opencv/samples/cpp/flann_search_dataset.cpp

// flann_search_dataset.cpp
// Naive program to search a query picture in a dataset illustrating usage of FLANN

#include <iostream>
#include <vector>
#include "opencv2/core.hpp"
#include "opencv2/core/utils/filesystem.hpp"
#include "opencv2/highgui.hpp"
#include "opencv2/features2d.hpp"
#include "opencv2/flann.hpp"

using namespace cv;
using std::cout;
using std::endl;

#define _ORB_

const char* keys =
    "{ help h | | Print help message. }"
    "{ dataset | | Path to the images folder used as dataset. }"
    "{ image |   | Path to the image to search for in the dataset. }"
    "{ save |    | Path and filename where to save the flann structure to. }"
    "{ load |    | Path and filename where to load the flann structure from. }";

struct img_info {
    int img_index;
    unsigned int nbr_of_matches;

    img_info(int _img_index, unsigned int _nbr_of_matches)
        : img_index(_img_index)
        , nbr_of_matches(_nbr_of_matches)
    {}
};


int main( int argc, char* argv[] )
{
    //-- Test the program options
    CommandLineParser parser( argc, argv, keys );
    if (parser.has("help"))
    {
        parser.printMessage();
        return -1;
    }

    const cv::String img_path = parser.get<String>("image");
    Mat img = imread( samples::findFile( img_path ), IMREAD_GRAYSCALE );
    if (img.empty() )
    {
        cout << "Could not open the image "<< img_path << endl;
        return -1;
    }

    const cv::String db_path = parser.get<String>("dataset");
    if (!utils::fs::isDirectory(db_path))
    {
        cout << "Dataset folder "<< db_path.c_str() <<" doesn't exist!" << endl;
        return -1;
    }

    const cv::String load_db_path = parser.get<String>("load");
    if ((load_db_path != String()) && (!utils::fs::exists(load_db_path)))
    {
        cout << "File " << load_db_path.c_str()
             << " where to load the flann structure from doesn't exist!" << endl;
        return -1;
    }

    const cv::String save_db_path = parser.get<String>("save");

    //-- Step 1: Detect the keypoints using a detector, compute the descriptors
    //   in the folder containing the images of the dataset
#ifdef _SIFT_
    int minHessian = 400;
    Ptr<Feature2D> detector = SIFT::create( minHessian );
#elif defined(_ORB_)
    Ptr<Feature2D> detector = ORB::create();
#else
    cout << "Missing or unknown defined descriptor. "
            "Only SIFT and ORB are currently interfaced here" << endl;
    return -1;
#endif

    std::vector<KeyPoint> db_keypoints;
    Mat db_descriptors;
    std::vector<unsigned int> db_images_indice_range; //store the range of indices per image
    std::vector<int> db_indice_2_image_lut;           //match descriptor indice to its image

    db_images_indice_range.push_back(0);
    std::vector<cv::String> files;
    utils::fs::glob(db_path, cv::String(), files);
    for (std::vector<cv::String>::iterator itr = files.begin(); itr != files.end(); ++itr)
    {
        Mat tmp_img = imread( *itr, IMREAD_GRAYSCALE );
        if (!tmp_img.empty())
        {
            std::vector<KeyPoint> kpts;
            Mat descriptors;
            detector->detectAndCompute( tmp_img, noArray(), kpts, descriptors );

            db_keypoints.insert( db_keypoints.end(), kpts.begin(), kpts.end() );
            db_descriptors.push_back( descriptors );
            db_images_indice_range.push_back( db_images_indice_range.back()
                                              + static_cast<unsigned int>(kpts.size()) );
        }
    }

    //-- Set the LUT
    db_indice_2_image_lut.resize( db_images_indice_range.back() );
    const int nbr_of_imgs = static_cast<int>( db_images_indice_range.size()-1 );
    for (int i = 0; i < nbr_of_imgs; ++i)
    {
        const unsigned int first_indice = db_images_indice_range[i];
        const unsigned int last_indice = db_images_indice_range[i+1];
        std::fill( db_indice_2_image_lut.begin() + first_indice,
                   db_indice_2_image_lut.begin() + last_indice,
                   i );
    }

