test-FDCM.C

00001 /*! @file SceneUnderstanding/test-FDCM.C Test the FDCM */
00002 
00003 // //////////////////////////////////////////////////////////////////// //
00004 // The iLab Neuromorphic Vision C++ Toolkit - Copyright (C) 2000-2005   //
00005 // by the University of Southern California (USC) and the iLab at USC.  //
00006 // See http://iLab.usc.edu for information about this project.          //
00007 // //////////////////////////////////////////////////////////////////// //
00008 // Major portions of the iLab Neuromorphic Vision Toolkit are protected //
00009 // under the U.S. patent ``Computation of Intrinsic Perceptual Saliency //
00010 // in Visual Environments, and Applications'' by Christof Koch and      //
00011 // Laurent Itti, California Institute of Technology, 2001 (patent       //
00012 // pending; application number 09/912,225 filed July 23, 2001; see      //
00013 // http://pair.uspto.gov/cgi-bin/final/home.pl for current status).     //
00014 // //////////////////////////////////////////////////////////////////// //
00015 // This file is part of the iLab Neuromorphic Vision C++ Toolkit.       //
00016 //                                                                      //
00017 // The iLab Neuromorphic Vision C++ Toolkit is free software; you can   //
00018 // redistribute it and/or modify it under the terms of the GNU General  //
00019 // Public License as published by the Free Software Foundation; either  //
00020 // version 2 of the License, or (at your option) any later version.     //
00021 //                                                                      //
00022 // The iLab Neuromorphic Vision C++ Toolkit is distributed in the hope  //
00023 // that it will be useful, but WITHOUT ANY WARRANTY; without even the   //
00024 // implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR      //
00025 // PURPOSE.  See the GNU General Public License for more details.       //
00026 //                                                                      //
00027 // You should have received a copy of the GNU General Public License    //
00028 // along with the iLab Neuromorphic Vision C++ Toolkit; if not, write   //
00029 // to the Free Software Foundation, Inc., 59 Temple Place, Suite 330,   //
00030 // Boston, MA 02111-1307 USA.                                           //
00031 // //////////////////////////////////////////////////////////////////// //
00032 //
00033 // Primary maintainer for this file: Lior Elazary <elazary@usc.edu>
00034 // $HeadURL: $
00035 // $Id: $
00036 //
00037 
00038 #include "Image/Image.H"
00039 #include "Component/ModelManager.H"
00040 #include "Raster/Raster.H"
00041 #include "GUI/DebugWin.H"
00042 #include "FeatureMatching/GHough.H"
00043 #include "FeatureMatching/OriChamferMatching.H"
00044 #include "Image/Rectangle.H"
00045 #include "Image/FilterOps.H"
00046 
00047 #include <signal.h>
00048 #include <sys/types.h>
00049 
00050 int main(const int argc, const char **argv)
00051 {
00052 
00053   MYLOGVERB = LOG_INFO;
00054   ModelManager manager("Test FDCM");
00055 
00056   if (manager.parseCommandLine(
00057         (const int)argc, (const char**)argv, "", 0, 0) == false)
00058     return 1;
00059 
00060   manager.start();
00061 
00062   //LMLineMatcher lineMatcher;
00063   //lineMatcher.Configure("para_line_matcher.txt");
00064   
00065 
00066   //Generate a random image
00067   for(float ori=360; ori>10; ori-=10)
00068   {
00069     Image<PixRGB<byte> > inputImg(320,240,ZEROS);
00070     Point2D<int> pos(100,100);
00071     float len=50;
00072     float x1 = cos(ori*M_PI/180)*len/2;
00073     float y1 = sin(ori*M_PI/180)*len/2;
00074 
00075     Point2D<float> p1(pos.i-x1, pos.j+y1);
00076     Point2D<float> p2(pos.i+x1, pos.j-y1);
00077 
00078     drawLine(inputImg, (Point2D<int>)p1, (Point2D<int>)p2, PixRGB<byte>(255,0,0));
00079 
00080 
00081     //Build the FDCM
00082     std::vector<Line> lines;
00083     lines.push_back(Line(p1,p2));
00084     OriChamferMatching matcher(lines,
00085         60, //Num Orientations
00086         2.5, //Direction cost
00087         inputImg.getDims());
00088     
00089   
00090     //lineMatcher.computeIDT3(inputImg.getWidth(), inputImg.getHeight(),
00091     //    lines.size(), &lines[0]);
00092 
00093     //Build the template model and match
00094 
00095     Image<float> costImg(inputImg.getDims(), NO_INIT);
00096     costImg.clear(1e10);
00097     for(int y=0; y<inputImg.getHeight(); y++)
00098     {
00099       for(int x=0; x<inputImg.getWidth(); x++)
00100       {
00101         for(int ori=0; ori < 360; ori++)
00102         {
00103           Point2D<int> pos(x,y);
00104           float len=50;
00105           float x1 = cos((ori)*M_PI/180)*len/2;
00106           float y1 = sin((ori)*M_PI/180)*len/2;
00107 
00108           Point2D<float> p1(pos.i-x1, pos.j+y1);
00109           Point2D<float> p2(pos.i+x1, pos.j-y1);
00110 
00111           Polygon model;
00112           model.addLine(Line(p1,p2));
00113           model.quantize(60);
00114 
00115           for(uint i=0; i<model.getNumLines(); i++)
00116           {
00117             Line l = model.getLine(i);
00118 
00119             float sum = matcher.getCost(l.getDirectionIdx(), Point2D<int>(l.getP1()), Point2D<int>(l.getP2()));
00120             //float sum2 = matcher.getCostFast(l.getDirectionIdx(), Point2D<int>(l.getP1()), Point2D<int>(l.getP2()));
00121             //LINFO("Line %i cost %f %f",i, sum, costImg.getVal(x,y));
00122             if (sum < costImg.getVal(x,y))
00123               costImg.setVal(x,y,sum);
00124           }
00125         }
00126       }
00127       LINFO("Y %i", y);
00128     }
00129     SHOWIMG(costImg);
00130 
00131 
00132     //SHOWIMG(inputImg);
00133   }
00134 
00135     
00136 
00137 
00138   manager.stop();
00139 
00140   return 0;
00141 }
00142