bool testDigitalSetBoardSnippet()
{
typedef SpaceND<2> Z2;
typedef HyperRectDomain<Z2> Domain;
typedef Z2::Point Point;
Point p1( -10, -10 );
Point p2( 10, 10 );
Domain domain( p1, p2 );
typedef DigitalSetSelector < Domain, BIG_DS + HIGH_ITER_DS + HIGH_BEL_DS >::Type SpecificSet;
BOOST_CONCEPT_ASSERT(( concepts::CDigitalSet< SpecificSet > ));
SpecificSet mySet( domain );
Point c( 0, 0 );
mySet.insert( c );
Point d( 5, 2 );
mySet.insert( d );
Point e( 1, -3 );
mySet.insert( e );
Board2D board;
board.setUnit(LibBoard::Board::UCentimeter);
board << mySet;
board.saveSVG("myset-export.svg");
board.clear();
board.setUnit(LibBoard::Board::UCentimeter);
board << SetMode( domain.className(), "Grid" ) << domain << mySet;
board.saveSVG("simpleSet-grid.svg");
board.clear();
board.setUnit(LibBoard::Board::UCentimeter);
board << SetMode( domain.className(), "Paving" ) << domain;
board << mySet;
board.saveSVG("simpleSet-paving.svg");
board.clear();
board.setUnit(LibBoard::Board::UCentimeter);
board << CustomStyle( mySet.className(), new MyDomainStyleCustomRed );
board << mySet;
board.saveSVG("simpleSet-color.svg");
return true;
}
bool testBadKeySizes()
{
typedef SpaceND<2> SpaceType;
typedef HyperRectDomain<SpaceType> TDomain;
typedef TDomain::Point Point;
Board2D board;
typedef HueShadeColorMap<unsigned char,2> HueTwice;
board.setUnit(Board2D::UCentimeter);
//Default image selector = STLVector
typedef ImageContainerByHashTree<TDomain, char> Image;
Point d(128,128);
trace.beginBlock ( "Test maximal depth > number of bits of the HashKey type" );
Image myImage ( 3, 80, 0 );
trace.info() << myImage;
trace.endBlock();
trace.beginBlock ( "Test morton hash size > number of bits of the HashKey type" );
///This should raise an ASSERT abort if uncommented
// Image myImage2 ( 80, 8, 0 );
//trace.info() << myImage2;
trace.endBlock();
//Default image selector = STLVector
typedef ImageContainerByHashTree<TDomain, unsigned int, DGtal::uint32_t> Image2;
trace.beginBlock ( "Changing the HashKey type" );
Image2 myImage3( 3, 80, 0 );
trace.info() << myImage3;
trace.endBlock();
return true;
}
void draw( const TImage aImg, const double& aMaxValue, std::string aBasename)
{
typedef typename TImage::Domain::ConstIterator ConstIteratorOnPoints;
typedef typename TImage::Domain::Point Point;
HueShadeColorMap<double, 2> colorMap(0,aMaxValue);
Board2D b;
b.setUnit ( LibBoard::Board::UCentimeter );
for (ConstIteratorOnPoints it = aImg.domain().begin(), itEnd = aImg.domain().end();
it != itEnd; ++it)
{
Point p = *it;
b << CustomStyle( p.className(), new CustomFillColor( colorMap( aImg(p) ) ) );
b << p;
}
{
std::stringstream s;
s << aBasename << ".eps";
b.saveEPS(s.str().c_str());
}
#ifdef WITH_CAIRO
{
std::stringstream s;
s << aBasename << ".png";
b.saveCairo(s.str().c_str(), Board2D::CairoPNG);
}
#endif
}
/**
* Display
*
*/
bool testDrawGridCurve(const string &filename)
{
GridCurve<KhalimskySpaceND<2> > c; //grid curve
trace.info() << endl;
trace.info() << "Displaying GridCurve " << endl;
//reading grid curve
fstream inputStream;
inputStream.open (filename.c_str(), ios::in);
c.initFromVectorStream(inputStream);
inputStream.close();
//displaying it
Board2D aBoard;
aBoard.setUnit(Board2D::UCentimeter);
aBoard << c;
aBoard.saveEPS( "GridCurve.eps", Board2D::BoundingBox, 5000 );
#ifdef WITH_CAIRO
aBoard.saveCairo("GridCurve-cairo.pdf", Board2D::CairoPDF, Board2D::BoundingBox, 5000);
#endif
return true;
}
bool testDrawRange(const Range &aRange, const string &aName, const string& aDomainMode)
{
std::stringstream s;
s << aName << "Range.eps";
trace.info() << endl;
trace.info() << "Drawing " << s.str() << " (" << aRange.size() << " elts)" << endl;
