// This file is part of OpenCV project. // It is subject to the license terms in the LICENSE file found in the top-level directory // of this distribution and at http://opencv.org/license.html. ////////////////////////////////////////////////////////////////////////////////////////// /////////////////// tests for matrix operations and math functions /////////////////////// ////////////////////////////////////////////////////////////////////////////////////////// #include "test_precomp.hpp" #include #include #include "opencv2/core/softfloat.hpp" namespace opencv_test { namespace { /// !!! NOTE !!! These tests happily avoid overflow cases & out-of-range arguments /// so that output arrays contain neigher Inf's nor Nan's. /// Handling such cases would require special modification of check function /// (validate_test_results) => TBD. /// Also, need some logarithmic-scale generation of input data. Right now it is done (in some tests) /// by generating min/max boundaries for random data in logarimithic scale, but /// within the same test case all the input array elements are of the same order. class Core_MathTest : public cvtest::ArrayTest { public: typedef cvtest::ArrayTest Base; Core_MathTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types); double get_success_error_level( int /*test_case_idx*/, int i, int j ); bool test_nd; }; Core_MathTest::Core_MathTest() { optional_mask = false; test_array[INPUT].push_back(NULL); test_array[OUTPUT].push_back(NULL); test_array[REF_OUTPUT].push_back(NULL); test_nd = false; } double Core_MathTest::get_success_error_level( int /*test_case_idx*/, int i, int j ) { return test_mat[i][j].depth() == CV_32F ? FLT_EPSILON*128 : DBL_EPSILON*1024; } void Core_MathTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types) { RNG& rng = ts->get_rng(); int depth = cvtest::randInt(rng)%2 + CV_32F; int cn = cvtest::randInt(rng) % 4 + 1, type = CV_MAKETYPE(depth, cn); size_t i, j; Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); for( i = 0; i < test_array.size(); i++ ) { size_t count = test_array[i].size(); for( j = 0; j < count; j++ ) types[i][j] = type; } test_nd = cvtest::randInt(rng)%3 == 0; } ////////// pow ///////////// class Core_PowTest : public Core_MathTest { public: typedef Core_MathTest Base; Core_PowTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); void get_minmax_bounds( int i, int j, int type, Scalar& low, Scalar& high ); void run_func(); void prepare_to_validation( int test_case_idx ); double get_success_error_level( int test_case_idx, int i, int j ); double power; }; Core_PowTest::Core_PowTest() { power = 0; } void Core_PowTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int depth = cvtest::randInt(rng) % (CV_64F+1); int cn = cvtest::randInt(rng) % 4 + 1; size_t i, j; Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); depth += depth == CV_8S; if( depth < CV_32F || cvtest::randInt(rng)%8 == 0 ) // integer power power = (int)(cvtest::randInt(rng)%21 - 10); else { i = cvtest::randInt(rng)%17; power = i == 16 ? 1./3 : i == 15 ? 0.5 : i == 14 ? -0.5 : cvtest::randReal(rng)*10 - 5; } for( i = 0; i < test_array.size(); i++ ) { size_t count = test_array[i].size(); int type = CV_MAKETYPE(depth, cn); for( j = 0; j < count; j++ ) types[i][j] = type; } test_nd = cvtest::randInt(rng)%3 == 0; } double Core_PowTest::get_success_error_level( int test_case_idx, int i, int j ) { int depth = test_mat[i][j].depth(); if( depth < CV_32F ) return power == cvRound(power) && power >= 0 ? 0 : 1; else { return depth != CV_64F ? Base::get_success_error_level( test_case_idx, i, j ) : DBL_EPSILON*1024*1.1; } } void Core_PowTest::get_minmax_bounds( int /*i*/, int /*j*/, int type, Scalar& low, Scalar& high ) { double l, u = cvtest::randInt(ts->get_rng())%1000 + 1; if( power > 0 ) { double mval = cvtest::getMaxVal(type); double u1 = pow(mval,1./power)*2; u = MIN(u,u1); } l = power == cvRound(power) ? -u : FLT_EPSILON; low = Scalar::all(l); high = Scalar::all(u); } void Core_PowTest::run_func() { if(!test_nd) { if( fabs(power-1./3) <= DBL_EPSILON && test_mat[INPUT][0].depth() == CV_32F ) { Mat a = test_mat[INPUT][0], b = test_mat[OUTPUT][0]; a = a.reshape(1); b = b.reshape(1); for( int i = 0; i < a.rows; i++ ) { b.at(i,0) = (float)fabs(cvCbrt(a.at(i,0))); for( int j = 1; j < a.cols; j++ ) b.at(i,j) = (float)fabs(cv::cubeRoot(a.at(i,j))); } } else cvPow( test_array[INPUT][0], test_array[OUTPUT][0], power ); } else { Mat& a = test_mat[INPUT][0]; Mat& b = test_mat[OUTPUT][0]; if(power == 0.5) cv::sqrt(a, b); else cv::pow(a, power, b); } } inline static int ipow( int a, int power ) { int b = 1; while( power > 0 ) { if( power&1 ) b *= a, power--; else a *= a, power >>= 1; } return b; } inline static double ipow( double a, int power ) { double b = 1.; while( power > 0 ) { if( power&1 ) b *= a, power--; else a *= a, power >>= 1; } return b; } void Core_PowTest::prepare_to_validation( int /*test_case_idx*/ ) { const Mat& a = test_mat[INPUT][0]; Mat& b = test_mat[REF_OUTPUT][0]; int depth = a.depth(); int ncols = a.cols*a.channels(); int ipower = cvRound(power), apower = abs(ipower); int i, j; for( i = 0; i < a.rows; i++ ) { const uchar* a_data = a.ptr(i); uchar* b_data = b.ptr(i); switch( depth ) { case CV_8U: if( ipower < 0 ) for( j = 0; j < ncols; j++ ) { int val = ((uchar*)a_data)[j]; ((uchar*)b_data)[j] = (uchar)(val == 0 ? 255 : val == 1 ? 1 : val == 2 && ipower == -1 ? 1 : 0); } else for( j = 0; j < ncols; j++ ) { int val = ((uchar*)a_data)[j]; val = ipow( val, ipower ); ((uchar*)b_data)[j] = saturate_cast(val); } break; case CV_8S: if( ipower < 0 ) for( j = 0; j < ncols; j++ ) { int val = ((schar*)a_data)[j]; ((schar*)b_data)[j] = (schar)(val == 0 ? 127 : val == 1 ? 1 : val ==-1 ? 1-2*(ipower&1) : val == 2 && ipower == -1 ? 1 : 0); } else for( j = 0; j < ncols; j++ ) { int val = ((schar*)a_data)[j]; val = ipow( val, ipower ); ((schar*)b_data)[j] = saturate_cast(val); } break; case CV_16U: if( ipower < 0 ) for( j = 0; j < ncols; j++ ) { int val = ((ushort*)a_data)[j]; ((ushort*)b_data)[j] = (ushort)(val == 0 ? 65535 : val == 1 ? 1 : val ==-1 ? 1-2*(ipower&1) : val == 2 && ipower == -1 ? 1 : 0); } else for( j = 0; j < ncols; j++ ) { int val = ((ushort*)a_data)[j]; val = ipow( val, ipower ); ((ushort*)b_data)[j] = saturate_cast(val); } break; case CV_16S: if( ipower < 0 ) for( j = 0; j < ncols; j++ ) { int val = ((short*)a_data)[j]; ((short*)b_data)[j] = (short)(val == 0 ? 32767 : val == 1 ? 1 : val ==-1 ? 1-2*(ipower&1) : val == 2 && ipower == -1 ? 1 : 0); } else for( j = 0; j < ncols; j++ ) { int val = ((short*)a_data)[j]; val = ipow( val, ipower ); ((short*)b_data)[j] = saturate_cast(val); } break; case CV_32S: if( ipower < 0 ) for( j = 0; j < ncols; j++ ) { int val = ((int*)a_data)[j]; ((int*)b_data)[j] = val == 0 ? INT_MAX : val == 1 ? 1 : val ==-1 ? 1-2*(ipower&1) : val == 2 && ipower == -1 ? 1 : 0; } else for( j = 0; j < ncols; j++ ) { int val = ((int*)a_data)[j]; val = ipow( val, ipower ); ((int*)b_data)[j] = val; } break; case CV_32F: if( power != ipower ) for( j = 0; j < ncols; j++ ) { double val = ((float*)a_data)[j]; val = pow( fabs(val), power ); ((float*)b_data)[j] = (float)val; } else for( j = 0; j < ncols; j++ ) { double val = ((float*)a_data)[j]; if( ipower < 0 ) val = 1./val; val = ipow( val, apower ); ((float*)b_data)[j] = (float)val; } break; case CV_64F: if( power != ipower ) for( j = 0; j < ncols; j++ ) { double val = ((double*)a_data)[j]; val = pow( fabs(val), power ); ((double*)b_data)[j] = (double)val; } else for( j = 0; j < ncols; j++ ) { double val = ((double*)a_data)[j]; if( ipower < 0 ) val = 1./val; val = ipow( val, apower ); ((double*)b_data)[j] = (double)val; } break; } } } ///////////////////////////////////////// matrix tests //////////////////////////////////////////// class Core_MatrixTest : public cvtest::ArrayTest { public: typedef cvtest::ArrayTest Base; Core_MatrixTest( int in_count, int out_count, bool allow_int, bool scalar_output, int max_cn ); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); double get_success_error_level( int test_case_idx, int i, int j ); bool allow_int; bool scalar_output; int max_cn; }; Core_MatrixTest::Core_MatrixTest( int in_count, int out_count, bool _allow_int, bool _scalar_output, int _max_cn ) : allow_int(_allow_int), scalar_output(_scalar_output), max_cn(_max_cn) { int i; for( i = 0; i < in_count; i++ ) test_array[INPUT].push_back(NULL); for( i = 0; i < out_count; i++ ) { test_array[OUTPUT].push_back(NULL); test_array[REF_OUTPUT].push_back(NULL); } element_wise_relative_error = false; } void Core_MatrixTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int depth = cvtest::randInt(rng) % (allow_int ? CV_64F+1 : 2); int cn = cvtest::randInt(rng) % max_cn + 1; size_t i, j; if( allow_int ) depth += depth == CV_8S; else depth += CV_32F; Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); for( i = 0; i < test_array.size(); i++ ) { size_t count = test_array[i].size(); int flag = (i == OUTPUT || i == REF_OUTPUT) && scalar_output; int type = !flag ? CV_MAKETYPE(depth, cn) : CV_64FC1; for( j = 0; j < count; j++ ) { types[i][j] = type; if( flag ) sizes[i][j] = Size( 4, 1 ); } } } double Core_MatrixTest::get_success_error_level( int test_case_idx, int i, int j ) { int input_depth = test_mat[INPUT][0].depth(); double input_precision = input_depth < CV_32F ? 0 : input_depth == CV_32F ? 5e-5 : 5e-10; double output_precision = Base::get_success_error_level( test_case_idx, i, j ); return MAX(input_precision, output_precision); } ///////////////// Trace ///////////////////// class Core_TraceTest : public Core_MatrixTest { public: Core_TraceTest(); protected: void run_func(); void prepare_to_validation( int test_case_idx ); }; Core_TraceTest::Core_TraceTest() : Core_MatrixTest( 1, 1, true, true, 4 ) { } void Core_TraceTest::run_func() { test_mat[OUTPUT][0].at(0,0) = cvTrace(test_array[INPUT][0]); } void Core_TraceTest::prepare_to_validation( int ) { Mat& mat = test_mat[INPUT][0]; int count = MIN( mat.rows, mat.cols ); Mat diag(count, 1, mat.type(), mat.ptr(), mat.step + mat.elemSize()); Scalar r = cvtest::mean(diag); r *= (double)count; test_mat[REF_OUTPUT][0].at(0,0) = r; } ///////// dotproduct ////////// class Core_DotProductTest : public Core_MatrixTest { public: Core_DotProductTest(); protected: void run_func(); void prepare_to_validation( int test_case_idx ); }; Core_DotProductTest::Core_DotProductTest() : Core_MatrixTest( 2, 1, true, true, 4 ) { } void Core_DotProductTest::run_func() { test_mat[OUTPUT][0].at(0,0) = Scalar(cvDotProduct( test_array[INPUT][0], test_array[INPUT][1] )); } void Core_DotProductTest::prepare_to_validation( int ) { test_mat[REF_OUTPUT][0].at(0,0) = Scalar(cvtest::crossCorr( test_mat[INPUT][0], test_mat[INPUT][1] )); } ///////// crossproduct ////////// class Core_CrossProductTest : public Core_MatrixTest { public: Core_CrossProductTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); void run_func(); void prepare_to_validation( int test_case_idx ); }; Core_CrossProductTest::Core_CrossProductTest() : Core_MatrixTest( 2, 1, false, false, 1 ) { } void Core_CrossProductTest::get_test_array_types_and_sizes( int, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int depth = cvtest::randInt(rng) % 2 + CV_32F; int cn = cvtest::randInt(rng) & 1 ? 