opencv/modules/features2d/src/matchers.cpp

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/*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,
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//M*/
#include "precomp.hpp"
#ifdef HAVE_EIGEN2
#include <Eigen/Array>
#endif
using namespace std;
namespace cv
{
Mat windowedMatchingMask( const vector<KeyPoint>& keypoints1, const vector<KeyPoint>& keypoints2,
float maxDeltaX, float maxDeltaY )
{
if( keypoints1.empty() || keypoints2.empty() )
return Mat();
Mat mask( keypoints1.size(), keypoints2.size(), CV_8UC1 );
for( size_t i = 0; i < keypoints1.size(); i++ )
{
for( size_t j = 0; j < keypoints2.size(); j++ )
{
Point2f diff = keypoints2[j].pt - keypoints1[i].pt;
mask.at<uchar>(i, j) = std::abs(diff.x) < maxDeltaX && std::abs(diff.y) < maxDeltaY;
}
}
return mask;
}
/****************************************************************************************\
* DescriptorMatcher *
\****************************************************************************************/
DescriptorMatcher::DescriptorCollection::DescriptorCollection()
{}
DescriptorMatcher::DescriptorCollection::DescriptorCollection( const DescriptorCollection& collection )
{
mergedDescriptors = collection.mergedDescriptors.clone();
copy( collection.startIdxs.begin(), collection.startIdxs.begin(), startIdxs.begin() );
}
DescriptorMatcher::DescriptorCollection::~DescriptorCollection()
{}
void DescriptorMatcher::DescriptorCollection::set( const vector<Mat>& descriptors )
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{
clear();
size_t imageCount = descriptors.size();
CV_Assert( imageCount > 0 );
startIdxs.resize( imageCount );
int dim = -1;
int type = -1;
startIdxs[0] = 0;
for( size_t i = 1; i < imageCount; i++ )
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{
int s = 0;
if( !descriptors[i-1].empty() )
{
dim = descriptors[i-1].cols;
type = descriptors[i-1].type();
s = descriptors[i-1].rows;
}
startIdxs[i] = startIdxs[i-1] + s;
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}
if( imageCount == 1 )
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{
if( descriptors[0].empty() ) return;
dim = descriptors[0].cols;
type = descriptors[0].type();
}
assert( dim > 0 );
int count = startIdxs[imageCount-1] + descriptors[imageCount-1].rows;
if( count > 0 )
{
mergedDescriptors.create( count, dim, type );
for( size_t i = 0; i < imageCount; i++ )
{
if( !descriptors[i].empty() )
{
CV_Assert( descriptors[i].cols == dim && descriptors[i].type() == type );
Mat m = mergedDescriptors.rowRange( startIdxs[i], startIdxs[i] + descriptors[i].rows );
descriptors[i].copyTo(m);
}
}
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}
}
void DescriptorMatcher::DescriptorCollection::clear()
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{
startIdxs.clear();
mergedDescriptors.release();
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}
const Mat DescriptorMatcher::DescriptorCollection::getDescriptor( int imgIdx, int localDescIdx ) const
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{
CV_Assert( imgIdx < (int)startIdxs.size() );
int globalIdx = startIdxs[imgIdx] + localDescIdx;
CV_Assert( globalIdx < (int)size() );
return getDescriptor( globalIdx );
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}
const Mat& DescriptorMatcher::DescriptorCollection::getDescriptors() const
{
return mergedDescriptors;
}
const Mat DescriptorMatcher::DescriptorCollection::getDescriptor( int globalDescIdx ) const
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{
CV_Assert( globalDescIdx < size() );
return mergedDescriptors.row( globalDescIdx );
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}
void DescriptorMatcher::DescriptorCollection::getLocalIdx( int globalDescIdx, int& imgIdx, int& localDescIdx ) const
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{
imgIdx = -1;
CV_Assert( globalDescIdx < size() );
for( size_t i = 1; i < startIdxs.size(); i++ )
{
if( globalDescIdx < startIdxs[i] )
{
imgIdx = i - 1;
break;
}
}
imgIdx = imgIdx == -1 ? startIdxs.size() -1 : imgIdx;
localDescIdx = globalDescIdx - startIdxs[imgIdx];
}
int DescriptorMatcher::DescriptorCollection::size() const
{
return mergedDescriptors.rows;
}
/*
* DescriptorMatcher
*/
void convertMatches( const vector<vector<DMatch> >& knnMatches, vector<DMatch>& matches )
{
matches.clear();
matches.reserve( knnMatches.size() );
for( size_t i = 0; i < knnMatches.size(); i++ )
{
CV_Assert( knnMatches[i].size() <= 1 );
if( !knnMatches[i].empty() )
matches.push_back( knnMatches[i][0] );
}
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}
DescriptorMatcher::~DescriptorMatcher()
{}
void DescriptorMatcher::add( const vector<Mat>& descriptors )
{
trainDescCollection.insert( trainDescCollection.end(), descriptors.begin(), descriptors.end() );
}
const vector<Mat>& DescriptorMatcher::getTrainDescriptors() const
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{
return trainDescCollection;
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}
void DescriptorMatcher::clear()
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{
trainDescCollection.clear();
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}
bool DescriptorMatcher::empty() const
{
return trainDescCollection.size() == 0;
}
void DescriptorMatcher::train()
{}
void DescriptorMatcher::match( const Mat& queryDescriptors, const Mat& trainDescriptors, vector<DMatch>& matches, const Mat& mask ) const
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{
Ptr<DescriptorMatcher> tempMatcher = clone(true);
tempMatcher->add( vector<Mat>(1, trainDescriptors) );