//board
Board2D aBoard;
aBoard.setUnit(Board2D::UCentimeter);
//displaying domain
PointVector<2,int> low(-1,-1);
PointVector<2,int> up(3,3);
if (aDomainMode == "Paving") up = PointVector<2,int>(4,4);
HyperRectDomain< SpaceND<2,int> > aDomain( low,up );
aBoard << SetMode(aDomain.className(), aDomainMode) << aDomain;
//displaying range
aBoard << aRange;
//save
aBoard.saveEPS( s.str().c_str(), Board2D::BoundingBox, 5000 );
return true;
}
bool testDigitalSetBoardSnippet()
{
typedef SpaceND<2> Z2;
typedef HyperRectDomain<Z2> Domain;
typedef Z2::Point Point;
Point p1( -10, -10 );
Point p2( 10, 10 );
Domain domain( p1, p2 );
typedef DigitalSetSelector < Domain, BIG_DS + HIGH_ITER_DS + HIGH_BEL_DS >::Type SpecificSet;
SpecificSet mySet( domain );
Point c( 0, 0 );
mySet.insert( c );
Point d( 5, 2 );
mySet.insert( d );
Point e( 1, -3 );
mySet.insert( e );
Board2D board;
board.setUnit(Board::UCentimeter);
board << mySet;
board.saveSVG("myset-export.svg");
board.clear();
board.setUnit(Board::UCentimeter);
board << DrawDomainGrid() << domain << mySet;
board.saveSVG("simpleSet-grid.svg");
board.clear();
board.setUnit(Board::UCentimeter);
board << DrawDomainPaving() << domain;
board << mySet;
board.saveSVG("simpleSet-paving.svg");
board.clear();
board.setUnit(Board::UCentimeter);
board << CustomStyle( mySet.styleName(), new MyDomainStyleCustomRed );
board << mySet;
board.saveSVG("simpleSet-color.svg");
return true;
}
/**
* Test for 8-connected points
*
*/
bool testDSS8drawing()
{
typedef PointVector<2,int> Point;
typedef std::vector<Point>::iterator Iterator;
typedef ArithmeticalDSS<Iterator,int,8> DSS8;
std::vector<Point> boundary;
boundary.push_back(Point(0,0));
boundary.push_back(Point(1,1));
boundary.push_back(Point(2,1));
boundary.push_back(Point(3,2));
boundary.push_back(Point(4,2));
boundary.push_back(Point(5,2));
boundary.push_back(Point(6,3));
boundary.push_back(Point(6,4));
// Good Initialisation
trace.beginBlock("Add points while it is possible and draw the result");
DSS8 theDSS8;
theDSS8.init( boundary.begin() );
trace.info() << theDSS8 << " " << theDSS8.isValid() << std::endl;
{
while ( (theDSS8.end()!=boundary.end())
&&(theDSS8.extendForward()) ) {}
trace.info() << theDSS8 << " " << theDSS8.isValid() << std::endl;
HyperRectDomain< SpaceND<2,int> > domain( Point(0,0), Point(10,10) );
Board2D board;
board.setUnit(Board::UCentimeter);
board << SetMode(domain.className(), "Paving")
<< domain;
board << SetMode("PointVector", "Both");
board << SetMode(theDSS8.className(), "Points")
<< theDSS8;
board << SetMode(theDSS8.className(), "BoundingBox")
<< theDSS8;
board.saveSVG("DSS8.svg");
}
trace.endBlock();
return true;
}
/**
* Simple 3d distance transform
* and slice display
*/
bool testDisplayDT3d(int size, int area, double distance)
{
static const DGtal::Dimension dimension = 3;
//Domain
typedef HyperRectDomain< SpaceND<dimension, int> > Domain;
typedef Domain::Point Point;
Domain d(Point::diagonal(-size), Point::diagonal(size));
DomainPredicate<Domain> dp(d);
//Image and set
typedef ImageContainerBySTLMap<Domain,double> Image;
Image map( d, 0.0 );
map.setValue( Point::diagonal(0), 0.0 );
typedef DigitalSetFromMap<Image> Set;
Set set(map);
//computation
trace.beginBlock ( "Display 3d FMM results " );
typedef FMM<Image, Set, DomainPredicate<Domain> > FMM;
FMM fmm(map, set, dp, area, distance);
fmm.compute();
trace.info() << fmm << std::endl;
trace.endBlock();
{ //display
HueShadeColorMap<unsigned char, 2> colorMap(0,2*size);
Board2D b;
b.setUnit ( LibBoard::Board::UCentimeter );
Domain::ConstIterator it = d.begin();
for ( ; it != d.end(); ++it)
{
Point p3 = *it;