3 : 1, type = CV_MAKETYPE(depth, cn); Size sz; types[INPUT][0] = types[INPUT][1] = types[OUTPUT][0] = types[REF_OUTPUT][0] = type; if( cn == 3 ) sz = Size(1,1); else if( cvtest::randInt(rng) & 1 ) sz = Size(3,1); else sz = Size(1,3); sizes[INPUT][0] = sizes[INPUT][1] = sizes[OUTPUT][0] = sizes[REF_OUTPUT][0] = sz; } void Core_CrossProductTest::run_func() { cvCrossProduct( test_array[INPUT][0], test_array[INPUT][1], test_array[OUTPUT][0] ); } void Core_CrossProductTest::prepare_to_validation( int ) { cv::Scalar a, b, c; if( test_mat[INPUT][0].rows > 1 ) { a.val[0] = cvGetReal2D( test_array[INPUT][0], 0, 0 ); a.val[1] = cvGetReal2D( test_array[INPUT][0], 1, 0 ); a.val[2] = cvGetReal2D( test_array[INPUT][0], 2, 0 ); b.val[0] = cvGetReal2D( test_array[INPUT][1], 0, 0 ); b.val[1] = cvGetReal2D( test_array[INPUT][1], 1, 0 ); b.val[2] = cvGetReal2D( test_array[INPUT][1], 2, 0 ); } else if( test_mat[INPUT][0].cols > 1 ) { a.val[0] = cvGetReal1D( test_array[INPUT][0], 0 ); a.val[1] = cvGetReal1D( test_array[INPUT][0], 1 ); a.val[2] = cvGetReal1D( test_array[INPUT][0], 2 ); b.val[0] = cvGetReal1D( test_array[INPUT][1], 0 ); b.val[1] = cvGetReal1D( test_array[INPUT][1], 1 ); b.val[2] = cvGetReal1D( test_array[INPUT][1], 2 ); } else { a = cvGet1D( test_array[INPUT][0], 0 ); b = cvGet1D( test_array[INPUT][1], 0 ); } c.val[2] = a.val[0]*b.val[1] - a.val[1]*b.val[0]; c.val[1] = -a.val[0]*b.val[2] + a.val[2]*b.val[0]; c.val[0] = a.val[1]*b.val[2] - a.val[2]*b.val[1]; if( test_mat[REF_OUTPUT][0].rows > 1 ) { cvSetReal2D( test_array[REF_OUTPUT][0], 0, 0, c.val[0] ); cvSetReal2D( test_array[REF_OUTPUT][0], 1, 0, c.val[1] ); cvSetReal2D( test_array[REF_OUTPUT][0], 2, 0, c.val[2] ); } else if( test_mat[REF_OUTPUT][0].cols > 1 ) { cvSetReal1D( test_array[REF_OUTPUT][0], 0, c.val[0] ); cvSetReal1D( test_array[REF_OUTPUT][0], 1, c.val[1] ); cvSetReal1D( test_array[REF_OUTPUT][0], 2, c.val[2] ); } else { cvSet1D( test_array[REF_OUTPUT][0], 0, cvScalar(c) ); } } ///////////////// gemm ///////////////////// class Core_GEMMTest : public Core_MatrixTest { public: typedef Core_MatrixTest Base; Core_GEMMTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); void get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ); int prepare_test_case( int test_case_idx ); void run_func(); void prepare_to_validation( int test_case_idx ); int tabc_flag; double alpha, beta; }; Core_GEMMTest::Core_GEMMTest() : Core_MatrixTest( 5, 1, false, false, 2 ) { test_case_count = 100; max_log_array_size = 10; tabc_flag = 0; alpha = beta = 0; } void Core_GEMMTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); Size sizeA; Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); sizeA = sizes[INPUT][0]; Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); sizes[INPUT][0] = sizeA; sizes[INPUT][2] = sizes[INPUT][3] = Size(1,1); types[INPUT][2] = types[INPUT][3] &= ~CV_MAT_CN_MASK; tabc_flag = cvtest::randInt(rng) & 7; switch( tabc_flag & (CV_GEMM_A_T|CV_GEMM_B_T) ) { case 0: sizes[INPUT][1].height = sizes[INPUT][0].width; sizes[OUTPUT][0].height = sizes[INPUT][0].height; sizes[OUTPUT][0].width = sizes[INPUT][1].width; break; case CV_GEMM_B_T: sizes[INPUT][1].width = sizes[INPUT][0].width; sizes[OUTPUT][0].height = sizes[INPUT][0].height; sizes[OUTPUT][0].width = sizes[INPUT][1].height; break; case CV_GEMM_A_T: sizes[INPUT][1].height = sizes[INPUT][0].height; sizes[OUTPUT][0].height = sizes[INPUT][0].width; sizes[OUTPUT][0].width = sizes[INPUT][1].width; break; case CV_GEMM_A_T | CV_GEMM_B_T: sizes[INPUT][1].width = sizes[INPUT][0].height; sizes[OUTPUT][0].height = sizes[INPUT][0].width; sizes[OUTPUT][0].width = sizes[INPUT][1].height; break; } sizes[REF_OUTPUT][0] = sizes[OUTPUT][0]; if( cvtest::randInt(rng) & 1 ) sizes[INPUT][4] = Size(0,0); else if( !(tabc_flag & CV_GEMM_C_T) ) sizes[INPUT][4] = sizes[OUTPUT][0]; else { sizes[INPUT][4].width = sizes[OUTPUT][0].height; sizes[INPUT][4].height = sizes[OUTPUT][0].width; } } int Core_GEMMTest::prepare_test_case( int test_case_idx ) { int code = Base::prepare_test_case( test_case_idx ); if( code > 0 ) { alpha = cvGetReal2D( test_array[INPUT][2], 0, 0 ); beta = cvGetReal2D( test_array[INPUT][3], 0, 0 ); } return code; } void Core_GEMMTest::get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ) { low = Scalar::all(-10.); high = Scalar::all(10.); } void Core_GEMMTest::run_func() { cvGEMM( test_array[INPUT][0], test_array[INPUT][1], alpha, test_array[INPUT][4], beta, test_array[OUTPUT][0], tabc_flag ); } void Core_GEMMTest::prepare_to_validation( int ) { cvtest::gemm( test_mat[INPUT][0], test_mat[INPUT][1], alpha, test_array[INPUT][4] ? test_mat[INPUT][4] : Mat(), beta, test_mat[REF_OUTPUT][0], tabc_flag ); } ///////////////// multransposed ///////////////////// class Core_MulTransposedTest : public Core_MatrixTest { public: Core_MulTransposedTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); void get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ); void run_func(); void prepare_to_validation( int test_case_idx ); int order; }; Core_MulTransposedTest::Core_MulTransposedTest() : Core_MatrixTest( 2, 1, false, false, 1 ) { test_case_count = 100; order = 0; test_array[TEMP].push_back(NULL); } void Core_MulTransposedTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int bits = cvtest::randInt(rng); int src_type = cvtest::randInt(rng) % 5; int dst_type = cvtest::randInt(rng) % 2; src_type = src_type == 0 ? CV_8U : src_type == 1 ? CV_16U : src_type == 2 ? CV_16S : src_type == 3 ? CV_32F : CV_64F; dst_type = dst_type == 0 ? CV_32F : CV_64F; dst_type = MAX( dst_type, src_type ); Core_MatrixTest::get_test_array_types_and_sizes( test_case_idx, sizes, types ); if( bits & 1 ) sizes[INPUT][1] = Size(0,0); else { sizes[INPUT][1] = sizes[INPUT][0]; if( bits & 2 ) sizes[INPUT][1].height = 1; if( bits & 4 ) sizes[INPUT][1].width = 1; } sizes[TEMP][0] = sizes[INPUT][0]; types[INPUT][0] = src_type; types[OUTPUT][0] = types[REF_OUTPUT][0] = types[INPUT][1] = types[TEMP][0] = dst_type; order = (bits & 8) != 0; sizes[OUTPUT][0].width = sizes[OUTPUT][0].height = order == 0 ? sizes[INPUT][0].height : sizes[INPUT][0].width; sizes[REF_OUTPUT][0] = sizes[OUTPUT][0]; } void Core_MulTransposedTest::get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ) { low = cvScalarAll(-10.); high = cvScalarAll(10.); } void Core_MulTransposedTest::run_func() { cvMulTransposed( test_array[INPUT][0], test_array[OUTPUT][0], order, test_array[INPUT][1] ); } void Core_MulTransposedTest::prepare_to_validation( int ) { const Mat& src = test_mat[INPUT][0]; Mat delta = test_mat[INPUT][1]; Mat& temp = test_mat[TEMP][0]; if( !delta.empty() ) { if( delta.rows < src.rows || delta.cols < src.cols ) { cv::repeat( delta, src.rows/delta.rows, src.cols/delta.cols, temp); delta = temp; } cvtest::add( src, 1, delta, -1, Scalar::all(0), temp, temp.type()); } else src.convertTo(temp, temp.type()); cvtest::gemm( temp, temp, 1., Mat(), 0, test_mat[REF_OUTPUT][0], order == 0 ? GEMM_2_T : GEMM_1_T ); } ///////////////// Transform ///////////////////// class Core_TransformTest : public Core_MatrixTest { public: typedef Core_MatrixTest Base; Core_TransformTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); double get_success_error_level( int test_case_idx, int i, int j ); int prepare_test_case( int test_case_idx ); void run_func(); void prepare_to_validation( int test_case_idx ); double scale; bool diagMtx; }; Core_TransformTest::Core_TransformTest() : Core_MatrixTest( 3, 1, true, false, 4 ) { scale = 1; diagMtx = false; } void Core_TransformTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int bits = cvtest::randInt(rng); int depth, dst_cn, mat_cols, mattype; Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); mat_cols = CV_MAT_CN(types[INPUT][0]); depth = CV_MAT_DEPTH(types[INPUT][0]); dst_cn = cvtest::randInt(rng) % 4 + 1; types[OUTPUT][0] = types[REF_OUTPUT][0] = CV_MAKETYPE(depth, dst_cn); mattype = depth < CV_32S ? CV_32F : depth == CV_64F ? CV_64F : bits & 1 ? CV_32F : CV_64F; types[INPUT][1] = mattype; types[INPUT][2] = CV_MAKETYPE(mattype, dst_cn); scale = 1./((cvtest::randInt(rng)%4)*50+1); if( bits & 2 ) { sizes[INPUT][2] = Size(0,0); mat_cols += (bits & 4) != 0; } else if( bits & 4 ) sizes[INPUT][2] = Size(1,1); else { if( bits & 8 ) sizes[INPUT][2] = Size(dst_cn,1); else sizes[INPUT][2] = Size(1,dst_cn); types[INPUT][2] &= ~CV_MAT_CN_MASK; } diagMtx = (bits & 16) != 0; sizes[INPUT][1] = Size(mat_cols,dst_cn); } int Core_TransformTest::prepare_test_case( int test_case_idx ) { int code = Base::prepare_test_case( test_case_idx ); if( code > 0 ) { Mat& m = test_mat[INPUT][1]; cvtest::add(m, scale, m, 0, Scalar::all(0), m, m.type() ); if(diagMtx) { Mat mask = Mat::eye(m.rows, m.cols, CV_8U)*255; mask = ~mask; m.setTo(Scalar::all(0), mask); } } return code; } double Core_TransformTest::get_success_error_level( int test_case_idx, int i, int j ) { int depth = test_mat[INPUT][0].depth(); return depth <= CV_8S ? 1 : depth <= CV_32S ? 9 : Base::get_success_error_level( test_case_idx, i, j ); } void Core_TransformTest::run_func() { CvMat _m = cvMat(test_mat[INPUT][1]), _shift = cvMat(test_mat[INPUT][2]); cvTransform( test_array[INPUT][0], test_array[OUTPUT][0], &_m, _shift.data.ptr ? &_shift : 0); } void Core_TransformTest::prepare_to_validation( int ) { Mat transmat = test_mat[INPUT][1]; Mat shift = test_mat[INPUT][2]; cvtest::transform( test_mat[INPUT][0], test_mat[REF_OUTPUT][0], transmat, shift ); } class Core_TransformLargeTest : public Core_TransformTest { public: typedef Core_MatrixTest Base; protected: void get_test_array_types_and_sizes(int test_case_idx, vector >& sizes, vector >& types); }; void Core_TransformLargeTest::get_test_array_types_and_sizes(int test_case_idx, vector >& sizes, vector >& types) { RNG& rng = ts->get_rng(); int bits = cvtest::randInt(rng); int depth, dst_cn, mat_cols, mattype; Base::get_test_array_types_and_sizes(test_case_idx, sizes, types); for (unsigned int j = 0; j < sizes.size(); j++) { for (unsigned int i = 0; i < sizes[j].size(); i++) { sizes[j][i].width *= 4; } } mat_cols = CV_MAT_CN(types[INPUT][0]); depth = CV_MAT_DEPTH(types[INPUT][0]); dst_cn = cvtest::randInt(rng) % 4 + 1; types[OUTPUT][0] = types[REF_OUTPUT][0] = CV_MAKETYPE(depth, dst_cn); mattype = depth < CV_32S ? CV_32F : depth == CV_64F ? CV_64F : bits & 1 ? CV_32F : CV_64F; types[INPUT][1] = mattype; types[INPUT][2] = CV_MAKETYPE(mattype, dst_cn); scale = 1. / ((cvtest::randInt(rng) % 4) * 50 + 1); if (bits & 2) { sizes[INPUT][2] = Size(0, 0); mat_cols += (bits & 4) != 0; } else if (bits & 4) sizes[INPUT][2] = Size(1, 1); else { if (bits & 8) sizes[INPUT][2] = Size(dst_cn, 1); else sizes[INPUT][2] = Size(1, dst_cn); types[INPUT][2] &= ~CV_MAT_CN_MASK; } diagMtx = (bits & 16) != 0; sizes[INPUT][1] = Size(mat_cols, dst_cn); } ///////////////// PerspectiveTransform ///////////////////// class Core_PerspectiveTransformTest : public Core_MatrixTest { public: Core_PerspectiveTransformTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); double get_success_error_level( int test_case_idx, int i, int j ); void run_func(); void prepare_to_validation( int test_case_idx ); }; Core_PerspectiveTransformTest::Core_PerspectiveTransformTest() : Core_MatrixTest( 2, 1, false, false, 2 ) { } void Core_PerspectiveTransformTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int bits = cvtest::randInt(rng); int depth, cn, mattype; Core_MatrixTest::get_test_array_types_and_sizes( test_case_idx, sizes, types ); cn = CV_MAT_CN(types[INPUT][0]) + 1; depth = CV_MAT_DEPTH(types[INPUT][0]); types[INPUT][0] = types[OUTPUT][0] = types[REF_OUTPUT][0] = CV_MAKETYPE(depth, cn); mattype = depth == CV_64F ? CV_64F : bits & 1 ? CV_32F : CV_64F; types[INPUT][1] = mattype; sizes[INPUT][1] = Size(cn + 1, cn + 1); } double Core_PerspectiveTransformTest::get_success_error_level( int test_case_idx, int i, int j ) { int depth = test_mat[INPUT][0].depth(); return depth == CV_32F ? 1e-4 : depth == CV_64F ? 1e-8 : Core_MatrixTest::get_success_error_level(test_case_idx, i, j); } void Core_PerspectiveTransformTest::run_func() { CvMat _m = cvMat(test_mat[INPUT][1]); cvPerspectiveTransform( test_array[INPUT][0], test_array[OUTPUT][0], &_m ); } static void cvTsPerspectiveTransform( const CvArr* _src, CvArr* _dst, const CvMat* transmat ) { int i, j, cols; int cn, depth, mat_depth; CvMat astub, bstub, *a, *b; double mat[16] = {0.0}; a = cvGetMat( _src, &astub, 0, 0 ); b = cvGetMat( _dst, &bstub, 0, 0 ); cn = CV_MAT_CN(a->type); depth = CV_MAT_DEPTH(a->type); mat_depth = CV_MAT_DEPTH(transmat->type); cols = transmat->cols; // prepare cn x (cn + 1) transform matrix if( mat_depth == CV_32F ) { for( i = 0; i < transmat->rows; i++ ) for( j = 0; j < cols; j++ ) mat[i*cols + j] = ((float*)(transmat->data.ptr + transmat->step*i))[j]; } else { CV_Assert( mat_depth == CV_64F ); for( i = 0; i < transmat->rows; i++ ) for( j = 0; j < cols; j++ ) mat[i*cols + j] = ((double*)(transmat->data.ptr + transmat->step*i))[j]; } // transform data cols = a->cols * cn; vector buf(cols); for( i = 0; i < a->rows; i++ ) { uchar* src = a->data.ptr + i*a->step; uchar* dst = b->data.ptr + i*b->step; switch( depth ) { case CV_32F: for( j = 0; j < cols; j++ ) buf[j] = ((float*)src)[j]; break; case CV_64F: for( j = 0; j < cols; j++ ) buf[j] = ((double*)src)[j]; break; default: CV_Assert(0); } switch( cn ) { case 2: for( j = 0; j < cols; j += 2 ) { double t0 = buf[j]*mat[0] + buf[j+1]*mat[1] + mat[2]; double t1 = buf[j]*mat[3] + buf[j+1]*mat[4] + mat[5]; double w = buf[j]*mat[6] + buf[j+1]*mat[7] + mat[8]; w = w ? 1./w : 0; buf[j] = t0*w; buf[j+1] = t1*w; } break; case 3: for( j = 0; j < cols; j += 3 ) { double t0 = buf[j]*mat[0] + buf[j+1]*mat[1] + buf[j+2]*mat[2] + mat[3]; double t1 = buf[j]*mat[4] + buf[j+1]*mat[5] + buf[j+2]*mat[6] + mat[7]; double t2 = buf[j]*mat[8] + buf[j+1]*mat[9] + buf[j+2]*mat[10] + mat[11]; double w = buf[j]*mat[12] + buf[j+1]*mat[13] + buf[j+2]*mat[14] + mat[15]; w = w ? 