/** \file * \brief Image Processing - Global Operations * * See Copyright Notice in im_lib.h */ #ifndef __IM_PROCESS_GLO_H #define __IM_PROCESS_GLO_H #include "im_image.h" #if defined(__cplusplus) extern "C" { #endif /** \defgroup transform Other Domain Transform Operations * \par * Hough, Distance. * * See \ref im_process_glo.h * \ingroup process */ /** Hough Lines Transform. \n * It will detect white lines in a black background. So the source image must be a IM_BINARY image * with the white lines of interest enhanced. The better the threshold with the white lines the better * the line detection. \n * The destiny image must have IM_GRAY, IM_INT, hg_width=180, hg_height=2*rmax+1, * where rmax is the image diagonal/2 (rmax = srqrt(width*width + height*height)). \n * The hough transform defines "cos(theta) * X + sin(theta) * Y = rho" and the parameters are in the interval: \n * theta = "0 .. 179", rho = "-hg_height/2 .. hg_height/2" .\n * Where rho is the perpendicular distance from the center of the image and theta the angle with the normal. * So do not confuse theta with the line angle, they are perpendicular. \n * Returns zero if the counter aborted. \n * Inspired from ideas in XITE, Copyright 1991, Blab, UiO \n * http://www.ifi.uio.no/~blab/Software/Xite/ * * \verbatim im.ProcessHoughLines(src_image: imImage, dst_image: imImage) -> counter: boolean [in Lua 5] \endverbatim * \verbatim im.ProcessHoughLinesNew(image: imImage) -> counter: boolean, new_image: imImage [in Lua 5] \endverbatim * \ingroup transform */ int imProcessHoughLines(const imImage* src_image, imImage* dst_image); /** Draw detected hough lines. \n * The source image must be IM_GRAY and IM_BYTE. The destiny image can be a clone of the source image or * it can be the source image for in place processing. \n * If the hough transform is not NULL, then the hough points are filtered to include only lines * that are significally different from each other. \n * The hough image is the hough transform image, but it is optional and can be NULL. * If not NULL then it will be used to filter lines that are very similar. \n * The hough points image is a hough transform image that was thresholded to a IM_BINARY image, * usually using a Local Max threshold operation (see \ref imProcessLocalMaxThreshold). Again the better the threshold the better the results. \n * The destiny image will be set to IM_MAP, and the detected lines will be drawn using a red color. \n * Returns the number of detected lines. * * \verbatim im.ProcessHoughLinesDraw(src_image: imImage, hough: imImage, hough_points: imImage, dst_image: imImage) -> lines: number [in Lua 5] \endverbatim * \verbatim im.ProcessHoughLinesDrawNew(image: imImage, hough: imImage, hough_points: imImage) -> lines: number, new_image: imImage [in Lua 5] \endverbatim * \ingroup transform */ int imProcessHoughLinesDraw(const imImage* src_image, const imImage* hough, const imImage* hough_points, imImage* dst_image); /** Calculates the Cross Correlation in the frequency domain. \n * CrossCorr(a,b) = IFFT(Conj(FFT(a))*FFT(b)) \n * Images must be of the same size and only destiny image must be of type complex. * * \verbatim im.ProcessCrossCorrelation(src_image1: imImage, src_image2: imImage, dst_image: imImage) [in Lua 5] \endverbatim * \verbatim im.ProcessCrossCorrelationNew(image1: imImage, image2: imImage) -> new_image: imImage [in Lua 5] \endverbatim * \ingroup transform */ void imProcessCrossCorrelation(const imImage* src_image1, const imImage* src_image2, imImage* dst_image); /** Calculates the Auto Correlation in the frequency domain. \n * Uses the cross correlation. * Images must be of the same size and only destiny image must be of type complex. * * \verbatim im.ProcessAutoCorrelation(src_image: imImage, dst_image: imImage) [in Lua 5] \endverbatim * \verbatim im.ProcessAutoCorrelationNew(image: imImage) -> new_image: imImage [in Lua 5] \endverbatim * \ingroup transform */ void imProcessAutoCorrelation(const imImage* src_image, imImage* dst_image); /** Calculates the Distance Transform of a binary image * using an aproximation of the euclidian distance.