if (p3[2] == 0)
{
PointVector<2,Point::Coordinate> p2(p3[0], p3[1]);
b << CustomStyle( p2.className(),
new CustomFillColor( colorMap(map(p3)) ) )
<< p2;
}
}
std::stringstream s;
s << "DTFrom3dPt-" << size << "-" << area << "-" << distance
<< ".eps";
b.saveEPS(s.str().c_str());
}
return fmm.isValid();
}
/**
* Test for 4-connected points
*
*/
bool testDSS4drawing()
{
typedef PointVector<2,int> Point;
typedef std::vector<Point>::iterator Iterator;
typedef ArithmeticalDSS<Iterator,int,4> DSS4;
std::vector<Point> contour;
contour.push_back(Point(0,0));
contour.push_back(Point(1,0));
contour.push_back(Point(1,1));
contour.push_back(Point(2,1));
contour.push_back(Point(3,1));
contour.push_back(Point(3,2));
contour.push_back(Point(4,2));
contour.push_back(Point(5,2));
contour.push_back(Point(6,2));
contour.push_back(Point(6,3));
contour.push_back(Point(6,4));
// Adding step
trace.beginBlock("Add points while it is possible and draw the result");
DSS4 theDSS4;
theDSS4.init( contour.begin() );
trace.info() << theDSS4 << " " << theDSS4.isValid() << std::endl;
while ( (theDSS4.end() != contour.end())
&&(theDSS4.extendForward()) ) {}
trace.info() << theDSS4 << " " << theDSS4.isValid() << std::endl;
HyperRectDomain< SpaceND<2,int> > domain( Point(0,0), Point(10,10) );
Board2D board;
board.setUnit(Board::UCentimeter);
board << SetMode(domain.className(), "Grid")
<< domain;
board << SetMode("PointVector", "Grid");
board << SetMode(theDSS4.className(), "Points")
<< theDSS4;
board << SetMode(theDSS4.className(), "BoundingBox")
<< theDSS4;
board.saveSVG("DSS4.svg");
trace.endBlock();
return true;
}
/**
* Example of a test. To be completed.
*
*/
bool testPNMWriter()
{
trace.beginBlock ( "Testing block ..." );
typedef SpaceND<2> TSpace;
typedef TSpace::Point Point;
typedef HyperRectDomain<TSpace> Domain;
typedef HueShadeColorMap<unsigned char> Hue;
typedef HueShadeColorMap<unsigned char,2> HueTwice;
typedef GrayscaleColorMap<unsigned char> Gray;
// Gradient using the "Jet" preset.
typedef GradientColorMap<unsigned char, CMAP_JET > Jet;
// Gradient from black to red.
const int BlackColor = DGTAL_RGB2INT(0,0,0);
const int RedColor = DGTAL_RGB2INT(255,0,0);
typedef GradientColorMap< unsigned char, CMAP_CUSTOM, BlackColor, RedColor > RedShade1;
// Gradient from black to red, using a ColorBrightnessColorMap.
typedef ColorBrightnessColorMap< unsigned char, RedColor > RedShade2;
Point a ( 1, 1);
Point b ( 16, 16);
typedef ImageSelector<Domain, unsigned char>::Type Image;
Image image(Domain(a,b));
for(unsigned int i=0 ; i < 256; i++)
image[i] = i;
PPMWriter<Image,Hue>::exportPPM("export-hue.ppm",image, Hue(0,255) );
PPMWriter<Image,HueTwice>::exportPPM("export-hue-twice.ppm",image,HueTwice(0,255));
PGMWriter<Image>::exportPGM("export-hue-twice.pgm",image);
PPMWriter<Image,Gray>::exportPPM("export-gray.ppm",image, Gray(0,255));
PPMWriter<Image,Jet>::exportPPM("export-jet.ppm",image,Jet(0,255));
PPMWriter<Image,RedShade1>::exportPPM("export-red1.ppm",image,RedShade1(0,255));
PPMWriter<Image,RedShade2>::exportPPM("export-red2.ppm",image,RedShade2(0,255));
//TestingFunctor
typedef DGtal::functors::Composer< Jet, functors::RedChannel, unsigned char> RedFunctor;
RedFunctor redFunctor( Jet(0,255), functors::RedChannel() ) ;
PGMWriter<Image, RedFunctor>::exportPGM("export-jet-red.pgm",image, redFunctor);
//test Raw export
RawWriter<Image>::exportRaw8("export-hue-twice.raw",image);
//test Image export with libboard
Board2D board;
board.setUnit(LibBoard::Board::UCentimeter);
Display2DFactory::drawImage<HueTwice>(board, image, (unsigned char)0, (unsigned char)255);
board.saveSVG("export-hue-twice.svg");
trace.endBlock();
