// 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. #include "test_precomp.hpp" namespace opencv_test { namespace { static Mat initDFTWave( int n, bool inv ) { int i; double angle = (inv ? 1 : -1)*CV_PI*2/n; Complexd wi, w1; Mat wave(1, n, CV_64FC2); Complexd* w = wave.ptr(); w1.re = cos(angle); w1.im = sin(angle); w[0].re = wi.re = 1.; w[0].im = wi.im = 0.; for( i = 1; i < n; i++ ) { double t = wi.re*w1.re - wi.im*w1.im; wi.im = wi.re*w1.im + wi.im*w1.re; wi.re = t; w[i] = wi; } return wave; } static void DFT_1D( const Mat& _src, Mat& _dst, int flags, const Mat& _wave=Mat()) { _dst.create(_src.size(), _src.type()); int i, j, k, n = _dst.cols + _dst.rows - 1; Mat wave = _wave; double scale = (flags & DFT_SCALE) ? 1./n : 1.; size_t esz = _src.elemSize(); size_t srcstep = esz, dststep = esz; const uchar* src0 = _src.ptr(); uchar* dst0 = _dst.ptr(); CV_Assert( _src.cols + _src.rows - 1 == n ); if( wave.empty() ) wave = initDFTWave( n, (flags & DFT_INVERSE) != 0 ); const Complexd* w = wave.ptr(); if( !_src.isContinuous() ) srcstep = _src.step; if( !_dst.isContinuous() ) dststep = _dst.step; if( _src.type() == CV_32FC2 ) { for( i = 0; i < n; i++ ) { Complexf* dst = (Complexf*)(dst0 + i*dststep); Complexd sum(0,0); int delta = i; k = 0; for( j = 0; j < n; j++ ) { const Complexf* src = (const Complexf*)(src0 + j*srcstep); sum.re += src->re*w[k].re - src->im*w[k].im; sum.im += src->re*w[k].im + src->im*w[k].re; k += delta; k -= (k >= n ? n : 0); } dst->re = (float)(sum.re*scale); dst->im = (float)(sum.im*scale); } } else if( _src.type() == CV_64FC2 ) { for( i = 0; i < n; i++ ) { Complexd* dst = (Complexd*)(dst0 + i*dststep); Complexd sum(0,0); int delta = i; k = 0; for( j = 0; j < n; j++ ) { const Complexd* src = (const Complexd*)(src0 + j*srcstep); sum.re += src->re*w[k].re - src->im*w[k].im; sum.im += src->re*w[k].im + src->im*w[k].re; k += delta; k -= (k >= n ? n : 0); } dst->re = sum.re*scale; dst->im = sum.im*scale; } } else CV_Error(CV_StsUnsupportedFormat, ""); } static void DFT_2D( const Mat& src, Mat& dst, int flags ) { const int cn = 2; int i; dst.create(src.size(), src.type()); Mat tmp( src.cols, src.rows, src.type()); Mat wave = initDFTWave( dst.cols, (flags & DFT_INVERSE) != 0 ); // 1. row-wise transform for( i = 0; i < dst.rows; i++ ) { Mat srci = src.row(i).reshape(cn, src.cols), dsti = tmp.col(i); DFT_1D(srci, dsti, flags, wave ); } if( (flags & DFT_ROWS) == 0 ) { if( dst.cols != dst.rows ) wave = initDFTWave( dst.rows, (flags & DFT_INVERSE) != 0 ); // 2. column-wise transform for( i = 0; i < dst.cols; i++ ) { Mat srci = tmp.row(i).reshape(cn, tmp.cols), dsti = dst.col(i); DFT_1D(srci, dsti, flags, wave ); } } else cvtest::transpose(tmp, dst); } static Mat initDCTWave( int n, bool inv ) { int i, k; double angle = CV_PI*0.5/n; Mat wave(n, n, CV_64F); double scale = sqrt(1./n); for( k = 0; k < n; k++ ) wave.at(0, k) = scale; scale *= sqrt(2.); for( i = 1; i < n; i++ ) for( k = 0; k < n; k++ ) wave.at(i, k) = scale*cos( angle*i*(2*k + 1) ); if( inv ) cv::transpose( wave, wave ); return wave; } static void DCT_1D( const Mat& _src, Mat& _dst, int flags, const Mat& _wave=Mat() ) { _dst.create( _src.size(), _src.type() ); int i, j, n = _dst.cols + _dst.rows - 1; Mat wave = _wave; int srcstep = 1, dststep = 1; double* w; CV_Assert( _src.cols + _src.rows - 1 == n); if( wave.empty() ) wave = initDCTWave( n, (flags & DFT_INVERSE) != 0 ); w = wave.ptr(); if( !