/*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. // // // License Agreement // For Open Source Computer Vision Library // // Copyright (C) 2000-2008, Intel Corporation, all rights reserved. // Copyright (C) 2009, Willow Garage Inc., all rights reserved. // Copyright (C) 2015, Itseez Inc., 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 the copyright holders 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 "test_precomp.hpp" namespace opencv_test { namespace { #define CALIB3D_HOMOGRAPHY_ERROR_MATRIX_SIZE 1 #define CALIB3D_HOMOGRAPHY_ERROR_MATRIX_DIFF 2 #define CALIB3D_HOMOGRAPHY_ERROR_REPROJ_DIFF 3 #define CALIB3D_HOMOGRAPHY_ERROR_RANSAC_MASK 4 #define CALIB3D_HOMOGRAPHY_ERROR_RANSAC_DIFF 5 #define MESSAGE_MATRIX_SIZE "Homography matrix must have 3*3 sizes." #define MESSAGE_MATRIX_DIFF "Accuracy of homography transformation matrix less than required." #define MESSAGE_REPROJ_DIFF_1 "Reprojection error for current pair of points more than required." #define MESSAGE_REPROJ_DIFF_2 "Reprojection error is not optimal." #define MESSAGE_RANSAC_MASK_1 "Sizes of inliers/outliers mask are incorrect." #define MESSAGE_RANSAC_MASK_2 "Mask mustn't have any outliers." #define MESSAGE_RANSAC_MASK_3 "All values of mask must be 1 (true) or 0 (false)." #define MESSAGE_RANSAC_MASK_4 "Mask of inliers/outliers is incorrect." #define MESSAGE_RANSAC_MASK_5 "Inlier in original mask shouldn't be outlier in found mask." #define MESSAGE_RANSAC_DIFF "Reprojection error for current pair of points more than required." #define MAX_COUNT_OF_POINTS 303 #define MIN_COUNT_OF_POINTS 4 #define COUNT_NORM_TYPES 3 #define METHODS_COUNT 4 int NORM_TYPE[COUNT_NORM_TYPES] = {cv::NORM_L1, cv::NORM_L2, cv::NORM_INF}; int METHOD[METHODS_COUNT] = {0, cv::RANSAC, cv::LMEDS, cv::RHO}; using namespace cv; using namespace std; namespace HomographyTestUtils { static const float max_diff = 0.032f; static const float max_2diff = 0.020f; static const int image_size = 100; static const double reproj_threshold = 3.0; static const double sigma = 0.01; static bool check_matrix_size(const cv::Mat& H) { return (H.rows == 3) && (H.cols == 3); } static bool check_matrix_diff(const cv::Mat& original, const cv::Mat& found, const int norm_type, double &diff) { diff = cvtest::norm(original, found, norm_type); return diff <= max_diff; } static int check_ransac_mask_1(const Mat& src, const Mat& mask) { if (!(mask.cols == 1) && (mask.rows == src.cols)) return 1; if (countNonZero(mask) < mask.rows) return 2; for (int i = 0; i < mask.rows; ++i) if (mask.at(i, 0) > 1) return 3; return 0; } static int check_ransac_mask_2(const Mat& original_mask, const Mat& found_mask) { if (!