return true;
}
/**
* Test for the tangential cover of
* 4-connected digital curves
*
*/
bool testCover4()
{
typedef int Coordinate;
typedef PointVector<2,Coordinate> Point;
typedef FreemanChain<Coordinate> ContourType;
typedef ArithmeticalDSS<ContourType::ConstIterator,Coordinate,4> PrimitiveType;
typedef MaximalSegments<PrimitiveType> DecompositionType;
std::string filename = testPath + "samples/france.fc";
std::cout << filename << std::endl;
std::fstream fst;
fst.open (filename.c_str(), std::ios::in);
ContourType theContour(fst);
//Segmentation
trace.beginBlock("Tangential cover of 4-connected digital curves");
PrimitiveType primitive;
DecompositionType theDecomposition(theContour.begin(), theContour.end(), primitive, false);
// Draw the grid
Board2D aBoard;
aBoard.setUnit(Board::UCentimeter);
aBoard << SetMode("PointVector", "Grid")
<< theContour;
//for each segment
unsigned int compteur = 0;
DecompositionType::SegmentIterator i = theDecomposition.begin();
for ( ; i != theDecomposition.end(); ++i) {
compteur++;
PrimitiveType segment(*i);
trace.info() << segment << std::endl; //standard output
aBoard << SetMode( "ArithmeticalDSS", "BoundingBox" )
<< segment; // draw each segment
}
aBoard.saveEPS("segmentationDSS4.eps");
trace.info() << "# segments" << compteur << std::endl;
trace.endBlock();
return true;
}
bool testSmartDSS()
{
typedef PointVector<2,int> Point;
typedef std::vector<Point>::iterator Iterator;
typedef ArithmeticalDSS<Iterator,int,4> DSS4;
std::vector<Point> contour;
contour.push_back(Point(0,0));
contour.push_back(Point(1,0));
contour.push_back(Point(1,1));
contour.push_back(Point(2,1));
contour.push_back(Point(3,1));
contour.push_back(Point(3,2));
contour.push_back(Point(4,2));
contour.push_back(Point(5,2));
contour.push_back(Point(6,2));
contour.push_back(Point(6,3));
contour.push_back(Point(6,4));
// Adding step
trace.beginBlock("extension");
DSS4 s;
s.init( contour.begin() );
while ( (s.end()!=contour.end())
&&(s.extend()) ) {}
HyperRectDomain< SpaceND<2,int> > domain( Point(0,0), Point(10,10) );
Board2D board;
board.setUnit(Board::UCentimeter);
board << SetMode(domain.styleName(), "Grid")
<< domain;
board << SetMode("PointVector", "Grid");
board << SetMode(s.styleName(), "Points")
<< s;
board << SetMode(s.styleName(), "BoundingBox")
<< s;
board.saveEPS("DSS.eps");
trace.endBlock();
return true;
}
/**
* Test for the segmentation of
* one DSS into DSSs
*
*/
bool testOneDSS()
{
typedef int Coordinate;
typedef PointVector<2,Coordinate> Point;
typedef ArithmeticalDSS<std::vector<Point>::iterator,Coordinate,8> PrimitiveType;
typedef MaximalSegments<PrimitiveType> DecompositionType;
std::vector<Point> curve;
curve.push_back(Point(0,0));
curve.push_back(Point(1,1));
curve.push_back(Point(2,1));
curve.push_back(Point(3,2));
curve.push_back(Point(4,2));
curve.push_back(Point(5,2));
curve.push_back(Point(6,3));
curve.push_back(Point(7,3));
//Segmentation
trace.beginBlock("Segmentation of one DSS");
PrimitiveType primitive;
DecompositionType theDecomposition(curve.begin(), curve.end(), primitive, false);
// Draw the pixels
Board2D aBoard;
aBoard.setUnit(Board::UCentimeter);
aBoard << SetMode("PointVector", "Both");
for (std::vector<Point>::iterator it = curve.begin(); it != curve.end(); ++it) {
aBoard << (*it);
}
//for each segment
unsigned int compteur = 0;
DecompositionType::SegmentIterator i = theDecomposition.begin();
for ( ; i != theDecomposition.end(); ++i) {
++compteur;
PrimitiveType segment(*i);
trace.info() << segment << std::endl; //standard output
aBoard << SetMode( "ArithmeticalDSS", "BoundingBox" )
<< segment; // draw each segment
}
aBoard.saveSVG("oneDSS.svg");
