/** \file * \brief Morphology Operations for Gray Images * * See Copyright Notice in im_lib.h * $Id: im_morphology_gray.cpp,v 1.1 2008/10/17 06:16:33 scuri Exp $ */ #include #include #include #include #include "im_process_loc.h" #include "im_process_pon.h" #include #include #include #include #include template static int DoGrayMorphConvolve(T *map, T* new_map, int width, int height, const imImage* kernel, int counter, int ismax, DT) { DT value, *kernel_line, max = 0, min = 0; int offset, new_offset, i, j, x, y, init; int kh, kw, kh2, kw2; kh = kernel->height; kw = kernel->width; kh2 = kernel->height/2; kw2 = kernel->width/2; DT* kernel_data = (DT*)kernel->data[0]; for(j = 0; j < height; j++) { new_offset = j * width; for(i = 0; i < width; i++) { init = 0; for(y = -kh2; y <= kh2; y++) { kernel_line = kernel_data + (y+kh2)*kw; if ((j + y < 0) || // pass the bottom border (j + y >= height)) // pass the top border continue; else offset = (j + y) * width; for(x = -kw2; x <= kw2; x++) { if (kernel_line[x+kw2] != -1) { if ((i + x < 0) || // pass the left border (i + x >= width)) // pass the right border continue; else value = kernel_line[x+kw2] + map[offset + (i + x)]; if (init == 0) // first time here for each pass { if (ismax) max = value; else min = value; init = 1; } else { if (ismax && value > max) max = value; if (!ismax && value < min) min = value; } } } } int size_of = sizeof(imbyte); if (sizeof(T) == size_of) { if (ismax) new_map[new_offset + i] = (T)IM_BYTECROP(max); else new_map[new_offset + i] = (T)IM_BYTECROP(min); } else { if (ismax) new_map[new_offset + i] = (T)max; else new_map[new_offset + i] = (T)min; } } if (!imCounterInc(counter)) return 0; } return 1; } int imProcessGrayMorphConvolve(const imImage* src_image, imImage* dst_image, const imImage *kernel, int ismax) { int ret = 0; int counter = imCounterBegin("Gray Morphological Convolution"); const char* msg = (const char*)imImageGetAttribute(kernel, "Description", NULL, NULL); if (!msg) msg = "Processing..."; imCounterTotal(counter, src_image->depth*src_image->height, msg); imImage* fkernel = NULL; if (src_image->data_type == IM_FLOAT && kernel->data_type != IM_FLOAT) { fkernel = imImageCreate(kernel->width, kernel->height, IM_GRAY, IM_FLOAT); imConvertDataType(kernel, fkernel, 0, 0, 0, IM_CAST_DIRECT); kernel = fkernel; } for (int i = 0; i < src_image->depth; i++) { switch(src_image->data_type) { case IM_BYTE: ret = DoGrayMorphConvolve((imbyte*)src_image->data[i], (imbyte*)dst_image->data[i], src_image->width, src_image->height, kernel, counter, ismax, (int)0); break; case IM_USHORT: ret = DoGrayMorphConvolve((imushort*)src_image->data[i], (imushort*)dst_image->data[i], src_image->width, src_image->height, kernel, counter, ismax, (int)0); break; case IM_INT: ret = DoGrayMorphConvolve((int*)src_image->data[i], (int*)dst_image->data[i], src_image->width, src_image->height, kernel, counter, ismax, (int)0); break; case IM_FLOAT: ret = DoGrayMorphConvolve((float*)src_image->data[i], (float*)dst_image->data[i], src_image->width, src_image->height, kernel, counter, ismax, (float)0); break; } if (!ret) break; } if (fkernel) imImageDestroy(fkernel); imCounterEnd(counter); return ret; } int imProcessGrayMorphErode(const imImage* src_image, imImage* dst_image, int kernel_size) { imImage* kernel = imImageCreate(kernel_size, kernel_size, IM_GRAY, IM_INT); imImageSetAttribute(kernel, "Description", IM_BYTE, -1, (void*)"Erode"); // Kernel is all zeros int ret = imProcessGrayMorphConvolve(src_image, dst_image, kernel, 0); imImageDestroy(kernel); return ret; } int imProcessGrayMorphDilate(const imImage* src_image, imImage* dst_image, int kernel_size) { imImage* kernel = imImageCreate(kernel_size, kernel_size, IM_GRAY, IM_INT); imImageSetAttribute(kernel, "Description", IM_BYTE, -1, (void*)"Dilate"); // Kernel is all zeros int ret = imProcessGrayMorphConvolve(src_image, dst_image, kernel, 1); imImageDestroy(kernel); return ret; } int imProcessGrayMorphOpen(const imImage* src_image, imImage* dst_image, int kernel_size) { imImage*temp = imImageClone(src_image); if (!temp) return 0; if (!imProcessGrayMorphErode(src_image, temp, kernel_size)) {imImageDestroy(temp); return 0;} if (!imProcessGrayMorphDilate(temp, dst_image, kernel_size)) {imImageDestroy(temp); return 0;} imImageDestroy(temp); return 1; } int imProcessGrayMorphClose(const imImage* src_image, imImage* dst_image, int kernel_size) { imImage*temp = imImageClone(src_image); if (!temp) return 0; if (!imProcessGrayMorphDilate(src_image, temp, kernel_size)) {imImageDestroy(temp); return 0;} if (!imProcessGrayMorphErode(temp, dst_image, kernel_size)) {imImageDestroy(temp); return 0;} imImageDestroy(temp); return 1; } int imProcessGrayMorphTopHat(const imImage* src_image, imImage* dst_image, int kernel_size) { if (!imProcessGrayMorphOpen(src_image, dst_image, kernel_size)) return 0; imProcessArithmeticOp(src_image, dst_image, dst_image, IM_BIN_DIFF); return 1; } int imProcessGrayMorphWell(const imImage* src_image, imImage* dst_image, int kernel_size) { if (!imProcessGrayMorphClose(src_image, dst_image, kernel_size)) return 0; imProcessArithmeticOp(src_image, dst_image, dst_image, IM_BIN_DIFF); return 1; } int imProcessGrayMorphGradient(const imImage* src_image, imImage* dst_image, int kernel_size) { imImage*temp = imImageClone(src_image); if (!temp) return 0; if (!imProcessGrayMorphDilate(src_image, temp, kernel_size)) {imImageDestroy(temp); return 0;} if (!imProcessGrayMorphErode(src_image, dst_image, kernel_size)) {imImageDestroy(temp); return 0;} imProcessArithmeticOp(temp, dst_image, dst_image, IM_BIN_DIFF); imImageDestroy(temp); return 1; }