Example: img_convolution_fft
C++ example source code:
/* +------------------------------------------------------------------------+ | Mobile Robot Programming Toolkit (MRPT) | | https://www.mrpt.org/ | | | | Copyright (c) 2005-2022, Individual contributors, see AUTHORS file | | See: https://www.mrpt.org/Authors - All rights reserved. | | Released under BSD License. See: https://www.mrpt.org/License | +------------------------------------------------------------------------+ */ #include <mrpt/gui/CDisplayWindow.h> #include <mrpt/img/CImage.h> #include <mrpt/math/CMatrixF.h> #include <mrpt/math/fourier.h> #include <mrpt/system/CTicTac.h> #include <iostream> using namespace mrpt; using namespace mrpt::img; using namespace mrpt::gui; using namespace mrpt::math; using namespace mrpt::system; using namespace std; #include <mrpt/examples_config.h> string myDataDir(MRPT_EXAMPLES_BASE_DIRECTORY + string("img_convolution_fft/")); // ------------------------------------------------------ // TestImageConvolutionFFT // ------------------------------------------------------ void TestImageConvolutionFFT() { CTicTac tictac; CImage img; CMatrixF imgCorr; // ==================== 1 =================== if (!img.loadFromFile(myDataDir + string("test_image.jpg"))) throw std::runtime_error("Cannot load test image!"); printf( "Computing %ux%u image convolution ...", (unsigned)img.getWidth(), (unsigned)img.getHeight()); CMatrixF res_R, res_I; double meanTime = 0; int N = 3; // Convolution using FFT 2D: for (int nTimes = 0; nTimes < N; nTimes++) { tictac.Tic(); size_t x, y; size_t actual_lx = img.getWidth(); size_t actual_ly = img.getHeight(); size_t lx = mrpt::round2up(actual_lx); size_t ly = mrpt::round2up(actual_ly); CMatrixF i1(ly, lx), i2; // Get as matrixes, padded with zeros up to power-of-two sizes: img.getAsMatrix(i1, false); // imgWindow.getAsMatrix(i2,false); i2.loadFromTextFile(myDataDir + string("test_convolution_window.txt")); i2.setSize(ly, lx); if (nTimes == 0) printf("\nMax real:%f Min real:%f\n", i1.maxCoeff(), i1.minCoeff()); // FFT: CMatrixF I1_R, I1_I, I2_R, I2_I; CMatrixF ZEROS(ly, lx); math::dft2_complex(i1, ZEROS, I1_R, I1_I); math::dft2_complex(i2, ZEROS, I2_R, I2_I); // Compute the COMPLEX MULTIPLICATION of I2 by I1: for (y = 0; y < ly; y++) for (x = 0; x < lx; x++) { float r1 = I1_R(y, x); float r2 = I2_R(y, x); float i1 = I1_I(y, x); float i2 = I2_I(y, x); I2_R(y, x) = r1 * r2 - i1 * i2; I2_I(y, x) = r2 * i1 + r1 * i2; } // IFFT: math::idft2_complex(I2_R, I2_I, res_R, res_I); res_R *= 1.0f; // SCALE! meanTime += tictac.Tac(); printf(" Done,%.06fms\n", tictac.Tac() * 1000.0f); printf("Max real:%f Min real:%f\n", res_R.maxCoeff(), res_R.minCoeff()); } printf("Mean time: %.06fms\n", 1000.0f * meanTime / N); CDisplayWindow winR("real"); CImage imgR; imgR.setFromMatrix(res_R, false /*it is not normalized */); winR.showImage(imgR); winR.waitForKey(); // DEBUG_SAVE_MATRIX(res_R); // DEBUG_SAVE_MATRIX(res_I); } // ------------------------------------------------------ // MAIN // ------------------------------------------------------ int main() { try { TestImageConvolutionFFT(); return 0; } catch (const std::exception& e) { std::cerr << "MRPT error: " << mrpt::exception_to_str(e) << std::endl; return -1; } catch (...) { printf("Untyped exception!!"); return -1; } }