tempMatcher->match( queryDescriptors, matches, vector<Mat>(1, mask) );
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}
void DescriptorMatcher::knnMatch( const Mat& queryDescriptors, const Mat& trainDescriptors, vector<vector<DMatch> >& matches, int knn,
const Mat& mask, bool compactResult ) const
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{
Ptr<DescriptorMatcher> tempMatcher = clone(true);
tempMatcher->add( vector<Mat>(1, trainDescriptors) );
tempMatcher->knnMatch( queryDescriptors, matches, knn, vector<Mat>(1, mask), compactResult );
}
void DescriptorMatcher::radiusMatch( const Mat& queryDescriptors, const Mat& trainDescriptors, vector<vector<DMatch> >& matches, float maxDistance,
const Mat& mask, bool compactResult ) const
{
Ptr<DescriptorMatcher> tempMatcher = clone(true);
tempMatcher->add( vector<Mat>(1, trainDescriptors) );
tempMatcher->radiusMatch( queryDescriptors, matches, maxDistance, vector<Mat>(1, mask), compactResult );
}
void DescriptorMatcher::match( const Mat& queryDescriptors, vector<DMatch>& matches, const vector<Mat>& masks )
{
vector<vector<DMatch> > knnMatches;
knnMatch( queryDescriptors, knnMatches, 1, masks, true /*compactResult*/ );
convertMatches( knnMatches, matches );
}
void DescriptorMatcher::checkMasks( const vector<Mat>& masks, int queryDescriptorsCount ) const
{
if( isMaskSupported() && !masks.empty() )
{
// Check masks
size_t imageCount = trainDescCollection.size();
CV_Assert( masks.size() == imageCount );
for( size_t i = 0; i < imageCount; i++ )
{
if( !masks[i].empty() && !trainDescCollection[i].empty() )
{
CV_Assert( masks[i].rows == queryDescriptorsCount &&
masks[i].cols == trainDescCollection[i].rows &&
masks[i].type() == CV_8UC1 );
}
}
}
}
void DescriptorMatcher::knnMatch( const Mat& queryDescriptors, vector<vector<DMatch> >& matches, int knn,
const vector<Mat>& masks, bool compactResult )
{
matches.empty();
if( empty() || queryDescriptors.empty() )
return;
CV_Assert( knn > 0 );
checkMasks( masks, queryDescriptors.rows );
train();
knnMatchImpl( queryDescriptors, matches, knn, masks, compactResult );
}
void DescriptorMatcher::radiusMatch( const Mat& queryDescriptors, vector<vector<DMatch> >& matches, float maxDistance,
const vector<Mat>& masks, bool compactResult )
{
matches.empty();
if( empty() || queryDescriptors.empty() )
return;
CV_Assert( maxDistance > std::numeric_limits<float>::epsilon() );
checkMasks( masks, queryDescriptors.rows );
train();
radiusMatchImpl( queryDescriptors, matches, maxDistance, masks, compactResult );
}
void DescriptorMatcher::read( const FileNode& )
{}
void DescriptorMatcher::write( FileStorage& ) const
{}
bool DescriptorMatcher::isPossibleMatch( const Mat& mask, int queryIdx, int trainIdx )
{
return mask.empty() || mask.at<uchar>(queryIdx, trainIdx);
}
bool DescriptorMatcher::isMaskedOut( const vector<Mat>& masks, int queryIdx )
{
size_t outCount = 0;
for( size_t i = 0; i < masks.size(); i++ )
{
if( !masks[i].empty() && (countNonZero(masks[i].row(queryIdx)) == 0) )
outCount++;
}
return !masks.empty() && outCount == masks.size() ;
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}
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template<>
void BruteForceMatcher<L2<float> >::knnMatchImpl( const Mat& queryDescriptors, vector<vector<DMatch> >& matches, int knn,
const vector<Mat>& masks, bool compactResult )
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{
#ifndef HAVE_EIGEN2
commonKnnMatchImpl( *this, queryDescriptors, matches, knn, masks, compactResult );
#else
CV_Assert( queryDescriptors.type() == CV_32FC1 || queryDescriptors.empty() );
CV_Assert( masks.empty() || masks.size() == trainDescCollection.size() );
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matches.reserve(queryDescriptors.rows);
size_t imgCount = trainDescCollection.size();
Eigen::Matrix<float, Eigen::Dynamic, Eigen::Dynamic> e_query_t;
vector<Eigen::Matrix<float, Eigen::Dynamic, Eigen::Dynamic> > e_trainCollection(trainDescCollection.size());
vector<Eigen::Matrix<float, Eigen::Dynamic, Eigen::Dynamic> > e_trainNorms2(trainDescCollection.size());
cv2eigen( queryDescriptors.t(), e_query_t);
for( size_t i = 0; i < trainDescCollection.size(); i++ )
{
cv2eigen( trainDescCollection[i], e_trainCollection[i] );
e_trainNorms2[i] = e_trainCollection[i].rowwise().squaredNorm() / 2;
}
vector<Eigen::Matrix<float, Eigen::Dynamic, 1> > e_allDists( imgCount ); // distances between one query descriptor and all train descriptors
for( int qIdx = 0; qIdx < queryDescriptors.rows; qIdx++ )
{
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if( isMaskedOut( masks, qIdx ) )
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{
if( !compactResult ) // push empty vector
matches.push_back( vector<DMatch>() );
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}
else
{
float queryNorm2 = e_query_t.col(qIdx).squaredNorm();
// 1. compute distances between i-th query descriptor and all train descriptors
for( size_t iIdx = 0; iIdx < imgCount; iIdx++ )
{
CV_Assert( masks.empty() || masks[iIdx].empty() ||
( masks[iIdx].rows == queryDescriptors.rows && masks[iIdx].cols == trainDescCollection[iIdx].rows &&
masks[iIdx].type() == CV_8UC1 ) );
CV_Assert( trainDescCollection[iIdx].type() == CV_32FC1 || trainDescCollection[iIdx].empty() );
CV_Assert( queryDescriptors.cols == trainDescCollection[iIdx].cols );
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e_allDists[iIdx] = e_trainCollection[iIdx] *e_query_t.col(qIdx);
e_allDists[iIdx] -= e_trainNorms2[iIdx];
if( !masks.empty() && !masks[iIdx].empty() )
{
const uchar* maskPtr = (uchar*)masks[iIdx].ptr(qIdx);
for( int c = 0; c < masks[iIdx].cols; c++ )
{