trace.endBlock();
return (compteur==1);
}
void draw( const TIterator& itb, const TIterator& ite, const int& size, std::string basename)
{
typedef typename std::iterator_traits<TIterator>::value_type Pair;
typedef typename Pair::first_type Point;
HueShadeColorMap<unsigned char, 2> colorMap(0,3*size);
Board2D b;
b.setUnit ( LibBoard::Board::UCentimeter );
TIterator it = itb;
for ( ; it != ite; ++it)
{
Point p = it->first;
b << CustomStyle( p.className(), new CustomFillColor( colorMap( it->second) ) );
b << p;
}
std::stringstream s;
s << basename << ".eps";
b.saveEPS(s.str().c_str());
}
/**
* testDisplay
*
*/
bool testDisplay()
{
typedef FreemanChain<int> FreemanChain;
//typedef FreemanChain::Point Point;
//typedef FreemanChain::Vector Vector;
//typedef FreemanChain::ConstIterator Iterator;
//typedef std::vector<unsigned int> numVector;
Board2D aBoard;
aBoard.setUnit(Board::UCentimeter);
fstream fst;
fst.open ((testPath + "samples/contourS.fc").c_str() , ios::in);
FreemanChain fc(fst);
aBoard.setPenColor(Color::Red);
//aBoard << DrawPavingPixel();
aBoard << fc;
std::string filenameImage = testPath + "samples/contourS.png"; // ! only PNG with Cairo for the moment !
LibBoard::Image image( 0, 84, 185, 85, filenameImage, 20 );
image.shiftDepth(500);
LibBoard::Board & board = aBoard;
board << image;
aBoard.saveSVG( "testDisplayFC.svg", Board::BoundingBox, 5000 );
aBoard.saveEPS( "testDisplayFC.eps", Board::BoundingBox, 5000 );
aBoard.saveFIG( "testDisplayFC.fig", Board::BoundingBox, 5000 );
#ifdef WITH_CAIRO
aBoard.saveCairo("testDisplayFC-cairo.pdf", Board2D::CairoPDF, Board::BoundingBox, 5000);
aBoard.saveCairo("testDisplayFC-cairo.png", Board2D::CairoPNG, Board::BoundingBox, 5000);
aBoard.saveCairo("testDisplayFC-cairo.ps", Board2D::CairoPS, Board::BoundingBox, 5000);
aBoard.saveCairo("testDisplayFC-cairo.svg", Board2D::CairoSVG, Board::BoundingBox, 5000);
#endif
return true;
}
int main(int /*argc*/, char** /*argv*/)
{
////////////////////////////////////////
Board2D board;
board.setUnit(Board2D::UCentimeter);
board.drawArc(0.0, 1.0, 5.0, 0, M_PI/2.0, false);
board.drawArc(0.0, 1.0, 4.0, 0, M_PI/2.0, true);
board.drawArc(0.0, 1.0, 3.0, -0.5, M_PI/2.0-0.5, false);
board.drawArc(0.0, 1.0, 2.0, 0.5, M_PI/2.0+0.5, false);
board.saveEPS( "essai.eps" );
board.saveSVG( "essai.svg" );
board.saveTikZ( "essai.tikz" );
#ifdef WITH_CAIRO
board.saveCairo("essai.pdf", Board2D::CairoPDF);
#endif
////////////////////////////////////////
return 0;
}
int main( int argc, char** argv )
{
// parse command line ----------------------------------------------
po::options_description general_opt("Allowed options are: ");
general_opt.add_options()
("help,h", "display this message")
("FreemanChain,f", po::value<std::string>(), "FreemanChain file name")
("SDP", po::value<std::string>(), "Import a contour as a Sequence of Discrete Points (SDP format)")
("SFP", po::value<std::string>(), "Import a contour as a Sequence of Floating Points (SFP format)")
("drawContourPoint", po::value<double>(), "<size> display contour points as disk of radius <size>")
("lineWidth", po::value<double>()->default_value(1.0), "Define the linewidth of the contour (SDP format)")
("withProcessing", po::value<std::string>(), "Processing (used only with --FreemanChain):\n\t DSS segmentation {DSS}\n\t Maximal segments {MS}\n\t Faithful Polygon {FP}\n\t Minimum Length Polygon {MLP}")
("outputEPS", po::value<std::string>(), " <filename> specify eps format (default format output.eps)")
("outputSVG", po::value<std::string>(), " <filename> specify svg format.")
("outputFIG", po::value<std::string>(), " <filename> specify fig format.")
