(1,1) = 1./srcSize2; M(1,0) = M(0,1) = 0; Mat_ invM; invert(M, invM); Mat_ Aff; linearizeHomographyAt(H, srcIt->pt, Aff); Mat_ dstM; invert(Aff*invM*Aff.t(), dstM); Mat_ eval; eigen( dstM, eval ); assert( eval(0,0) && eval(1,0) ); float dstSize = (float)pow(1./(eval(0,0)*eval(1,0)), 0.25); // TODO: check angle projection float srcAngleRad = (float)(srcIt->angle*CV_PI/180); Point2f vec1(cos(srcAngleRad), sin(srcAngleRad)), vec2; vec2.x = (float)(Aff(0,0)*vec1.x + Aff(0,1)*vec1.y); vec2.y = (float)(Aff(1,0)*vec1.x + Aff(0,1)*vec1.y); float dstAngleGrad = fastAtan2(vec2.y, vec2.x); *dstIt = KeyPoint( dstPt, dstSize, dstAngleGrad, srcIt->response, srcIt->octave, srcIt->class_id ); } } } static void filterKeyPointsByImageSize( vector& keypoints, const Size& imgSize ) { if( !keypoints.empty() ) { vector filtered; filtered.reserve(keypoints.size()); Rect r(0, 0, imgSize.width, imgSize.height); vector::const_iterator it = keypoints.begin(); for( int i = 0; it != keypoints.end(); ++it, i++ ) if( r.contains(it->pt) ) filtered.push_back(*it); keypoints.assign(filtered.begin(), filtered.end()); } } /****************************************************************************************\ * Detectors evaluation * \****************************************************************************************/ const int DATASETS_COUNT = 8; const int TEST_CASE_COUNT = 5; const string IMAGE_DATASETS_DIR = "detectors_descriptors_evaluation/images_datasets/"; const string DETECTORS_DIR = "detectors_descriptors_evaluation/detectors/"; const string DESCRIPTORS_DIR = "detectors_descriptors_evaluation/descriptors/"; const string KEYPOINTS_DIR = "detectors_descriptors_evaluation/keypoints_datasets/"; const string PARAMS_POSTFIX = "_params.xml"; const string RES_POSTFIX = "_res.xml"; const string REPEAT = "repeatability"; const string CORRESP_COUNT = "correspondence_count"; string DATASET_NAMES[DATASETS_COUNT] = { "bark", "bikes", "boat", "graf", "leuven", "trees", "ubc", "wall"}; string DEFAULT_PARAMS = "default"; string IS_ACTIVE_PARAMS = "isActiveParams"; string IS_SAVE_KEYPOINTS = "isSaveKeypoints"; class BaseQualityEvaluator { public: BaseQualityEvaluator( const char* _algName, const char* _testName ) : algName(_algName), testName(_testName) { //TODO: change this isWriteGraphicsData = true; } void run(); virtual ~BaseQualityEvaluator(){} protected: virtual string getRunParamsFilename() const = 0; virtual string getResultsFilename() const = 0; virtual string getPlotPath() const = 0; virtual void calcQualityClear( int datasetIdx ) = 0; virtual bool isCalcQualityEmpty( int datasetIdx ) const = 0; void readAllDatasetsRunParams(); virtual void readDatasetRunParams( FileNode& fn, int datasetIdx ) = 0; void writeAllDatasetsRunParams() const; virtual void writeDatasetRunParams( FileStorage& fs, int datasetIdx ) const = 0; void setDefaultAllDatasetsRunParams(); virtual void setDefaultDatasetRunParams( int datasetIdx ) = 0; virtual void readDefaultRunParams( FileNode& /*fn*/ ) {} virtual void writeDefaultRunParams( FileStorage& /*fs*/ ) const {} bool readDataset( const string& datasetName, vector& Hs, vector& imgs ); virtual void readAlgorithm() {} virtual void processRunParamsFile() {} virtual void runDatasetTest( const vector& /*imgs*/, const vector& /*Hs*/, int /*di*/, int& /*progress*/ ) {} virtual void processResults( int datasetIdx ); virtual void processResults(); virtual void writePlotData( int /*datasetIdx*/ ) const {} string algName, testName; bool isWriteParams, isWriteGraphicsData; }; void BaseQualityEvaluator::readAllDatasetsRunParams() { string filename = getRunParamsFilename(); FileStorage fs( filename, FileStorage::READ ); if( !fs.isOpened() ) { isWriteParams = true; setDefaultAllDatasetsRunParams(); printf("All runParams are default.