1./w : 0; buf[j] = t0*w; buf[j+1] = t1*w; buf[j+2] = t2*w; } break; default: CV_Assert(0); } switch( depth ) { case CV_32F: for( j = 0; j < cols; j++ ) ((float*)dst)[j] = (float)buf[j]; break; case CV_64F: for( j = 0; j < cols; j++ ) ((double*)dst)[j] = buf[j]; break; default: CV_Assert(0); } } } void Core_PerspectiveTransformTest::prepare_to_validation( int ) { CvMat transmat = cvMat(test_mat[INPUT][1]); cvTsPerspectiveTransform( test_array[INPUT][0], test_array[REF_OUTPUT][0], &transmat ); } ///////////////// Mahalanobis ///////////////////// class Core_MahalanobisTest : public Core_MatrixTest { public: typedef Core_MatrixTest Base; Core_MahalanobisTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); int prepare_test_case( int test_case_idx ); void run_func(); void prepare_to_validation( int test_case_idx ); }; Core_MahalanobisTest::Core_MahalanobisTest() : Core_MatrixTest( 3, 1, false, true, 1 ) { test_case_count = 100; test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); } void Core_MahalanobisTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); Core_MatrixTest::get_test_array_types_and_sizes( test_case_idx, sizes, types ); if( cvtest::randInt(rng) & 1 ) sizes[INPUT][0].width = sizes[INPUT][1].width = 1; else sizes[INPUT][0].height = sizes[INPUT][1].height = 1; sizes[TEMP][0] = sizes[TEMP][1] = sizes[INPUT][0]; sizes[INPUT][2].width = sizes[INPUT][2].height = sizes[INPUT][0].width + sizes[INPUT][0].height - 1; sizes[TEMP][2] = sizes[INPUT][2]; types[TEMP][0] = types[TEMP][1] = types[TEMP][2] = types[INPUT][0]; } int Core_MahalanobisTest::prepare_test_case( int test_case_idx ) { int code = Base::prepare_test_case( test_case_idx ); if( code > 0 ) { // make sure that the inverted "covariation" matrix is symmetrix and positively defined. cvtest::gemm( test_mat[INPUT][2], test_mat[INPUT][2], 1., Mat(), 0., test_mat[TEMP][2], GEMM_2_T ); cvtest::copy( test_mat[TEMP][2], test_mat[INPUT][2] ); } return code; } void Core_MahalanobisTest::run_func() { test_mat[OUTPUT][0].at(0,0) = cvRealScalar(cvMahalanobis(test_array[INPUT][0], test_array[INPUT][1], test_array[INPUT][2])); } void Core_MahalanobisTest::prepare_to_validation( int ) { cvtest::add( test_mat[INPUT][0], 1., test_mat[INPUT][1], -1., Scalar::all(0), test_mat[TEMP][0], test_mat[TEMP][0].type() ); if( test_mat[INPUT][0].rows == 1 ) cvtest::gemm( test_mat[TEMP][0], test_mat[INPUT][2], 1., Mat(), 0., test_mat[TEMP][1], 0 ); else cvtest::gemm( test_mat[INPUT][2], test_mat[TEMP][0], 1., Mat(), 0., test_mat[TEMP][1], 0 ); test_mat[REF_OUTPUT][0].at(0,0) = cvRealScalar(sqrt(cvtest::crossCorr(test_mat[TEMP][0], test_mat[TEMP][1]))); } ///////////////// covarmatrix ///////////////////// class Core_CovarMatrixTest : public Core_MatrixTest { public: Core_CovarMatrixTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); int prepare_test_case( int test_case_idx ); void run_func(); void prepare_to_validation( int test_case_idx ); vector temp_hdrs; vector hdr_data; int flags, t_flag, len, count; bool are_images; }; Core_CovarMatrixTest::Core_CovarMatrixTest() : Core_MatrixTest( 1, 1, true, false, 1 ), flags(0), t_flag(0), len(0), count(0), are_images(false) { test_case_count = 100; test_array[INPUT_OUTPUT].push_back(NULL); test_array[REF_INPUT_OUTPUT].push_back(NULL); test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); } void Core_CovarMatrixTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int bits = cvtest::randInt(rng); int i, single_matrix; Core_MatrixTest::get_test_array_types_and_sizes( test_case_idx, sizes, types ); flags = bits & (CV_COVAR_NORMAL | CV_COVAR_USE_AVG | CV_COVAR_SCALE | CV_COVAR_ROWS ); single_matrix = flags & CV_COVAR_ROWS; t_flag = (bits & 256) != 0; const int min_count = 2; if( !t_flag ) { len = sizes[INPUT][0].width; count = sizes[INPUT][0].height; count = MAX(count, min_count); sizes[INPUT][0] = Size(len, count); } else { len = sizes[INPUT][0].height; count = sizes[INPUT][0].width; count = MAX(count, min_count); sizes[INPUT][0] = Size(count, len); } if( single_matrix && t_flag ) flags = (flags & ~CV_COVAR_ROWS) | CV_COVAR_COLS; if( CV_MAT_DEPTH(types[INPUT][0]) == CV_32S ) types[INPUT][0] = (types[INPUT][0] & ~CV_MAT_DEPTH_MASK) | CV_32F; sizes[OUTPUT][0] = sizes[REF_OUTPUT][0] = flags & CV_COVAR_NORMAL ? Size(len,len) : Size(count,count); sizes[INPUT_OUTPUT][0] = sizes[REF_INPUT_OUTPUT][0] = !t_flag ? Size(len,1) : Size(1,len); sizes[TEMP][0] = sizes[INPUT][0]; types[INPUT_OUTPUT][0] = types[REF_INPUT_OUTPUT][0] = types[OUTPUT][0] = types[REF_OUTPUT][0] = types[TEMP][0] = CV_MAT_DEPTH(types[INPUT][0]) == CV_64F || (bits & 512) ? CV_64F : CV_32F; are_images = (bits & 1024) != 0; for( i = 0; i < (single_matrix ? 1 : count); i++ ) temp_hdrs.push_back(NULL); } int Core_CovarMatrixTest::prepare_test_case( int test_case_idx ) { int code = Core_MatrixTest::prepare_test_case( test_case_idx ); if( code > 0 ) { int i; int single_matrix = flags & (CV_COVAR_ROWS|CV_COVAR_COLS); int hdr_size = are_images ? sizeof(IplImage) : sizeof(CvMat); hdr_data.resize(count*hdr_size); uchar* _hdr_data = &hdr_data[0]; if( single_matrix ) { if( !are_images ) *((CvMat*)_hdr_data) = cvMat(test_mat[INPUT][0]); else *((IplImage*)_hdr_data) = cvIplImage(test_mat[INPUT][0]); temp_hdrs[0] = _hdr_data; } else for( i = 0; i < count; i++ ) { Mat part; void* ptr = _hdr_data + i*hdr_size; if( !t_flag ) part = test_mat[INPUT][0].row(i); else part = test_mat[INPUT][0].col(i); if( !are_images ) *((CvMat*)ptr) = cvMat(part); else *((IplImage*)ptr) = cvIplImage(part); temp_hdrs[i] = ptr; } } return code; } void Core_CovarMatrixTest::run_func() { cvCalcCovarMatrix( (const void**)&temp_hdrs[0], count, test_array[OUTPUT][0], test_array[INPUT_OUTPUT][0], flags ); } void Core_CovarMatrixTest::prepare_to_validation( int ) { Mat& avg = test_mat[REF_INPUT_OUTPUT][0]; double scale = 1.; if( !(flags & CV_COVAR_USE_AVG) ) { Mat hdrs0 = cvarrToMat(temp_hdrs[0]); int i; avg = Scalar::all(0); for( i = 0; i < count; i++ ) { Mat vec; if( flags & CV_COVAR_ROWS ) vec = hdrs0.row(i); else if( flags & CV_COVAR_COLS ) vec = hdrs0.col(i); else vec = cvarrToMat(temp_hdrs[i]); cvtest::add(avg, 1, vec, 1, Scalar::all(0), avg, avg.type()); } cvtest::add(avg, 1./count, avg, 0., Scalar::all(0), avg, avg.type()); } if( flags & CV_COVAR_SCALE ) { scale = 1./count; } Mat& temp0 = test_mat[TEMP][0]; cv::repeat( avg, temp0.rows/avg.rows, temp0.cols/avg.cols, temp0 ); cvtest::add( test_mat[INPUT][0], 1, temp0, -1, Scalar::all(0), temp0, temp0.type()); cvtest::gemm( temp0, temp0, scale, Mat(), 0., test_mat[REF_OUTPUT][0], t_flag ^ ((flags & CV_COVAR_NORMAL) != 0) ? CV_GEMM_A_T : CV_GEMM_B_T ); temp_hdrs.clear(); } static void cvTsFloodWithZeros( Mat& mat, RNG& rng ) { int k, total = mat.rows*mat.cols, type = mat.type(); int zero_total = cvtest::randInt(rng) % total; CV_Assert( type == CV_32FC1 || type == CV_64FC1 ); for( k = 0; k < zero_total; k++ ) { int i = cvtest::randInt(rng) % mat.rows; int j = cvtest::randInt(rng) % mat.cols; if( type == CV_32FC1 ) mat.at(i,j) = 0.f; else mat.at(i,j) = 0.; } } ///////////////// determinant ///////////////////// class Core_DetTest : public Core_MatrixTest { public: typedef Core_MatrixTest Base; Core_DetTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); double get_success_error_level( int test_case_idx, int i, int j ); void get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ); int prepare_test_case( int test_case_idx ); void run_func(); void prepare_to_validation( int test_case_idx ); }; Core_DetTest::Core_DetTest() : Core_MatrixTest( 1, 1, false, true, 1 ) { test_case_count = 100; max_log_array_size = 7; test_array[TEMP].push_back(NULL); } void Core_DetTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); sizes[INPUT][0].width = sizes[INPUT][0].height; sizes[TEMP][0] = sizes[INPUT][0]; types[TEMP][0] = CV_64FC1; } void Core_DetTest::get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ) { low = cvScalarAll(-2.); high = cvScalarAll(2.); } double Core_DetTest::get_success_error_level( int /*test_case_idx*/, int /*i*/, int /*j*/ ) { return CV_MAT_DEPTH(cvGetElemType(test_array[INPUT][0])) == CV_32F ? 1e-2 : 1e-5; } int Core_DetTest::prepare_test_case( int test_case_idx ) { int code = Core_MatrixTest::prepare_test_case( test_case_idx ); if( code > 0 ) cvTsFloodWithZeros( test_mat[INPUT][0], ts->get_rng() ); return code; } void Core_DetTest::run_func() { test_mat[OUTPUT][0].at(0,0) = cvRealScalar(cvDet(test_array[INPUT][0])); } // LU method that chooses the optimal in a column pivot element static double cvTsLU( CvMat* a, CvMat* b=NULL, CvMat* x=NULL, int* rank=0 ) { int i, j, k, N = a->rows, N1 = a->cols, Nm = MIN(N, N1), step = a->step/sizeof(double); int M = b ? b->cols : 0, b_step = b ? b->step/sizeof(double) : 0; int x_step = x ? x->step/sizeof(double) : 0; double *a0 = a->data.db, *b0 = b ? b->data.db : 0; double *x0 = x ? x->data.db : 0; double t, det = 1.; CV_Assert( CV_MAT_TYPE(a->type) == CV_64FC1 && (!b || CV_ARE_TYPES_EQ(a,b)) && (!x || CV_ARE_TYPES_EQ(a,x))); for( i = 0; i < Nm; i++ ) { double max_val = fabs(a0[i*step + i]); double *a1, *a2, *b1 = 0, *b2 = 0; k = i; for( j = i+1; j < N; j++ ) { t = fabs(a0[j*step + i]); if( max_val < t ) { max_val = t; k = j; } } if( k != i ) { for( j = i; j < N1; j++ ) CV_SWAP( a0[i*step + j], a0[k*step + j], t ); for( j = 0; j < M; j++ ) CV_SWAP( b0[i*b_step + j], b0[k*b_step + j], t ); det = -det; } if( max_val == 0 ) { if( rank ) *rank = i; return 0.; } a1 = a0 + i*step; a2 = a1 + step; b1 = b0 + i*b_step; b2 = b1 + b_step; for( j = i+1; j < N; j++, a2 += step, b2 += b_step ) { t = a2[i]/a1[i]; for( k = i+1; k < N1; k++ ) a2[k] -= t*a1[k]; for( k = 0; k < M; k++ ) b2[k] -= t*b1[k]; } det *= a1[i]; } if( x ) { CV_Assert( b ); for( i = N-1; i >= 0; i-- ) { double* a1 = a0 + i*step; double* b1 = b0 + i*b_step; for( j = 0; j < M; j++ ) { t = b1[j]; for( k = i+1; k < N1; k++ ) t -= a1[k]*x0[k*x_step + j]; x0[i*x_step + j] = t/a1[i]; } } } if( rank ) *rank = i; return det; } void Core_DetTest::prepare_to_validation( int ) { test_mat[INPUT][0].convertTo(test_mat[TEMP][0], test_mat[TEMP][0].type()); CvMat temp0 = cvMat(test_mat[TEMP][0]); test_mat[REF_OUTPUT][0].at(0,0) = cvRealScalar(cvTsLU(&temp0, 0, 0)); } ///////////////// invert ///////////////////// class Core_InvertTest : public Core_MatrixTest { public: typedef Core_MatrixTest Base; Core_InvertTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); void get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ); double get_success_error_level( int test_case_idx, int i, int j ); int prepare_test_case( int test_case_idx ); void run_func(); void prepare_to_validation( int test_case_idx ); int method, rank; double result; }; Core_InvertTest::Core_InvertTest() : Core_MatrixTest( 1, 1, false, false, 1 ), method(0), rank(0), result(0.) { test_case_count = 100; max_log_array_size = 7; test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); } void Core_InvertTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int bits = cvtest::randInt(rng); Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); int min_size = MIN( sizes[INPUT][0].width, sizes[INPUT][0].height ); if( (bits & 3) == 0 ) { method = CV_SVD; if( bits & 4 ) { sizes[INPUT][0] = Size(min_size, min_size); if( bits & 16 ) method = CV_CHOLESKY; } } else { method = CV_LU; sizes[INPUT][0] = Size(min_size, min_size); } sizes[TEMP][0].width = sizes[INPUT][0].height; sizes[TEMP][0].height = sizes[INPUT][0].width; sizes[TEMP][1] = sizes[INPUT][0]; types[TEMP][0] = types[INPUT][0]; types[TEMP][1] = CV_64FC1; sizes[OUTPUT][0] = sizes[REF_OUTPUT][0] = Size(min_size, min_size); } double Core_InvertTest::get_success_error_level( int /*test_case_idx*/, int, int ) { return CV_MAT_DEPTH(cvGetElemType(test_array[OUTPUT][0])) == CV_32F ? 1e-2 : 1e-6; } int Core_InvertTest::prepare_test_case( int test_case_idx ) { int code = Core_MatrixTest::prepare_test_case( test_case_idx ); if( code > 0 ) { cvTsFloodWithZeros( test_mat[INPUT][0], ts->get_rng() ); if( method == CV_CHOLESKY ) { cvtest::gemm( test_mat[INPUT][0], test_mat[INPUT][0], 1., Mat(), 0., test_mat[TEMP][0], CV_GEMM_B_T ); cvtest::copy( test_mat[TEMP][0], test_mat[INPUT][0] ); } } return code; } void Core_InvertTest::get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ) { low = cvScalarAll(-1.); high = cvScalarAll(1.); } void Core_InvertTest::run_func() { result = cvInvert(test_array[INPUT][0], test_array[TEMP][0], method); } static double cvTsSVDet( CvMat* mat, double* ratio ) { int type = CV_MAT_TYPE(mat->type); int i, nm = MIN( mat->rows, mat->cols ); CvMat* w = cvCreateMat( nm, 1, type ); double det = 1.; cvSVD( mat, w, 0, 0, 0 ); if( type == CV_32FC1 ) { for( i = 0; i < nm; i++ ) det *= w->data.fl[i]; *ratio = w->data.fl[nm-1] < FLT_EPSILON ? 