opencv/modules/features2d/src/detectors.cpp

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/*M///////////////////////////////////////////////////////////////////////////////////////
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#include "precomp.hpp"
using namespace std;
namespace cv
{
/*
* FeatureDetector
*/
struct MaskPredicate
{
MaskPredicate( const Mat& _mask ) : mask(_mask)
{}
MaskPredicate& operator=(const MaskPredicate&) { return *this; }
bool operator() (const KeyPoint& key_pt) const
{
return mask.at<uchar>( (int)(key_pt.pt.y + 0.5f), (int)(key_pt.pt.x + 0.5f) ) == 0;
}
const Mat& mask;
};
void FeatureDetector::detect(const vector<Mat>& imageCollection, vector<vector<KeyPoint> >& pointCollection, const vector<Mat>& masks ) const
{
pointCollection.resize( imageCollection.size() );
for( size_t i = 0; i < imageCollection.size(); i++ )
detect( imageCollection[i], pointCollection[i], masks.empty() ? Mat() : masks[i] );
}
void FeatureDetector::removeInvalidPoints( const Mat& mask, vector<KeyPoint>& keypoints )
{
if( mask.empty() )
return;
keypoints.erase(remove_if(keypoints.begin(), keypoints.end(), MaskPredicate(mask)), keypoints.end());
};
/*
* FastFeatureDetector
*/
FastFeatureDetector::FastFeatureDetector( int _threshold, bool _nonmaxSuppression )
: threshold(_threshold), nonmaxSuppression(_nonmaxSuppression)
{}
void FastFeatureDetector::read (const FileNode& fn)
{
threshold = fn["threshold"];
nonmaxSuppression = (int)fn["nonmaxSuppression"] ? true : false;
}
void FastFeatureDetector::write (FileStorage& fs) const
{
fs << "threshold" << threshold;
fs << "nonmaxSuppression" << nonmaxSuppression;
}
void FastFeatureDetector::detect( const Mat& image, vector<KeyPoint>& keypoints, const Mat& mask ) const
{
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Mat grayImage = image;
if( image.type() != CV_8U ) cvtColor( image, grayImage, CV_BGR2GRAY );
FAST( grayImage, keypoints, threshold, nonmaxSuppression );
removeInvalidPoints( mask, keypoints );
}
/*
* GoodFeaturesToTrackDetector
*/
GoodFeaturesToTrackDetector::GoodFeaturesToTrackDetector( int _maxCorners, double _qualityLevel, \
double _minDistance, int _blockSize,
bool _useHarrisDetector, double _k )
: maxCorners(_maxCorners), qualityLevel(_qualityLevel), minDistance(_minDistance),
blockSize(_blockSize), useHarrisDetector(_useHarrisDetector), k(_k)
{}
void GoodFeaturesToTrackDetector::read (const FileNode& fn)
{
maxCorners = fn["maxCorners"];
qualityLevel = fn["qualityLevel"];
minDistance = fn["minDistance"];
blockSize = fn["blockSize"];
useHarrisDetector = (int)fn["useHarrisDetector"] != 0;
k = fn["k"];
}
void GoodFeaturesToTrackDetector::write (FileStorage& fs) const
{
fs << "maxCorners" << maxCorners;
fs << "qualityLevel" << qualityLevel;
fs << "minDistance" << minDistance;
fs << "blockSize" << blockSize;
fs << "useHarrisDetector" << useHarrisDetector;
fs << "k" << k;
}
void GoodFeaturesToTrackDetector::detect( const Mat& image, vector<KeyPoint>& keypoints, const Mat& mask) const
{
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Mat grayImage = image;
if( image.type() != CV_8U ) cvtColor( image, grayImage, CV_BGR2GRAY );
vector<Point2f> corners;
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goodFeaturesToTrack( grayImage, corners, maxCorners, qualityLevel, minDistance, mask,
blockSize, useHarrisDetector, k );
keypoints.resize(corners.size());
vector<Point2f>::const_iterator corner_it = corners.begin();
vector<KeyPoint>::iterator keypoint_it = keypoints.begin();
for( ; corner_it != corners.end(); ++corner_it, ++keypoint_it )
{
*keypoint_it = KeyPoint( *corner_it, (float)blockSize );
}
}
/*
* MserFeatureDetector
*/
MserFeatureDetector::MserFeatureDetector( int delta, int minArea, int maxArea,
double maxVariation, double minDiversity,