(found_mask.cols == 1) && (found_mask.rows == original_mask.rows)) return 1; for (int i = 0; i < found_mask.rows; ++i) if (found_mask.at(i, 0) > 1) return 2; return 0; } static void print_information_1(int j, int N, int _method, const Mat& H) { cout << endl; cout << "Checking for homography matrix sizes..." << endl; cout << endl; cout << "Type of srcPoints: "; if ((j>-1) && (j<2)) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << " Type of dstPoints: "; if (j % 2 == 0) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << endl; cout << "Count of points: " << N << endl; cout << endl; cout << "Method: "; if (_method == 0) cout << 0; else if (_method == 8) cout << "RANSAC"; else if (_method == cv::RHO) cout << "RHO"; else cout << "LMEDS"; cout << endl; cout << "Homography matrix:" << endl; cout << endl; cout << H << endl; cout << endl; cout << "Number of rows: " << H.rows << " Number of cols: " << H.cols << endl; cout << endl; } static void print_information_2(int j, int N, int _method, const Mat& H, const Mat& H_res, int k, double diff) { cout << endl; cout << "Checking for accuracy of homography matrix computing..." << endl; cout << endl; cout << "Type of srcPoints: "; if ((j>-1) && (j<2)) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << " Type of dstPoints: "; if (j % 2 == 0) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << endl; cout << "Count of points: " << N << endl; cout << endl; cout << "Method: "; if (_method == 0) cout << 0; else if (_method == 8) cout << "RANSAC"; else if (_method == cv::RHO) cout << "RHO"; else cout << "LMEDS"; cout << endl; cout << "Original matrix:" << endl; cout << endl; cout << H << endl; cout << endl; cout << "Found matrix:" << endl; cout << endl; cout << H_res << endl; cout << endl; cout << "Norm type using in criteria: "; if (NORM_TYPE[k] == 1) cout << "INF"; else if (NORM_TYPE[k] == 2) cout << "L1"; else cout << "L2"; cout << endl; cout << "Difference between matrices: " << diff << endl; cout << "Maximum allowed difference: " << max_diff << endl; cout << endl; } static void print_information_3(int _method, int j, int N, const Mat& mask) { cout << endl; cout << "Checking for inliers/outliers mask..." << endl; cout << endl; cout << "Type of srcPoints: "; if ((j>-1) && (j<2)) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << " Type of dstPoints: "; if (j % 2 == 0) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << endl; cout << "Count of points: " << N << endl; cout << endl; cout << "Method: "; if (_method == RANSAC) cout << "RANSAC" << endl; else if (_method == cv::RHO) cout << "RHO" << endl; else cout << _method << endl; cout << "Found mask:" << endl; cout << endl; cout << mask << endl; cout << endl; cout << "Number of rows: " << mask.rows << " Number of cols: " << mask.cols << endl; cout << endl; } static void print_information_4(int _method, int j, int N, int k, int l, double diff) { cout << endl; cout << "Checking for accuracy of reprojection error computing..." << endl; cout << endl; cout << "Method: "; if (_method == 0) cout << 0 << endl; else cout << "CV_LMEDS" << endl; cout << "Type of srcPoints: "; if ((j>-1) && (j<2)) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << " Type of dstPoints: "; if (j % 2 == 0) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << endl; cout << "Sigma of normal noise: " << sigma << endl; cout << "Count of points: " << N << endl; cout << "Number of point: " << k << endl; cout << "Norm type using in criteria: "; if (NORM_TYPE[l] == 1) cout << "INF"; else if (NORM_TYPE[l] == 2) cout << "L1"; else cout << "L2"; cout << endl; cout << "Difference with noise of point: " << diff << endl; cout << "Maximum allowed difference: " << max_2diff << endl; cout << endl; } static void print_information_5(int _method, int j, int N, int l, double diff) { cout << endl; cout << "Checking for accuracy of reprojection error computing..." << endl; cout << endl; cout << "Method: "; if (_method == 0) cout << 0 << endl; else cout << "CV_LMEDS" << endl; cout << "Type of srcPoints: "; if ((j>-1) && (j<2)) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << " Type of dstPoints: "; if (j % 2 == 0) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << endl; cout << "Sigma of normal noise: " << sigma << endl; cout << "Count of points: " << N << endl; cout << "Norm type using in criteria: "; if (NORM_TYPE[l] == 1) cout << "INF"; else if (NORM_TYPE[l] == 2) cout << "L1"; else cout << "L2"; cout << endl; cout << "Difference with noise of points: " << diff << endl; cout << "Maximum allowed difference: " << max_diff << endl; cout << endl; } static void print_information_6(int _method, int j, int N, int k, double diff, bool value) { cout << endl; cout << "Checking for inliers/outliers mask..." << endl; cout << endl; cout << "Method: "; if (_method == RANSAC) cout << "RANSAC" << endl; else if (_method == cv::RHO) cout << "RHO" << endl; else cout << _method << endl; cout << "Type of srcPoints: "; if ((j>-1) && (j<2)) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << " Type of dstPoints: "; if (j % 2 == 0) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << endl; cout << "Count of points: " << N << " " << endl; cout << "Number of point: " << k << " " << endl; cout << "Reprojection error for this point: " << diff << " " << endl; cout << "Reprojection error threshold: " << reproj_threshold << " " << endl; cout << "Value of found mask: "<< value << endl; cout << endl; } static void print_information_7(int _method, int j, int N, int k, double diff, bool original_value, bool found_value) { cout << endl; cout << "Checking for inliers/outliers mask..." << endl; cout << endl; cout << "Method: "; if (_method == RANSAC) cout << "RANSAC" << endl; else if (_method == cv::RHO) cout << "RHO" << endl; else cout << _method << endl; cout << "Type of srcPoints: "; if ((j>-1) && (j<2)) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << " Type of dstPoints: "; if (j % 2 == 0) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << endl; cout << "Count of points: " << N << " " << endl; cout << "Number of point: " << k << " " << endl; cout << "Reprojection error for this point: " << diff << " " << endl; cout << "Reprojection error threshold: " << reproj_threshold << " " << endl; cout << "Value of original mask: "<< original_value << " Value of found mask: " << found_value << endl; cout << endl; } static void print_information_8(int _method, int j, int N, int k, int l, double diff) { cout << endl; cout << "Checking for reprojection error of inlier..." << endl; cout << endl; cout << "Method: "; if (_method == RANSAC) cout << "RANSAC" << endl; else if (_method == cv::RHO) cout << "RHO" << endl; else cout << _method << endl; cout << "Sigma of normal noise: " << sigma << endl; cout << "Type of srcPoints: "; if ((j>-1) && (j<2)) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << " Type of dstPoints: "; if (j % 2 == 0) cout << "Mat of CV_32FC2"; else cout << "vector "; cout << endl; cout << "Count of points: " << N << " " << endl; cout << "Number of point: " << k << " " << endl; cout << "Norm type using in criteria: "; if (NORM_TYPE[l] == 1) cout << "INF"; else if (NORM_TYPE[l] == 2) cout << "L1"; else cout << "L2"; cout << endl; cout << "Difference with noise of point: " << diff << endl; cout << "Maximum allowed difference: " << max_2diff << endl; cout << endl; } } // HomographyTestUtils:: TEST(Calib3d_Homography, accuracy) { using namespace HomographyTestUtils; for (int N = MIN_COUNT_OF_POINTS; N <= MAX_COUNT_OF_POINTS; ++N) { RNG& rng = cv::theRNG(); float *src_data = new float [2*N]; for (int i = 0; i < N; ++i) { src_data[2*i] = (float)cvtest::randReal(rng)*image_size; src_data[2*i+1] = (float)cvtest::randReal(rng)*image_size; } cv::Mat src_mat_2f(1, N, CV_32FC2, src_data), src_mat_2d(2, N, CV_32F, src_data), src_mat_3d(3, N, CV_32F); cv::Mat dst_mat_2f, dst_mat_2d, dst_mat_3d; vector src_vec, dst_vec; for (int i = 0; i < N; ++i) { float *tmp = src_mat_2d.ptr()+2*i; src_mat_3d.at(0, i) = tmp[0]; src_mat_3d.at(1, i) = tmp[1]; src_mat_3d.at(2, i) = 1.0f; src_vec.push_back(Point2f(tmp[0], tmp[1])); } double fi = cvtest::randReal(rng)*2*CV_PI; double t_x = cvtest::randReal(rng)*sqrt(image_size*1.0), t_y = cvtest::randReal(rng)*sqrt(image_size*1.0); double Hdata[9] = { cos(fi), -sin(fi), t_x, sin(fi), cos(fi), t_y, 0.0f, 0.0f, 1.0f }; cv::Mat H_64(3, 3, CV_64F, Hdata), H_32; H_64.convertTo(H_32, CV_32F); dst_mat_3d = H_32*src_mat_3d; dst_mat_2d.create(2, N, CV_32F); dst_mat_2f.create(1, N, CV_32FC2); for (int i = 0; i < N; ++i) { float *tmp_2f = dst_mat_2f.ptr()+2*i; tmp_2f[0] = dst_mat_2d.at(0, i) = dst_mat_3d.at(0, i) /= dst_mat_3d.at(2, i); tmp_2f[1] = dst_mat_2d.at(1, i) = dst_mat_3d.at(1, i) /= dst_mat_3d.at(2, i); dst_mat_3d.at(2, i) = 1.0f; dst_vec.push_back(Point2f(tmp_2f[0], tmp_2f[1])); } for (int i = 0; i < METHODS_COUNT; ++i) { const int method = METHOD[i]; switch (method) { case 0: case LMEDS: { Mat H_res_64 [4] = { cv::findHomography(src_mat_2f, dst_mat_2f, method), cv::findHomography(src_mat_2f, dst_vec, method), cv::findHomography(src_vec, dst_mat_2f, method), cv::findHomography(src_vec, dst_vec, method) }; for (int j = 0; j < 4; ++j) { if (!check_matrix_size(H_res_64[j])) { print_information_1(j, N, method, H_res_64[j]); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_MATRIX_SIZE, MESSAGE_MATRIX_SIZE); return; } double diff; for (int k = 0; k < COUNT_NORM_TYPES; ++k) if (!check_matrix_diff(H_64, H_res_64[j], NORM_TYPE[k], diff)) { print_information_2(j, N, method, H_64, H_res_64[j], k, diff); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_MATRIX_DIFF, MESSAGE_MATRIX_DIFF); return; } } continue; } case