_src.isContinuous() ) srcstep = (int)(_src.step/_src.elemSize()); if( !_dst.isContinuous() ) dststep = (int)(_dst.step/_dst.elemSize()); if( _src.type() == CV_32FC1 ) { float *dst = _dst.ptr(); for( i = 0; i < n; i++, dst += dststep ) { const float* src = _src.ptr(); double sum = 0; for( j = 0; j < n; j++, src += srcstep ) sum += src[0]*w[j]; w += n; dst[0] = (float)sum; } } else if( _src.type() == CV_64FC1 ) { double *dst = _dst.ptr(); for( i = 0; i < n; i++, dst += dststep ) { const double* src = _src.ptr(); double sum = 0; for( j = 0; j < n; j++, src += srcstep ) sum += src[0]*w[j]; w += n; dst[0] = sum; } } else CV_Assert(0); } static void DCT_2D( const Mat& src, Mat& dst, int flags ) { const int cn = 1; int i; dst.create( src.size(), src.type() ); Mat tmp(dst.cols, dst.rows, dst.type() ); Mat wave = initDCTWave( dst.cols, (flags & DCT_INVERSE) != 0 ); // 1. row-wise transform for( i = 0; i < dst.rows; i++ ) { Mat srci = src.row(i).reshape(cn, src.cols); Mat dsti = tmp.col(i); DCT_1D(srci, dsti, flags, wave); } if( (flags & DCT_ROWS) == 0 ) { if( dst.cols != dst.rows ) wave = initDCTWave( dst.rows, (flags & DCT_INVERSE) != 0 ); // 2. column-wise transform for( i = 0; i < dst.cols; i++ ) { Mat srci = tmp.row(i).reshape(cn, tmp.cols); Mat dsti = dst.col(i); DCT_1D( srci, dsti, flags, wave ); } } else cvtest::transpose( tmp, dst ); } static void convertFromCCS( const Mat& _src0, const Mat& _src1, Mat& _dst, int flags ) { if( _dst.rows > 1 && (_dst.cols > 1 || (flags & DFT_ROWS)) ) { int i, count = _dst.rows, len = _dst.cols; bool is2d = (flags & DFT_ROWS) == 0; Mat src0row, src1row, dstrow; for( i = 0; i < count; i++ ) { int j = !is2d || i == 0 ? i : count - i; src0row = _src0.row(i); src1row = _src1.row(j); dstrow = _dst.row(i); convertFromCCS( src0row, src1row, dstrow, 0 ); } if( is2d ) { src0row = _src0.col(0); dstrow = _dst.col(0); convertFromCCS( src0row, src0row, dstrow, 0 ); if( (len & 1) == 0 ) { src0row = _src0.col(_src0.cols - 1); dstrow = _dst.col(len/2); convertFromCCS( src0row, src0row, dstrow, 0 ); } } } else { int i, n = _dst.cols + _dst.rows - 1, n2 = (n+1) >> 1; int cn = _src0.channels(); int srcstep = cn, dststep = 1; if( !_dst.isContinuous() ) dststep = (int)(_dst.step/_dst.elemSize()); if( !