0 : w->data.fl[nm-1]/w->data.fl[0]; } else { for( i = 0; i < nm; i++ ) det *= w->data.db[i]; *ratio = w->data.db[nm-1] < FLT_EPSILON ? 0 : w->data.db[nm-1]/w->data.db[0]; } cvReleaseMat( &w ); return det; } void Core_InvertTest::prepare_to_validation( int ) { Mat& input = test_mat[INPUT][0]; Mat& temp0 = test_mat[TEMP][0]; Mat& temp1 = test_mat[TEMP][1]; Mat& dst0 = test_mat[REF_OUTPUT][0]; Mat& dst = test_mat[OUTPUT][0]; CvMat _input = cvMat(input); double ratio = 0, det = cvTsSVDet( &_input, &ratio ); double threshold = (input.depth() == CV_32F ? FLT_EPSILON : DBL_EPSILON)*1000; cvtest::convert( input, temp1, temp1.type() ); if( det < threshold || ((method == CV_LU || method == CV_CHOLESKY) && (result == 0 || ratio < threshold)) || ((method == CV_SVD || method == CV_SVD_SYM) && result < threshold) ) { dst = Scalar::all(0); dst0 = Scalar::all(0); return; } if( input.rows >= input.cols ) cvtest::gemm( temp0, input, 1., Mat(), 0., dst, 0 ); else cvtest::gemm( input, temp0, 1., Mat(), 0., dst, 0 ); cv::setIdentity( dst0, Scalar::all(1) ); } ///////////////// solve ///////////////////// class Core_SolveTest : public Core_MatrixTest { public: typedef Core_MatrixTest Base; Core_SolveTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); void get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ); double get_success_error_level( int test_case_idx, int i, int j ); int prepare_test_case( int test_case_idx ); void run_func(); void prepare_to_validation( int test_case_idx ); int method, rank; double result; }; Core_SolveTest::Core_SolveTest() : Core_MatrixTest( 2, 1, false, false, 1 ), method(0), rank(0), result(0.) { test_case_count = 100; max_log_array_size = 7; test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); } void Core_SolveTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int bits = cvtest::randInt(rng); Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); CvSize in_sz = cvSize(sizes[INPUT][0]); if( in_sz.width > in_sz.height ) in_sz = cvSize(in_sz.height, in_sz.width); Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); sizes[INPUT][0] = in_sz; int min_size = MIN( sizes[INPUT][0].width, sizes[INPUT][0].height ); if( (bits & 3) == 0 ) { method = CV_SVD; if( bits & 4 ) { sizes[INPUT][0] = Size(min_size, min_size); /*if( bits & 8 ) method = CV_SVD_SYM;*/ } } else { method = CV_LU; sizes[INPUT][0] = Size(min_size, min_size); } sizes[INPUT][1].height = sizes[INPUT][0].height; sizes[TEMP][0].width = sizes[INPUT][1].width; sizes[TEMP][0].height = sizes[INPUT][0].width; sizes[TEMP][1] = sizes[INPUT][0]; types[TEMP][0] = types[INPUT][0]; types[TEMP][1] = CV_64FC1; sizes[OUTPUT][0] = sizes[REF_OUTPUT][0] = Size(sizes[INPUT][1].width, min_size); } int Core_SolveTest::prepare_test_case( int test_case_idx ) { int code = Core_MatrixTest::prepare_test_case( test_case_idx ); /*if( method == CV_SVD_SYM ) { cvTsGEMM( test_array[INPUT][0], test_array[INPUT][0], 1., 0, 0., test_array[TEMP][0], CV_GEMM_B_T ); cvTsCopy( test_array[TEMP][0], test_array[INPUT][0] ); }*/ return code; } void Core_SolveTest::get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ) { low = cvScalarAll(-1.); high = cvScalarAll(1.); } double Core_SolveTest::get_success_error_level( int /*test_case_idx*/, int, int ) { return CV_MAT_DEPTH(cvGetElemType(test_array[OUTPUT][0])) == CV_32F ? 5e-2 : 1e-8; } void Core_SolveTest::run_func() { result = cvSolve(test_array[INPUT][0], test_array[INPUT][1], test_array[TEMP][0], method); } void Core_SolveTest::prepare_to_validation( int ) { //int rank = test_mat[REF_OUTPUT][0].rows; Mat& input = test_mat[INPUT][0]; Mat& dst = test_mat[OUTPUT][0]; Mat& dst0 = test_mat[REF_OUTPUT][0]; if( method == CV_LU ) { if( result == 0 ) { Mat& temp1 = test_mat[TEMP][1]; cvtest::convert(input, temp1, temp1.type()); dst = Scalar::all(0); CvMat _temp1 = cvMat(temp1); double det = cvTsLU( &_temp1, 0, 0 ); dst0 = Scalar::all(det != 0); return; } double threshold = (input.type() == CV_32F ? FLT_EPSILON : DBL_EPSILON)*1000; CvMat _input = cvMat(input); double ratio = 0, det = cvTsSVDet( &_input, &ratio ); if( det < threshold || ratio < threshold ) { dst = Scalar::all(0); dst0 = Scalar::all(0); return; } } Mat* pdst = input.rows <= input.cols ? &test_mat[OUTPUT][0] : &test_mat[INPUT][1]; cvtest::gemm( input, test_mat[TEMP][0], 1., test_mat[INPUT][1], -1., *pdst, 0 ); if( pdst != &dst ) cvtest::gemm( input, *pdst, 1., Mat(), 0., dst, CV_GEMM_A_T ); dst0 = Scalar::all(0); } ///////////////// SVD ///////////////////// class Core_SVDTest : public Core_MatrixTest { public: typedef Core_MatrixTest Base; Core_SVDTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); double get_success_error_level( int test_case_idx, int i, int j ); void get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ); int prepare_test_case( int test_case_idx ); void run_func(); void prepare_to_validation( int test_case_idx ); int flags; bool have_u, have_v, symmetric, compact, vector_w; }; Core_SVDTest::Core_SVDTest() : Core_MatrixTest( 1, 4, false, false, 1 ), flags(0), have_u(false), have_v(false), symmetric(false), compact(false), vector_w(false) { test_case_count = 100; max_log_array_size = 8; test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); } void Core_SVDTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int bits = cvtest::randInt(rng); Core_MatrixTest::get_test_array_types_and_sizes( test_case_idx, sizes, types ); int min_size, i, m, n; min_size = MIN( sizes[INPUT][0].width, sizes[INPUT][0].height ); flags = bits & (CV_SVD_MODIFY_A+CV_SVD_U_T+CV_SVD_V_T); have_u = (bits & 8) != 0; have_v = (bits & 16) != 0; symmetric = (bits & 32) != 0; compact = (bits & 64) != 0; vector_w = (bits & 128) != 0; if( symmetric ) sizes[INPUT][0] = Size(min_size, min_size); m = sizes[INPUT][0].height; n = sizes[INPUT][0].width; if( compact ) sizes[TEMP][0] = Size(min_size, min_size); else sizes[TEMP][0] = sizes[INPUT][0]; sizes[TEMP][3] = Size(0,0); if( vector_w ) { sizes[TEMP][3] = sizes[TEMP][0]; if( bits & 256 ) sizes[TEMP][0] = Size(1, min_size); else sizes[TEMP][0] = Size(min_size, 1); } if( have_u ) { sizes[TEMP][1] = compact ? Size(min_size, m) : Size(m, m); if( flags & CV_SVD_U_T ) CV_SWAP( sizes[TEMP][1].width, sizes[TEMP][1].height, i ); } else sizes[TEMP][1] = Size(0,0); if( have_v ) { sizes[TEMP][2] = compact ? Size(n, min_size) : Size(n, n); if( !(flags & CV_SVD_V_T) ) CV_SWAP( sizes[TEMP][2].width, sizes[TEMP][2].height, i ); } else sizes[TEMP][2] = Size(0,0); types[TEMP][0] = types[TEMP][1] = types[TEMP][2] = types[TEMP][3] = types[INPUT][0]; types[OUTPUT][0] = types[OUTPUT][1] = types[OUTPUT][2] = types[INPUT][0]; types[OUTPUT][3] = CV_8UC1; sizes[OUTPUT][0] = !have_u || !have_v ? Size(0,0) : sizes[INPUT][0]; sizes[OUTPUT][1] = !have_u ? Size(0,0) : compact ? Size(min_size,min_size) : Size(m,m); sizes[OUTPUT][2] = !have_v ? Size(0,0) : compact ? Size(min_size,min_size) : Size(n,n); sizes[OUTPUT][3] = Size(min_size,1); for( i = 0; i < 4; i++ ) { sizes[REF_OUTPUT][i] = sizes[OUTPUT][i]; types[REF_OUTPUT][i] = types[OUTPUT][i]; } } int Core_SVDTest::prepare_test_case( int test_case_idx ) { int code = Core_MatrixTest::prepare_test_case( test_case_idx ); if( code > 0 ) { Mat& input = test_mat[INPUT][0]; cvTsFloodWithZeros( input, ts->get_rng() ); if( symmetric && (have_u || have_v) ) { Mat& temp = test_mat[TEMP][have_u ? 1 : 2]; cvtest::gemm( input, input, 1., Mat(), 0., temp, CV_GEMM_B_T ); cvtest::copy( temp, input ); } if( (flags & CV_SVD_MODIFY_A) && test_array[OUTPUT][0] ) cvtest::copy( input, test_mat[OUTPUT][0] ); } return code; } void Core_SVDTest::get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ) { low = cvScalarAll(-2.); high = cvScalarAll(2.); } double Core_SVDTest::get_success_error_level( int test_case_idx, int i, int j ) { int input_depth = CV_MAT_DEPTH(cvGetElemType( test_array[INPUT][0] )); double input_precision = input_depth < CV_32F ? 0 : input_depth == CV_32F ? 1e-5 : 5e-11; double output_precision = Base::get_success_error_level( test_case_idx, i, j ); return MAX(input_precision, output_precision); } void Core_SVDTest::run_func() { CvArr* src = test_array[!(flags & CV_SVD_MODIFY_A) ? INPUT : OUTPUT][0]; if( !src ) src = test_array[INPUT][0]; cvSVD( src, test_array[TEMP][0], test_array[TEMP][1], test_array[TEMP][2], flags ); } void Core_SVDTest::prepare_to_validation( int /*test_case_idx*/ ) { Mat& input = test_mat[INPUT][0]; int depth = input.depth(); int i, m = input.rows, n = input.cols, min_size = MIN(m, n); Mat *src, *dst, *w; double prev = 0, threshold = depth == CV_32F ? FLT_EPSILON : DBL_EPSILON; if( have_u ) { src = &test_mat[TEMP][1]; dst = &test_mat[OUTPUT][1]; cvtest::gemm( *src, *src, 1., Mat(), 0., *dst, src->rows == dst->rows ? CV_GEMM_B_T : CV_GEMM_A_T ); cv::setIdentity( test_mat[REF_OUTPUT][1], Scalar::all(1.) ); } if( have_v ) { src = &test_mat[TEMP][2]; dst = &test_mat[OUTPUT][2]; cvtest::gemm( *src, *src, 1., Mat(), 0., *dst, src->rows == dst->rows ? CV_GEMM_B_T : CV_GEMM_A_T ); cv::setIdentity( test_mat[REF_OUTPUT][2], Scalar::all(1.) ); } w = &test_mat[TEMP][0]; for( i = 0; i < min_size; i++ ) { double normval = 0, aii; if( w->rows > 1 && w->cols > 1 ) { normval = cvtest::norm( w->row(i), NORM_L1 ); aii = depth == CV_32F ? w->at(i,i) : w->at(i,i); } else { normval = aii = depth == CV_32F ? w->at(i) : w->at(i); } normval = fabs(normval - aii); test_mat[OUTPUT][3].at(i) = aii >= 0 && normval < threshold && (i == 0 || aii <= prev); prev = aii; } test_mat[REF_OUTPUT][3] = Scalar::all(1); if( have_u && have_v ) { if( vector_w ) { test_mat[TEMP][3] = Scalar::all(0); for( i = 0; i < min_size; i++ ) { double val = depth == CV_32F ? w->at(i) : w->at(i); cvSetReal2D( test_array[TEMP][3], i, i, val ); } w = &test_mat[TEMP][3]; } if( m >= n ) { cvtest::gemm( test_mat[TEMP][1], *w, 1., Mat(), 0., test_mat[REF_OUTPUT][0], flags & CV_SVD_U_T ? CV_GEMM_A_T : 0 ); cvtest::gemm( test_mat[REF_OUTPUT][0], test_mat[TEMP][2], 1., Mat(), 0., test_mat[OUTPUT][0], flags & CV_SVD_V_T ? 0 : CV_GEMM_B_T ); } else { cvtest::gemm( *w, test_mat[TEMP][2], 1., Mat(), 0., test_mat[REF_OUTPUT][0], flags & CV_SVD_V_T ? 0 : CV_GEMM_B_T ); cvtest::gemm( test_mat[TEMP][1], test_mat[REF_OUTPUT][0], 1., Mat(), 0., test_mat[OUTPUT][0], flags & CV_SVD_U_T ? CV_GEMM_A_T : 0 ); } cvtest::copy( test_mat[INPUT][0], test_mat[REF_OUTPUT][0] ); } } ///////////////// SVBkSb ///////////////////// class Core_SVBkSbTest : public Core_MatrixTest { public: typedef Core_MatrixTest Base; Core_SVBkSbTest(); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); double get_success_error_level( int test_case_idx, int i, int j ); void get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ); int prepare_test_case( int test_case_idx ); void run_func(); void prepare_to_validation( int test_case_idx ); int flags; bool have_b, symmetric, compact, vector_w; }; Core_SVBkSbTest::Core_SVBkSbTest() : Core_MatrixTest( 2, 1, false, false, 1 ), flags(0), have_b(false), symmetric(false), compact(false), vector_w(false) { test_case_count = 100; test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); } void Core_SVBkSbTest::get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ) { RNG& rng = ts->get_rng(); int bits = cvtest::randInt(rng); Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); int min_size, i, m, n; cv::Size b_size; min_size = MIN( sizes[INPUT][0].width, sizes[INPUT][0].height ); flags = bits & (CV_SVD_MODIFY_A+CV_SVD_U_T+CV_SVD_V_T); have_b = (bits & 16) != 0; symmetric = (bits & 32) != 0; compact = (bits & 64) != 0; vector_w = (bits & 128) != 0; if( symmetric ) sizes[INPUT][0] = Size(min_size, min_size); m = sizes[INPUT][0].height; n = sizes[INPUT][0].width; sizes[INPUT][1] = Size(0,0); b_size = cvSize(m, m); if( have_b ) { sizes[INPUT][1].height = sizes[INPUT][0].height; sizes[INPUT][1].width = cvtest::randInt(rng) % 100 + 1; b_size = sizes[INPUT][1]; } if( compact ) sizes[TEMP][0] = Size(min_size, min_size); else sizes[TEMP][0] = sizes[INPUT][0]; if( vector_w ) { if( bits & 256 ) sizes[TEMP][0] = Size(1, min_size); else sizes[TEMP][0] = Size(min_size, 1); } sizes[TEMP][1] = compact ? Size(min_size, m) : Size(m, m); if( flags & CV_SVD_U_T ) CV_SWAP( sizes[TEMP][1].width, sizes[TEMP][1].height, i ); sizes[TEMP][2] = compact ? Size(n, min_size) : Size(n, n); if( !