    //-- Step 2: build the structure storing the descriptors
#if defined(_SIFT_)
    cv::Ptr<flann::GenericIndex<cvflann::L2<float> > > index;
    if (load_db_path != String())
        index = cv::makePtr<flann::GenericIndex<cvflann::L2<float> > >(db_descriptors,
                                                             cvflann::SavedIndexParams(load_db_path));
    else
        index = cv::makePtr<flann::GenericIndex<cvflann::L2<float> > >(db_descriptors,
                                                             cvflann::KDTreeIndexParams(4));

#elif defined(_ORB_)
    cv::Ptr<flann::GenericIndex<cvflann::Hamming<unsigned char> > > index;
    if (load_db_path != String())
        index  = cv::makePtr<flann::GenericIndex<cvflann::Hamming<unsigned char> > >
                (db_descriptors, cvflann::SavedIndexParams(load_db_path));
    else
        index  = cv::makePtr<flann::GenericIndex<cvflann::Hamming<unsigned char> > >
                (db_descriptors, cvflann::LshIndexParams());
#else
    cout<< "Descriptor not listed. Set the proper FLANN distance for this descriptor" <<endl;
    return -1;
#endif
    if (save_db_path != String())
        index->save(save_db_path);


    // Return if no query image was set
    if (img_path == String())
        return 0;

    //-- Detect the keypoints and compute the descriptors for the query image
    std::vector<KeyPoint> img_keypoints;
    Mat img_descriptors;
    detector->detectAndCompute( img, noArray(), img_keypoints, img_descriptors );


    //-- Step 3: retrieve the descriptors in the dataset matching the ones of the query image
    // /!\ knnSearch doesn't follow OpenCV standards by not initialising empty Mat properties
    const int knn = 2;
    Mat indices(img_descriptors.rows, knn, CV_32S);
#if defined(_SIFT_)
#define DIST_TYPE float
    Mat dists(img_descriptors.rows, knn, CV_32F);
#elif defined(_ORB_)
#define DIST_TYPE int
    Mat dists(img_descriptors.rows, knn, CV_32S);
#endif
    index->knnSearch( img_descriptors, indices, dists, knn, cvflann::SearchParams(32) );

    //-- Filter matches using the Lowe's ratio test
    const float ratio_thresh = 0.7f;
    std::vector<DMatch> good_matches; //contains
    std::vector<unsigned int> matches_per_img_histogram( nbr_of_imgs, 0 );
    for (int i = 0; i < dists.rows; ++i)
    {
        if (dists.at<DIST_TYPE>(i,0) < ratio_thresh * dists.at<DIST_TYPE>(i,1))
        {
            const int indice_in_db = indices.at<int>(i,0);
            DMatch dmatch(i, indice_in_db, db_indice_2_image_lut[indice_in_db],
                          static_cast<float>(dists.at<DIST_TYPE>(i,0)));
            good_matches.push_back( dmatch );
            matches_per_img_histogram[ db_indice_2_image_lut[indice_in_db] ]++;
        }
    }


    //-- Step 4: find the dataset image with the highest proportion of matches
    std::multimap<float, img_info> images_infos;
    for (int i = 0; i < nbr_of_imgs; ++i)
    {
        const unsigned int nbr_of_matches = matches_per_img_histogram[i];
        if (nbr_of_matches < 4) //we need at leat 4 points for a homography
            continue;

        const unsigned int nbr_of_kpts = db_images_indice_range[i+1] - db_images_indice_range[i];
        const float inverse_proportion_of_retrieved_kpts =
                static_cast<float>(nbr_of_kpts) / static_cast<float>(nbr_of_matches);

        img_info info(i, nbr_of_matches);
        images_infos.insert( std::pair<float,img_info>(inverse_proportion_of_retrieved_kpts,
                                                       info) );
    }

    if (images_infos.begin() == images_infos.end())
    {
        cout<<"No good match could be found."<<endl;
        return 0;
    }

    //-- if there are several images with a similar proportion of matches,
    // select the one with the highest number of matches weighted by the
    // squared ratio of proportions
    const float best_matches_proportion = images_infos.begin()->first;
    float new_matches_proportion = best_matches_proportion;
    img_info best_img = images_infos.begin()->second;

    std::multimap<float, img_info>::iterator it = images_infos.begin();
    ++it;
    while ((it!=images_infos.end()) && (it->first < 1.1*best_matches_proportion))
    {
        const float ratio = new_matches_proportion / it->first;
        if( it->second.nbr_of_matches * (ratio * ratio) > best_img.nbr_of_matches)
        {
            new_matches_proportion = it->first;
            best_img = it->second;
        }
        ++it;
    }