int maxEvolution, double areaThreshold,
double minMargin, int edgeBlurSize )
: mser( delta, minArea, maxArea, maxVariation, minDiversity,
maxEvolution, areaThreshold, minMargin, edgeBlurSize )
{}
MserFeatureDetector::MserFeatureDetector( CvMSERParams params )
: mser( params.delta, params.minArea, params.maxArea, params.maxVariation, params.minDiversity,
params.maxEvolution, params.areaThreshold, params.minMargin, params.edgeBlurSize )
{}
void MserFeatureDetector::read (const FileNode& fn)
{
int delta = fn["delta"];
int minArea = fn["minArea"];
int maxArea = fn["maxArea"];
float maxVariation = fn["maxVariation"];
float minDiversity = fn["minDiversity"];
int maxEvolution = fn["maxEvolution"];
double areaThreshold = fn["areaThreshold"];
double minMargin = fn["minMargin"];
int edgeBlurSize = fn["edgeBlurSize"];
mser = MSER( delta, minArea, maxArea, maxVariation, minDiversity,
maxEvolution, areaThreshold, minMargin, edgeBlurSize );
}
void MserFeatureDetector::write (FileStorage& fs) const
{
//fs << "algorithm" << getAlgorithmName ();
fs << "delta" << mser.delta;
fs << "minArea" << mser.minArea;
fs << "maxArea" << mser.maxArea;
fs << "maxVariation" << mser.maxVariation;
fs << "minDiversity" << mser.minDiversity;
fs << "maxEvolution" << mser.maxEvolution;
fs << "areaThreshold" << mser.areaThreshold;
fs << "minMargin" << mser.minMargin;
fs << "edgeBlurSize" << mser.edgeBlurSize;
}
void MserFeatureDetector::detect( const Mat& image, vector<KeyPoint>& keypoints, const Mat& mask ) const
{
vector<vector<Point> > msers;
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Mat grayImage = image;
if( image.type() != CV_8U ) cvtColor( image, grayImage, CV_BGR2GRAY );
mser(grayImage, msers, mask);
keypoints.resize( msers.size() );
vector<vector<Point> >::const_iterator contour_it = msers.begin();
vector<KeyPoint>::iterator keypoint_it = keypoints.begin();
for( ; contour_it != msers.end(); ++contour_it, ++keypoint_it )
{
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// TODO check transformation from MSER region to KeyPoint
RotatedRect rect = fitEllipse(Mat(*contour_it));
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*keypoint_it = KeyPoint( rect.center, sqrt(rect.size.height*rect.size.width), rect.angle);
}
}
/*
* StarFeatureDetector
*/
StarFeatureDetector::StarFeatureDetector(int maxSize, int responseThreshold,
int lineThresholdProjected,
int lineThresholdBinarized,
int suppressNonmaxSize)
: star( maxSize, responseThreshold, lineThresholdProjected,
lineThresholdBinarized, suppressNonmaxSize)
{}
void StarFeatureDetector::read (const FileNode& fn)
{
int maxSize = fn["maxSize"];
int responseThreshold = fn["responseThreshold"];
int lineThresholdProjected = fn["lineThresholdProjected"];
int lineThresholdBinarized = fn["lineThresholdBinarized"];
int suppressNonmaxSize = fn["suppressNonmaxSize"];
star = StarDetector( maxSize, responseThreshold, lineThresholdProjected,
lineThresholdBinarized, suppressNonmaxSize);
}
void StarFeatureDetector::write (FileStorage& fs) const
{
//fs << "algorithm" << getAlgorithmName ();
fs << "maxSize" << star.maxSize;
fs << "responseThreshold" << star.responseThreshold;
fs << "lineThresholdProjected" << star.lineThresholdProjected;
fs << "lineThresholdBinarized" << star.lineThresholdBinarized;
fs << "suppressNonmaxSize" << star.suppressNonmaxSize;
}
void StarFeatureDetector::detect( const Mat& image, vector<KeyPoint>& keypoints, const Mat& mask ) const
{
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Mat grayImage = image;
if( image.type() != CV_8U ) cvtColor( image, grayImage, CV_BGR2GRAY );
star(grayImage, keypoints);
removeInvalidPoints(mask, keypoints);
}
/*
* SiftFeatureDetector
*/
SiftFeatureDetector::SiftFeatureDetector(double threshold, double edgeThreshold,
int nOctaves, int nOctaveLayers, int firstOctave, int angleMode) :