\n * Each white pixel in the binary image is * assigned a value equal to its distance from the nearest * black pixel. \n * Uses a two-pass algorithm incrementally calculating the distance. \n * Source image must be IM_BINARY, destiny must be IM_FLOAT. * * \verbatim im.ProcessDistanceTransform(src_image: imImage, dst_image: imImage) [in Lua 5] \endverbatim * \verbatim im.ProcessDistanceTransformNew(image: imImage) -> new_image: imImage [in Lua 5] \endverbatim * \ingroup transform */ void imProcessDistanceTransform(const imImage* src_image, imImage* dst_image); /** Marks all the regional maximum of the distance transform. \n * source is IMGRAY/IM_FLOAT destiny in IM_BINARY. \n * We consider maximum all connected pixel values that have smaller pixel values around it. * * \verbatim im.ProcessRegionalMaximum(src_image: imImage, dst_image: imImage) [in Lua 5] \endverbatim * \verbatim im.ProcessRegionalMaximumNew(image: imImage) -> new_image: imImage [in Lua 5] \endverbatim * \ingroup transform */ void imProcessRegionalMaximum(const imImage* src_image, imImage* dst_image); /** \defgroup fourier Fourier Transform Operations * \par * All Fourier transforms use FFTW library version 2.1.5. \n * Although there are newer versions, we build binaries only to version 2 * because it is small and as fast as newer versions. * Source code to use FFTW version 3 is available. * \par * FFTW Copyright Matteo Frigo, Steven G. Johnson and the MIT. \n * http://www.fftw.org \n * See "fftw.h" * \par * Must link with "im_fftw" library. \n * \par * The FFTW lib has a GPL license. The license of the "im_fftw" library is automatically the GPL. * So you cannot use it for commercial applications without contacting the authors. * \par * See \ref im_process_glo.h * \ingroup process */ /** Forward FFT. \n * The result has its lowest frequency at the center of the image. \n * This is an unnormalized fft. \n * Images must be of the same size. Destiny image must be of type complex. * * \verbatim im.ProcessFFT(src_image: imImage, dst_image: imImage) [in Lua 5] \endverbatim * \verbatim im.ProcessFFTNew(image: imImage) -> new_image: imImage [in Lua 5] \endverbatim * \ingroup fourier */ void imProcessFFT(const imImage* src_image, imImage* dst_image); /** Inverse FFT. \n * The image has its lowest frequency restored to the origin before the transform. \n * The result is normalized by (width*height). \n * Images must be of the same size and both must be of type complex. * * \verbatim im.ProcessIFFT(src_image: imImage, dst_image: imImage) [in Lua 5] \endverbatim * \verbatim im.ProcessIFFTNew(image: imImage) -> new_image: imImage [in Lua 5] \endverbatim * \ingroup fourier */ void imProcessIFFT(const imImage* src_image, imImage* dst_image); /** Raw in-place FFT (forward or inverse). \n * The lowest frequency can be centered after forward, or * can be restored to the origin before inverse. \n * The result can be normalized after the transform by sqrt(w*h) [1] or by (w*h) [2], * or left unnormalized [0]. \n * Images must be of the same size and both must be of type complex. * * \verbatim im.ProcessFFTraw(image: imImage, inverse: number, center: number, normalize: number) [in Lua 5] \endverbatim * \ingroup fourier */ void imProcessFFTraw(imImage* image, int inverse, int center, int normalize); /** Auxiliary function for the raw FFT. \n * This is the function used internally to change the lowest frequency position in the image. \n * If the image size has even dimensions the flag "center2origin" is useless. But if it is odd, * you must specify if its from center to origin (usually used before inverse) or * from origin to center (usually used after forward). \n * Notice that this function is used for images in the the frequency domain. \n * Image type must be complex. * * \verbatim im.ProcessSwapQuadrants(image: imImage, center2origin: number) [in Lua 5] \endverbatim * \ingroup fourier */ void imProcessSwapQuadrants(imImage* image, int center2origin); #if defined(__cplusplus) } #endif #endif