_src0.isContinuous() ) srcstep = (int)(_src0.step/_src0.elemSize1()); if( _dst.depth() == CV_32F ) { Complexf* dst = _dst.ptr(); const float* src0 = _src0.ptr(); const float* src1 = _src1.ptr(); int delta0, delta1; dst->re = src0[0]; dst->im = 0; if( (n & 1) == 0 ) { dst[n2*dststep].re = src0[(cn == 1 ? n-1 : n2)*srcstep]; dst[n2*dststep].im = 0; } delta0 = srcstep; delta1 = delta0 + (cn == 1 ? srcstep : 1); if( cn == 1 ) srcstep *= 2; for( i = 1; i < n2; i++, delta0 += srcstep, delta1 += srcstep ) { float t0 = src0[delta0]; float t1 = src0[delta1]; dst[i*dststep].re = t0; dst[i*dststep].im = t1; t0 = src1[delta0]; t1 = -src1[delta1]; dst[(n-i)*dststep].re = t0; dst[(n-i)*dststep].im = t1; } } else { Complexd* dst = _dst.ptr(); const double* src0 = _src0.ptr(); const double* src1 = _src1.ptr(); int delta0, delta1; dst->re = src0[0]; dst->im = 0; if( (n & 1) == 0 ) { dst[n2*dststep].re = src0[(cn == 1 ? n-1 : n2)*srcstep]; dst[n2*dststep].im = 0; } delta0 = srcstep; delta1 = delta0 + (cn == 1 ? srcstep : 1); if( cn == 1 ) srcstep *= 2; for( i = 1; i < n2; i++, delta0 += srcstep, delta1 += srcstep ) { double t0 = src0[delta0]; double t1 = src0[delta1]; dst[i*dststep].re = t0; dst[i*dststep].im = t1; t0 = src1[delta0]; t1 = -src1[delta1]; dst[(n-i)*dststep].re = t0; dst[(n-i)*dststep].im = t1; } } } } static void fixCCS( Mat& mat, int cols, int flags ) { int i, rows = mat.rows; int rows2 = (flags & DFT_ROWS) ? rows : rows/2 + 1, cols2 = cols/2 + 1; CV_Assert( cols2 == mat.cols ); if( mat.type() == CV_32FC2 ) { for( i = 0; i < rows2; i++ ) { Complexf* row = mat.ptr(i); if( (flags & DFT_ROWS) || i == 0 || (i == rows2 - 1 && rows % 2 == 0) ) { row[0].im = 0; if( cols % 2 == 0 ) row[cols2-1].im = 0; } else { Complexf* row2 = mat.ptr(rows-i); row2[0].re = row[0].re; row2[0].im = -row[0].im; if( cols % 2 == 0 ) { row2[cols2-1].re = row[cols2-1].re; row2[cols2-1].im = -row[cols2-1].im; } } } } else if( mat.type() == CV_64FC2 ) { for( i = 0; i < rows2; i++ ) { Complexd* row = mat.ptr(i); if( (flags & DFT_ROWS) || i == 0 || (i == rows2 - 1 && rows % 2 == 0) ) { row[0].im = 0; if( cols % 2 == 0 ) row[cols2-1].im = 0; } else { Complexd* row2 = mat.ptr(rows-i); row2[0].re = row[0].re; row2[0].im = -row[0].im; if( cols % 2 == 0 ) { row2[cols2-1].re = row[cols2-1].re; row2[cols2-1].im = -row[cols2-1].im; } } } } } static void mulComplex( const Mat& src1, const Mat& src2, Mat& dst, int flags ) { dst.create(src1.rows, src1.cols, src1.type()); int i, j, depth = src1.depth(), cols = src1.cols*2; CV_Assert( src1.size == src2.size && src1.type() == src2.type() && (src1.type() == CV_32FC2 || src1.type() == CV_64FC2) ); const Mat* src1_ = &src1; Mat src1_tmp; if (dst.data == src1.data) { src1_tmp = src1.clone(); src1_ = &src1_tmp; } const Mat* src2_ = &src2; Mat src2_tmp; if (dst.data == src2.data) { src2_tmp = src2.clone(); src2_ = &src2_tmp; } for( i = 0; i < dst.rows; i++ ) { if( depth == CV_32F ) { const float* a = src1_->ptr(i); const float* b = src2_->ptr(i); float* c = dst.ptr(i); if( !(flags & CV_DXT_MUL_CONJ) ) for( j = 0; j < cols; j += 2 ) { double re = (double)a[j]*(double)b[j] - (double)a[j+1]*(double)b[j+1]; double im = (double)a[j+1]*(double)b[j] + (double)a[j]*(double)b[j+1]; c[j] = (float)re; c[j+1] = (float)im; } else for( j = 0; j < cols; j += 2 ) { double re = (double)a[j]*(double)b[j] + (double)a[j+1]*(double)b[j+1]; double im = (double)a[j+1]*(double)b[j] - (double)a[j]*(double)b[j+1]; c[j] = (float)re; c[j+1] = (float)im; } } else { const double* a = src1_->ptr(i); const double* b = src2_->ptr(i); double* c = dst.ptr(i); if( !