if( maskPtr[c] == 0 )
e_allDists[iIdx](c) = std::numeric_limits<float>::min();
}
}
}
// 2. choose knn nearest matches for query[i]
matches.push_back( vector<DMatch>() );
vector<vector<DMatch> >::reverse_iterator curMatches = matches.rbegin();
for( int k = 0; k < knn; k++ )
{
float totalMaxCoeff = std::numeric_limits<float>::min();
int bestTrainIdx = -1, bestImgIdx = -1;
for( size_t iIdx = 0; iIdx < imgCount; iIdx++ )
{
int loc;
float curMaxCoeff = e_allDists[iIdx].maxCoeff( &loc );
if( curMaxCoeff > totalMaxCoeff )
{
totalMaxCoeff = curMaxCoeff;
bestTrainIdx = loc;
bestImgIdx = iIdx;
}
}
if( bestTrainIdx == -1 )
break;
e_allDists[bestImgIdx](bestTrainIdx) = std::numeric_limits<float>::min();
curMatches->push_back( DMatch(qIdx, bestTrainIdx, bestImgIdx, sqrt((-2)*totalMaxCoeff + queryNorm2)) );
}
std::sort( curMatches->begin(), curMatches->end() );
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}
}
#endif
}
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template<>
void BruteForceMatcher<L2<float> >::radiusMatchImpl( const Mat& queryDescriptors, vector<vector<DMatch> >& matches, float maxDistance,
const vector<Mat>& masks, bool compactResult )
{
#ifndef HAVE_EIGEN2
commonRadiusMatchImpl( *this, queryDescriptors, matches, maxDistance, masks, compactResult );
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#else
CV_Assert( queryDescriptors.type() == CV_32FC1 || queryDescriptors.empty() );
CV_Assert( masks.empty() || masks.size() == trainDescCollection.size() );
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matches.reserve(queryDescriptors.rows);
size_t imgCount = trainDescCollection.size();
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Eigen::Matrix<float, Eigen::Dynamic, Eigen::Dynamic> e_query_t;
vector<Eigen::Matrix<float, Eigen::Dynamic, Eigen::Dynamic> > e_trainCollection(trainDescCollection.size());
vector<Eigen::Matrix<float, Eigen::Dynamic, Eigen::Dynamic> > e_trainNorms2(trainDescCollection.size());
cv2eigen( queryDescriptors.t(), e_query_t);
for( size_t i = 0; i < trainDescCollection.size(); i++ )
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{
cv2eigen( trainDescCollection[i], e_trainCollection[i] );
e_trainNorms2[i] = e_trainCollection[i].rowwise().squaredNorm() / 2;
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}
vector<Eigen::Matrix<float, Eigen::Dynamic, 1> > e_allDists( imgCount ); // distances between one query descriptor and all train descriptors
for( int qIdx = 0; qIdx < queryDescriptors.rows; qIdx++ )
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{
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if( isMaskedOut( masks, qIdx ) )
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{
if( !compactResult ) // push empty vector
matches.push_back( vector<DMatch>() );
}
else
{
float queryNorm2 = e_query_t.col(qIdx).squaredNorm();
// 1. compute distances between i-th query descriptor and all train descriptors
for( size_t iIdx = 0; iIdx < imgCount; iIdx++ )
{
CV_Assert( masks.empty() || masks[iIdx].empty() ||
( masks[iIdx].rows == queryDescriptors.rows && masks[iIdx].cols == trainDescCollection[iIdx].rows &&
masks[iIdx].type() == CV_8UC1 ) );
CV_Assert( trainDescCollection[iIdx].type() == CV_32FC1 || trainDescCollection[iIdx].empty() );
CV_Assert( queryDescriptors.cols == trainDescCollection[iIdx].cols );
e_allDists[iIdx] = e_trainCollection[iIdx] *e_query_t.col(qIdx);
e_allDists[iIdx] -= e_trainNorms2[iIdx];
}
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matches.push_back( vector<DMatch>() );
vector<vector<DMatch> >::reverse_iterator curMatches = matches.rbegin();
for( size_t iIdx = 0; iIdx < imgCount; iIdx++ )
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{
assert( e_allDists[iIdx].rows() == trainDescCollection[iIdx].rows );
for( int tIdx = 0; tIdx < e_allDists[iIdx].rows(); tIdx++ )
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{
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if( masks.empty() || isPossibleMatch(masks[iIdx], qIdx, tIdx) )
{
float d = sqrt((-2)*e_allDists[iIdx](tIdx) + queryNorm2);
if( d < maxDistance )
curMatches->push_back( DMatch( qIdx, tIdx, iIdx, d ) );
}
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}
}
std::sort( curMatches->begin(), curMatches->end() );
}
}
#endif
}
/*
* Flann based matcher
*/
FlannBasedMatcher::FlannBasedMatcher( const Ptr<flann::IndexParams>& _indexParams, const Ptr<flann::SearchParams>& _searchParams )
: indexParams(_indexParams), searchParams(_searchParams), addedDescCount(0)
{
CV_Assert( !_indexParams.empty() );
CV_Assert( !_searchParams.empty() );
}
void FlannBasedMatcher::add( const vector<Mat>& descriptors )
{
DescriptorMatcher::add( descriptors );
for( size_t i = 0; i < descriptors.size(); i++ )
{
addedDescCount += descriptors[i].rows;
}
}
void FlannBasedMatcher::clear()
{
DescriptorMatcher::clear();
mergedDescriptors.clear();
flannIndex.release();
addedDescCount = 0;
}
void FlannBasedMatcher::train()
{
if( flannIndex.empty() || mergedDescriptors.size() < addedDescCount )
{
mergedDescriptors.set( trainDescCollection );
flannIndex = new flann::Index( mergedDescriptors.getDescriptors(), *indexParams );
}
}
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bool FlannBasedMatcher::isMaskSupported() const
{
return false;
}
Ptr<DescriptorMatcher> FlannBasedMatcher::clone( bool emptyTrainData ) const
{
FlannBasedMatcher* matcher = new FlannBasedMatcher(indexParams, searchParams);
if( !emptyTrainData )
{
CV_Error( CV_StsNotImplemented, "deep clone functionality is not implemented, because "
"Flann::Index has not copy constructor or clone method ");
//matcher->flannIndex;