\n"); } else { isWriteParams = false; FileNode topfn = fs.getFirstTopLevelNode(); FileNode pfn = topfn[DEFAULT_PARAMS]; readDefaultRunParams(pfn); for( int i = 0; i < DATASETS_COUNT; i++ ) { FileNode fn = topfn[DATASET_NAMES[i]]; if( fn.empty() ) { printf( "%d-runParams is default.\n", i); setDefaultDatasetRunParams(i); } else readDatasetRunParams(fn, i); } } } void BaseQualityEvaluator::writeAllDatasetsRunParams() const { string filename = getRunParamsFilename(); FileStorage fs( filename, FileStorage::WRITE ); if( fs.isOpened() ) { fs << "run_params" << "{"; // top file node fs << DEFAULT_PARAMS << "{"; writeDefaultRunParams(fs); fs << "}"; for( int i = 0; i < DATASETS_COUNT; i++ ) { fs << DATASET_NAMES[i] << "{"; writeDatasetRunParams(fs, i); fs << "}"; } fs << "}"; } else printf( "File %s for writing run params can not be opened.\n", filename.c_str() ); } void BaseQualityEvaluator::setDefaultAllDatasetsRunParams() { for( int i = 0; i < DATASETS_COUNT; i++ ) setDefaultDatasetRunParams(i); } bool BaseQualityEvaluator::readDataset( const string& datasetName, vector& Hs, vector& imgs ) { Hs.resize( TEST_CASE_COUNT ); imgs.resize( TEST_CASE_COUNT+1 ); string dirname = data_path + IMAGE_DATASETS_DIR + datasetName + "/"; for( int i = 0; i < (int)Hs.size(); i++ ) { stringstream filename; filename << "H1to" << i+2 << "p.xml"; FileStorage fs( dirname + filename.str(), FileStorage::READ ); if( !fs.isOpened() ) { cout << "filename " << dirname + filename.str() << endl; FileStorage fs2( dirname + filename.str(), FileStorage::READ ); return false; } fs.getFirstTopLevelNode() >> Hs[i]; } for( int i = 0; i < (int)imgs.size(); i++ ) { stringstream filename; filename << "img" << i+1 << ".png"; imgs[i] = imread( dirname + filename.str(), 0 ); if( imgs[i].empty() ) { cout << "filename " << filename.str() << endl; return false; } } return true; } void BaseQualityEvaluator::processResults( int datasetIdx ) { if( isWriteGraphicsData ) writePlotData( datasetIdx ); } void BaseQualityEvaluator::processResults() { if( isWriteParams ) writeAllDatasetsRunParams(); } void BaseQualityEvaluator::run() { readAlgorithm (); processRunParamsFile (); int notReadDatasets = 0; int progress = 0; FileStorage runParamsFS( getRunParamsFilename(), FileStorage::READ ); isWriteParams = (! runParamsFS.isOpened()); FileNode topfn = runParamsFS.getFirstTopLevelNode(); FileNode defaultParams = topfn[DEFAULT_PARAMS]; readDefaultRunParams (defaultParams); cout << testName << endl; for(int di = 0; di < DATASETS_COUNT; di++ ) { cout << "Dataset " << di << " [" << DATASET_NAMES[di] << "] " << flush; vector imgs, Hs; if( !readDataset( DATASET_NAMES[di], Hs, imgs ) ) { calcQualityClear (di); printf( "Images or homography matrices of dataset named %s can not be read\n", DATASET_NAMES[di].c_str()); notReadDatasets++; continue; } FileNode fn = topfn[DATASET_NAMES[di]]; readDatasetRunParams(fn, di); runDatasetTest (imgs, Hs, di, progress); processResults( di ); cout << endl; } if( notReadDatasets == DATASETS_COUNT ) { printf( "All datasets were not be read\n"); exit(-1); } else processResults(); runParamsFS.release(); } class DetectorQualityEvaluator : public BaseQualityEvaluator { public: DetectorQualityEvaluator( const