(flags & CV_DXT_MUL_CONJ) ) for( j = 0; j < cols; j += 2 ) { double re = a[j]*b[j] - a[j+1]*b[j+1]; double im = a[j+1]*b[j] + a[j]*b[j+1]; c[j] = re; c[j+1] = im; } else for( j = 0; j < cols; j += 2 ) { double re = a[j]*b[j] + a[j+1]*b[j+1]; double im = a[j+1]*b[j] - a[j]*b[j+1]; c[j] = re; c[j+1] = im; } } } } class CxCore_DXTBaseTest : public cvtest::ArrayTest { public: typedef cvtest::ArrayTest Base; CxCore_DXTBaseTest( bool _allow_complex=false, bool _allow_odd=false, bool _spectrum_mode=false ); protected: void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); int prepare_test_case( int test_case_idx ); double get_success_error_level( int /*test_case_idx*/, int /*i*/, int /*j*/ ); int flags; // transformation flags bool allow_complex; // whether input/output may be complex or not: // true for DFT and MulSpectrums, false for DCT bool allow_odd; // whether input/output may be have odd (!=1) dimensions: // true for DFT and MulSpectrums, false for DCT bool spectrum_mode; // (2 complex/ccs inputs, 1 complex/ccs output): // true for MulSpectrums, false for DFT and DCT bool inplace; // inplace operation (set for each individual test case) bool temp_dst; // use temporary destination (for real->ccs DFT and ccs MulSpectrums) }; CxCore_DXTBaseTest::CxCore_DXTBaseTest( bool _allow_complex, bool _allow_odd, bool _spectrum_mode ) : Base(), flags(0), allow_complex(_allow_complex), allow_odd(_allow_odd), spectrum_mode(_spectrum_mode), inplace(false), temp_dst(false) { test_array[INPUT].push_back(NULL); if( spectrum_mode ) test_array[INPUT].push_back(NULL); test_array[OUTPUT].push_back(NULL); test_array[REF_OUTPUT].push_back(NULL); test_array[TEMP].push_back(NULL); test_array[TEMP].push_back(NULL); max_log_array_size = 9; element_wise_relative_error = spectrum_mode; } void CxCore_DXTBaseTest::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 = cvtest::randInt(rng)%2 + CV_32F; int cn = !allow_complex || !(bits & 256) ? 1 : 2; Size size; Base::get_test_array_types_and_sizes( test_case_idx, sizes, types ); flags = bits & (CV_DXT_INVERSE | CV_DXT_SCALE | CV_DXT_ROWS | CV_DXT_MUL_CONJ); if( spectrum_mode ) flags &= ~CV_DXT_INVERSE; types[TEMP][0] = types[TEMP][1] = types[INPUT][0] = types[OUTPUT][0] = CV_MAKETYPE(depth, cn); size = sizes[INPUT][0]; temp_dst = false; if( flags & CV_DXT_ROWS && (bits&1024) ) { if( bits&16 ) size.width = 1; else size.height = 1; flags &= ~CV_DXT_ROWS; } const int P2_MIN_SIZE = 32; if( ((bits >> 10) & 1) == 0 ) { size.width = (size.width / P2_MIN_SIZE)*P2_MIN_SIZE; size.width = MAX(size.width, 1); size.height = (size.height / P2_MIN_SIZE)*P2_MIN_SIZE; size.height = MAX(size.height, 1); } if( !allow_odd ) { if( size.width > 1 && (size.width&1) != 0 ) size.width = (size.width + 1) & -2; if( size.height > 1 && (size.height&1) != 0 && !