matcher->addedDescCount = addedDescCount;
matcher->mergedDescriptors = DescriptorCollection( mergedDescriptors );
transform( trainDescCollection.begin(), trainDescCollection.end(),
matcher->trainDescCollection.begin(), clone_op );
}
return matcher;
}
void FlannBasedMatcher::convertToDMatches( const DescriptorCollection& collection, const Mat& indices, const Mat& dists,
vector<vector<DMatch> >& matches )
{
matches.resize( indices.rows );
for( int i = 0; i < indices.rows; i++ )
{
for( int j = 0; j < indices.cols; j++ )
{
int idx = indices.at<int>(i, j);
if( idx >= 0 )
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{
int imgIdx, trainIdx;
collection.getLocalIdx( idx, imgIdx, trainIdx );
matches[i].push_back( DMatch( i, trainIdx, imgIdx, std::sqrt(dists.at<float>(i,j))) );
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}
}
}
}
void FlannBasedMatcher::knnMatchImpl( const Mat& queryDescriptors, vector<vector<DMatch> >& matches, int knn,
const vector<Mat>& /*masks*/, bool /*compactResult*/ )
{
Mat indices( queryDescriptors.rows, knn, CV_32SC1 );
Mat dists( queryDescriptors.rows, knn, CV_32FC1);
flannIndex->knnSearch( queryDescriptors, indices, dists, knn, *searchParams );
convertToDMatches( mergedDescriptors, indices, dists, matches );
}
void FlannBasedMatcher::radiusMatchImpl( const Mat& queryDescriptors, vector<vector<DMatch> >& matches, float maxDistance,
const vector<Mat>& /*masks*/, bool /*compactResult*/ )
{
const int count = mergedDescriptors.size(); // TODO do count as param?
Mat indices( queryDescriptors.rows, count, CV_32SC1, Scalar::all(-1) );
Mat dists( queryDescriptors.rows, count, CV_32FC1, Scalar::all(-1) );
for( int qIdx = 0; qIdx < queryDescriptors.rows; qIdx++ )
{
Mat queryDescriptorsRow = queryDescriptors.row(qIdx);
Mat indicesRow = indices.row(qIdx);
Mat distsRow = dists.row(qIdx);
flannIndex->radiusSearch( queryDescriptorsRow, indicesRow, distsRow, maxDistance*maxDistance, *searchParams );
}
convertToDMatches( mergedDescriptors, indices, dists, matches );
}
/*
* Factory function for DescriptorMatcher creating
*/
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Ptr<DescriptorMatcher> createDescriptorMatcher( const string& descriptorMatcherType )
{
DescriptorMatcher* dm = 0;
if( !descriptorMatcherType.compare( "BruteForce" ) )
{
dm = new BruteForceMatcher<L2<float> >();
}
else if( !descriptorMatcherType.compare( "BruteForce-L1" ) )
{
dm = new BruteForceMatcher<L1<float> >();
}
else if ( !descriptorMatcherType.compare( "FlannBased" ) )
{
dm = new FlannBasedMatcher();
}
else if (!descriptorMatcherType.compare("BruteForce-Hamming"))
{
dm = new BruteForceMatcher<Hamming> ();
}
else if (!descriptorMatcherType.compare("BruteForce-HammingLUT"))
{
dm = new BruteForceMatcher<HammingLUT> ();
}
else
{
//CV_Error( CV_StsBadArg, "unsupported descriptor matcher type");
}
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return dm;
}
/****************************************************************************************\
* GenericDescriptorMatcher *
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\****************************************************************************************/
/*
* KeyPointCollection
*/
GenericDescriptorMatcher::KeyPointCollection::KeyPointCollection() : pointCount(0)
{}
GenericDescriptorMatcher::KeyPointCollection::KeyPointCollection( const KeyPointCollection& collection )
{
pointCount = collection.pointCount;
transform( collection.images.begin(), collection.images.end(), images.begin(), clone_op );
keypoints.resize( collection.keypoints.size() );
for( size_t i = 0; i < keypoints.size(); i++ )
copy( collection.keypoints[i].begin(), collection.keypoints[i].end(), keypoints[i].begin() );
copy( collection.startIndices.begin(), collection.startIndices.end(), startIndices.begin() );
}
void GenericDescriptorMatcher::KeyPointCollection::add( const vector<Mat>& _images,
const vector<vector<KeyPoint> >& _points )
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{
CV_Assert( !_images.empty() );
CV_Assert( _images.size() == _points.size() );
images.insert( images.end(), _images.begin(), _images.end() );
keypoints.insert( keypoints.end(), _points.begin(), _points.end() );
for( size_t i = 0; i < _points.size(); i++ )
pointCount += _points[i].size();
size_t prevSize = startIndices.size(), addSize = _images.size();
startIndices.resize( prevSize + addSize );
if( prevSize == 0 )
startIndices[prevSize] = 0; //first
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else
startIndices[prevSize] = startIndices[prevSize-1] + keypoints[prevSize-1].size();
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for( size_t i = prevSize + 1; i < prevSize + addSize; i++ )
{
startIndices[i] = startIndices[i - 1] + keypoints[i - 1].size();
}
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}
void GenericDescriptorMatcher::KeyPointCollection::clear()
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{
keypoints.clear();
}
size_t GenericDescriptorMatcher::KeyPointCollection::keypointCount() const
{
return pointCount;
}
size_t GenericDescriptorMatcher::KeyPointCollection::imageCount() const
{
return images.size();
}
const vector<vector<KeyPoint> >& GenericDescriptorMatcher::KeyPointCollection::getKeypoints() const
{
return keypoints;
}
const vector<KeyPoint>& GenericDescriptorMatcher::KeyPointCollection::getKeypoints( int imgIdx ) const
{
CV_Assert( imgIdx < (int)imageCount() );
return keypoints[imgIdx];
}
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const KeyPoint& GenericDescriptorMatcher::KeyPointCollection::getKeyPoint( int imgIdx, int localPointIdx ) const
{
CV_Assert( imgIdx < (int)images.size() );