    //-- Step 5: filter goodmatches that belong to the best image match of the dataset
    std::vector<DMatch> filtered_good_matches;
    for (std::vector<DMatch>::iterator itr(good_matches.begin()); itr != good_matches.end(); ++itr)
    {
        if (itr->imgIdx == best_img.img_index)
            filtered_good_matches.push_back(*itr);
    }

    //-- Retrieve the best image match from the dataset
    Mat db_img = imread( files[best_img.img_index], IMREAD_GRAYSCALE );

    //-- Draw matches
    Mat img_matches;
    drawMatches( img, img_keypoints, db_img, db_keypoints, filtered_good_matches, img_matches, Scalar::all(-1),
                 Scalar::all(-1), std::vector<char>(), DrawMatchesFlags::NOT_DRAW_SINGLE_POINTS );

    //-- Show detected matches
    imshow("Good Matches", img_matches );
    waitKey();

    return 0;
}
Merge pull request #17643 from pemmanuelviel:pev--new-flann-demo * Add a FLANN example showing how to search a query image in a dataset * Clean: remove warning * Replace dependency to boost::filesystem by calls to core/utils/filesystem * Wait for escape key to exit * Add an example of binary descriptors support * Add program options for saving and loading the flann structure * Fix warnings on Win64 * Fix warnings on 3.4 branch still relying on C++03 * Add ctor to img_info structure * Comments modification * * Demo file of FLANN moved and renamed * Fix distances type when using binary vectors in the FLANN example * Rename FLANN example file * Remove dependency of the flann example to opencv_contrib's SURF. * Remove mention of FLANN and other descriptors that aimed at giving hint on the other options * Cleaner program options management * Make waitKey usage minimal in FLANN example * Fix the conditions order * Use cv::Ptr 4 years ago			`// flann_search_dataset.cpp`
			`// Naive program to search a query picture in a dataset illustrating usage of FLANN`

			`#include <iostream>`
			`#include <vector>`
			`#include "opencv2/core.hpp"`
			`#include "opencv2/core/utils/filesystem.hpp"`
			`#include "opencv2/highgui.hpp"`
			`#include "opencv2/features2d.hpp"`
			`#include "opencv2/flann.hpp"`

			`using namespace cv;`
			`using std::cout;`
			`using std::endl;`

			`#define _ORB_`

			`const char* keys =`
			`"{ help h \| \| Print help message. }"`
			`"{ dataset \| \| Path to the images folder used as dataset. }"`
			`"{ image \| \| Path to the image to search for in the dataset. }"`
			`"{ save \| \| Path and filename where to save the flann structure to. }"`
			`"{ load \| \| Path and filename where to load the flann structure from. }";`

			`struct img_info {`
			`int img_index;`
			`unsigned int nbr_of_matches;`

			`img_info(int _img_index, unsigned int _nbr_of_matches)`
			`: img_index(_img_index)`
			`, nbr_of_matches(_nbr_of_matches)`
			`{}`
			`};`


			`int main( int argc, char* argv[] )`
			`{`
			`//-- Test the program options`
			`CommandLineParser parser( argc, argv, keys );`
			`if (parser.has("help"))`
			`{`
			`parser.printMessage();`
			`return -1;`
			`}`

			`const cv::String img_path = parser.get<String>("image");`
			`Mat img = imread( samples::findFile( img_path ), IMREAD_GRAYSCALE );`
			`if (img.empty() )`
			`{`
			`cout << "Could not open the image "<< img_path << endl;`
			`return -1;`
			`}`

			`const cv::String db_path = parser.get<String>("dataset");`
			`if (!utils::fs::isDirectory(db_path))`
			`{`
			`cout << "Dataset folder "<< db_path.c_str() <<" doesn't exist!" << endl;`
			`return -1;`
			`}`

			`const cv::String load_db_path = parser.get<String>("load");`
			`if ((load_db_path != String()) && (!utils::fs::exists(load_db_path)))`
			`{`
			`cout << "File " << load_db_path.c_str()`
			`<< " where to load the flann structure from doesn't exist!" << endl;`
			`return -1;`
			`}`