(flags & CV_DXT_ROWS) ) size.height = (size.height + 1) & -2; } sizes[INPUT][0] = sizes[OUTPUT][0] = size; sizes[TEMP][0] = sizes[TEMP][1] = cvSize(0,0); if( spectrum_mode ) { if( cn == 1 ) { types[OUTPUT][0] = depth + 8; sizes[TEMP][0] = size; } sizes[INPUT][0] = sizes[INPUT][1] = size; types[INPUT][1] = types[INPUT][0]; } else if( /*(cn == 2 && (bits&32)) ||*/ (cn == 1 && allow_complex) ) { types[TEMP][0] = depth + 8; // CV_??FC2 sizes[TEMP][0] = size; size = cvSize(size.width/2+1, size.height); if( flags & CV_DXT_INVERSE ) { if( cn == 2 ) { types[OUTPUT][0] = depth; sizes[INPUT][0] = size; } types[TEMP][1] = types[TEMP][0]; sizes[TEMP][1] = sizes[TEMP][0]; } else { if( allow_complex ) types[OUTPUT][0] = depth + 8; if( cn == 2 ) { types[INPUT][0] = depth; types[TEMP][1] = types[TEMP][0]; sizes[TEMP][1] = size; } else { types[TEMP][1] = depth; sizes[TEMP][1] = sizes[TEMP][0]; } temp_dst = true; } } inplace = false; if( spectrum_mode || (!temp_dst && types[INPUT][0] == types[OUTPUT][0]) || (temp_dst && types[INPUT][0] == types[TEMP][1]) ) inplace = (bits & 64) != 0; types[REF_OUTPUT][0] = types[OUTPUT][0]; sizes[REF_OUTPUT][0] = sizes[OUTPUT][0]; } double CxCore_DXTBaseTest::get_success_error_level( int test_case_idx, int i, int j ) { return Base::get_success_error_level( test_case_idx, i, j ); } int CxCore_DXTBaseTest::prepare_test_case( int test_case_idx ) { int code = Base::prepare_test_case( test_case_idx ); if( code > 0 ) { int in_type = test_mat[INPUT][0].type(); int out_type = test_mat[OUTPUT][0].type(); if( CV_MAT_CN(in_type) == 2 && CV_MAT_CN(out_type) == 1 ) fixCCS( test_mat[INPUT][0], test_mat[OUTPUT][0].cols, flags ); if( inplace ) cvtest::copy( test_mat[INPUT][test_case_idx & (int)spectrum_mode], temp_dst ? test_mat[TEMP][1] : in_type == out_type ? test_mat[OUTPUT][0] : test_mat[TEMP][0] ); } return code; } ////////////////////// FFT //////////////////////// class CxCore_DFTTest : public CxCore_DXTBaseTest { public: CxCore_DFTTest(); protected: void run_func(); void prepare_to_validation( int test_case_idx ); }; CxCore_DFTTest::CxCore_DFTTest() : CxCore_DXTBaseTest( true, true, false ) { } void CxCore_DFTTest::run_func() { Mat& dst = temp_dst ? test_mat[TEMP][1] : test_mat[OUTPUT][0]; const Mat& src = inplace ? dst : test_mat[INPUT][0]; if(!(flags & CV_DXT_INVERSE)) cv::dft( src, dst, flags ); else cv::idft(src, dst, flags & ~CV_DXT_INVERSE); } void CxCore_DFTTest::prepare_to_validation( int /*test_case_idx*/ ) { Mat& src = test_mat[INPUT][0]; Mat& dst = test_mat[REF_OUTPUT][0]; Mat* tmp_src = &src; Mat* tmp_dst = &dst; int src_cn = src.channels(); int dst_cn = dst.channels(); if( src_cn != 2 || dst_cn != 2 ) { tmp_src = &test_mat[TEMP][0]; if( !(flags & CV_DXT_INVERSE ) ) { Mat& cvdft_dst = test_mat[TEMP][1]; convertFromCCS( cvdft_dst, cvdft_dst, test_mat[OUTPUT][0], flags ); *tmp_src = Scalar::all(0); cvtest::insert( src, *tmp_src, 0 ); } else { convertFromCCS( src, src, *tmp_src, flags ); tmp_dst = &test_mat[TEMP][1]; } } if( src.rows == 1 || (src.cols == 1 && !