#ifdef WITH_CAIRO
("outputPDF", po::value<std::string>(), "outputPDF <filename> specify pdf format. ")
("outputPNG", po::value<std::string>(), "outputPNG <filename> specify png format.")
("invertYaxis", " invertYaxis invert the Y axis for display contours (used only with --SDP)")
#endif
#ifdef WITH_MAGICK
("backgroundImage", po::value<std::string>(), "backgroundImage <filename> <alpha> : display image as background with transparency alpha (defaut 1) (transparency works only if cairo is available)")
("alphaBG", po::value<double>(), "alphaBG <value> 0-1.0 to display the background image in transparency (default 1.0)")
#endif
("scale", po::value<double>(), "scale <value> 1: normal; >1 : larger ; <1 lower resolutions )");
po::variables_map vm;
po::store(po::parse_command_line(argc, argv, general_opt), vm);
po::notify(vm);
if(vm.count("help")||argc<=1 || (not(vm.count("FreemanChain")) && not(vm.count("SDP")) && not(vm.count("SFP"))&&
not(vm.count("backgroundImage")) ) )
{
trace.info()<< "Display discrete contours. " <<std::endl << "Basic usage: "<<std::endl
<< "\t displayContours [options] --FreemanChain <fileName> --imageName image.png "<<std::endl
<< general_opt << "\n";
return 0;
}
double lineWidth= vm["lineWidth"].as<double>();
double scale=1.0;
if(vm.count("scale")){
scale = vm["scale"].as<double>();
}
Board2D aBoard;
aBoard.setUnit (0.05*scale, LibBoard::Board::UCentimeter);
#ifdef WITH_MAGICK
double alpha=1.0;
if(vm.count("alphaBG")){
alpha = vm["alphaBG"].as<double>();
}
if(vm.count("backgroundImage")){
string imageName = vm["backgroundImage"].as<string>();
typedef ImageSelector<Z2i::Domain, unsigned char>::Type Image;
DGtal::MagickReader<Image> reader;
Image img = reader.importImage( imageName );
Z2i::Point ptInf = img.lowerBound();
Z2i::Point ptSup = img.upperBound();
unsigned int width = abs(ptSup.at(0)-ptInf.at(0)+1);
unsigned int height = abs(ptSup.at(1)-ptInf.at(1)+1);
aBoard.drawImage(imageName, 0-0.5,height-0.5, width, height, -1, alpha );
}
#endif
if(vm.count("FreemanChain")){
string fileName = vm["FreemanChain"].as<string>();
vector< FreemanChain<int> > vectFc = PointListReader< Z2i::Point>:: getFreemanChainsFromFile<int> (fileName);
//aBoard << SetMode( vectFc.at(0).styleName(), "InterGrid" );
aBoard << CustomStyle( vectFc.at(0).styleName(),
new CustomColors( Color::Red , Color::None ) );
for(unsigned int i=0; i<vectFc.size(); i++){
aBoard << vectFc.at(i) ;
if(vm.count("withProcessing")){
std::string processingName = vm["withProcessing"].as<std::string>();
vector<Z2i::Point> vPts(vectFc.at(i).size()+1);
copy ( vectFc.at(i).begin(), vectFc.at(i).end(), vPts.begin() );
bool isClosed;
if ( vPts.at(0) == vPts.at(vPts.size()-1) ) {
isClosed = true;
vPts.pop_back();
} else isClosed = false;
if (processingName == "DSS") {
typedef ArithmeticalDSS<vector<Z2i::Point>::iterator,int,4> DSS4;
typedef deprecated::GreedyDecomposition<DSS4> Decomposition4;
//Segmentation
DSS4 computer;
Decomposition4 theDecomposition( vPts.begin(),vPts.end(),computer,isClosed );
//for each segment
aBoard << SetMode( computer.styleName(), "BoundingBox" );
string styleName = computer.styleName() + "/BoundingBox";
for ( Decomposition4::SegmentIterator it = theDecomposition.begin();
it != theDecomposition.end(); ++it )
{
DSS4 segment(*it);
aBoard << CustomStyle( styleName,
new CustomPenColor( DGtal::Color::Gray ) );
aBoard << segment; // draw each segment
}
} else if (processingName == "MS") {
typedef ArithmeticalDSS<vector<Z2i::Point>::iterator,int,4> DSS4;
typedef deprecated::MaximalSegments<DSS4> Decomposition4;
//Segmentation
DSS4 computer;
Decomposition4 theDecomposition( vPts.begin(),vPts.end(),computer,isClosed );