cv::RHO: case RANSAC: { cv::Mat mask [4]; double diff; Mat H_res_64 [4] = { cv::findHomography(src_mat_2f, dst_mat_2f, method, reproj_threshold, mask[0]), cv::findHomography(src_mat_2f, dst_vec, method, reproj_threshold, mask[1]), cv::findHomography(src_vec, dst_mat_2f, method, reproj_threshold, mask[2]), cv::findHomography(src_vec, dst_vec, method, reproj_threshold, mask[3]) }; for (int j = 0; j < 4; ++j) { if (!check_matrix_size(H_res_64[j])) { print_information_1(j, N, method, H_res_64[j]); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_MATRIX_SIZE, MESSAGE_MATRIX_SIZE); return; } for (int k = 0; k < COUNT_NORM_TYPES; ++k) if (!check_matrix_diff(H_64, H_res_64[j], NORM_TYPE[k], diff)) { print_information_2(j, N, method, H_64, H_res_64[j], k, diff); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_MATRIX_DIFF, MESSAGE_MATRIX_DIFF); return; } int code = check_ransac_mask_1(src_mat_2f, mask[j]); if (code) { print_information_3(method, j, N, mask[j]); switch (code) { case 1: { CV_Error(CALIB3D_HOMOGRAPHY_ERROR_RANSAC_MASK, MESSAGE_RANSAC_MASK_1); break; } case 2: { CV_Error(CALIB3D_HOMOGRAPHY_ERROR_RANSAC_MASK, MESSAGE_RANSAC_MASK_2); break; } case 3: { CV_Error(CALIB3D_HOMOGRAPHY_ERROR_RANSAC_MASK, MESSAGE_RANSAC_MASK_3); break; } default: break; } return; } } continue; } default: continue; } } Mat noise_2f(1, N, CV_32FC2); rng.fill(noise_2f, RNG::NORMAL, Scalar::all(0), Scalar::all(sigma)); cv::Mat mask(N, 1, CV_8UC1); for (int i = 0; i < N; ++i) { float *a = noise_2f.ptr()+2*i, *_2f = dst_mat_2f.ptr()+2*i; _2f[0] += a[0]; _2f[1] += a[1]; mask.at(i, 0) = !(sqrt(a[0]*a[0]+a[1]*a[1]) > reproj_threshold); } for (int i = 0; i < METHODS_COUNT; ++i) { const int method = METHOD[i]; switch (method) { case 0: case LMEDS: { Mat H_res_64 [4] = { cv::findHomography(src_mat_2f, dst_mat_2f), cv::findHomography(src_mat_2f, dst_vec), cv::findHomography(src_vec, dst_mat_2f), cv::findHomography(src_vec, dst_vec) }; for (int j = 0; j < 4; ++j) { if (!check_matrix_size(H_res_64[j])) { print_information_1(j, N, method, H_res_64[j]); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_MATRIX_SIZE, MESSAGE_MATRIX_SIZE); return; } Mat H_res_32; H_res_64[j].convertTo(H_res_32, CV_32F); cv::Mat dst_res_3d(3, N, CV_32F), noise_2d(2, N, CV_32F); for (int k = 0; k < N; ++k) { Mat tmp_mat_3d = H_res_32*src_mat_3d.col(k); dst_res_3d.at(0, k) = tmp_mat_3d.at(0, 0) /= tmp_mat_3d.at(2, 0); dst_res_3d.at(1, k) = tmp_mat_3d.at(1, 0) /= tmp_mat_3d.at(2, 0); dst_res_3d.at(2, k) = tmp_mat_3d.at(2, 0) = 1.0f; float *a = noise_2f.ptr()+2*k; noise_2d.at(0, k) = a[0]; noise_2d.at(1, k) = a[1]; for (int l = 0; l < COUNT_NORM_TYPES; ++l) if (cv::norm(tmp_mat_3d, dst_mat_3d.col(k), NORM_TYPE[l]) - cv::norm(noise_2d.col(k), NORM_TYPE[l]) > max_2diff) { print_information_4(method, j, N, k, l, cv::norm(tmp_mat_3d, dst_mat_3d.col(k), NORM_TYPE[l]) - cv::norm(noise_2d.col(k), NORM_TYPE[l])); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_REPROJ_DIFF, MESSAGE_REPROJ_DIFF_1); return; } } for (int l = 0; l < COUNT_NORM_TYPES; ++l) if (cv::norm(dst_res_3d, dst_mat_3d, NORM_TYPE[l]) - cv::norm(noise_2d, NORM_TYPE[l]) > max_diff) { print_information_5(method, j, N, l, cv::norm(dst_res_3d, dst_mat_3d, NORM_TYPE[l]) - cv::norm(noise_2d, NORM_TYPE[l])); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_REPROJ_DIFF, MESSAGE_REPROJ_DIFF_2); return; } } continue; } case cv::RHO: case RANSAC: { cv::Mat mask_res [4]; Mat H_res_64 [4] = { cv::findHomography(src_mat_2f, dst_mat_2f, method, reproj_threshold, mask_res[0]), cv::findHomography(src_mat_2f, dst_vec, method, reproj_threshold, mask_res[1]), cv::findHomography(src_vec, dst_mat_2f, method, reproj_threshold, mask_res[2]), cv::findHomography(src_vec, dst_vec, method, reproj_threshold, mask_res[3]) }; for (int j = 0; j < 4; ++j) { if (!check_matrix_size(H_res_64[j])) { print_information_1(j, N, method, H_res_64[j]); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_MATRIX_SIZE, MESSAGE_MATRIX_SIZE); return; } int code = check_ransac_mask_2(mask, mask_res[j]); if (code) { print_information_3(method, j, N, mask_res[j]); switch (code) { case 1: { CV_Error(CALIB3D_HOMOGRAPHY_ERROR_RANSAC_MASK, MESSAGE_RANSAC_MASK_1); break; } case 2: { CV_Error(CALIB3D_HOMOGRAPHY_ERROR_RANSAC_MASK, MESSAGE_RANSAC_MASK_3); break; } default: break; } return; } cv::Mat H_res_32; H_res_64[j].convertTo(H_res_32, CV_32F); cv::Mat dst_res_3d = H_res_32*src_mat_3d; for (int k = 0; k < N; ++k) { dst_res_3d.at(0, k) /= dst_res_3d.at(2, k); dst_res_3d.at(1, k) /= dst_res_3d.at(2, k); dst_res_3d.at(2, k) = 1.0f; float *p = dst_mat_2f.ptr()+2*k; dst_mat_3d.at(0, k) = p[0]; dst_mat_3d.at(1, k) = p[1]; double diff = cv::norm(dst_res_3d.col(k), dst_mat_3d.col(k), NORM_L2); if (mask_res[j].at(k, 0) != (diff <= reproj_threshold)) { print_information_6(method, j, N, k, diff, mask_res[j].at(k, 0)); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_RANSAC_MASK, MESSAGE_RANSAC_MASK_4); return; } if (mask.at(k, 0) && !mask_res[j].at(k, 0)) { print_information_7(method, j, N, k, diff, mask.at(k, 0), mask_res[j].at(k, 0)); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_RANSAC_MASK, MESSAGE_RANSAC_MASK_5); return; } if (mask_res[j].at(k, 0)) { float *a = noise_2f.ptr()+2*k; dst_mat_3d.at(0, k) -= a[0]; dst_mat_3d.at(1, k) -= a[1]; cv::Mat noise_2d(2, 1, CV_32F); noise_2d.at(0, 0) = a[0]; noise_2d.at(1, 0) = a[1]; for (int l = 0; l < COUNT_NORM_TYPES; ++l) { diff = cv::norm(dst_res_3d.col(k), dst_mat_3d.col(k), NORM_TYPE[l]); if (diff - cv::norm(noise_2d, NORM_TYPE[l]) > max_2diff) { print_information_8(method, j, N, k, l, diff - cv::norm(noise_2d, NORM_TYPE[l])); CV_Error(CALIB3D_HOMOGRAPHY_ERROR_RANSAC_DIFF, MESSAGE_RANSAC_DIFF); return; } } } } } continue; } default: continue; } } delete[]src_data; src_data = NULL; } } TEST(Calib3d_Homography, EKcase) { float pt1data[] = { 2.80073029e+002f, 2.39591217e+002f, 2.21912201e+002f, 2.59783997e+002f, 2.16053192e+002f, 2.78826569e+002f, 2.22782532e+002f, 2.82330383e+002f, 2.09924820e+002f, 2.89122559e+002f, 2.11077698e+002f, 2.89384674e+002f, 2.25287689e+002f, 