(flags & CV_SVD_V_T) ) CV_SWAP( sizes[TEMP][2].width, sizes[TEMP][2].height, i ); types[TEMP][0] = types[TEMP][1] = types[TEMP][2] = types[INPUT][0]; types[OUTPUT][0] = types[REF_OUTPUT][0] = types[INPUT][0]; sizes[OUTPUT][0] = sizes[REF_OUTPUT][0] = Size( b_size.width, n ); } int Core_SVBkSbTest::prepare_test_case( int test_case_idx ) { int code = Base::prepare_test_case( test_case_idx ); if( code > 0 ) { Mat& input = test_mat[INPUT][0]; cvTsFloodWithZeros( input, ts->get_rng() ); if( symmetric ) { Mat& temp = test_mat[TEMP][1]; cvtest::gemm( input, input, 1., Mat(), 0., temp, CV_GEMM_B_T ); cvtest::copy( temp, input ); } CvMat _input = cvMat(input); cvSVD( &_input, test_array[TEMP][0], test_array[TEMP][1], test_array[TEMP][2], flags ); } return code; } void Core_SVBkSbTest::get_minmax_bounds( int /*i*/, int /*j*/, int /*type*/, Scalar& low, Scalar& high ) { low = cvScalarAll(-2.); high = cvScalarAll(2.); } double Core_SVBkSbTest::get_success_error_level( int /*test_case_idx*/, int /*i*/, int /*j*/ ) { return CV_MAT_DEPTH(cvGetElemType(test_array[INPUT][0])) == CV_32F ? 1e-3 : 1e-7; } void Core_SVBkSbTest::run_func() { cvSVBkSb( test_array[TEMP][0], test_array[TEMP][1], test_array[TEMP][2], test_array[INPUT][1], test_array[OUTPUT][0], flags ); } void Core_SVBkSbTest::prepare_to_validation( int ) { Mat& input = test_mat[INPUT][0]; int i, m = input.rows, n = input.cols, min_size = MIN(m, n); bool is_float = input.type() == CV_32F; Size w_size = compact ? Size(min_size,min_size) : Size(m,n); Mat& w = test_mat[TEMP][0]; Mat wdb( w_size.height, w_size.width, CV_64FC1 ); CvMat _w = cvMat(w), _wdb = cvMat(wdb); // use exactly the same threshold as in icvSVD... , // so the changes in the library and here should be synchronized. double threshold = cv::sum(w)[0]*(DBL_EPSILON*2);//(is_float ? FLT_EPSILON*10 : DBL_EPSILON*2); wdb = Scalar::all(0); for( i = 0; i < min_size; i++ ) { double wii = vector_w ? cvGetReal1D(&_w,i) : cvGetReal2D(&_w,i,i); cvSetReal2D( &_wdb, i, i, wii > threshold ? 1./wii : 0. ); } Mat u = test_mat[TEMP][1]; Mat v = test_mat[TEMP][2]; Mat b = test_mat[INPUT][1]; if( is_float ) { test_mat[TEMP][1].convertTo(u, CV_64F); test_mat[TEMP][2].convertTo(v, CV_64F); if( !b.empty() ) test_mat[INPUT][1].convertTo(b, CV_64F); } Mat t0, t1; if( !b.empty() ) cvtest::gemm( u, b, 1., Mat(), 0., t0, !(flags & CV_SVD_U_T) ? CV_GEMM_A_T : 0 ); else if( flags & CV_SVD_U_T ) cvtest::copy( u, t0 ); else cvtest::transpose( u, t0 ); cvtest::gemm( wdb, t0, 1, Mat(), 0, t1, 0 ); cvtest::gemm( v, t1, 1, Mat(), 0, t0, flags & CV_SVD_V_T ? CV_GEMM_A_T : 0 ); Mat& dst0 = test_mat[REF_OUTPUT][0]; t0.convertTo(dst0, dst0.type() ); } typedef std::complex complex_type; struct pred_complex { bool operator() (const complex_type& lhs, const complex_type& rhs) const { return fabs(lhs.real() - rhs.real()) > fabs(rhs.real())*FLT_EPSILON ? lhs.real() < rhs.real() : lhs.imag() < rhs.imag(); } }; struct pred_double { bool operator() (const double& lhs, const double& rhs) const { return lhs < rhs; } }; class Core_SolvePolyTest : public cvtest::BaseTest { public: Core_SolvePolyTest(); ~Core_SolvePolyTest(); protected: virtual void run( int start_from ); }; Core_SolvePolyTest::Core_SolvePolyTest() {} Core_SolvePolyTest::~Core_SolvePolyTest() {} void Core_SolvePolyTest::run( int ) { RNG& rng = ts->get_rng(); int fig = 100; double range = 50; double err_eps = 1e-4; for (int idx = 0, max_idx = 1000, progress = 0; idx < max_idx; ++idx) { progress = update_progress(progress, idx-1, max_idx, 0); int n = cvtest::randInt(rng) % 13 + 1; std::vector r(n), ar(n), c(n + 1, 0); std::vector a(n + 1), u(n * 2), ar1(n), ar2(n); int rr_odds = 3; // odds that we get a real root for (int j = 0; j < n;) { if (cvtest::randInt(rng) % rr_odds == 0 || j == n - 1) r[j++] = cvtest::randReal(rng) * range; else { r[j] = complex_type(cvtest::randReal(rng) * range, cvtest::randReal(rng) * range + 1); r[j + 1] = std::conj(r[j]); j += 2; } } for (int j = 0, k = 1 << n, jj, kk; j < k; ++j) { int p = 0; complex_type v(1); for (jj = 0, kk = 1; jj < n && !(j & kk); ++jj, ++p, kk <<= 1) ; for (; jj < n; ++jj, kk <<= 1) { if (j & kk) v *= -r[jj]; else ++p; } c[p] += v; } bool pass = false; double div = 0, s = 0; int cubic_case = idx & 1; for (int maxiter = 100; !pass && maxiter < 10000; maxiter *= 2, cubic_case = (cubic_case + 1) % 2) { for (int j = 0; j < n + 1; ++j) a[j] = c[j].real(); CvMat amat, umat; cvInitMatHeader(&amat, n + 1, 1, CV_64FC1, &a[0]); cvInitMatHeader(&umat, n, 1, CV_64FC2, &u[0]); cvSolvePoly(&amat, &umat, maxiter, fig); for (int j = 0; j < n; ++j) ar[j] = complex_type(u[j * 2], u[j * 2 + 1]); std::sort(r.begin(), r.end(), pred_complex()); std::sort(ar.begin(), ar.end(), pred_complex()); pass = true; if( n == 3 ) { ar2.resize(n); cv::Mat _umat2(3, 1, CV_64F, &ar2[0]), umat2 = _umat2; cvFlip(&amat, &amat, 0); int nr2; if( cubic_case == 0 ) nr2 = cv::solveCubic(cv::cvarrToMat(&amat),umat2); else nr2 = cv::solveCubic(cv::Mat_(cv::cvarrToMat(&amat)), umat2); cvFlip(&amat, &amat, 0); if(nr2 > 0) std::sort(ar2.begin(), ar2.begin()+nr2, pred_double()); ar2.resize(nr2); int nr1 = 0; for(int j = 0; j < n; j++) if( fabs(r[j].imag()) < DBL_EPSILON ) ar1[nr1++] = r[j].real(); pass = pass && nr1 == nr2; if( nr2 > 0 ) { div = s = 0; for(int j = 0; j < nr1; j++) { s += fabs(ar1[j]); div += fabs(ar1[j] - ar2[j]); } div /= s; pass = pass && div < err_eps; } } div = s = 0; for (int j = 0; j < n; ++j) { s += fabs(r[j].real()) + fabs(r[j].imag()); div += sqrt(pow(r[j].real() - ar[j].real(), 2) + pow(r[j].imag() - ar[j].imag(), 2)); } div /= s; pass = pass && div < err_eps; } //test x^3 = 0 cv::Mat coeffs_5623(4, 1, CV_64FC1); cv::Mat r_5623(3, 1, CV_64FC2); coeffs_5623.at(0) = 1; coeffs_5623.at(1) = 0; coeffs_5623.at(2) = 0; coeffs_5623.at(3) = 0; double prec_5623 = cv::solveCubic(coeffs_5623, r_5623); pass = pass && r_5623.at(0) == 0 && r_5623.at(1) == 0 && r_5623.at(2) == 0; pass = pass && prec_5623 == 1; if (!pass) { ts->set_failed_test_info(cvtest::TS::FAIL_INVALID_OUTPUT); ts->printf( cvtest::TS::LOG, "too big diff = %g\n", div ); for (size_t j=0;jprintf( cvtest::TS::LOG, "ar2[%d]=%g\n", j, ar2[j]); ts->printf(cvtest::TS::LOG, "\n"); for (size_t j=0;jprintf( cvtest::TS::LOG, "r[%d]=(%g, %g)\n", j, r[j].real(), r[j].imag()); ts->printf( cvtest::TS::LOG, "\n" ); for (size_t j=0;jprintf( cvtest::TS::LOG, "ar[%d]=(%g, %g)\n", j, ar[j].real(), ar[j].imag()); break; } } } template static void checkRoot(Mat& r, T re, T im) { for (int i = 0; i < r.cols*r.rows; i++) { Vec v = *(Vec*)r.ptr(i); if (fabs(re - v[0]) < 1e-6 && fabs(im - v[1]) < 1e-6) { v[0] = std::numeric_limits::quiet_NaN(); v[1] = std::numeric_limits::quiet_NaN(); return; } } GTEST_NONFATAL_FAILURE_("Can't find root") << "(" << re << ", " << im << ")"; } TEST(Core_SolvePoly, regression_5599) { // x^4 - x^2 = 0, roots: 1, -1, 0, 0 cv::Mat coefs = (cv::Mat_(1,5) << 0, 0, -1, 0, 1 ); { cv::Mat r; double prec; prec = cv::solvePoly(coefs, r); EXPECT_LE(prec, 1e-6); EXPECT_EQ(4u, r.total()); //std::cout << "Preciseness = " << prec << std::endl; //std::cout << "roots:\n" << r << "\n" << std::endl; ASSERT_EQ(CV_32FC2, r.type()); checkRoot(r, 1, 0); checkRoot(r, -1, 0); checkRoot(r, 0, 0); checkRoot(r, 0, 0); } // x^2 - 2x + 1 = 0, roots: 1, 1 coefs = (cv::Mat_(1,3) << 1, -2, 1 ); { cv::Mat r; double prec; prec = cv::solvePoly(coefs, r); EXPECT_LE(prec, 1e-6); EXPECT_EQ(2u, r.total()); //std::cout << "Preciseness = " << prec << std::endl; //std::cout << "roots:\n" << r << "\n" << std::endl; ASSERT_EQ(CV_32FC2, r.type()); checkRoot(r, 1, 0); checkRoot(r, 1, 0); } } class Core_PhaseTest : public cvtest::BaseTest { int t; public: Core_PhaseTest(int t_) : t(t_) {} ~Core_PhaseTest() {} protected: virtual void run(int) { const float maxAngleDiff = 0.5; //in degrees const int axisCount = 8; const int dim = theRNG().uniform(1,10); const float scale = theRNG().uniform(1.f, 100.f); Mat x(axisCount + 1, dim, t), y(axisCount + 1, dim, t); Mat anglesInDegrees(axisCount + 1, dim, t); // fill the data x.row(0).setTo(Scalar(0)); y.row(0).setTo(Scalar(0)); anglesInDegrees.row(0).setTo(Scalar(0)); x.row(1).setTo(Scalar(scale)); y.row(1).setTo(Scalar(0)); anglesInDegrees.row(1).setTo(Scalar(0)); x.row(2).setTo(Scalar(scale)); y.row(2).setTo(Scalar(scale)); anglesInDegrees.row(2).setTo(Scalar(45)); x.row(3).setTo(Scalar(0)); y.row(3).setTo(Scalar(scale)); anglesInDegrees.row(3).setTo(Scalar(90)); x.row(4).setTo(Scalar(-scale)); y.row(4).setTo(Scalar(scale)); anglesInDegrees.row(4).setTo(Scalar(135)); x.row(5).setTo(Scalar(-scale)); y.row(5).setTo(Scalar(0)); anglesInDegrees.row(5).setTo(Scalar(180)); x.row(6).setTo(Scalar(-scale)); y.row(6).setTo(Scalar(-scale)); anglesInDegrees.row(6).setTo(Scalar(225)); x.row(7).setTo(Scalar(0)); y.row(7).setTo(Scalar(-scale)); anglesInDegrees.row(7).setTo(Scalar(270)); x.row(8).setTo(Scalar(scale)); y.row(8).setTo(Scalar(-scale)); anglesInDegrees.row(8).setTo(Scalar(315)); Mat resInRad, resInDeg; phase(x, y, resInRad, false); phase(x, y, resInDeg, true); CV_Assert(resInRad.size() == x.size()); CV_Assert(resInRad.type() == x.type()); CV_Assert(resInDeg.size() == x.size()); CV_Assert(resInDeg.type() == x.type()); // check the result int outOfRangeCount = countNonZero((resInDeg > 360) | (resInDeg < 0)); if(outOfRangeCount > 0) { ts->printf(cvtest::TS::LOG, "There are result angles that are out of range [0, 360] (part of them is %f)\n", static_cast(outOfRangeCount)/resInDeg.total()); ts->set_failed_test_info(cvtest::TS::FAIL_INVALID_OUTPUT); } Mat diff = abs(anglesInDegrees - resInDeg); size_t errDegCount = diff.total() - countNonZero((diff < maxAngleDiff) | ((360 - diff) < maxAngleDiff)); if(errDegCount > 0) { ts->printf(cvtest::TS::LOG, "There are incorrect result angles (in degrees) (part of them is %f)\n", static_cast(errDegCount)/resInDeg.total()); ts->set_failed_test_info(cvtest::TS::FAIL_INVALID_OUTPUT); } Mat convertedRes = resInRad * 180. / CV_PI; double normDiff = cvtest::norm(convertedRes - resInDeg, NORM_INF); if(normDiff > FLT_EPSILON * 180.) { ts->printf(cvtest::TS::LOG, "There are incorrect result angles (in radians)\n"); ts->set_failed_test_info(cvtest::TS::FAIL_INVALID_OUTPUT); } ts->set_failed_test_info(cvtest::TS::OK); } }; TEST(Core_CheckRange_Empty, accuracy) { cv::Mat m; ASSERT_TRUE( cv::checkRange(m) ); } TEST(Core_CheckRange_INT_MAX, accuracy) { cv::Mat m(3, 3, CV_32SC1, cv::Scalar(INT_MAX)); ASSERT_FALSE( cv::checkRange(m, true, 0, 0, INT_MAX) ); ASSERT_TRUE( cv::checkRange(m) ); } TEST(Core_CheckRange_INT_MAX1, accuracy) { cv::Mat m(3, 3, CV_32SC1, cv::Scalar(INT_MAX)); ASSERT_TRUE( cv::checkRange(m, true, 0, 0, INT_MAX+1.0f) ); ASSERT_TRUE( cv::checkRange(m) ); } template class Core_CheckRange : public testing::Test {}; TYPED_TEST_CASE_P(Core_CheckRange); TYPED_TEST_P(Core_CheckRange, Negative) { double min_bound = 4.5; double max_bound = 16.0; TypeParam data[] = {5, 10, 15, 10, 10, 2, 8, 12, 14}; cv::Mat src = cv::Mat(3,3, cv::DataDepth::value, data); cv::Point bad_pt(0, 0); ASSERT_FALSE(checkRange(src, true, &bad_pt, min_bound, max_bound)); ASSERT_EQ(bad_pt.x, 2); ASSERT_EQ(bad_pt.y, 1); } TYPED_TEST_P(Core_CheckRange, Negative3CN) { double min_bound = 4.5; double max_bound = 16.0; TypeParam data[] = { 5, 6, 7, 10, 11, 12, 13, 14, 15, 10, 11, 12, 10, 11, 12, 2, 5, 6, 8, 8, 8, 12, 12, 12, 14, 14, 14}; cv::Mat src = cv::Mat(3,3, CV_MAKETYPE(cv::DataDepth::value, 3), data); cv::Point bad_pt(0, 0); ASSERT_FALSE(checkRange(src, true, &bad_pt, min_bound, max_bound)); ASSERT_EQ(bad_pt.x, 2); ASSERT_EQ(bad_pt.y, 1); } TYPED_TEST_P(Core_CheckRange, Positive) { double min_bound = -1; double max_bound = 16.0; TypeParam data[] = {5, 10, 15, 4, 10, 2, 8, 12, 14}; cv::Mat src = cv::Mat(3,3, cv::DataDepth::value, data); cv::Point bad_pt(0, 0); ASSERT_TRUE(checkRange(src, true, &bad_pt, min_bound, max_bound)); ASSERT_EQ(bad_pt.x, 0); ASSERT_EQ(bad_pt.y, 0); } TYPED_TEST_P(Core_CheckRange, Bounds) { double min_bound = 24.5; double max_bound = 1.0; TypeParam data[] = {5, 10, 15, 4, 10, 2, 8, 12, 14}; cv::Mat src = cv::Mat(3,3, cv::DataDepth::value, data); cv::Point bad_pt(0, 0); ASSERT_FALSE(checkRange(src, true, &bad_pt, min_bound, max_bound)); ASSERT_EQ(bad_pt.x, 0); ASSERT_EQ(bad_pt.y, 0); } TYPED_TEST_P(Core_CheckRange, Zero) { double min_bound = 0.0; double max_bound = 0.1; cv::Mat src1 = cv::Mat::zeros(3, 3, cv::DataDepth::value); int sizes[] = {5, 6, 7}; cv::Mat src2 = cv::Mat::zeros(3, sizes, cv::DataDepth::value); ASSERT_TRUE( checkRange(src1, true, NULL, min_bound, max_bound) ); ASSERT_TRUE( checkRange(src2, true, NULL, min_bound, max_bound) ); } TYPED_TEST_P(Core_CheckRange, One) { double min_bound = 1.0; double max_bound = 1.1; cv::Mat src1 = cv::Mat::ones(3, 3, cv::DataDepth::value); int sizes[] = {5, 6, 7}; cv::Mat src2 = cv::Mat::ones(3, sizes, cv::DataDepth::value); ASSERT_TRUE( checkRange(src1, true, NULL, min_bound, max_bound) ); ASSERT_TRUE( checkRange(src2, true, NULL, min_bound, max_bound) ); } TEST(Core_CheckRange, NaN) { float data[] = { 5, 6, 7, 10, 11, 12, 13, 14, 15, 10, 11, 12, 10, 11, 12, 5, 5, std::numeric_limits::quiet_NaN(), 8, 8, 8, 12, 12, 12, 14, 14, 14}; cv::Mat src = cv::Mat(3,3, CV_32FC3, data); cv::Point bad_pt(0, 0); ASSERT_FALSE(checkRange(src, true, &bad_pt)); ASSERT_EQ(bad_pt.x, 2); ASSERT_EQ(bad_pt.y, 1); } TEST(Core_CheckRange, Inf) { float data[] = { 5, 6, 7, 10, 11, 12, 13, 14, 15, 10, 11, 12, 10, 11, 12, 5, 5, std::numeric_limits::infinity(), 8, 8, 8, 12, 12, 12, 14, 14, 14}; cv::Mat src = cv::Mat(3,3, CV_32FC3, data); cv::Point bad_pt(0, 0); ASSERT_FALSE(checkRange(src, true, &bad_pt)); ASSERT_EQ(bad_pt.x, 2); ASSERT_EQ(bad_pt.y, 1); } TEST(Core_CheckRange, Inf_Minus) { float data[] = { 5, 6, 7, 10, 11, 12, 13, 14, 15, 10, 11, 12, 10, 11, 12, 5, 5, -std::numeric_limits::infinity(), 8, 8, 8, 12, 12, 12, 14, 14, 14}; cv::Mat src = cv::Mat(3,3, CV_32FC3, data); cv::Point bad_pt(0, 0); ASSERT_FALSE(checkRange(src, true, &bad_pt)); ASSERT_EQ(bad_pt.x, 2); ASSERT_EQ(bad_pt.y, 1); } REGISTER_TYPED_TEST_CASE_P(Core_CheckRange, Negative, Negative3CN, Positive, Bounds, Zero, One); typedef ::testing::Types mat_data_types; INSTANTIATE_TYPED_TEST_CASE_P(Negative_Test, Core_CheckRange, mat_data_types); TEST(Core_Invert, small) { cv::Mat a = (cv::Mat_(3,3) << 2.42104644730331, 1.81444796521479, -3.98072565304758, 0, 7.08389214348967e-3, 5.55326770986007e-3, 0,0, 7.44556154284261e-3); //cv::randu(a, -1, 1); cv::Mat b = a.t()*a; cv::Mat c, i = Mat_::eye(3, 3); cv::invert(b, c, cv::DECOMP_LU); //std::cout << b*c << std::endl; ASSERT_LT( cvtest::norm(b*c, i, CV_C), 0.1 ); cv::invert(b, c, cv::DECOMP_SVD); //std::cout << b*c << std::endl; ASSERT_LT( cvtest::norm(b*c, i, CV_C), 0.1 ); cv::invert(b, c, cv::DECOMP_CHOLESKY); //std::cout << b*c << std::endl; ASSERT_LT( cvtest::norm(b*c, i, CV_C), 0.1 ); } ///////////////////////////////////////////////////////////////////////////////////////////////////// TEST(Core_CovarMatrix, accuracy) { Core_CovarMatrixTest test; test.safe_run(); } TEST(Core_CrossProduct, accuracy) { Core_CrossProductTest test; test.safe_run(); } TEST(Core_Determinant, accuracy) { Core_DetTest test; test.safe_run(); } TEST(Core_DotProduct, accuracy) { Core_DotProductTest test; test.safe_run(); } TEST(Core_GEMM, accuracy) { Core_GEMMTest test; test.safe_run(); } TEST(Core_Invert, accuracy) { Core_InvertTest test; test.safe_run(); } TEST(Core_Mahalanobis, accuracy) { Core_MahalanobisTest test; test.safe_run(); } TEST(Core_MulTransposed, accuracy) { Core_MulTransposedTest test; test.safe_run(); } TEST(Core_Transform, accuracy) { Core_TransformTest test; test.safe_run(); } TEST(Core_TransformLarge, accuracy) { Core_TransformLargeTest test; test.safe_run(); } TEST(Core_PerspectiveTransform, accuracy) { Core_PerspectiveTransformTest test; test.safe_run(); } TEST(Core_Pow, accuracy) { Core_PowTest test; test.safe_run(); } TEST(Core_SolveLinearSystem, accuracy) { Core_SolveTest test; test.safe_run(); } TEST(Core_SVD, accuracy) { Core_SVDTest test; test.safe_run(); } TEST(Core_SVBkSb, accuracy) { Core_SVBkSbTest test; test.safe_run(); } TEST(Core_Trace, accuracy) { Core_TraceTest test; test.safe_run(); } TEST(Core_SolvePoly, accuracy) { Core_SolvePolyTest test; test.safe_run(); } TEST(Core_Phase, accuracy32f) { Core_PhaseTest test(CV_32FC1); test.safe_run(); } TEST(Core_Phase, accuracy64f) { Core_PhaseTest test(CV_64FC1); test.safe_run(); } TEST(Core_SVD, flt) { float a[] = { 1.23377746e+011f, -7.05490125e+010f, -4.18380882e+010f, -11693456.f, -39091328.f, 77492224.f, -7.05490125e+010f, 2.36211143e+011f, -3.51093473e+010f, 70773408.f, -4.83386156e+005f, -129560368.f, -4.18380882e+010f, -3.51093473e+010f, 9.25311222e+010f, -49052424.f, 43922752.f, 12176842.f, -11693456.f, 70773408.f, -49052424.f, 8.40836094e+004f, 5.17475293e+003f, -1.16122949e+004f, -39091328.f, -4.83386156e+005f, 43922752.f, 5.17475293e+003f, 5.16047969e+004f, 5.68887842e+003f, 77492224.f, -129560368.f, 12176842.f, -1.16122949e+004f, 5.68887842e+003f, 1.28060578e+005f }; float b[] = { 283751232.f, 2.61604198e+009f, -745033216.f, 2.31125625e+005f, -4.52429188e+005f, -1.37596525e+006f }; Mat A(6, 6, CV_32F, a); Mat B(6, 1, CV_32F, b); Mat X, B1; solve(A, B, X, DECOMP_SVD); B1 = A*X; EXPECT_LE(cvtest::norm(B1, B, NORM_L2 + NORM_RELATIVE), FLT_EPSILON*10); } // TODO: eigenvv, invsqrt, cbrt, fastarctan, (round, floor, ceil(?)), enum { MAT_N_DIM_C1, MAT_N_1_CDIM, MAT_1_N_CDIM, MAT_N_DIM_C1_NONCONT, MAT_N_1_CDIM_NONCONT, VECTOR }; class CV_KMeansSingularTest : public cvtest::BaseTest { public: CV_KMeansSingularTest() {} ~CV_KMeansSingularTest() {} protected: void run(int inVariant) { RNG& rng = ts->get_rng(); int i, iter = 0, N = 0, N0 = 0, K = 0, dims = 0; Mat labels; { const int MAX_DIM=5; int MAX_POINTS = 100, maxIter = 100; for( iter = 0; iter < maxIter; iter++ ) { ts->update_context(this, iter, true); dims = rng.uniform(inVariant == MAT_1_N_CDIM ? 2 : 1, MAX_DIM+1); N = rng.uniform(2, MAX_POINTS+1); N0 = rng.uniform(1, MAX(N/10, 2)); K = rng.uniform(1, N+1); Mat centers; if (inVariant == VECTOR) { dims = 2; std::vector data0(N0); rng.fill(data0, RNG::UNIFORM, -1, 1); std::vector data(N); for( i = 0; i < N; i++ ) data[i] = data0[rng.uniform(0, N0)]; kmeans(data, K, labels, TermCriteria(TermCriteria::MAX_ITER+TermCriteria::EPS, 30, 0), 5, KMEANS_PP_CENTERS, centers); } else { Mat data0(N0, dims, CV_32F); rng.fill(data0, RNG::UNIFORM, -1, 1); Mat data; switch (inVariant) { case MAT_N_DIM_C1: data.create(N, dims, CV_32F); for( i = 0; i < N; i++ ) data0.row(rng.uniform(0, N0)).copyTo(data.row(i)); break; case MAT_N_1_CDIM: data.create(N, 1, CV_32FC(dims)); for( i = 0; i < N; i++ ) memcpy(data.ptr(i), data0.ptr(rng.uniform(0, N0)), dims * sizeof(float)); break; case MAT_1_N_CDIM: data.create(1, N, CV_32FC(dims)); for( i = 0; i < N; i++ ) memcpy(data.ptr() + i * dims * sizeof(float), data0.ptr(rng.uniform(0, N0)), dims * sizeof(float)); break; case MAT_N_DIM_C1_NONCONT: data.create(N, dims + 5, CV_32F); data = data(Range(0, N), Range(0, dims)); for( i = 0; i < N; i++ ) data0.row(rng.uniform(0, N0)).copyTo(data.row(i)); break; case MAT_N_1_CDIM_NONCONT: data.create(N, 3, CV_32FC(dims)); data = data.colRange(0, 1); for( i = 0; i < N; i++ ) memcpy(data.ptr(i), data0.ptr(rng.uniform(0, N0)), dims * sizeof(float)); break; } kmeans(data, K, labels, TermCriteria(TermCriteria::MAX_ITER+TermCriteria::EPS, 30, 0), 5, KMEANS_PP_CENTERS, centers); } ASSERT_EQ(centers.rows, K); ASSERT_EQ(labels.rows, N); Mat hist(K, 1, CV_32S, Scalar(0)); for( i = 0; i < N; i++ ) { int l = labels.at(i); ASSERT_GE(l, 0); ASSERT_LT(l, K); hist.at(l)++; } for( i = 0; i < K; i++ ) ASSERT_GT(hist.at(i), 0); } } } }; TEST(Core_KMeans, singular) { CV_KMeansSingularTest test; test.safe_run(MAT_N_DIM_C1); } CV_ENUM(KMeansInputVariant, MAT_N_DIM_C1, MAT_N_1_CDIM, MAT_1_N_CDIM, MAT_N_DIM_C1_NONCONT, MAT_N_1_CDIM_NONCONT, VECTOR) typedef testing::TestWithParam Core_KMeans_InputVariants; TEST_P(Core_KMeans_InputVariants, singular) { CV_KMeansSingularTest test; test.safe_run(GetParam()); } INSTANTIATE_TEST_CASE_P(AllVariants, Core_KMeans_InputVariants, KMeansInputVariant::all()); TEST(Core_KMeans, compactness) { const int N = 1024; const int attempts = 4; const TermCriteria crit = TermCriteria(TermCriteria::COUNT, 5, 0); // low number of iterations cvtest::TS& ts = *cvtest::TS::ptr(); for (int K = 1; K <= N; K *= 2) { Mat data(N, 1, CV_32FC2); cvtest::randUni(ts.get_rng(), data, Scalar(-200, -200), Scalar(200, 200)); Mat labels, centers; double compactness = kmeans(data, K, labels, crit, attempts, KMEANS_PP_CENTERS, centers); centers = centers.reshape(2); EXPECT_EQ(labels.rows, N); EXPECT_EQ(centers.rows, K); EXPECT_GE(compactness, 0.0); double expected = 0.0; for (int i = 0; i < N; ++i) { int l = labels.at(i); Point2f d = data.at(i) - centers.at(l); expected += d.x * d.x + d.y * d.y; } EXPECT_NEAR(expected, compactness, expected * 1e-8); if (K == N) { EXPECT_DOUBLE_EQ(compactness, 0.0); } } } TEST(Core_KMeans, bad_input) { const int N = 100; const int attempts = 4; const TermCriteria crit = TermCriteria(TermCriteria::COUNT, 5, 0); // low number of iterations const int K = 3; Mat data(N, 1, CV_32FC2); cv::randu(data, Scalar(-200, -200), Scalar(200, 200)); { SCOPED_TRACE("Huge value"); data.at(10, 0) = Vec2f(1e20f, 0); Mat labels, centers; EXPECT_ANY_THROW(kmeans(data, K, labels, crit, attempts, KMEANS_PP_CENTERS, centers)); } { SCOPED_TRACE("Negative value"); data.at(10, 0) = Vec2f(0, -1e20f); Mat labels, centers; EXPECT_ANY_THROW(kmeans(data, K, labels, crit, attempts, KMEANS_PP_CENTERS, centers)); } { SCOPED_TRACE("NaN"); data.at(10, 0) = Vec2f(0, std::numeric_limits::quiet_NaN()); Mat labels, centers; EXPECT_ANY_THROW(kmeans(data, K, labels, crit, attempts, KMEANS_PP_CENTERS, centers)); } } TEST(CovariationMatrixVectorOfMat, accuracy) { unsigned int col_problem_size = 8, row_problem_size = 8, vector_size = 16; cv::Mat src(vector_size, col_problem_size * row_problem_size, CV_32F); int singleMatFlags = CV_COVAR_ROWS; cv::Mat gold; cv::Mat goldMean; cv::randu(src,cv::Scalar(-128), cv::Scalar(128)); cv::calcCovarMatrix(src,gold,goldMean,singleMatFlags,CV_32F); std::vector srcVec; for(size_t i = 0; i < vector_size; i++) { srcVec.push_back(src.row(static_cast(i)).reshape(0,col_problem_size)); } cv::Mat actual; cv::Mat actualMean; cv::calcCovarMatrix(srcVec, actual, actualMean,singleMatFlags,CV_32F); cv::Mat diff; cv::absdiff(gold, actual, diff); cv::Scalar s = cv::sum(diff); ASSERT_EQ(s.dot(s), 0.0); cv::Mat meanDiff; cv::absdiff(goldMean, actualMean.reshape(0,1), meanDiff); cv::Scalar sDiff = cv::sum(meanDiff); ASSERT_EQ(sDiff.dot(sDiff), 0.0); } TEST(CovariationMatrixVectorOfMatWithMean, accuracy) { unsigned int col_problem_size = 8, row_problem_size = 8, vector_size = 16; cv::Mat src(vector_size, col_problem_size * row_problem_size, CV_32F); int singleMatFlags = CV_COVAR_ROWS | CV_COVAR_USE_AVG; cv::Mat gold; cv::randu(src,cv::Scalar(-128), cv::Scalar(128)); cv::Mat goldMean; cv::reduce(src,goldMean,0 ,CV_REDUCE_AVG, CV_32F); cv::calcCovarMatrix(src,gold,goldMean,singleMatFlags,CV_32F); std::vector srcVec; for(size_t i = 0; i < vector_size; i++) { srcVec.push_back(src.row(static_cast(i)).reshape(0,col_problem_size)); } cv::Mat actual; cv::Mat actualMean = goldMean.reshape(0, row_problem_size); cv::calcCovarMatrix(srcVec, actual, actualMean,singleMatFlags,CV_32F); cv::Mat diff; cv::absdiff(gold, actual, diff); cv::Scalar s = cv::sum(diff); ASSERT_EQ(s.dot(s), 0.0); cv::Mat meanDiff; cv::absdiff(goldMean, actualMean.reshape(0,1), meanDiff); cv::Scalar sDiff = cv::sum(meanDiff); ASSERT_EQ(sDiff.dot(sDiff), 0.0); } TEST(Core_Pow, special) { for( int i = 0; i < 100; i++ ) { int n = theRNG().uniform(1, 30); Mat mtx0(1, n, CV_8S), mtx, result; randu(mtx0, -5, 5); int type = theRNG().uniform(0, 2) ? CV_64F : CV_32F; double eps = type == CV_32F ? 