sift(threshold, edgeThreshold, nOctaves, nOctaveLayers, firstOctave, angleMode)
{
}
void SiftFeatureDetector::read (const FileNode& fn)
{
double threshold = fn["threshold"];
double edgeThreshold = fn["edgeThreshold"];
int nOctaves = fn["nOctaves"];
int nOctaveLayers = fn["nOctaveLayers"];
int firstOctave = fn["firstOctave"];
int angleMode = fn["angleMode"];
sift = SIFT(threshold, edgeThreshold, nOctaves, nOctaveLayers, firstOctave, angleMode);
}
void SiftFeatureDetector::write (FileStorage& fs) const
{
//fs << "algorithm" << getAlgorithmName ();
SIFT::CommonParams commParams = sift.getCommonParams ();
SIFT::DetectorParams detectorParams = sift.getDetectorParams ();
fs << "threshold" << detectorParams.threshold;
fs << "edgeThreshold" << detectorParams.edgeThreshold;
fs << "nOctaves" << commParams.nOctaves;
fs << "nOctaveLayers" << commParams.nOctaveLayers;
fs << "firstOctave" << commParams.firstOctave;
fs << "angleMode" << commParams.angleMode;
}
void SiftFeatureDetector::detect( const Mat& image, vector<KeyPoint>& keypoints, const Mat& mask ) const
{
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Mat grayImage = image;
if( image.type() != CV_8U ) cvtColor( image, grayImage, CV_BGR2GRAY );
sift(grayImage, mask, keypoints);
}
/*
* SurfFeatureDetector
*/
SurfFeatureDetector::SurfFeatureDetector( double hessianThreshold, int octaves, int octaveLayers)
: surf(hessianThreshold, octaves, octaveLayers)
{}
void SurfFeatureDetector::read (const FileNode& fn)
{
double hessianThreshold = fn["hessianThreshold"];
int octaves = fn["octaves"];
int octaveLayers = fn["octaveLayers"];
surf = SURF( hessianThreshold, octaves, octaveLayers );
}
void SurfFeatureDetector::write (FileStorage& fs) const
{
//fs << "algorithm" << getAlgorithmName ();
fs << "hessianThreshold" << surf.hessianThreshold;
fs << "octaves" << surf.nOctaves;
fs << "octaveLayers" << surf.nOctaveLayers;
}
void SurfFeatureDetector::detect( const Mat& image, vector<KeyPoint>& keypoints, const Mat& mask ) const
{
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Mat grayImage = image;
if( image.type() != CV_8U ) cvtColor( image, grayImage, CV_BGR2GRAY );
surf(grayImage, mask, keypoints);
}
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/*
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* DenseFeatureDetector
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*/
void DenseFeatureDetector::detect( const Mat& image, vector<KeyPoint>& keypoints, const Mat& mask ) const
{
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keypoints.clear();
float curScale = initFeatureScale;
int curStep = initXyStep;
int curBound = initImgBound;
for( int curLevel = 0; curLevel < featureScaleLevels; curLevel++ )
{
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for( int x = curBound; x < image.cols - curBound; x += curStep )
{
for( int y = curBound; y < image.rows - curBound; y += curStep )
{
keypoints.push_back( KeyPoint(static_cast<float>(x), static_cast<float>(y), curScale) );
}
}
curScale = curScale * featureScaleMul;
if( varyXyStepWithScale ) curStep = static_cast<int>( curStep * featureScaleMul + 0.5f );
if( varyImgBoundWithScale ) curBound = static_cast<int>( curBound * featureScaleMul + 0.5f );
}
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removeInvalidPoints( mask, keypoints );
}
/*
* GridAdaptedFeatureDetector
*/
GridAdaptedFeatureDetector::GridAdaptedFeatureDetector( const Ptr<FeatureDetector>& _detector,
int _maxTotalKeypoints, int _gridRows, int _gridCols )
: detector(_detector), maxTotalKeypoints(_maxTotalKeypoints), gridRows(_gridRows), gridCols(_gridCols)
{}
struct ResponseComparator
{
bool operator() (const KeyPoint& a, const KeyPoint& b)
{
return std::abs(a.response) > std::abs(b.response);
}
};