2.88795532e+002f, 2.11180801e+002f, 2.89653503e+002f, 2.24126404e+002f, 2.90466064e+002f, 2.10914429e+002f, 2.90886963e+002f, 2.23439362e+002f, 2.91657715e+002f, 2.24809387e+002f, 2.91891602e+002f, 2.09809082e+002f, 2.92891113e+002f, 2.08771164e+002f, 2.93093231e+002f, 2.23160095e+002f, 2.93259460e+002f, 2.07874023e+002f, 2.93989990e+002f, 2.08963638e+002f, 2.94209839e+002f, 2.23963165e+002f, 2.94479645e+002f, 2.23241791e+002f, 2.94887817e+002f, 2.09438782e+002f, 2.95233337e+002f, 2.08901886e+002f, 2.95762878e+002f, 2.21867981e+002f, 2.95747711e+002f, 2.24195511e+002f, 2.98270905e+002f, 2.09331345e+002f, 3.05958191e+002f, 2.24727875e+002f, 3.07186035e+002f, 2.26718842e+002f, 3.08095795e+002f, 2.25363953e+002f, 3.08200226e+002f, 2.19897797e+002f, 3.13845093e+002f, 2.25013474e+002f, 3.15558777e+002f }; float pt2data[] = { 1.84072723e+002f, 1.43591202e+002f, 1.25912483e+002f, 1.63783859e+002f, 2.06439407e+002f, 2.20573929e+002f, 1.43801437e+002f, 1.80703903e+002f, 9.77904129e+000f, 2.49660202e+002f, 1.38458405e+001f, 2.14502701e+002f, 1.50636337e+002f, 2.15597183e+002f, 6.43103180e+001f, 2.51667648e+002f, 1.54952499e+002f, 2.20780014e+002f, 1.26638412e+002f, 2.43040924e+002f, 3.67568909e+002f, 1.83624954e+001f, 1.60657944e+002f, 2.21794052e+002f, -1.29507828e+000f, 3.32472443e+002f, 8.51442242e+000f, 4.15561554e+002f, 1.27161377e+002f, 1.97260361e+002f, 5.40714645e+000f, 4.90978302e+002f, 2.25571690e+001f, 3.96912415e+002f, 2.95664978e+002f, 7.36064959e+000f, 1.27241104e+002f, 1.98887573e+002f, -1.25569367e+000f, 3.87713226e+002f, 1.04194012e+001f, 4.31495758e+002f, 1.25868874e+002f, 1.99751617e+002f, 1.28195480e+002f, 2.02270355e+002f, 2.23436356e+002f, 1.80489182e+002f, 1.28727692e+002f, 2.11185410e+002f, 2.03336639e+002f, 2.52182083e+002f, 1.29366486e+002f, 2.12201904e+002f, 1.23897598e+002f, 2.17847351e+002f, 1.29015259e+002f, 2.19560623e+002f }; int npoints = (int)(sizeof(pt1data)/sizeof(pt1data[0])/2); Mat p1(1, npoints, CV_32FC2, pt1data); Mat p2(1, npoints, CV_32FC2, pt2data); Mat mask; Mat h = findHomography(p1, p2, RANSAC, 0.01, mask); ASSERT_TRUE(!h.empty()); cv::transpose(mask, mask); Mat p3, mask2; int ninliers = countNonZero(mask); Mat nmask[] = { mask, mask }; merge(nmask, 2, mask2); perspectiveTransform(p1, p3, h); mask2 = mask2.reshape(1); p2 = p2.reshape(1); p3 = p3.reshape(1); double err = cvtest::norm(p2, p3, NORM_INF, mask2); printf("ninliers: %d, inliers err: %.2g\n", ninliers, err); ASSERT_GE(ninliers, 10); ASSERT_LE(err, 0.01); } TEST(Calib3d_Homography, fromImages) { Mat img_1 = imread(cvtest::TS::ptr()->get_data_path() + "cv/optflow/image1.png", 0); Mat img_2 = imread(cvtest::TS::ptr()->get_data_path() + "cv/optflow/image2.png", 0); Ptr orb = ORB::create(); vector keypoints_1, keypoints_2; Mat descriptors_1, descriptors_2; orb->detectAndCompute( img_1, Mat(), keypoints_1, descriptors_1, false ); orb->detectAndCompute( img_2, Mat(), keypoints_2, descriptors_2, false ); //-- Step 3: Matching descriptor vectors using Brute Force matcher BFMatcher matcher(NORM_HAMMING,false); std::vector< DMatch > matches; matcher.match( descriptors_1, descriptors_2, matches ); double max_dist = 0; double min_dist = 100; //-- Quick calculation of max and min distances between keypoints for( int i = 0; i < descriptors_1.rows; i++ ) { double dist = matches[i].distance; if( dist < min_dist ) min_dist = dist; if( dist > max_dist ) max_dist = dist; } //-- Draw only "good" matches (i.e. whose distance is less than 3*min_dist ) std::vector< DMatch > good_matches; for( int i = 0; i < descriptors_1.rows; i++ ) { if( matches[i].distance <= 100 ) good_matches.push_back( matches[i]); } //-- Localize the model std::vector pointframe1; std::vector pointframe2; for( int i = 0; i < (int)good_matches.size(); i++ ) { //-- Get the keypoints from the good matches pointframe1.push_back( keypoints_1[ good_matches[i].queryIdx ].pt ); pointframe2.push_back( keypoints_2[ good_matches[i].trainIdx ].pt ); } Mat H0, H1, inliers0, inliers1; double min_t0 = DBL_MAX, min_t1 = DBL_MAX; for( int i = 0; i < 10; i++ ) { double t = (double)getTickCount(); H0 = findHomography( pointframe1, pointframe2, RANSAC, 3.0, inliers0 ); t = (double)getTickCount() - t; min_t0 = std::min(min_t0, t); } int ninliers0 = countNonZero(inliers0); for( int i = 0; i < 10; i++ ) { double t = (double)getTickCount(); H1 = findHomography( pointframe1, pointframe2, RHO, 3.0, inliers1 ); t = (double)getTickCount() - t; min_t1 = std::min(min_t1, t); } int ninliers1 = countNonZero(inliers1); double freq = getTickFrequency(); printf("nfeatures1 = %d, nfeatures2=%d, matches=%d, ninliers(RANSAC)=%d, " "time(RANSAC)=%.2fmsec, ninliers(RHO)=%d, time(RHO)=%.2fmsec\n", (int)keypoints_1.size(), (int)keypoints_2.size(), (int)good_matches.size(), ninliers0, min_t0*1000./freq, ninliers1, min_t1*1000./freq); ASSERT_TRUE(!H0.empty()); ASSERT_GE(ninliers0, 80); ASSERT_TRUE(!H1.empty()); ASSERT_GE(ninliers1, 80); } TEST(Calib3d_Homography, minPoints) { float pt1data[] = { 2.80073029e+002f, 2.39591217e+002f, 2.21912201e+002f, 2.59783997e+002f }; float pt2data[] = { 1.84072723e+002f, 1.43591202e+002f, 1.25912483e+002f, 1.63783859e+002f }; int npoints = (int)(sizeof(pt1data)/sizeof(pt1data[0])/2); printf("npoints = %d\n", npoints); // npoints = 2 Mat p1(1, npoints, CV_32FC2, pt1data); Mat p2(1, npoints, CV_32FC2, pt2data); Mat mask; // findHomography should raise an error since npoints < MIN_COUNT_OF_POINTS EXPECT_THROW(findHomography(p1, p2, RANSAC, 0.01, mask), cv::Exception); } TEST(Calib3d_Homography, not_normalized) { Mat_ p1({5, 2}, {-1, -1, -2, -2, -1, 1, -2, 2, -1, 0}); Mat_ p2({5, 2}, {0, -1, -1, -1, 0, 0, -1, 0, 0, -0.5}); Mat_ ref({3, 3}, { 0.74276086, 0., 0.74276086, 0.18569022, 0.18569022, 0., -0.37138043, 0., 0. }); for (int method : std::vector({0, RANSAC, LMEDS})) { Mat h = findHomography(p1, p2, method); for (auto it = h.begin(); it != h.end(); ++it) { ASSERT_FALSE(cvIsNaN(*it)) << format("method %d\nResult:\n", method) << h; } if (h.at(0, 0) * ref.at(0, 0) < 0) { h *= -1; } ASSERT_LE(cv::norm(h, ref, NORM_INF), 1e-8) << format("method %d\nResult:\n", method) << h; } } }} // namespace