//for each segment
aBoard << SetMode( computer.styleName(), "BoundingBox" );
string styleName = computer.styleName() + "/BoundingBox";
for ( Decomposition4::SegmentIterator it = theDecomposition.begin();
it != theDecomposition.end(); ++it )
{
DSS4 segment(*it);
aBoard << CustomStyle( styleName,
new CustomPenColor( DGtal::Color::Black ) );
aBoard << segment; // draw each segment
}
} else if (processingName == "FP") {
typedef FP<vector<Z2i::Point>::iterator,int,4> FP;
FP theFP( vPts.begin(),vPts.end(),isClosed );
aBoard << CustomStyle( theFP.styleName(),
new CustomPenColor( DGtal::Color::Black ) );
aBoard << theFP;
} else if (processingName == "MLP") {
typedef FP<vector<Z2i::Point>::iterator,int,4> FP;
FP theFP( vPts.begin(),vPts.end(),isClosed );
vector<FP::RealPoint> v( theFP.size() );
theFP.copyMLP( v.begin() );
//polyline to draw
vector<LibBoard::Point> polyline;
vector<FP::RealPoint>::const_iterator it = v.begin();
for ( ;it != v.end();++it) {
FP::RealPoint p = (*it);
polyline.push_back(LibBoard::Point(p[0],p[1]));
}
if (isClosed) {
FP::RealPoint p = (*v.begin());
polyline.push_back(LibBoard::Point(p[0],p[1]));
}
aBoard.setPenColor(DGtal::Color::Black);
aBoard.drawPolyline(polyline);
}
}
}
}
if(vm.count("SDP") || vm.count("SFP")){
bool drawPoints= vm.count("drawContourPoint");
bool invertYaxis = vm.count("invertYaxis");
double pointSize=1.0;
if(drawPoints){
pointSize = vm["drawContourPoint"].as<double>();
}
vector<LibBoard::Point> contourPt;
if(vm.count("SDP")){
string fileName = vm["SDP"].as<string>();
vector< Z2i::Point > contour =
PointListReader< Z2i::Point >::getPointsFromFile(fileName);
for(unsigned int j=0; j<contour.size(); j++){
LibBoard::Point pt((double)(contour.at(j)[0]),
(invertYaxis? (double)(-contour.at(j)[1]+contour.at(0)[1]):(double)(contour.at(j)[1])));
contourPt.push_back(pt);
if(drawPoints){
aBoard.fillCircle(pt.x, pt.y, pointSize);
}
}
}
if(vm.count("SFP")){
string fileName = vm["SFP"].as<string>();
vector< PointVector<2,double> > contour =
PointListReader< PointVector<2,double> >::getPointsFromFile(fileName);
for(unsigned int j=0; j<contour.size(); j++){
LibBoard::Point pt((double)(contour.at(j)[0]),
(invertYaxis? (double)(-contour.at(j)[1]+contour.at(0)[1]):(double)(contour.at(j)[1])));
contourPt.push_back(pt);
if(drawPoints){
aBoard.fillCircle(pt.x, pt.y, pointSize);
}
}
}
aBoard.setPenColor(Color::Red);
aBoard.setLineStyle (LibBoard::Shape::SolidStyle );
aBoard.setLineWidth (lineWidth);
aBoard.drawPolyline(contourPt);
}
if (vm.count("outputSVG")){
string outputFileName= vm["outputSVG"].as<string>();
aBoard.saveSVG(outputFileName.c_str());
} else
if (vm.count("outputFIG")){
string outputFileName= vm["outputFIG"].as<string>();
aBoard.saveFIG(outputFileName.c_str());
} else
if (vm.count("outputEPS")){
string outputFileName= vm["outputEPS"].as<string>();
aBoard.saveEPS(outputFileName.c_str());
}
#ifdef WITH_CAIRO
else
if (vm.count("outputEPS")){
string outputFileName= vm["outputEPS"].as<string>();
aBoard.saveCairo(outputFileName.c_str(),Board2D::CairoEPS );
} else
if (vm.count("outputPDF")){
string outputFileName= vm["outputPDF"].as<string>();
aBoard.saveCairo(outputFileName.c_str(),Board2D::CairoPDF );
} else
if (vm.count("outputPNG")){
string outputFileName= vm["outputPNG"].as<string>();
aBoard.saveCairo(outputFileName.c_str(),Board2D::CairoPNG );
}
#endif
else { //default output
string outputFileName= "output.eps";
aBoard.saveEPS(outputFileName.c_str());
}
}
bool testChessboard()
{
unsigned int nbok = 0;
unsigned int nb = 0;
trace.beginBlock ( "Testing DT computation with Infinity values at the first step" );