CV_Assert( localPointIdx < (int)keypoints[imgIdx].size() );
return keypoints[imgIdx][localPointIdx];
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}
const KeyPoint& GenericDescriptorMatcher::KeyPointCollection::getKeyPoint( int globalPointIdx ) const
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{
int imgIdx, localPointIdx;
getLocalIdx( globalPointIdx, imgIdx, localPointIdx );
return keypoints[imgIdx][localPointIdx];
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}
void GenericDescriptorMatcher::KeyPointCollection::getLocalIdx( int globalPointIdx, int& imgIdx, int& localPointIdx ) const
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{
imgIdx = -1;
CV_Assert( globalPointIdx < (int)keypointCount() );
for( size_t i = 1; i < startIndices.size(); i++ )
{
if( globalPointIdx < startIndices[i] )
{
imgIdx = i - 1;
break;
}
}
imgIdx = imgIdx == -1 ? startIndices.size() -1 : imgIdx;
localPointIdx = globalPointIdx - startIndices[imgIdx];
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}
const vector<Mat>& GenericDescriptorMatcher::KeyPointCollection::getImages() const
{
return images;
}
const Mat& GenericDescriptorMatcher::KeyPointCollection::getImage( int imgIdx ) const
{
CV_Assert( imgIdx < (int)imageCount() );
return images[imgIdx];
}
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/*
* GenericDescriptorMatcher
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*/
GenericDescriptorMatcher::GenericDescriptorMatcher()
{}
GenericDescriptorMatcher::~GenericDescriptorMatcher()
{}
void GenericDescriptorMatcher::add( const vector<Mat>& imgCollection,
vector<vector<KeyPoint> >& pointCollection )
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{
trainPointCollection.add( imgCollection, pointCollection );
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}
const vector<Mat>& GenericDescriptorMatcher::getTrainImages() const
{
return trainPointCollection.getImages();
}
const vector<vector<KeyPoint> >& GenericDescriptorMatcher::getTrainKeypoints() const
{
return trainPointCollection.getKeypoints();
}
void GenericDescriptorMatcher::clear()
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{
trainPointCollection.clear();
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}
void GenericDescriptorMatcher::train()
{}
void GenericDescriptorMatcher::classify( const Mat& queryImage, vector<KeyPoint>& queryPoints,
const Mat& trainImage, vector<KeyPoint>& trainPoints ) const
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{
vector<DMatch> matches;
match( queryImage, queryPoints, trainImage, trainPoints, matches );
// remap keypoint indices to descriptors
for( size_t i = 0; i < matches.size(); i++ )
queryPoints[matches[i].queryIdx].class_id = trainPoints[matches[i].trainIdx].class_id;
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}
void GenericDescriptorMatcher::classify( const Mat& queryImage, vector<KeyPoint>& queryPoints )
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{
vector<DMatch> matches;
match( queryImage, queryPoints, matches );
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// remap keypoint indices to descriptors
for( size_t i = 0; i < matches.size(); i++ )
queryPoints[matches[i].queryIdx].class_id = trainPointCollection.getKeyPoint( matches[i].trainIdx, matches[i].trainIdx ).class_id;
}
void GenericDescriptorMatcher::match( const Mat& queryImg, vector<KeyPoint>& queryPoints,
const Mat& trainImg, vector<KeyPoint>& trainPoints,
vector<DMatch>& matches, const Mat& mask ) const
{
Ptr<GenericDescriptorMatcher> tempMatcher = clone( true );
vector<vector<KeyPoint> > vecTrainPoints(1, trainPoints);
tempMatcher->add( vector<Mat>(1, trainImg), vecTrainPoints );
tempMatcher->match( queryImg, queryPoints, matches, vector<Mat>(1, mask) );
vecTrainPoints[0].swap( trainPoints );
}
void GenericDescriptorMatcher::knnMatch( const Mat& queryImg, vector<KeyPoint>& queryPoints,
const Mat& trainImg, vector<KeyPoint>& trainPoints,
vector<vector<DMatch> >& matches, int knn, const Mat& mask, bool compactResult ) const
{
Ptr<GenericDescriptorMatcher> tempMatcher = clone( true );
vector<vector<KeyPoint> > vecTrainPoints(1, trainPoints);
tempMatcher->add( vector<Mat>(1, trainImg), vecTrainPoints );
tempMatcher->knnMatch( queryImg, queryPoints, matches, knn, vector<Mat>(1, mask), compactResult );
vecTrainPoints[0].swap( trainPoints );
}
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void GenericDescriptorMatcher::radiusMatch( const Mat& queryImg, vector<KeyPoint>& queryPoints,
const Mat& trainImg, vector<KeyPoint>& trainPoints,
vector<vector<DMatch> >& matches, float maxDistance,
const Mat& mask, bool compactResult ) const
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{
Ptr<GenericDescriptorMatcher> tempMatcher = clone( true );
vector<vector<KeyPoint> > vecTrainPoints(1, trainPoints);
tempMatcher->add( vector<Mat>(1, trainImg), vecTrainPoints );
tempMatcher->radiusMatch( queryImg, queryPoints, matches, maxDistance, vector<Mat>(1, mask), compactResult );
vecTrainPoints[0].swap( trainPoints );
}
void GenericDescriptorMatcher::match( const Mat& queryImg, vector<KeyPoint>& queryPoints,
vector<DMatch>& matches, const vector<Mat>& masks )
{
vector<vector<DMatch> > knnMatches;
knnMatch( queryImg, queryPoints, knnMatches, 1, masks, false );
convertMatches( knnMatches, matches );
}
void GenericDescriptorMatcher::knnMatch( const Mat& queryImg, vector<KeyPoint>& queryPoints,
vector<vector<DMatch> >& matches, int knn,
const vector<Mat>& masks, bool compactResult )
{
train();
knnMatchImpl( queryImg, queryPoints, matches, knn, masks, compactResult );
}