char* _detectorName, const char* _testName ) : BaseQualityEvaluator( _detectorName, _testName ) { calcQuality.resize(DATASETS_COUNT); isSaveKeypoints.resize(DATASETS_COUNT); isActiveParams.resize(DATASETS_COUNT); isSaveKeypointsDefault = false; isActiveParamsDefault = false; } protected: virtual string getRunParamsFilename() const; virtual string getResultsFilename() const; virtual string getPlotPath() const; virtual void calcQualityClear( int datasetIdx ); virtual bool isCalcQualityEmpty( int datasetIdx ) const; virtual void readDatasetRunParams( FileNode& fn, int datasetIdx ); virtual void writeDatasetRunParams( FileStorage& fs, int datasetIdx ) const; virtual void setDefaultDatasetRunParams( int datasetIdx ); virtual void readDefaultRunParams( FileNode &fn ); virtual void writeDefaultRunParams( FileStorage &fs ) const; virtual void writePlotData( int di ) const; void openToWriteKeypointsFile( FileStorage& fs, int datasetIdx ); virtual void readAlgorithm(); virtual void processRunParamsFile() {} virtual void runDatasetTest( const vector &imgs, const vector &Hs, int di, int &progress ); Ptr specificDetector; Ptr defaultDetector; struct Quality { float repeatability; int correspondenceCount; }; vector > calcQuality; vector isSaveKeypoints; vector isActiveParams; bool isSaveKeypointsDefault; bool isActiveParamsDefault; }; string DetectorQualityEvaluator::getRunParamsFilename() const { return data_path + DETECTORS_DIR + algName + PARAMS_POSTFIX; } string DetectorQualityEvaluator::getResultsFilename() const { return data_path + DETECTORS_DIR + algName + RES_POSTFIX; } string DetectorQualityEvaluator::getPlotPath() const { return data_path + DETECTORS_DIR + "plots/"; } void DetectorQualityEvaluator::calcQualityClear( int datasetIdx ) { calcQuality[datasetIdx].clear(); } bool DetectorQualityEvaluator::isCalcQualityEmpty( int datasetIdx ) const { return calcQuality[datasetIdx].empty(); } void DetectorQualityEvaluator::readDefaultRunParams (FileNode &fn) { if (! fn.empty() ) { isSaveKeypointsDefault = (int)fn[IS_SAVE_KEYPOINTS] != 0; defaultDetector->read (fn); } } void DetectorQualityEvaluator::writeDefaultRunParams (FileStorage &fs) const { fs << IS_SAVE_KEYPOINTS << isSaveKeypointsDefault; defaultDetector->write (fs); } void DetectorQualityEvaluator::readDatasetRunParams( FileNode& fn, int datasetIdx ) { isActiveParams[datasetIdx] = (int)fn[IS_ACTIVE_PARAMS] != 0; if (isActiveParams[datasetIdx]) { isSaveKeypoints[datasetIdx] = (int)fn[IS_SAVE_KEYPOINTS] != 0; specificDetector->read (fn); } else { setDefaultDatasetRunParams(datasetIdx); } } void DetectorQualityEvaluator::writeDatasetRunParams( FileStorage& fs, int datasetIdx ) const { fs << IS_ACTIVE_PARAMS << isActiveParams[datasetIdx]; fs << IS_SAVE_KEYPOINTS << isSaveKeypoints[datasetIdx]; defaultDetector->write (fs); } void DetectorQualityEvaluator::setDefaultDatasetRunParams( int datasetIdx ) { isSaveKeypoints[datasetIdx] = isSaveKeypointsDefault; isActiveParams[datasetIdx] = isActiveParamsDefault; } void DetectorQualityEvaluator::writePlotData(int di ) const { int imgXVals[] = { 2, 3, 4, 5, 6 }; // if scale, blur or light changes int viewpointXVals[] = { 20, 30, 40, 50, 60 }; // if viewpoint changes int jpegXVals[] = { 60, 80, 90, 95, 98 }; // if jpeg compression int* xVals = 0; if( !DATASET_NAMES[di].compare("ubc") ) { xVals = jpegXVals; } else if( !DATASET_NAMES[di].compare("graf") || !DATASET_NAMES[di].compare("wall") ) { xVals = viewpointXVals; } else xVals = imgXVals; stringstream rFilename, cFilename; rFilename << getPlotPath() << algName << "_" << DATASET_NAMES[di] << "_repeatability.csv"; cFilename << getPlotPath() << algName << "_" << DATASET_NAMES[di] << "_correspondenceCount.csv"; ofstream rfile(rFilename.str().c_str()), cfile(cFilename.str().c_str()); for( int ci = 0; ci < TEST_CASE_COUNT; ci++ ) { rfile << xVals[ci] << ", " << calcQuality[di][ci].repeatability << endl; cfile << xVals[ci] << ", " << calcQuality[di][ci].correspondenceCount << endl; } } void DetectorQualityEvaluator::openToWriteKeypointsFile( FileStorage& fs, int datasetIdx ) { string filename = data_path + KEYPOINTS_DIR + algName + "_"+ DATASET_NAMES[datasetIdx] + ".xml.gz" ; fs.open(filename, FileStorage::WRITE); if( !fs.isOpened() ) printf( "keypoints can not be written in file %s because this file can not be opened\n", filename.c_str() ); } inline void writeKeypoints( FileStorage& fs, const vector& keypoints, int imgIdx ) { if( fs.isOpened() ) { stringstream imgName; imgName << "img" << imgIdx; write( fs, imgName.str(), keypoints ); } } inline void readKeypoints( FileStorage& fs, vector& keypoints, int imgIdx ) { assert( fs.isOpened() ); stringstream imgName; imgName << "img" << imgIdx; read( fs[imgName.str()], keypoints); } void DetectorQualityEvaluator::readAlgorithm () { defaultDetector = FeatureDetector::create( algName ); specificDetector = FeatureDetector::create( algName ); if( defaultDetector.empty() ) { printf( "Algorithm can not be read\n" ); exit(-1); } } static int update_progress( const string& /*name*/, int progress, int test_case_idx, int count, double dt ) { int width = 60 /*- (int)name.length()*/; if( count > 0 ) { int t = cvRound( ((double)test_case_idx * width)/count ); if( t > progress ) { cout << "." << flush; progress = t; } } else if( cvRound(dt) > progress ) { cout << "." << flush; progress = cvRound(dt); } return progress; } void DetectorQualityEvaluator::runDatasetTest (const vector &imgs, const vector &Hs, int di, int &progress) { Ptr detector = isActiveParams[di] ? specificDetector : defaultDetector; FileStorage keypontsFS; if( isSaveKeypoints[di] ) openToWriteKeypointsFile( keypontsFS, di ); calcQuality[di].resize(TEST_CASE_COUNT); vector keypoints1; detector->detect( imgs[0], keypoints1 ); writeKeypoints( keypontsFS, keypoints1, 0); int progressCount = DATASETS_COUNT*TEST_CASE_COUNT; for( int ci = 0; ci < TEST_CASE_COUNT; ci++ ) { progress = update_progress( testName, progress, di*TEST_CASE_COUNT + ci + 1, progressCount, 0 ); vector keypoints2; float rep; evaluateFeatureDetector( imgs[0], imgs[ci+1], Hs[ci], &keypoints1, &keypoints2, rep, calcQuality[di][ci].correspondenceCount, detector ); calcQuality[di][ci].repeatability = rep == -1 ? rep : 100.f*rep; writeKeypoints( keypontsFS, keypoints2, ci+1); } } // static void testLog( bool isBadAccuracy ) // { // if( isBadAccuracy ) // printf(" bad accuracy\n"); // else // printf("\n"); // } /****************************************************************************************\ * Descriptors evaluation * \****************************************************************************************/ const string RECALL = "recall"; const string PRECISION = "precision"; const string KEYPOINTS_FILENAME = "keypointsFilename"; const string PROJECT_KEYPOINTS_FROM_1IMAGE = "projectKeypointsFrom1Image"; const string MATCH_FILTER = "matchFilter"; const string RUN_PARAMS_IS_IDENTICAL = "runParamsIsIdentical"; const string ONE_WAY_TRAIN_DIR = "detectors_descriptors_evaluation/one_way_train_images/"; const