#include #include "opencv2/imgproc.hpp" #include "opencv2/imgcodecs.hpp" #include "opencv2/highgui.hpp" #include using namespace std; using namespace cv; int maskSize0 = DIST_MASK_5; int voronoiType = -1; int edgeThresh = 100; int distType0 = DIST_L1; // The output and temporary images Mat gray; // threshold trackbar callback static void onTrackbar( int, void* ) { static const Scalar colors[] = { Scalar(0,0,0), Scalar(255,0,0), Scalar(255,128,0), Scalar(255,255,0), Scalar(0,255,0), Scalar(0,128,255), Scalar(0,255,255), Scalar(0,0,255), Scalar(255,0,255) }; int maskSize = voronoiType >= 0 ? DIST_MASK_5 : maskSize0; int distType = voronoiType >= 0 ? DIST_L2 : distType0; Mat edge = gray >= edgeThresh, dist, labels, dist8u; if( voronoiType < 0 ) distanceTransform( edge, dist, distType, maskSize ); else distanceTransform( edge, dist, labels, distType, maskSize, voronoiType ); if( voronoiType < 0 ) { // begin "painting" the distance transform result dist *= 5000; pow(dist, 0.5, dist); Mat dist32s, dist8u1, dist8u2; dist.convertTo(dist32s, CV_32S, 1, 0.5); dist32s &= Scalar::all(255); dist32s.convertTo(dist8u1, CV_8U, 1, 0); dist32s *= -1; dist32s += Scalar::all(255); dist32s.convertTo(dist8u2, CV_8U); Mat planes[] = {dist8u1, dist8u2, dist8u2}; merge(planes, 3, dist8u); } else { dist8u.create(labels.size(), CV_8UC3); for( int i = 0; i < labels.rows; i++ ) { const int* ll = (const int*)labels.ptr(i); const float* dd = (const float*)dist.ptr(i); uchar* d = (uchar*)dist8u.ptr(i); for( int j = 0; j < labels.cols; j++ ) { int idx = ll[j] == 0 || dd[j] == 0 ? 0 : (ll[j]-1)%8 + 1; float scale = 1.f/(1 + dd[j]*dd[j]*0.0004f); int b = cvRound(colors[idx][0]*scale); int g = cvRound(colors[idx][1]*scale); int r = cvRound(colors[idx][2]*scale); d[j*3] = (uchar)b; d[j*3+1] = (uchar)g; d[j*3+2] = (uchar)r; } } } imshow("Distance Map", dist8u ); } static void help(const char** argv) { printf("\nProgram to demonstrate the use of the distance transform function between edge images.\n" "Usage:\n" "%s [image_name -- default image is stuff.jpg]\n" "\nHot keys: \n" "\tESC - quit the program\n" "\tC - use C/Inf metric\n" "\tL1 - use L1 metric\n" "\tL2 - use L2 metric\n" "\t3 - use 3x3 mask\n" "\t5 - use 5x5 mask\n" "\t0 - use precise distance transform\n" "\tv - switch to Voronoi diagram mode\n" "\tp - switch to pixel-based Voronoi diagram mode\n" "\tSPACE - loop through all the modes\n\n", argv[0]); } const char* keys = { "{help h||}{@image |stuff.jpg|input image file}" }; int main( int argc, const char** argv ) { CommandLineParser parser(argc, argv, keys); help(argv); if (parser.has("help")) return 0; string filename = parser.get(0); gray = imread(samples::findFile(filename), 0); if(gray.empty()) { printf("Cannot read image file: %s\n", filename.c_str()); help(argv); return -1; } namedWindow("Distance Map", 1); createTrackbar("Brightness Threshold", "Distance Map", &edgeThresh, 255, onTrackbar, 0); for(;;) { // Call to update the view onTrackbar(0, 0); char c = (char)waitKey(0); if( c == 27 ) break; if( c == 'c' || c == 'C' || c == '1' || c == '2' || c == '3' || c == '5' || c == '0' ) voronoiType = -1; if( c == 'c' || c == 'C' ) distType0 = DIST_C; else if( c == '1' ) distType0 = DIST_L1; else if( c == '2' ) distType0 = DIST_L2; else if( c == '3' ) maskSize0 = DIST_MASK_3; else if( c == '5' ) maskSize0 = DIST_MASK_5; else if( c == '0' ) maskSize0 = DIST_MASK_PRECISE; else if( c == 'v' ) voronoiType = 0; else if( c == 'p' ) voronoiType = 1; else if( c == ' ' ) { if( voronoiType == 0 ) voronoiType = 1; else if( voronoiType == 1 ) { voronoiType = -1; maskSize0 = DIST_MASK_3; distType0 = DIST_C; } else if( distType0 == DIST_C ) distType0 = DIST_L1; else if( distType0 == DIST_L1 ) distType0 = DIST_L2; else if( maskSize0 == DIST_MASK_3 ) maskSize0 = DIST_MASK_5; else if( maskSize0 == DIST_MASK_5 ) maskSize0 = DIST_MASK_PRECISE; else if( maskSize0 == DIST_MASK_PRECISE ) voronoiType = 0; } } return 0; }