void GenericDescriptorMatcher::radiusMatch( const Mat& queryImg, vector<KeyPoint>& queryPoints,
vector<vector<DMatch> >& matches, float maxDistance,
const vector<Mat>& masks, bool compactResult )
{
train();
radiusMatchImpl( queryImg, queryPoints, matches, maxDistance, masks, compactResult );
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}
void GenericDescriptorMatcher::read( const FileNode& )
{}
void GenericDescriptorMatcher::write( FileStorage& ) const
{}
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/****************************************************************************************\
* OneWayDescriptorMatcher *
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\****************************************************************************************/
OneWayDescriptorMatcher::Params::Params( int _poseCount, Size _patchSize, string _pcaFilename,
string _trainPath, string _trainImagesList,
float _minScale, float _maxScale, float _stepScale ) :
poseCount(_poseCount), patchSize(_patchSize), pcaFilename(_pcaFilename),
trainPath(_trainPath), trainImagesList(_trainImagesList),
minScale(_minScale), maxScale(_maxScale), stepScale(_stepScale)
{}
OneWayDescriptorMatcher::OneWayDescriptorMatcher( const Params& _params)
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{
initialize(_params);
}
OneWayDescriptorMatcher::~OneWayDescriptorMatcher()
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{}
void OneWayDescriptorMatcher::initialize( const Params& _params, const Ptr<OneWayDescriptorBase>& _base )
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{
clear();
if( _base.empty() )
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base = _base;
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params = _params;
}
void OneWayDescriptorMatcher::clear()
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{
GenericDescriptorMatcher::clear();
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prevTrainCount = 0;
base->clear();
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}
void OneWayDescriptorMatcher::train()
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{
if( base.empty() || prevTrainCount < (int)trainPointCollection.keypointCount() )
{
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base = new OneWayDescriptorObject( params.patchSize, params.poseCount, params.pcaFilename,
params.trainPath, params.trainImagesList, params.minScale, params.maxScale, params.stepScale );
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base->Allocate( trainPointCollection.keypointCount() );
prevTrainCount = trainPointCollection.keypointCount();
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const vector<vector<KeyPoint> >& points = trainPointCollection.getKeypoints();
int count = 0;
for( size_t i = 0; i < points.size(); i++ )
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{
IplImage _image = trainPointCollection.getImage(i);
for( size_t j = 0; j < points[i].size(); j++ )
base->InitializeDescriptor( count++, &_image, points[i][j], "" );
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}
#if defined(_KDTREE)
base->ConvertDescriptorsArrayToTree();
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#endif
}
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}
bool OneWayDescriptorMatcher::isMaskSupported()
{
return false;
}
void OneWayDescriptorMatcher::knnMatchImpl( const Mat& queryImg, vector<KeyPoint>& queryPoints,
vector<vector<DMatch> >& matches, int knn,
const vector<Mat>& /*masks*/, bool /*compactResult*/ )
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{
train();
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CV_Assert( knn == 1 ); // knn > 1 unsupported because of bug in OneWayDescriptorBase for this case
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matches.resize( queryPoints.size() );
IplImage _qimage = queryImg;
for( size_t i = 0; i < queryPoints.size(); i++ )
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{
int descIdx = -1, poseIdx = -1;
float distance;
base->FindDescriptor( &_qimage, queryPoints[i].pt, descIdx, poseIdx, distance );
matches[i].push_back( DMatch(i, descIdx, distance) );
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}
}
void OneWayDescriptorMatcher::radiusMatchImpl( const Mat& queryImg, vector<KeyPoint>& queryPoints,
vector<vector<DMatch> >& matches, float maxDistance,
const vector<Mat>& /*masks*/, bool /*compactResult*/ )
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{
train();
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matches.resize( queryPoints.size() );
IplImage _qimage = queryImg;
for( size_t i = 0; i < queryPoints.size(); i++ )
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{
int descIdx = -1, poseIdx = -1;
float distance;
base->FindDescriptor( &_qimage, queryPoints[i].pt, descIdx, poseIdx, distance );
if( distance < maxDistance )
matches[i].push_back( DMatch(i, descIdx, distance) );
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}
}
void OneWayDescriptorMatcher::read( const FileNode &fn )
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{
base = new OneWayDescriptorObject( params.patchSize, params.poseCount, string (), string (), string (),
params.minScale, params.maxScale, params.stepScale );
base->Read (fn);
}
void OneWayDescriptorMatcher::write( FileStorage& fs ) const
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{
base->Write (fs);
}
Ptr<GenericDescriptorMatcher> OneWayDescriptorMatcher::clone( bool emptyTrainData ) const
{
OneWayDescriptorMatcher* matcher = new OneWayDescriptorMatcher( params );
if( !emptyTrainData )
{
CV_Error( CV_StsNotImplemented, "deep clone dunctionality is not implemented, because "