string ONE_WAY_IMAGES_LIST = "one_way_train_images.txt"; class DescriptorQualityEvaluator : public BaseQualityEvaluator { public: enum{ NO_MATCH_FILTER = 0 }; DescriptorQualityEvaluator( const char* _descriptorName, const char* _testName, const char* _matcherName = 0 ) : BaseQualityEvaluator( _descriptorName, _testName ) { calcQuality.resize(DATASETS_COUNT); calcDatasetQuality.resize(DATASETS_COUNT); commRunParams.resize(DATASETS_COUNT); commRunParamsDefault.projectKeypointsFrom1Image = true; commRunParamsDefault.matchFilter = NO_MATCH_FILTER; commRunParamsDefault.isActiveParams = false; if( _matcherName ) matcherName = _matcherName; } protected: virtual string getRunParamsFilename() const; virtual string getResultsFilename() const; virtual string getPlotPath() const; virtual void calcQualityClear( int datasetIdx ); virtual bool isCalcQualityEmpty( int datasetIdx ) const; virtual void readDatasetRunParams( FileNode& fn, int datasetIdx ); // virtual void writeDatasetRunParams( FileStorage& fs, int datasetIdx ) const; virtual void setDefaultDatasetRunParams( int datasetIdx ); virtual void readDefaultRunParams( FileNode &fn ); virtual void writeDefaultRunParams( FileStorage &fs ) const; virtual void readAlgorithm(); virtual void processRunParamsFile() {} virtual void runDatasetTest( const vector &imgs, const vector &Hs, int di, int &progress ); virtual void writePlotData( int di ) const; void calculatePlotData( vector > &allMatches, vector > &allCorrectMatchesMask, int di ); struct Quality { float recall; float precision; }; vector > calcQuality; vector > calcDatasetQuality; struct CommonRunParams { string keypontsFilename; bool projectKeypointsFrom1Image; int matchFilter; // not used now bool isActiveParams; }; vector commRunParams; Ptr specificDescMatcher; Ptr defaultDescMatcher; CommonRunParams commRunParamsDefault; string matcherName; }; string DescriptorQualityEvaluator::getRunParamsFilename() const { return data_path + DESCRIPTORS_DIR + algName + PARAMS_POSTFIX; } string DescriptorQualityEvaluator::getResultsFilename() const { return data_path + DESCRIPTORS_DIR + algName + RES_POSTFIX; } string DescriptorQualityEvaluator::getPlotPath() const { return data_path + DESCRIPTORS_DIR + "plots/"; } void DescriptorQualityEvaluator::calcQualityClear( int datasetIdx ) { calcQuality[datasetIdx].clear(); } bool DescriptorQualityEvaluator::isCalcQualityEmpty( int datasetIdx ) const { return calcQuality[datasetIdx].empty(); } void DescriptorQualityEvaluator::readDefaultRunParams (FileNode &fn) { if (! fn.empty() ) { commRunParamsDefault.projectKeypointsFrom1Image = (int)fn[PROJECT_KEYPOINTS_FROM_1IMAGE] != 0; commRunParamsDefault.matchFilter = (int)fn[MATCH_FILTER]; defaultDescMatcher->read (fn); } } void DescriptorQualityEvaluator::writeDefaultRunParams (FileStorage &fs) const { fs << PROJECT_KEYPOINTS_FROM_1IMAGE << commRunParamsDefault.projectKeypointsFrom1Image; fs << MATCH_FILTER << commRunParamsDefault.matchFilter; defaultDescMatcher->write (fs); } void DescriptorQualityEvaluator::readDatasetRunParams( FileNode& fn, int datasetIdx ) { commRunParams[datasetIdx].isActiveParams = (int)fn[IS_ACTIVE_PARAMS] != 0; if (commRunParams[datasetIdx].isActiveParams) { commRunParams[datasetIdx].keypontsFilename = (string)fn[KEYPOINTS_FILENAME]; commRunParams[datasetIdx].projectKeypointsFrom1Image = (int)fn[PROJECT_KEYPOINTS_FROM_1IMAGE] != 0; commRunParams[datasetIdx].matchFilter = (int)fn[MATCH_FILTER]; specificDescMatcher->read (fn); } else { setDefaultDatasetRunParams(datasetIdx); } } void DescriptorQualityEvaluator::writeDatasetRunParams( FileStorage& fs, int datasetIdx ) const { fs << IS_ACTIVE_PARAMS << commRunParams[datasetIdx].isActiveParams; fs << KEYPOINTS_FILENAME << commRunParams[datasetIdx].keypontsFilename; fs << PROJECT_KEYPOINTS_FROM_1IMAGE << commRunParams[datasetIdx].projectKeypointsFrom1Image; fs << MATCH_FILTER << commRunParams[datasetIdx].matchFilter; defaultDescMatcher->write (fs); } void DescriptorQualityEvaluator::setDefaultDatasetRunParams( int datasetIdx ) { commRunParams[datasetIdx] = commRunParamsDefault; commRunParams[datasetIdx].keypontsFilename = "SURF_" + DATASET_NAMES[datasetIdx] + ".xml.gz"; } void DescriptorQualityEvaluator::writePlotData( int di ) const { stringstream filename; filename << getPlotPath() << algName << "_" << DATASET_NAMES[di] << ".csv"; FILE *file = fopen (filename.str().c_str(), "w"); size_t size = calcDatasetQuality[di].size(); for (size_t i=0;i extractor = DescriptorExtractor::create( algName ); Ptr matcher = DescriptorMatcher::create( matcherName ); defaultDescMatcher = new VectorDescriptorMatch( extractor, matcher ); specificDescMatcher = new VectorDescriptorMatch( extractor, matcher ); if( extractor.empty() || matcher.empty() ) { printf("Algorithm can not be read\n"); exit(-1); } } } void DescriptorQualityEvaluator::calculatePlotData( vector > &allMatches, vector > &allCorrectMatchesMask, int di ) { vector recallPrecisionCurve; computeRecallPrecisionCurve( allMatches, allCorrectMatchesMask, recallPrecisionCurve ); calcDatasetQuality[di].clear(); const float resultPrecision = 0.5; bool isResultCalculated = false; const double eps = 1e-2; Quality initQuality; initQuality.recall = 0; initQuality.precision = 0; calcDatasetQuality[di].push_back( initQuality ); for( size_t i=0;i &imgs, const vector &Hs, int di, int &progress) { FileStorage keypontsFS( data_path + KEYPOINTS_DIR + commRunParams[di].keypontsFilename, FileStorage::READ ); if( !keypontsFS.isOpened()) { calcQuality[di].clear(); printf( "keypoints from file %s can not be read\n", commRunParams[di].keypontsFilename.c_str() ); return; } Ptr descMatch = commRunParams[di].isActiveParams ? specificDescMatcher : defaultDescMatcher; calcQuality[di].resize(TEST_CASE_COUNT); vector keypoints1; readKeypoints( keypontsFS, keypoints1, 0); int progressCount = DATASETS_COUNT*TEST_CASE_COUNT; vector > allMatches1to2; vector > allCorrectMatchesMask; for( int ci = 0; ci < TEST_CASE_COUNT; ci++ ) { progress = update_progress( testName, progress, di*TEST_CASE_COUNT + ci + 1, progressCount, 0 ); vector keypoints2; if( commRunParams[di].projectKeypointsFrom1Image ) { // TODO need to test function calcKeyPointProjections calcKeyPointProjections( keypoints1, Hs[ci], keypoints2 ); filterKeyPointsByImageSize( keypoints2, imgs[ci+1].size() ); } else readKeypoints( keypontsFS, keypoints2, ci+1 ); // TODO if( commRunParams[di].matchFilter ) vector > matches1to2; vector > correctMatchesMask; vector recallPrecisionCurve; // not used because we need recallPrecisionCurve for // all images in dataset evaluateGenericDescriptorMatcher( imgs[0], imgs[ci+1], Hs[ci], keypoints1, keypoints2, &matches1to2, &correctMatchesMask, recallPrecisionCurve, descMatch ); allMatches1to2.insert( allMatches1to2.end(), matches1to2.begin(), matches1to2.end() ); allCorrectMatchesMask.insert( allCorrectMatchesMask.end(), correctMatchesMask.begin(), correctMatchesMask.end() ); } calculatePlotData( allMatches1to2, allCorrectMatchesMask, di ); } //--------------------------------- Calonder descriptor test -------------------------------------------- class CalonderDescriptorQualityEvaluator : public DescriptorQualityEvaluator { public: CalonderDescriptorQualityEvaluator() : DescriptorQualityEvaluator( "Calonder", "quality-descriptor-calonder") {} virtual void readAlgorithm( ) { string classifierFile = data_path + "/features2d/calonder_classifier.rtc"; defaultDescMatcher = new VectorDescriptorMatch( new CalonderDescriptorExtractor( classifierFile ), new BFMatcher(NORM_L2) ); specificDescMatcher = defaultDescMatcher; } }; //--------------------------------- One Way descriptor test -------------------------------------------- class OneWayDescriptorQualityTest : public DescriptorQualityEvaluator { public: OneWayDescriptorQualityTest() : DescriptorQualityEvaluator("ONEWAY", "quality-descriptor-one-way") { } protected: virtual void processRunParamsFile (); virtual void writeDatasetRunParams( FileStorage& fs, int datasetIdx ) const; }; void OneWayDescriptorQualityTest::processRunParamsFile () { string filename = getRunParamsFilename(); FileStorage fs = FileStorage (filename, FileStorage::READ); FileNode fn = fs.getFirstTopLevelNode(); fn = fn[DEFAULT_PARAMS]; string pcaFilename = data_path + (string)fn["pcaFilename"]; string trainPath = data_path + (string)fn["trainPath"]; string trainImagesList = (string)fn["trainImagesList"]; int patch_width = fn["patchWidth"]; int patch_height = fn["patchHeight"]; Size patchSize = cvSize (patch_width, patch_height); int poseCount = fn["poseCount"]; if (trainImagesList.length () == 0 ) return; fs.release (); readAllDatasetsRunParams(); OneWayDescriptorBase *base = new OneWayDescriptorBase(patchSize, poseCount, pcaFilename, trainPath, trainImagesList); OneWayDescriptorMatch *match = new OneWayDescriptorMatch (); match->initialize( OneWayDescriptorMatch::Params (), base ); defaultDescMatcher = match; writeAllDatasetsRunParams(); } void OneWayDescriptorQualityTest::writeDatasetRunParams( FileStorage& fs, int datasetIdx ) const { fs << IS_ACTIVE_PARAMS << commRunParams[datasetIdx].isActiveParams; fs << KEYPOINTS_FILENAME << commRunParams[datasetIdx].keypontsFilename; fs << PROJECT_KEYPOINTS_FROM_1IMAGE << commRunParams[datasetIdx].projectKeypointsFrom1Image; fs << MATCH_FILTER << commRunParams[datasetIdx].matchFilter; } int main( int argc, char** argv ) { if( argc != 2 ) { cout << "Format: " << argv[0] << " testdata path (path to testdata/cv)" << endl; return -1; } data_path = argv[1]; #ifdef WIN32 if( *data_path.rbegin() != '\\' ) data_path = data_path + "\\"; #else if( *data_path.rbegin() != '/' ) data_path = data_path + "/"; #endif Ptr evals[] = { new DetectorQualityEvaluator( "FAST", "quality-detector-fast" ), new DetectorQualityEvaluator( "GFTT", "quality-detector-gftt" ), new DetectorQualityEvaluator( "HARRIS", "quality-detector-harris" ), new DetectorQualityEvaluator( "MSER", "quality-detector-mser" ), new DetectorQualityEvaluator( "STAR", "quality-detector-star" ), new DetectorQualityEvaluator( "SIFT", "quality-detector-sift" ), new DetectorQualityEvaluator( "SURF", "quality-detector-surf" ), new DescriptorQualityEvaluator( "SIFT", "quality-descriptor-sift", "BruteForce" ), new DescriptorQualityEvaluator( "SURF", "quality-descriptor-surf", "BruteForce" ), new DescriptorQualityEvaluator( "FERN", "quality-descriptor-fern"), new CalonderDescriptorQualityEvaluator() }; for( size_t i = 0; i < sizeof(evals)/sizeof(evals[0]); i++ ) { evals[i]->run(); cout << endl; } }