			`const cv::String save_db_path = parser.get<String>("save");`

			`//-- Step 1: Detect the keypoints using a detector, compute the descriptors`
			`// in the folder containing the images of the dataset`
			`#ifdef _SIFT_`
			`int minHessian = 400;`
			`Ptr<Feature2D> detector = SIFT::create( minHessian );`
			`#elif defined(_ORB_)`
			`Ptr<Feature2D> detector = ORB::create();`
			`#else`
			`cout << "Missing or unknown defined descriptor. "`
			`"Only SIFT and ORB are currently interfaced here" << endl;`
			`return -1;`
			`#endif`

			`std::vector<KeyPoint> db_keypoints;`
			`Mat db_descriptors;`
			`std::vector<unsigned int> db_images_indice_range; //store the range of indices per image`
			`std::vector<int> db_indice_2_image_lut; //match descriptor indice to its image`

			`db_images_indice_range.push_back(0);`
			`std::vector<cv::String> files;`
			`utils::fs::glob(db_path, cv::String(), files);`
			`for (std::vector<cv::String>::iterator itr = files.begin(); itr != files.end(); ++itr)`
			`{`
			`Mat tmp_img = imread( *itr, IMREAD_GRAYSCALE );`
			`if (!tmp_img.empty())`
			`{`
			`std::vector<KeyPoint> kpts;`
			`Mat descriptors;`
			`detector->detectAndCompute( tmp_img, noArray(), kpts, descriptors );`

			`db_keypoints.insert( db_keypoints.end(), kpts.begin(), kpts.end() );`
			`db_descriptors.push_back( descriptors );`
			`db_images_indice_range.push_back( db_images_indice_range.back()`
			`+ static_cast<unsigned int>(kpts.size()) );`
			`}`
			`}`

			`//-- Set the LUT`
			`db_indice_2_image_lut.resize( db_images_indice_range.back() );`
			`const int nbr_of_imgs = static_cast<int>( db_images_indice_range.size()-1 );`
			`for (int i = 0; i < nbr_of_imgs; ++i)`
			`{`
			`const unsigned int first_indice = db_images_indice_range[i];`
			`const unsigned int last_indice = db_images_indice_range[i+1];`
			`std::fill( db_indice_2_image_lut.begin() + first_indice,`
			`db_indice_2_image_lut.begin() + last_indice,`
			`i );`
			`}`

			`//-- Step 2: build the structure storing the descriptors`
			`#if defined(_SIFT_)`
			`cv::Ptr<flann::GenericIndex<cvflann::L2<float> > > index;`
			`if (load_db_path != String())`
			`index = cv::makePtr<flann::GenericIndex<cvflann::L2<float> > >(db_descriptors,`
			`cvflann::SavedIndexParams(load_db_path));`
			`else`
			`index = cv::makePtr<flann::GenericIndex<cvflann::L2<float> > >(db_descriptors,`
			`cvflann::KDTreeIndexParams(4));`

			`#elif defined(_ORB_)`
			`cv::Ptr<flann::GenericIndex<cvflann::Hamming<unsigned char> > > index;`
			`if (load_db_path != String())`
			`index = cv::makePtr<flann::GenericIndex<cvflann::Hamming<unsigned char> > >`
			`(db_descriptors, cvflann::SavedIndexParams(load_db_path));`
			`else`
			`index = cv::makePtr<flann::GenericIndex<cvflann::Hamming<unsigned char> > >`
			`(db_descriptors, cvflann::LshIndexParams());`
			`#else`
			`cout<< "Descriptor not listed. Set the proper FLANN distance for this descriptor" <<endl;`
			`return -1;`
			`#endif`
			`if (save_db_path != String())`
			`index->save(save_db_path);`


			`// Return if no query image was set`
			`if (img_path == String())`
			`return 0;`

			`//-- Detect the keypoints and compute the descriptors for the query image`
			`std::vector<KeyPoint> img_keypoints;`
			`Mat img_descriptors;`
			`detector->detectAndCompute( img, noArray(), img_keypoints, img_descriptors );`