"OneWayDescriptorBase has not copy constructor or clone method ");
//matcher->base;
matcher->params = params;
matcher->prevTrainCount = prevTrainCount;
matcher->trainPointCollection = trainPointCollection;
}
return matcher;
}
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/****************************************************************************************\
* FernDescriptorMatcher *
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\****************************************************************************************/
FernDescriptorMatcher::Params::Params( int _nclasses, int _patchSize, int _signatureSize,
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int _nstructs, int _structSize, int _nviews, int _compressionMethod,
const PatchGenerator& _patchGenerator ) :
nclasses(_nclasses), patchSize(_patchSize), signatureSize(_signatureSize),
nstructs(_nstructs), structSize(_structSize), nviews(_nviews),
compressionMethod(_compressionMethod), patchGenerator(_patchGenerator)
{}
FernDescriptorMatcher::Params::Params( const string& _filename )
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{
filename = _filename;
}
FernDescriptorMatcher::FernDescriptorMatcher( const Params& _params )
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{
prevTrainCount = 0;
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params = _params;
if( !params.filename.empty() )
{
classifier = new FernClassifier;
FileStorage fs(params.filename, FileStorage::READ);
if( fs.isOpened() )
classifier->read( fs.getFirstTopLevelNode() );
}
}
FernDescriptorMatcher::~FernDescriptorMatcher()
{}
void FernDescriptorMatcher::clear()
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{
GenericDescriptorMatcher::clear();
classifier.release();
prevTrainCount = 0;
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}
void FernDescriptorMatcher::train()
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{
if( classifier.empty() || prevTrainCount < (int)trainPointCollection.keypointCount() )
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{
assert( params.filename.empty() );
vector<vector<Point2f> > points( trainPointCollection.imageCount() );
for( size_t imgIdx = 0; imgIdx < trainPointCollection.imageCount(); imgIdx++ )
KeyPoint::convert( trainPointCollection.getKeypoints(imgIdx), points[imgIdx] );
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classifier = new FernClassifier( points, trainPointCollection.getImages(), vector<vector<int> >(), 0, // each points is a class
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params.patchSize, params.signatureSize, params.nstructs, params.structSize,
params.nviews, params.compressionMethod, params.patchGenerator );
}
}
bool FernDescriptorMatcher::isMaskSupported()
{
return false;
}
void FernDescriptorMatcher::calcBestProbAndMatchIdx( const Mat& image, const Point2f& pt,
float& bestProb, int& bestMatchIdx, vector<float>& signature )
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{
(*classifier)( image, pt, signature);
bestProb = -FLT_MAX;
bestMatchIdx = -1;
for( int ci = 0; ci < classifier->getClassCount(); ci++ )
{
if( signature[ci] > bestProb )
{
bestProb = signature[ci];
bestMatchIdx = ci;
}
}
}
void FernDescriptorMatcher::knnMatchImpl( const Mat& queryImg, vector<KeyPoint>& queryPoints,
vector<vector<DMatch> >& matches, int knn,
const vector<Mat>& /*masks*/, bool /*compactResult*/ )
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{
train();
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matches.resize( queryPoints.size() );
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vector<float> signature( (size_t)classifier->getClassCount() );
for( size_t queryIdx = 0; queryIdx < queryPoints.size(); queryIdx++ )
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{
(*classifier)( queryImg, queryPoints[queryIdx].pt, signature);
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for( int k = 0; k < knn; k++ )
{
DMatch bestMatch;
size_t ci = 0;
for( ; ci < signature.size(); ci++ )
{
if( -signature[ci] < bestMatch.distance )
{
int imgIdx = -1, trainIdx = -1;
trainPointCollection.getLocalIdx( ci , imgIdx, trainIdx );
bestMatch = DMatch( queryIdx, trainIdx, imgIdx, -signature[ci] );
}
}
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if( bestMatch.trainIdx == -1 )
break;
signature[ci] = std::numeric_limits<float>::min();
matches[queryIdx].push_back( bestMatch );
}
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}
}
void FernDescriptorMatcher::radiusMatchImpl( const Mat& queryImg, vector<KeyPoint>& queryPoints,
vector<vector<DMatch> >& matches, float maxDistance,
const vector<Mat>& /*masks*/, bool /*compactResult*/ )
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{
train();
matches.resize( queryPoints.size() );
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vector<float> signature( (size_t)classifier->getClassCount() );
for( size_t i = 0; i < queryPoints.size(); i++ )
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{
(*classifier)( queryImg, queryPoints[i].pt, signature);
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for( int ci = 0; ci < classifier->getClassCount(); ci++ )
{
if( -signature[ci] < maxDistance )
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{
int imgIdx = -1, trainIdx = -1;
trainPointCollection.getLocalIdx( ci , imgIdx, trainIdx );
matches[i].push_back( DMatch( i, trainIdx, imgIdx, -signature[ci] ) );
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}
}
}
}
void FernDescriptorMatcher::read( const FileNode &fn )
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{
params.nclasses = fn["nclasses"];