1e-3 : 1e-10; mtx0.convertTo(mtx, type); // generate power from [-n, n] interval with 1/8 step - enough to check various cases. const int max_pf = 3; int pf = theRNG().uniform(0, max_pf*2+1); double power = ((1 << pf) - (1 << (max_pf*2-1)))/16.; int ipower = cvRound(power); bool is_ipower = ipower == power; cv::pow(mtx, power, result); for( int j = 0; j < n; j++ ) { double val = type == CV_32F ? (double)mtx.at(j) : mtx.at(j); double r = type == CV_32F ? (double)result.at(j) : result.at(j); double r0; if( power == 0. ) r0 = 1; else if( is_ipower ) { r0 = 1; for( int k = 0; k < std::abs(ipower); k++ ) r0 *= val; if( ipower < 0 ) r0 = 1./r0; } else r0 = std::pow(val, power); if( cvIsInf(r0) ) { ASSERT_TRUE(cvIsInf(r) != 0); } else if( cvIsNaN(r0) ) { ASSERT_TRUE(cvIsNaN(r) != 0); } else { ASSERT_TRUE(cvIsInf(r) == 0 && cvIsNaN(r) == 0); ASSERT_LT(fabs(r - r0), eps); } } } } TEST(Core_Cholesky, accuracy64f) { const int n = 5; Mat A(n, n, CV_64F), refA; Mat mean(1, 1, CV_64F); *mean.ptr() = 10.0; Mat dev(1, 1, CV_64F); *dev.ptr() = 10.0; RNG rng(10); rng.fill(A, RNG::NORMAL, mean, dev); A = A*A.t(); A.copyTo(refA); Cholesky(A.ptr(), A.step, n, NULL, 0, 0); for (int i = 0; i < A.rows; i++) for (int j = i + 1; j < A.cols; j++) A.at(i, j) = 0.0; EXPECT_LE(cvtest::norm(refA, A*A.t(), CV_RELATIVE_L2), FLT_EPSILON); } TEST(Core_QR_Solver, accuracy64f) { int m = 20, n = 18; Mat A(m, m, CV_64F); Mat B(m, n, CV_64F); Mat mean(1, 1, CV_64F); *mean.ptr() = 10.0; Mat dev(1, 1, CV_64F); *dev.ptr() = 10.0; RNG rng(10); rng.fill(A, RNG::NORMAL, mean, dev); rng.fill(B, RNG::NORMAL, mean, dev); A = A*A.t(); Mat solutionQR; //solve system with square matrix solve(A, B, solutionQR, DECOMP_QR); EXPECT_LE(cvtest::norm(A*solutionQR, B, CV_RELATIVE_L2), FLT_EPSILON); A = Mat(m, n, CV_64F); B = Mat(m, n, CV_64F); rng.fill(A, RNG::NORMAL, mean, dev); rng.fill(B, RNG::NORMAL, mean, dev); //solve normal system solve(A, B, solutionQR, DECOMP_QR | DECOMP_NORMAL); EXPECT_LE(cvtest::norm(A.t()*(A*solutionQR), A.t()*B, CV_RELATIVE_L2), FLT_EPSILON); //solve overdeterminated system as a least squares problem Mat solutionSVD; solve(A, B, solutionQR, DECOMP_QR); solve(A, B, solutionSVD, DECOMP_SVD); EXPECT_LE(cvtest::norm(solutionQR, solutionSVD, CV_RELATIVE_L2), FLT_EPSILON); //solve system with singular matrix A = Mat(10, 10, CV_64F); B = Mat(10, 1, CV_64F); rng.fill(A, RNG::NORMAL, mean, dev); rng.fill(B, RNG::NORMAL, mean, dev); for (int i = 0; i < A.cols; i++) A.at(0, i) = A.at(1, i); ASSERT_FALSE(solve(A, B, solutionQR, DECOMP_QR)); } TEST(Core_Solve, regression_11888) { cv::Matx A( 2, 1, 3, 1, 6, 1 ); cv::Vec b(4, 5, 7); cv::Matx xQR = A.solve(b, DECOMP_QR); cv::Matx xSVD = A.solve(b, DECOMP_SVD); EXPECT_LE(cvtest::norm(xQR, xSVD, NORM_L2 | NORM_RELATIVE), 0.001); cv::Matx iA = A.inv(DECOMP_SVD); EXPECT_LE(cvtest::norm(iA*A, Matx::eye(), NORM_L2), 1e-3); EXPECT_ANY_THROW({ /*cv::Matx xLU =*/ A.solve(b, DECOMP_LU); std::cout << "FATAL ERROR" << std::endl; }); } TEST(Core_Solve, Matx_2_2) { cv::Matx A( 2, 1, 1, 1 ); cv::Vec b(4, 5); cv::Matx xLU = A.solve(b, DECOMP_LU); cv::Matx xQR = A.solve(b, DECOMP_QR); cv::Matx xSVD = A.solve(b, DECOMP_SVD); EXPECT_LE(cvtest::norm(xQR, xSVD, NORM_L2 | NORM_RELATIVE), 1e-3); EXPECT_LE(cvtest::norm(xQR, xLU, NORM_L2 | NORM_RELATIVE), 1e-3); cv::Matx iA = A.inv(DECOMP_SVD); EXPECT_LE(cvtest::norm(iA*A, Matx::eye(), NORM_L2), 1e-3); } TEST(Core_Solve, Matx_3_3) { cv::Matx A( 2, 1, 0, 0, 1, 1, 1, 0, 1 ); cv::Vec b(4, 5, 6); cv::Matx xLU = A.solve(b, DECOMP_LU); cv::Matx xQR = A.solve(b, DECOMP_QR); cv::Matx xSVD = A.solve(b, DECOMP_SVD); EXPECT_LE(cvtest::norm(xQR, xSVD, NORM_L2 | NORM_RELATIVE), 1e-3); EXPECT_LE(cvtest::norm(xQR, xLU, NORM_L2 | NORM_RELATIVE), 1e-3); cv::Matx iA = A.inv(DECOMP_SVD); EXPECT_LE(cvtest::norm(iA*A, Matx::eye(), NORM_L2), 1e-3); } TEST(Core_Solve, Matx_4_4) { cv::Matx A( 2, 1, 0, 4, 0, 1, 1, 3, 1, 0, 1, 2, 2, 2, 0, 1 ); cv::Vec b(4, 5, 6, 7); cv::Matx xLU = A.solve(b, DECOMP_LU); cv::Matx xQR = A.solve(b, DECOMP_QR); cv::Matx xSVD = A.solve(b, DECOMP_SVD); EXPECT_LE(cvtest::norm(xQR, xSVD, NORM_L2 | NORM_RELATIVE), 1e-3); EXPECT_LE(cvtest::norm(xQR, xLU, NORM_L2 | NORM_RELATIVE), 1e-3); cv::Matx iA = A.inv(DECOMP_SVD); EXPECT_LE(cvtest::norm(iA*A, Matx::eye(), NORM_L2), 1e-3); } softdouble naiveExp(softdouble x) { int exponent = x.getExp(); int sign = x.getSign() ? -1 : 1; if(sign < 0 && exponent >= 10) return softdouble::inf(); softdouble mantissa = x.getFrac(); //Taylor series for mantissa uint64 fac[20] = {1, 2, 6, 24, 120, 720, 5040, 40320, 362880, 3628800, 39916800, 479001600, 6227020800, 87178291200, 1307674368000, 20922789888000, 355687428096000, 6402373705728000, 121645100408832000, 2432902008176640000}; softdouble sum = softdouble::one(); // 21! > (2 ** 64) for(int i = 20; i > 0; i--) sum += pow(mantissa, softdouble(i))/softdouble(fac[i-1]); if(exponent >= 0) { exponent = (1 << exponent); return pow(sum, softdouble(exponent*sign)); } else { if(sign < 0) sum = softdouble::one()/sum; exponent = -exponent; for(int j = 0; j < exponent; j++) sum = sqrt(sum); return sum; } } static float makeFP32(int sign, int exponent, int significand) { Cv32suf x; x.u = (unsigned)(((sign & 1) << 31) | ((exponent&255) << 23) | (significand & 0x7fffff)); return x.f; } static float makeRandomFP32(RNG& rng, int sign, int exprange) { if( sign == -1 ) sign = rng() % 2; int exponent = rng() % exprange; int significand = rng() % (1 << 23); return makeFP32(sign, exponent, significand); } TEST(Core_SoftFloat, exp32) { //special cases EXPECT_TRUE(exp( softfloat::nan()).isNaN()); EXPECT_TRUE(exp( softfloat::inf()).isInf()); EXPECT_EQ (exp(-softfloat::inf()), softfloat::zero()); //ln(FLT_MAX) ~ 88.722 const softfloat ln_max(88.722f); vector inputs; RNG rng(0); inputs.push_back(softfloat::zero()); inputs.push_back(softfloat::one()); inputs.push_back(softfloat::min()); for(int i = 0; i < 50000; i++) { float x = makeRandomFP32(rng, -1, 10+127 //bigger exponent will produce inf ); if(softfloat(x) > ln_max) x = rng.uniform(0.0f, (float)ln_max); inputs.push_back(softfloat(x)); } for(size_t i = 0; i < inputs.size(); i++) { softfloat x(inputs[i]); softfloat y = exp(x); ASSERT_TRUE(!y.isNaN()); ASSERT_TRUE(!y.isInf()); ASSERT_GE(y, softfloat::zero()); softfloat ygood = naiveExp(x); softfloat diff = abs(ygood - y); const softfloat eps = softfloat::eps(); if(diff > eps) { ASSERT_LE(diff/max(abs(y), abs(ygood)), eps); } } } TEST(Core_SoftFloat, exp64) { //special cases EXPECT_TRUE(exp( softdouble::nan()).isNaN()); EXPECT_TRUE(exp( softdouble::inf()).isInf()); EXPECT_EQ (exp(-softdouble::inf()), softdouble::zero()); //ln(DBL_MAX) ~ 709.7827 const softdouble ln_max(709.7827); vector inputs; RNG rng(0); inputs.push_back(softdouble::zero()); inputs.push_back(softdouble::one()); inputs.push_back(softdouble::min()); for(int i = 0; i < 50000; i++) { Cv64suf x; uint64 sign = rng() % 2; uint64 exponent = rng() % (10 + 1023); //bigger exponent will produce inf uint64 mantissa = (((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng)) & ((1LL << 52) - 1); x.u = (sign << 63) | (exponent << 52) | mantissa; if(softdouble(x.f) > ln_max) x.f = rng.uniform(0.0, (double)ln_max); inputs.push_back(softdouble(x.f)); } for(size_t i = 0; i < inputs.size(); i++) { softdouble x(inputs[i]); softdouble y = exp(x); ASSERT_TRUE(!y.isNaN()); ASSERT_TRUE(!y.isInf()); ASSERT_GE(y, softdouble::zero()); softdouble ygood = naiveExp(x); softdouble diff = abs(ygood - y); const softdouble eps = softdouble::eps(); if(diff > eps) { ASSERT_LE(diff/max(abs(y), abs(ygood)), softdouble(8192)*eps); } } } TEST(Core_SoftFloat, log32) { const int nValues = 50000; RNG rng(0); //special cases EXPECT_TRUE(log(softfloat::nan()).isNaN()); for(int i = 0; i < nValues; i++) { softfloat x32(makeRandomFP32(rng, 1, 255)); ASSERT_TRUE(log(x32).isNaN()); } EXPECT_TRUE(log(softfloat::zero()).isInf()); vector inputs; inputs.push_back(softfloat::one()); inputs.push_back(softfloat(exp(softfloat::one()))); inputs.push_back(softfloat::min()); inputs.push_back(softfloat::max()); for(int i = 0; i < nValues; i++) { inputs.push_back(softfloat(makeRandomFP32(rng, 0, 255))); } for(size_t i = 0; i < inputs.size(); i++) { softfloat x(inputs[i]); softfloat y = log(x); ASSERT_TRUE(!y.isNaN()); ASSERT_TRUE(!y.isInf()); softfloat ex = exp(y); softfloat diff = abs(ex - x); // 88 is approx estimate of max exp() argument ASSERT_TRUE(!ex.isInf() || (y > softfloat(88))); const softfloat eps2 = softfloat().setExp(-17); if(!ex.isInf() && diff > softfloat::eps()) { ASSERT_LT(diff/max(abs(ex), x), eps2); } } } TEST(Core_SoftFloat, log64) { const int nValues = 50000; RNG rng(0); //special cases EXPECT_TRUE(log(softdouble::nan()).isNaN()); for(int i = 0; i < nValues; i++) { Cv64suf x; uint64 sign = 1; uint64 exponent = rng() % 2047; uint64 mantissa = (((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng)) & ((1LL << 52) - 1); x.u = (sign << 63) | (exponent << 52) | mantissa; softdouble x64(x.f); ASSERT_TRUE(log(x64).isNaN()); } EXPECT_TRUE(log(softdouble::zero()).isInf()); vector inputs; inputs.push_back(softdouble::one()); inputs.push_back(exp(softdouble::one())); inputs.push_back(softdouble::min()); inputs.push_back(softdouble::max()); for(int i = 0; i < nValues; i++) { Cv64suf x; uint64 sign = 0; uint64 exponent = rng() % 2047; uint64 mantissa = (((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng)) & ((1LL << 52) - 1); x.u = (sign << 63) | (exponent << 52) | mantissa; inputs.push_back(softdouble(x.f)); } for(size_t i = 0; i < inputs.size(); i++) { softdouble x(inputs[i]); softdouble y = log(x); ASSERT_TRUE(!y.isNaN()); ASSERT_TRUE(!y.isInf()); softdouble ex = exp(y); softdouble diff = abs(ex - x); // 700 is approx estimate of max exp() argument ASSERT_TRUE(!ex.isInf() || (y > softdouble(700))); const softdouble eps2 = softdouble().setExp(-41); if(!ex.isInf() && diff > softdouble::eps()) { ASSERT_LT(diff/max(abs(ex), x), eps2); } } } TEST(Core_SoftFloat, cbrt32) { vector inputs; RNG rng(0); inputs.push_back(softfloat::zero()); inputs.push_back(softfloat::one()); inputs.push_back(softfloat::max()); inputs.push_back(softfloat::min()); for(int i = 0; i < 50000; i++) { inputs.push_back(softfloat(makeRandomFP32(rng, -1, 255))); } for(size_t i = 0; i < inputs.size(); i++) { softfloat x(inputs[i]); softfloat y = cbrt(x); ASSERT_TRUE(!y.isNaN()); ASSERT_TRUE(!y.isInf()); softfloat cube = y*y*y; softfloat diff = abs(x - cube); const softfloat eps = softfloat::eps(); if(diff > eps) { ASSERT_LT(diff/max(abs(x), abs(cube)), softfloat(4)*eps); } } } TEST(Core_SoftFloat, pow32) { const softfloat zero = softfloat::zero(), one = softfloat::one(); const softfloat inf = softfloat::inf(), nan = softfloat::nan(); const size_t nValues = 5000; RNG rng(0); //x ** nan == nan for(size_t i = 0; i < nValues; i++) { Cv32suf x; x.u = rng(); ASSERT_TRUE(pow(softfloat(x.f), nan).isNaN()); } //x ** inf check for(size_t i = 0; i < nValues; i++) { Cv32suf x; x.u = rng(); softfloat x32(x.f); softfloat ax = abs(x32); if(x32.isNaN()) { ASSERT_TRUE(pow(x32, inf).isNaN()); } if(ax > one) { ASSERT_TRUE(pow(x32, inf).isInf()); ASSERT_EQ (pow(x32, -inf), zero); } if(ax < one && ax > zero) { ASSERT_TRUE(pow(x32, -inf).isInf()); ASSERT_EQ (pow(x32, inf), zero); } } //+-1 ** inf EXPECT_TRUE(pow( one, inf).isNaN()); EXPECT_TRUE(pow(-one, inf).isNaN()); // x ** 0 == 1 for(size_t i = 0; i < nValues; i++) { Cv32suf x; x.u = rng(); ASSERT_EQ(pow(softfloat(x.f), zero), one); } // x ** 1 == x for(size_t i = 0; i < nValues; i++) { Cv32suf x; x.u = rng(); softfloat x32(x.f); softfloat val = pow(x32, one); // don't compare val and x32 directly because x != x if x is nan ASSERT_EQ(val.v, x32.v); } // nan ** y == nan, if y != 0 for(size_t i = 0; i < nValues; i++) { unsigned u = rng(); softfloat x32 = softfloat::fromRaw(u); x32 = (x32 != softfloat::zero()) ? x32 : softfloat::min(); ASSERT_TRUE(pow(nan, x32).isNaN()); } // nan ** 0 == 1 EXPECT_EQ(pow(nan, zero), one); // inf ** y == 0, if y < 0 // inf ** y == inf, if y > 0 for(size_t i = 0; i < nValues; i++) { float x = makeRandomFP32(rng, 0, 255); softfloat x32 = softfloat(x); ASSERT_TRUE(pow( inf, x32).isInf()); ASSERT_TRUE(pow(-inf, x32).isInf()); ASSERT_EQ(pow( inf, -x32), zero); ASSERT_EQ(pow(-inf, -x32), zero); } // x ** y == (-x) ** y, if y % 2 == 0 // x ** y == - (-x) ** y, if y % 2 == 1 // x ** y == nan, if x < 0 and y is not integer for(size_t i = 0; i < nValues; i++) { softfloat x32(makeRandomFP32(rng, 1, 255)); softfloat y32(makeRandomFP32(rng, -1, 23+127 //bigger exponent produces integer numbers only )); int yi = cvRound(y32); if(y32 != softfloat(yi)) ASSERT_TRUE(pow(x32, y32).isNaN()); else if(yi % 2) ASSERT_EQ(pow(-x32, y32), -pow(x32, y32)); else ASSERT_EQ(pow(-x32, y32), pow(x32, y32)); } // (0 ** 0) == 1 EXPECT_EQ(pow(zero, zero), one); // 0 ** y == inf, if y < 0 // 0 ** y == 0, if y > 0 for(size_t i = 0; i < nValues; i++) { softfloat x32(makeRandomFP32(rng, 0, 255)); ASSERT_TRUE(pow(zero, -x32).isInf()); if(x32 != one) { ASSERT_EQ(pow(zero, x32), zero); } } } TEST(Core_SoftFloat, pow64) { const softdouble zero = softdouble::zero(), one = softdouble::one(); const softdouble inf = softdouble::inf(), nan = softdouble::nan(); const size_t nValues = 5000; RNG rng(0); //x ** nan == nan for(size_t i = 0; i < nValues; i++) { Cv64suf x; x.u = ((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng); ASSERT_TRUE(pow(softdouble(x.f), nan).isNaN()); } //x ** inf check for(size_t i = 0; i < nValues; i++) { Cv64suf x; x.u = ((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng); softdouble x64(x.f); softdouble ax = abs(x64); if(x64.isNaN()) { ASSERT_TRUE(pow(x64, inf).isNaN()); } if(ax > one) { ASSERT_TRUE(pow(x64, inf).isInf()); ASSERT_EQ(pow(x64, -inf), zero); } if(ax < one && ax > zero) { ASSERT_TRUE(pow(x64, -inf).isInf()); ASSERT_EQ(pow(x64, inf), zero); } } //+-1 ** inf EXPECT_TRUE(pow( one, inf).isNaN()); EXPECT_TRUE(pow(-one, inf).isNaN()); // x ** 0 == 1 for(size_t i = 0; i < nValues; i++) { Cv64suf x; x.u = ((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng); ASSERT_EQ(pow(softdouble(x.f), zero), one); } // x ** 1 == x for(size_t i = 0; i < nValues; i++) { Cv64suf x; x.u = ((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng); softdouble