			`//-- Step 3: retrieve the descriptors in the dataset matching the ones of the query image`
			`// /!\ knnSearch doesn't follow OpenCV standards by not initialising empty Mat properties`
			`const int knn = 2;`
			`Mat indices(img_descriptors.rows, knn, CV_32S);`
			`#if defined(_SIFT_)`
			`#define DIST_TYPE float`
			`Mat dists(img_descriptors.rows, knn, CV_32F);`
			`#elif defined(_ORB_)`
			`#define DIST_TYPE int`
			`Mat dists(img_descriptors.rows, knn, CV_32S);`
			`#endif`
			`index->knnSearch( img_descriptors, indices, dists, knn, cvflann::SearchParams(32) );`

			`//-- Filter matches using the Lowe's ratio test`
			`const float ratio_thresh = 0.7f;`
			`std::vector<DMatch> good_matches; //contains`
			`std::vector<unsigned int> matches_per_img_histogram( nbr_of_imgs, 0 );`
			`for (int i = 0; i < dists.rows; ++i)`
			`{`
			`if (dists.at<DIST_TYPE>(i,0) < ratio_thresh * dists.at<DIST_TYPE>(i,1))`
			`{`
			`const int indice_in_db = indices.at<int>(i,0);`
			`DMatch dmatch(i, indice_in_db, db_indice_2_image_lut[indice_in_db],`
			`static_cast<float>(dists.at<DIST_TYPE>(i,0)));`
			`good_matches.push_back( dmatch );`
			`matches_per_img_histogram[ db_indice_2_image_lut[indice_in_db] ]++;`
			`}`
			`}`


			`//-- Step 4: find the dataset image with the highest proportion of matches`
			`std::multimap<float, img_info> images_infos;`
			`for (int i = 0; i < nbr_of_imgs; ++i)`
			`{`
			`const unsigned int nbr_of_matches = matches_per_img_histogram[i];`
			`if (nbr_of_matches < 4) //we need at leat 4 points for a homography`
			`continue;`

			`const unsigned int nbr_of_kpts = db_images_indice_range[i+1] - db_images_indice_range[i];`
			`const float inverse_proportion_of_retrieved_kpts =`
			`static_cast<float>(nbr_of_kpts) / static_cast<float>(nbr_of_matches);`

			`img_info info(i, nbr_of_matches);`
			`images_infos.insert( std::pair<float,img_info>(inverse_proportion_of_retrieved_kpts,`
			`info) );`
			`}`

			`if (images_infos.begin() == images_infos.end())`
			`{`
			`cout<<"No good match could be found."<<endl;`
			`return 0;`
			`}`

			`//-- if there are several images with a similar proportion of matches,`
			`// select the one with the highest number of matches weighted by the`
			`// squared ratio of proportions`
			`const float best_matches_proportion = images_infos.begin()->first;`
			`float new_matches_proportion = best_matches_proportion;`
			`img_info best_img = images_infos.begin()->second;`

			`std::multimap<float, img_info>::iterator it = images_infos.begin();`
			`++it;`
			`while ((it!=images_infos.end()) && (it->first < 1.1*best_matches_proportion))`
			`{`
			`const float ratio = new_matches_proportion / it->first;`
			`if( it->second.nbr_of_matches * (ratio * ratio) > best_img.nbr_of_matches)`
			`{`
			`new_matches_proportion = it->first;`
			`best_img = it->second;`
			`}`
			`++it;`
			`}`

			`//-- Step 5: filter goodmatches that belong to the best image match of the dataset`
			`std::vector<DMatch> filtered_good_matches;`
			`for (std::vector<DMatch>::iterator itr(good_matches.begin()); itr != good_matches.end(); ++itr)`
			`{`
			`if (itr->imgIdx == best_img.img_index)`
			`filtered_good_matches.push_back(*itr);`
			`}`

			`//-- Retrieve the best image match from the dataset`
			`Mat db_img = imread( files[best_img.img_index], IMREAD_GRAYSCALE );`

			`//-- Draw matches`
			`Mat img_matches;`
			`drawMatches( img, img_keypoints, db_img, db_keypoints, filtered_good_matches, img_matches, Scalar::all(-1),`
			`Scalar::all(-1), std::vector<char>(), DrawMatchesFlags::NOT_DRAW_SINGLE_POINTS );`

			`//-- Show detected matches`
			`imshow("Good Matches", img_matches );`
			`waitKey();`

			`return 0;`
			`}`