(flags & CV_DXT_ROWS)) ) DFT_1D( *tmp_src, *tmp_dst, flags ); else DFT_2D( *tmp_src, *tmp_dst, flags ); if( tmp_dst != &dst ) cvtest::extract( *tmp_dst, dst, 0 ); } ////////////////////// DCT //////////////////////// class CxCore_DCTTest : public CxCore_DXTBaseTest { public: CxCore_DCTTest(); protected: void run_func(); void prepare_to_validation( int test_case_idx ); }; CxCore_DCTTest::CxCore_DCTTest() : CxCore_DXTBaseTest( false, false, false ) { } void CxCore_DCTTest::run_func() { Mat& dst = test_mat[OUTPUT][0]; const Mat& src = inplace ? dst : test_mat[INPUT][0]; if(!(flags & CV_DXT_INVERSE)) cv::dct( src, dst, flags ); else cv::idct( src, dst, flags & ~CV_DXT_INVERSE); } void CxCore_DCTTest::prepare_to_validation( int /*test_case_idx*/ ) { const Mat& src = test_mat[INPUT][0]; Mat& dst = test_mat[REF_OUTPUT][0]; if( src.rows == 1 || (src.cols == 1 && !(flags & CV_DXT_ROWS)) ) DCT_1D( src, dst, flags ); else DCT_2D( src, dst, flags ); } ////////////////////// MulSpectrums //////////////////////// class CxCore_MulSpectrumsTest : public CxCore_DXTBaseTest { public: CxCore_MulSpectrumsTest(); protected: void run_func(); void prepare_to_validation( int test_case_idx ); double get_success_error_level( int test_case_idx, int i, int j ); }; CxCore_MulSpectrumsTest::CxCore_MulSpectrumsTest() : CxCore_DXTBaseTest( true, true, true ) { } double CxCore_MulSpectrumsTest::get_success_error_level( int test_case_idx, int i, int j ) { CV_UNUSED(test_case_idx); CV_Assert(i == OUTPUT); CV_Assert(j == 0); int elem_depth = CV_MAT_DEPTH(cvGetElemType(test_array[i][j])); CV_Assert(elem_depth == CV_32F || elem_depth == CV_64F); element_wise_relative_error = false; double maxInputValue = 1000; // ArrayTest::get_minmax_bounds double err = 8 * maxInputValue; // result = A*B + C*D return (elem_depth == CV_32F ? FLT_EPSILON : DBL_EPSILON) * err; } void CxCore_MulSpectrumsTest::run_func() { Mat& dst = !test_mat[TEMP].empty() && !test_mat[TEMP][0].empty() ? test_mat[TEMP][0] : test_mat[OUTPUT][0]; const Mat* src1 = &test_mat[INPUT][0], *src2 = &test_mat[INPUT][1]; if( inplace ) { if( ts->get_current_test_info()->test_case_idx & 1 ) src2 = &dst; else src1 = &dst; } cv::mulSpectrums( *src1, *src2, dst, flags, (flags & CV_DXT_MUL_CONJ) != 0 ); } void CxCore_MulSpectrumsTest::prepare_to_validation( int /*test_case_idx*/ ) { Mat* src1 = &test_mat[INPUT][0]; Mat* src2 = &test_mat[INPUT][1]; Mat& dst = test_mat[OUTPUT][0]; Mat& dst0 = test_mat[REF_OUTPUT][0]; int cn = src1->channels(); if( cn == 1 ) { convertFromCCS( *src1, *src1, dst, flags ); convertFromCCS( *src2, *src2, dst0, flags ); src1 = &dst; src2 = &dst0; } mulComplex( *src1, *src2, dst0, flags ); if( cn == 1 ) { Mat& temp = test_mat[TEMP][0]; convertFromCCS( temp, temp, dst, flags ); } } TEST(Core_DCT, accuracy) { CxCore_DCTTest test; test.safe_run(); } TEST(Core_DFT, accuracy) { CxCore_DFTTest test; test.safe_run(); } TEST(Core_MulSpectrums, accuracy) { CxCore_MulSpectrumsTest test; test.safe_run(); } class Core_DFTComplexOutputTest : public cvtest::BaseTest { public: Core_DFTComplexOutputTest() {} ~Core_DFTComplexOutputTest() {} protected: void run(int) { RNG& rng = theRNG(); for( int i = 0; i < 10; i++ ) { int m = rng.uniform(2, 11); int n = rng.uniform(2, 11); int depth = rng.uniform(0, 2) + CV_32F; Mat src8u(m, n, depth), src(m, n, depth), dst(m, n, CV_MAKETYPE(depth, 2)); Mat z = Mat::zeros(m, n, depth), dstz; randu(src8u, Scalar::all(0), Scalar::all(10)); src8u.convertTo(src, src.type()); dst = Scalar::all(123); Mat mv[] = {src, z}, srcz; merge(mv, 2, srcz); dft(srcz, dstz); dft(src, dst, DFT_COMPLEX_OUTPUT); if (cvtest::norm(dst, dstz, NORM_INF) > 1e-3) { cout << "actual:\n" << dst << endl << endl; cout << "reference:\n" << dstz << endl << endl; CV_Error(CV_StsError, ""); } } } }; TEST(Core_DFT, complex_output) { Core_DFTComplexOutputTest test; test.safe_run(); } TEST(Core_DFT, complex_output2) { for( int i = 0; i < 100; i++ ) { int type = theRNG().uniform(0, 2) ? CV_64F : CV_32F; int m = theRNG().uniform(1, 10); int n = theRNG().uniform(1, 10); Mat x(m, n, type), out; randu(x, -1., 1.); dft(x, out, DFT_ROWS | DFT_COMPLEX_OUTPUT); double nrm = cvtest::norm(out, NORM_INF); double thresh = n*m*2; if( nrm > thresh ) { cout << "x: " << x << endl; cout << "out: " << out << endl; ASSERT_LT(nrm, thresh); } } } class Core_DXTReverseTest : public cvtest::BaseTest { public: enum Mode { ModeDFT, ModeDCT }; Core_DXTReverseTest(Mode m) : mode(m) {} private: Mode mode; protected: void run(int) { for (int i = 0; i < 3; ++i) { if (mode == ModeDCT && i != 0) continue; int flags = 0; int flags_inv = DFT_INVERSE | DFT_SCALE; int cn_in = 0; int cn_out = 0; switch (i) { case 0: cn_in = 1; cn_out = 1; break; case 1: cn_in = 1; cn_out = 2; flags |= DFT_COMPLEX_OUTPUT; flags_inv |= DFT_REAL_OUTPUT; break; case 2: cn_in = 2; cn_out = 2; break; }; for (int j = 0; j < 100; ++j) { RNG& rng = ts->get_rng(); int type = rng.uniform(0, 2) ? CV_64F : CV_32F; int m = rng.uniform(1, 10); int n = rng.uniform(1, 10); if (mode == ModeDCT) { m *= 2; n *= 2; } Mat one(m, n, CV_MAKETYPE(type, cn_in)); cvtest::randUni(rng, one, Scalar::all(-1.), Scalar::all(1.)); Mat out; Mat two; if (mode == ModeDFT) { cv::dft(one, out, flags); cv::dft(out, two, flags_inv); } else if (mode == ModeDCT) { cv::dct(one, out, flags); cv::dct(out, two, flags_inv); } if (out.channels() != cn_out || two.channels() != cn_in || cvtest::norm(one, two, NORM_INF) > 1e-5) { cout << "Test #" << j + 1 << " - " << "elements: " << m << " x " << n << ", " << "channels: " << one.channels() << " (" << cn_in << ")" << " -> " << out.channels() << " (" << cn_out << ")" << " -> " << two.channels() << " (" << cn_in << ")" << endl; cout << "signal:\n" << one << endl << endl; cout << "spectrum:\n" << out << endl << endl; cout << "inverse:\n" << two << endl << endl; ts->set_failed_test_info(cvtest::TS::FAIL_INVALID_OUTPUT); break; } } } } }; TEST(Core_DFT, reverse) { Core_DXTReverseTest test(Core_DXTReverseTest::ModeDFT); test.safe_run(); } TEST(Core_DCT, reverse) { Core_DXTReverseTest test(Core_DXTReverseTest::ModeDCT); test.safe_run(); } }} // namespace