params.patchSize = fn["patchSize"];
params.signatureSize = fn["signatureSize"];
params.nstructs = fn["nstructs"];
params.structSize = fn["structSize"];
params.nviews = fn["nviews"];
params.compressionMethod = fn["compressionMethod"];
//classifier->read(fn);
}
void FernDescriptorMatcher::write( FileStorage& fs ) const
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{
fs << "nclasses" << params.nclasses;
fs << "patchSize" << params.patchSize;
fs << "signatureSize" << params.signatureSize;
fs << "nstructs" << params.nstructs;
fs << "structSize" << params.structSize;
fs << "nviews" << params.nviews;
fs << "compressionMethod" << params.compressionMethod;
// classifier->write(fs);
}
Ptr<GenericDescriptorMatcher> FernDescriptorMatcher::clone( bool emptyTrainData ) const
{
FernDescriptorMatcher* matcher = new FernDescriptorMatcher( params );
if( !emptyTrainData )
{
CV_Error( CV_StsNotImplemented, "deep clone dunctionality is not implemented, because "
"FernClassifier has not copy constructor or clone method ");
//matcher->classifier;
matcher->params = params;
matcher->prevTrainCount = prevTrainCount;
matcher->trainPointCollection = trainPointCollection;
}
return matcher;
}
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/****************************************************************************************\
* VectorDescriptorMatcher *
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\****************************************************************************************/
VectorDescriptorMatcher::VectorDescriptorMatcher( const Ptr<DescriptorExtractor>& _extractor,
const Ptr<DescriptorMatcher>& _matcher )
: extractor( _extractor ), matcher( _matcher )
{
CV_Assert( !extractor.empty() && !matcher.empty() );
}
VectorDescriptorMatcher::~VectorDescriptorMatcher()
{}
void VectorDescriptorMatcher::add( const vector<Mat>& imgCollection,
vector<vector<KeyPoint> >& pointCollection )
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{
vector<Mat> descriptors;
extractor->compute( imgCollection, pointCollection, descriptors );
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matcher->add( descriptors );
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trainPointCollection.add( imgCollection, pointCollection );
}
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void VectorDescriptorMatcher::clear()
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{
//extractor->clear();
matcher->clear();
GenericDescriptorMatcher::clear();
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}
void VectorDescriptorMatcher::train()
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{
matcher->train();
}
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bool VectorDescriptorMatcher::isMaskSupported()
{
return matcher->isMaskSupported();
}
void VectorDescriptorMatcher::knnMatchImpl( const Mat& queryImg, vector<KeyPoint>& queryPoints,
vector<vector<DMatch> >& matches, int knn,
const vector<Mat>& masks, bool compactResult )
{
Mat queryDescriptors;
extractor->compute( queryImg, queryPoints, queryDescriptors );
matcher->knnMatch( queryDescriptors, matches, knn, masks, compactResult );
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}
void VectorDescriptorMatcher::radiusMatchImpl( const Mat& queryImg, vector<KeyPoint>& queryPoints,
vector<vector<DMatch> >& matches, float maxDistance,
const vector<Mat>& masks, bool compactResult )
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{
Mat queryDescriptors;
extractor->compute( queryImg, queryPoints, queryDescriptors );
matcher->radiusMatch( queryDescriptors, matches, maxDistance, masks, compactResult );
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}
void VectorDescriptorMatcher::read( const FileNode& fn )
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{
GenericDescriptorMatcher::read(fn);
extractor->read(fn);
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}
void VectorDescriptorMatcher::write (FileStorage& fs) const
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{
GenericDescriptorMatcher::write(fs);
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extractor->write (fs);
}
Ptr<GenericDescriptorMatcher> VectorDescriptorMatcher::clone( bool emptyTrainData ) const
{
// TODO clone extractor
return new VectorDescriptorMatcher( extractor, matcher->clone(emptyTrainData) );
}
/*
* Factory function for GenericDescriptorMatch creating
*/
Ptr<GenericDescriptorMatcher> createGenericDescriptorMatcher( const string& genericDescritptorMatcherType, const string &paramsFilename )
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{
Ptr<GenericDescriptorMatcher> descriptorMatcher;
if( ! genericDescritptorMatcherType.compare("ONEWAY") )
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{
descriptorMatcher = new OneWayDescriptorMatcher();
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}
else if( ! genericDescritptorMatcherType.compare("FERN") )
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{
descriptorMatcher = new FernDescriptorMatcher();
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}
else if( ! genericDescritptorMatcherType.compare ("CALONDER") )
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{
//descriptorMatch = new CalonderDescriptorMatch ();
}
if( !paramsFilename.empty() && descriptorMatcher != 0 )
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{
FileStorage fs = FileStorage( paramsFilename, FileStorage::READ );
if( fs.isOpened() )
{
descriptorMatcher->read( fs.root() );
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fs.release();
}
}
return descriptorMatcher;
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}
}