void keepStrongest( int N, vector<KeyPoint>& keypoints )
{
if( (int)keypoints.size() > N )
{
vector<KeyPoint>::iterator nth = keypoints.begin() + N;
std::nth_element( keypoints.begin(), nth, keypoints.end(), ResponseComparator() );
keypoints.erase( nth, keypoints.end() );
}
}
void GridAdaptedFeatureDetector::detect( const Mat& image, vector<KeyPoint>& keypoints, const Mat& mask ) const
{
keypoints.clear();
keypoints.reserve(maxTotalKeypoints);
int maxPerCell = maxTotalKeypoints / (gridRows * gridCols);
for( int i = 0; i < gridRows; ++i )
{
Range row_range((i*image.rows)/gridRows, ((i+1)*image.rows)/gridRows);
for( int j = 0; j < gridCols; ++j )
{
Range col_range((j*image.cols)/gridCols, ((j+1)*image.cols)/gridCols);
Mat sub_image = image(row_range, col_range);
Mat sub_mask;
if( !mask.empty() )
sub_mask = mask(row_range, col_range);
vector<KeyPoint> sub_keypoints;
detector->detect( sub_image, sub_keypoints, sub_mask );
keepStrongest( maxPerCell, sub_keypoints );
for( std::vector<cv::KeyPoint>::iterator it = sub_keypoints.begin(), end = sub_keypoints.end();
it != end; ++it )
{
it->pt.x += col_range.start;
it->pt.y += row_range.start;
}
keypoints.insert( keypoints.end(), sub_keypoints.begin(), sub_keypoints.end() );
}
}
}
/*
* GridAdaptedFeatureDetector
*/
PyramidAdaptedFeatureDetector::PyramidAdaptedFeatureDetector( const Ptr<FeatureDetector>& _detector, int _levels )
: detector(_detector), levels(_levels)
{}
void PyramidAdaptedFeatureDetector::detect( const Mat& image, vector<KeyPoint>& keypoints, const Mat& mask ) const
{
Mat src = image;
for( int l = 0, multiplier = 1; l <= levels; ++l, multiplier *= 2 )
{
// Detect on current level of the pyramid
vector<KeyPoint> new_pts;
detector->detect(src, new_pts);
for( vector<KeyPoint>::iterator it = new_pts.begin(), end = new_pts.end(); it != end; ++it)
{
it->pt.x *= multiplier;
it->pt.y *= multiplier;
it->size *= multiplier;
it->octave = l;
}
removeInvalidPoints( mask, new_pts );
keypoints.insert( keypoints.end(), new_pts.begin(), new_pts.end() );
// Downsample
if( l < levels )
{
Mat dst;
pyrDown(src, dst);
src = dst;
}
}
}
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Ptr<FeatureDetector> createFeatureDetector( const string& detectorType )
{
FeatureDetector* fd = 0;
if( !detectorType.compare( "FAST" ) )
{
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fd = new FastFeatureDetector( 10/*threshold*/, true/*nonmax_suppression*/ );
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}
else if( !detectorType.compare( "STAR" ) )
{
fd = new StarFeatureDetector( 16/*max_size*/, 5/*response_threshold*/, 10/*line_threshold_projected*/,
8/*line_threshold_binarized*/, 5/*suppress_nonmax_size*/ );
}
else if( !detectorType.compare( "SIFT" ) )
{
fd = new SiftFeatureDetector(SIFT::DetectorParams::GET_DEFAULT_THRESHOLD(),
SIFT::DetectorParams::GET_DEFAULT_EDGE_THRESHOLD());
}
else if( !detectorType.compare( "SURF" ) )
{
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fd = new SurfFeatureDetector( 400./*hessian_threshold*/, 3 /*octaves*/, 4/*octave_layers*/ );
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}
else if( !detectorType.compare( "MSER" ) )
{
fd = new MserFeatureDetector( 5/*delta*/, 60/*min_area*/, 14400/*_max_area*/, 0.25f/*max_variation*/,
0.2/*min_diversity*/, 200/*max_evolution*/, 1.01/*area_threshold*/, 0.003/*min_margin*/,
5/*edge_blur_size*/ );
}
else if( !detectorType.compare( "GFTT" ) )
{
fd = new GoodFeaturesToTrackDetector( 1000/*maxCorners*/, 0.01/*qualityLevel*/, 1./*minDistance*/,
3/*int _blockSize*/, false/*useHarrisDetector*/, 0.04/*k*/ );
}
else if( !detectorType.compare( "HARRIS" ) )
{
fd = new GoodFeaturesToTrackDetector( 1000/*maxCorners*/, 0.01/*qualityLevel*/, 1./*minDistance*/,
3/*int _blockSize*/, true/*useHarrisDetector*/, 0.04/*k*/ );
}
return fd;
}
}