x64(x.f); softdouble val = pow(x64, one); // don't compare val and x64 directly because x != x if x is nan ASSERT_EQ(val.v, x64.v); } // nan ** y == nan, if y != 0 for(size_t i = 0; i < nValues; i++) { uint64 u = ((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng); softdouble x64 = softdouble::fromRaw(u); x64 = (x64 != softdouble::zero()) ? x64 : softdouble::min(); ASSERT_TRUE(pow(nan, x64).isNaN()); } // nan ** 0 == 1 EXPECT_EQ(pow(nan, zero), one); // inf ** y == 0, if y < 0 // inf ** y == inf, if y > 0 for(size_t i = 0; i < nValues; i++) { Cv64suf x; uint64 sign = 0; uint64 exponent = rng() % 2047; uint64 mantissa = (((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng)) & ((1LL << 52) - 1); x.u = (sign << 63) | (exponent << 52) | mantissa; softdouble x64(x.f); ASSERT_TRUE(pow( inf, x64).isInf()); ASSERT_TRUE(pow(-inf, x64).isInf()); ASSERT_EQ(pow( inf, -x64), zero); ASSERT_EQ(pow(-inf, -x64), zero); } // x ** y == (-x) ** y, if y % 2 == 0 // x ** y == - (-x) ** y, if y % 2 == 1 // x ** y == nan, if x < 0 and y is not integer for(size_t i = 0; i < nValues; i++) { Cv64suf x; uint64 sign = 1; uint64 exponent = rng() % 2047; uint64 mantissa = (((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng)) & ((1LL << 52) - 1); x.u = (sign << 63) | (exponent << 52) | mantissa; softdouble x64(x.f); Cv64suf y; sign = rng() % 2; //bigger exponent produces integer numbers only //exponent = rng() % (52 + 1023); //bigger exponent is too big exponent = rng() % (23 + 1023); mantissa = (((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng)) & ((1LL << 52) - 1); y.u = (sign << 63) | (exponent << 52) | mantissa; softdouble y64(y.f); uint64 yi = cvRound(y64); if(y64 != softdouble(yi)) ASSERT_TRUE(pow(x64, y64).isNaN()); else if(yi % 2) ASSERT_EQ(pow(-x64, y64), -pow(x64, y64)); else ASSERT_EQ(pow(-x64, y64), pow(x64, y64)); } // (0 ** 0) == 1 EXPECT_EQ(pow(zero, zero), one); // 0 ** y == inf, if y < 0 // 0 ** y == 0, if y > 0 for(size_t i = 0; i < nValues; i++) { Cv64suf x; uint64 sign = 0; uint64 exponent = rng() % 2047; uint64 mantissa = (((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng)) & ((1LL << 52) - 1); x.u = (sign << 63) | (exponent << 52) | mantissa; softdouble x64(x.f); ASSERT_TRUE(pow(zero, -x64).isInf()); if(x64 != one) { ASSERT_EQ(pow(zero, x64), zero); } } } TEST(Core_SoftFloat, sincos64) { static const softdouble two = softdouble(2), three = softdouble(3), half = softdouble::one()/two, zero = softdouble::zero(), one = softdouble::one(), pi = softdouble::pi(), piby2 = pi/two, eps = softdouble::eps(), sin45 = sqrt(two)/two, sin60 = sqrt(three)/two; softdouble vstdAngles[] = //x, sin(x), cos(x) { zero, zero, one, pi/softdouble(6), half, sin60, pi/softdouble(4), sin45, sin45, pi/three, sin60, half, }; vector stdAngles; stdAngles.assign(vstdAngles, vstdAngles + 3*4); static const softdouble stdEps = eps.setExp(-39); const size_t nStdValues = 5000; for(size_t i = 0; i < nStdValues; i++) { for(size_t k = 0; k < stdAngles.size()/3; k++) { softdouble x = stdAngles[k*3] + pi*softdouble(2*((int)i-(int)nStdValues/2)); softdouble s = stdAngles[k*3+1]; softdouble c = stdAngles[k*3+2]; ASSERT_LE(abs(sin(x) - s), stdEps); ASSERT_LE(abs(cos(x) - c), stdEps); //sin(x+pi/2) = cos(x) ASSERT_LE(abs(sin(x + piby2) - c), stdEps); //sin(x+pi) = -sin(x) ASSERT_LE(abs(sin(x + pi) + s), stdEps); //cos(x+pi/2) = -sin(x) ASSERT_LE(abs(cos(x+piby2) + s), stdEps); //cos(x+pi) = -cos(x) ASSERT_LE(abs(cos(x+pi) + c), stdEps); } } // sin(x) is NaN iff x ix NaN or Inf EXPECT_TRUE(sin(softdouble::inf()).isNaN()); EXPECT_TRUE(sin(softdouble::nan()).isNaN()); vector exponents; exponents.push_back(0); for(int i = 1; i < 52; i++) { exponents.push_back( i); exponents.push_back(-i); } exponents.push_back(256); exponents.push_back(-256); exponents.push_back(512); exponents.push_back(-512); exponents.push_back(1022); exponents.push_back(-1022); vector inputs; RNG rng(0); static const size_t nValues = 1 << 18; for(size_t i = 0; i < nValues; i++) { softdouble x; uint64 mantissa = (((long long int)((unsigned int)(rng)) << 32 ) | (unsigned int)(rng)) & ((1LL << 52) - 1); x.v = mantissa; x = x.setSign((rng() % 2) != 0); x = x.setExp(exponents[rng() % exponents.size()]); inputs.push_back(x); } for(size_t i = 0; i < inputs.size(); i++) { softdouble x = inputs[i]; int xexp = x.getExp(); softdouble randEps = eps.setExp(std::max(xexp-52, -46)); softdouble sx = sin(x); softdouble cx = cos(x); ASSERT_FALSE(sx.isInf()); ASSERT_FALSE(cx.isInf()); ASSERT_FALSE(sx.isNaN()); ASSERT_FALSE(cx.isNaN()); ASSERT_LE(abs(sx), one); ASSERT_LE(abs(cx), one); ASSERT_LE(abs((sx*sx + cx*cx) - one), eps); ASSERT_LE(abs(sin(x*two) - two*sx*cx), randEps); ASSERT_LE(abs(cos(x*two) - (cx*cx - sx*sx)), randEps); ASSERT_LE(abs(sin(-x) + sx), eps); ASSERT_LE(abs(cos(-x) - cx), eps); ASSERT_LE(abs(sin(x + piby2) - cx), randEps); ASSERT_LE(abs(sin(x + pi) + sx), randEps); ASSERT_LE(abs(cos(x+piby2) + sx), randEps); ASSERT_LE(abs(cos(x+pi) + cx), randEps); } } TEST(Core_SoftFloat, CvRound) { struct { uint64_t inVal; int64_t out64; int32_t out32; } _values[] = { { 0x0123456789abcdefU, 0, 0 }, // 3.51270056408850369812238561681E-303 { 0x0000000000000000U, 0, 0 }, // 0 { 0x8000000000000000U, 0, 0 }, // -0 { 0x000123456789abcdU, 0, 0 }, // 1.5822747438273385725152200433E-309 { 0x800123456789abcdU, 0, 0 }, // -1.5822747438273385725152200433E-309 { 0x7ff0000000000000U, INT64_MAX, INT32_MAX }, // +inf { 0xfff0000000000000U, INT64_MIN, INT32_MIN }, // -inf { 0x7ff0000000000001U, INT64_MAX, INT32_MAX }, // nan(casts to maximum value) { 0xfff0000000000001U, INT64_MAX, INT32_MAX }, // nan(casts to maximum value) { 0x7ffa5a5a5a5a5a5aU, INT64_MAX, INT32_MAX }, // nan(casts to maximum value) { 0xfffa5a5a5a5a5a5aU, INT64_MAX, INT32_MAX }, // nan(casts to maximum value) { 0x7fe123456789abcdU, INT64_MAX, INT32_MAX }, // 9.627645455595956656406699747E307 { 0xffe123456789abcdU, INT64_MIN, INT32_MIN }, // -9.627645455595956656406699747E307 { 0x43ffffffffffffffU, INT64_MAX, INT32_MAX }, // (2^53-1)*2^12 { 0xc3ffffffffffffffU, INT64_MIN, INT32_MIN }, // -(2^53-1)*2^12 { 0x43f0000000000000U, INT64_MAX, INT32_MAX }, // 2^64 { 0xc3f0000000000000U, INT64_MIN, INT32_MIN }, // -2^64 { 0x43efffffffffffffU, INT64_MAX, INT32_MAX }, // (2^53-1)*2^11 { 0xc3efffffffffffffU, INT64_MIN, INT32_MIN }, // -(2^53-1)*2^11 { 0x43e0000000000000U, INT64_MAX, INT32_MAX }, // 2^63 { 0xc3e0000000000000U, -0x7fffffffffffffff-1, INT32_MIN }, // -2^63 { 0x43dfffffffffffffU, 0x7ffffffffffffc00, INT32_MAX }, // (2^53-1)*2^10 { 0xc3dfffffffffffffU, -0x7ffffffffffffc00, INT32_MIN }, // -(2^53-1)*2^10 { 0x433fffffffffffffU, 0x1fffffffffffff, INT32_MAX }, // (2^53-1) { 0xc33fffffffffffffU, -0x1fffffffffffff, INT32_MIN }, // -(2^53-1) { 0x432fffffffffffffU, 0x10000000000000, INT32_MAX }, // (2^52-1) + 0.5 { 0xc32fffffffffffffU, -0x10000000000000, INT32_MIN }, // -(2^52-1) - 0.5 { 0x431fffffffffffffU, 0x8000000000000, INT32_MAX }, // (2^51-1) + 0.75 { 0xc31fffffffffffffU, -0x8000000000000, INT32_MIN }, // -(2^51-1) - 0.75 { 0x431ffffffffffffeU, 0x8000000000000, INT32_MAX }, // (2^51-1) + 0.5 { 0xc31ffffffffffffeU, -0x8000000000000, INT32_MIN }, // -(2^51-1) - 0.5 { 0x431ffffffffffffdU, 0x7ffffffffffff, INT32_MAX }, // (2^51-1) + 0.25 { 0xc31ffffffffffffdU, -0x7ffffffffffff, INT32_MIN }, // -(2^51-1) - 0.25 { 0x41f0000000000000U, 0x100000000, INT32_MAX }, // 2^32 = 4294967296 { 0xc1f0000000000000U, -0x100000000, INT32_MIN }, // -2^32 = -4294967296 { 0x41efffffffffffffU, 0x100000000, INT32_MAX }, // 4294967295.99999952316284179688 { 0xc1efffffffffffffU, -0x100000000, INT32_MIN }, // -4294967295.99999952316284179688 { 0x41effffffff00000U, 0x100000000, INT32_MAX }, // (2^32-1) + 0.5 = 4294967295.5 { 0xc1effffffff00000U, -0x100000000, INT32_MIN }, // -(2^32-1) - 0.5 = -4294967295.5 { 0x41efffffffe00000U, 0xffffffffll, INT32_MAX }, // (2^32-1) { 0xc1efffffffe00000U, -0xffffffffll, INT32_MIN }, // -(2^32-1) { 0x41e0000000000000U, 0x80000000ll, INT32_MAX }, // 2^31 = 2147483648 { 0xc1e0000000000000U, -0x80000000ll, -0x7fffffff-1 }, // -2^31 = -2147483648 { 0x41dfffffffffffffU, 0x80000000ll, INT32_MAX }, // 2147483647.99999976158142089844 { 0xc1dfffffffffffffU, -0x80000000ll, -0x7fffffff-1 }, // -2147483647.99999976158142089844 { 0x41dffffffff00000U, 0x80000000ll, INT32_MAX }, // (2^31-1) + 0.75 { 0xc1dffffffff00000U, -0x80000000ll, -0x7fffffff-1 }, // -(2^31-1) - 0.75 { 0x41dfffffffe00001U, 0x80000000ll, INT32_MAX }, // (2^31-1) + 0.5 + 2^-22 { 0xc1dfffffffe00001U, -0x80000000ll, -0x7fffffff-1 }, // -(2^31-1) - 0.5 - 2^-22 { 0x41dfffffffe00000U, 0x80000000ll, INT32_MAX }, // (2^31-1) + 0.5 { 0xc1dfffffffe00000U, -0x80000000ll, -0x7fffffff-1 }, // -(2^31-1) - 0.5 { 0x41dfffffffdfffffU, 0x7fffffff, 0x7fffffff }, // (2^31-1) + 0.5 - 2^-22 { 0xc1dfffffffdfffffU, -0x7fffffff, -0x7fffffff }, // -(2^31-1) - 0.5 + 2^-22 { 0x41dfffffffd00000U, 0x7fffffff, 0x7fffffff }, // (2^31-1) + 0.25 { 0xc1dfffffffd00000U, -0x7fffffff, -0x7fffffff }, // -(2^31-1) - 0.25 { 0x41dfffffffc00000U, 0x7fffffff, 0x7fffffff }, // (2^31-1) { 0xc1dfffffffc00000U, -0x7fffffff, -0x7fffffff }, // -(2^31-1) { 0x41d0000000000000U, 0x40000000, 0x40000000 }, // 2^30 = 2147483648 { 0xc1d0000000000000U, -0x40000000, -0x40000000 }, // -2^30 = -2147483648 { 0x4006000000000000U, 3, 3 }, // 2.75 { 0xc006000000000000U, -3, -3 }, // -2.75 { 0x4004000000000001U, 3, 3 }, // 2.5 + 2^-51 { 0xc004000000000001U, -3, -3 }, // -2.5 - 2^-51 { 0x4004000000000000U, 2, 2 }, // 2.5 { 0xc004000000000000U, -2, -2 }, // -2.5 { 0x4003ffffffffffffU, 2, 2 }, // 2.5 - 2^-51 { 0xc003ffffffffffffU, -2, -2 }, // -2.5 + 2^-51 { 0x4002000000000000U, 2, 2 }, // 2.25 { 0xc002000000000000U, -2, -2 }, // -2.25 { 0x3ffc000000000000U, 2, 2 }, // 1.75 { 0xbffc000000000000U, -2, -2 }, // -1.75 { 0x3ff8000000000001U, 2, 2 }, // 1.5 + 2^-52 { 0xbff8000000000001U, -2, -2 }, // -1.5 - 2^-52 { 0x3ff8000000000000U, 2, 2 }, // 1.5 { 0xbff8000000000000U, -2, -2 }, // -1.5 { 0x3ff7ffffffffffffU, 1, 1 }, // 1.5 - 2^-52 { 0xbff7ffffffffffffU, -1, -1 }, // -1.5 + 2^-52 { 0x3ff4000000000000U, 1, 1 }, // 1.25 { 0xbff4000000000000U, -1, -1 }, // -1.25 { 0x3fe8000000000000U, 1, 1 }, // 0.75 { 0xbfe8000000000000U, -1, -1 }, // -0.75 { 0x3fe0000000000001U, 1, 1 }, // 0.5 + 2^-53 { 0xbfe0000000000001U, -1, -1 }, // -0.5 - 2^-53 { 0x3fe0000000000000U, 0, 0 }, // 0.5 { 0xbfe0000000000000U, 0, 0 }, // -0.5 { 0x3fd8000000000000U, 0, 0 }, // 0.375 { 0xbfd8000000000000U, 0, 0 }, // -0.375 { 0x3fd0000000000000U, 0, 0 }, // 0.25 { 0xbfd0000000000000U, 0, 0 }, // -0.25 { 0x0ff123456789abcdU, 0, 0 }, // 6.89918601543515033558134828315E-232 { 0x8ff123456789abcdU, 0, 0 } // -6.89918601543515033558134828315E-232 }; struct testvalues { softdouble inVal; int64_t out64; int32_t out32; } *values = (testvalues*)_values; for (int i = 0, maxi = sizeof(_values) / sizeof(_values[0]); i < maxi; i++) { EXPECT_EQ(values[i].out64, cvRound64(values[i].inVal)); EXPECT_EQ(values[i].out64, saturate_cast(values[i].inVal)); EXPECT_EQ((uint64_t)(values[i].out64), saturate_cast(values[i].inVal)); EXPECT_EQ(values[i].out32, cvRound(values[i].inVal)); EXPECT_EQ(values[i].out32, saturate_cast(values[i].inVal)); EXPECT_EQ((uint32_t)(values[i].out32), saturate_cast(values[i].inVal)); } } template static void checkRounding(T in, int outCeil, int outFloor) { EXPECT_EQ(outCeil,cvCeil(in)); EXPECT_EQ(outFloor,cvFloor(in)); /* cvRound is not expected to be IEEE compliant. The implementation should round to one of the above. */ EXPECT_TRUE((cvRound(in) == outCeil) || (cvRound(in) == outFloor)); } TEST(Core_FastMath, InlineRoundingOps) { struct { double in; int outCeil; int outFloor; } values[] = { // Values are chosen to convert to binary float 32/64 exactly { 1.0, 1, 1 }, { 1.5, 2, 1 }, { -1.5, -1, -2} }; for (int i = 0, maxi = sizeof(values) / sizeof(values[0]); i < maxi; i++) { checkRounding(values[i].in, values[i].outCeil, values[i].outFloor); checkRounding((float)values[i].in, values[i].outCeil, values[i].outFloor); } } TEST(Core_FastMath, InlineNaN) { EXPECT_EQ( cvIsNaN((float) NAN), 1); EXPECT_EQ( cvIsNaN((float) -NAN), 1); EXPECT_EQ( cvIsNaN(0.0f), 0); EXPECT_EQ( cvIsNaN((double) NAN), 1); EXPECT_EQ( cvIsNaN((double) -NAN), 1); EXPECT_EQ( cvIsNaN(0.0), 0); } TEST(Core_FastMath, InlineIsInf) { // Assume HUGE_VAL is infinity. Strictly speaking, may not always be true. EXPECT_EQ( cvIsInf((float) HUGE_VAL), 1); EXPECT_EQ( cvIsInf((float) -HUGE_VAL), 1); EXPECT_EQ( cvIsInf(0.0f), 0); EXPECT_EQ( cvIsInf((double) HUGE_VAL), 1); EXPECT_EQ( cvIsInf((double) -HUGE_VAL), 1); EXPECT_EQ( cvIsInf(0.0), 0); } }} // namespace /* End of file. */