typedef SpaceND<2> TSpace;
typedef TSpace::Point Point;
typedef HyperRectDomain<TSpace> Domain;
typedef HueShadeColorMap<DGtal::uint64_t, 2> Hue;
typedef GrayscaleColorMap<DGtal::uint64_t> Gray;
Point a (0, 0 );
Point b ( 128, 128 );
typedef ImageSelector<Domain, unsigned int>::Type Image;
Image image ( a, b );
for ( Image::Iterator it = image.begin(), itend = image.end();it != itend; ++it)
image.setValue ( it, 128 );
randomSeeds(image, 19, 0);
typedef ImageSelector<Domain, long int>::Type ImageLong;
//L_euc metric
typedef DistanceTransformation<Image, 2> DT2;
DT2 dt2;
//L_infinity metric
typedef DistanceTransformation<Image, 0> DT;
DT dt;
//L_1 metric
typedef DistanceTransformation<Image, 1> DT1;
DT1 dt1;
dt.checkTypesValidity ( image );
DT::OutputImage result = dt.compute ( image );
DT1::OutputImage result1 = dt1.compute ( image );
DT2::OutputImage result2 = dt2.compute (image);
DGtal::int64_t maxv = 0;
for ( DT::OutputImage::Iterator it = result.begin(), itend = result.end();it != itend; ++it)
if ( (*it) > maxv)
maxv = (*it);
DT::OutputImage::ConstIterator it = result.begin();
trace.warning() << result << "MaxV = " << maxv << endl;
//We display the values on a 2D slice
for (unsigned int y = 0; y < 16; y++)
{
for (unsigned int x = 0; x < 16; x++)
{
Point p(x, y);
std::cout << std::setw(4) << result(p) << " ";
}
std::cout << std::endl;
}
trace.info()<< "Exporting to SVG"<<endl;
Board2D board;
board.setUnit ( LibBoard::Board::UCentimeter );
result.selfDraw<Hue> ( board, 0, maxv + 1);
board.saveSVG ( "image-DT-linfty.svg" );
trace.info()<< "done"<<endl;
trace.info()<< "max L1"<<endl;
maxv = 0;
for ( DT1::OutputImage::Iterator it2 = result1.begin(), itend = result1.end();
it2 != itend; ++it2)
{
if ( result1(it2) > maxv)
maxv = (*it2);
}
trace.info()<< "Exporting to SVG L1"<<endl;
board.clear();
result1.selfDraw<Hue> ( board, 0, maxv + 1);
board.saveSVG ( "image-DT-l1.svg" );
trace.info()<< "done"<<endl;
trace.info()<< "max Leuc"<<endl;
maxv = 0;
for ( DT2::OutputImage::Iterator it = result2.begin(), itend = result2.end();
it != itend; ++it)
{
if ( result2(it) > maxv)
maxv = (*it);
}
trace.info()<< "Exporting to SVG L2"<<endl;
board.clear();
result2.selfDraw<Hue> ( board, 0, maxv + 1);
board.saveSVG ( "image-DT-l2.svg" );
trace.info()<< "done"<<endl;
trace.info() << result << endl;
trace.endBlock();
return nbok == nb;
}
/**
* Example of a test. To be completed.
*
*/
bool testDistanceTransformation()
{
unsigned int nbok = 0;
unsigned int nb = 0;
trace.beginBlock ( "Testing the whole DT computation" );
typedef SpaceND<2> TSpace;
typedef TSpace::Point Point;
typedef HyperRectDomain<TSpace> Domain;
typedef HueShadeColorMap<unsigned char, 2> HueTwice;
typedef GrayscaleColorMap<unsigned char> Gray;
Point a ( 2, 2 );
Point b ( 15, 15 );
typedef ImageSelector<Domain, unsigned int>::Type Image;
Image image ( a, b );
for ( unsigned k = 0; k < 49; k++ )
{
a[0] = ( k / 7 ) + 5;
a[1] = ( k % 7 ) + 5;
image.setValue ( a, 128 );
}
DistanceTransformation<Image, 2> dt;
typedef DistanceTransformation<Image, 2>::OutputImage ImageLong;
dt.checkTypesValidity ( image );
Board2D board;
board.setUnit ( LibBoard::Board::UCentimeter );
image.selfDraw<Gray> ( board, 0, 255 );
board.saveSVG ( "image-preDT.svg" );
//We just iterate on the Domain points and print out the point coordinates.
std::copy ( image.begin(),
image.end(),
std::ostream_iterator<unsigned int> ( std::cout, " " ) );
ImageLong result = dt.compute ( image );
trace.warning() << result << endl;
//We just iterate on the Domain points and print out the point coordinates.
ImageLong::ConstIterator it = result.begin();
for (unsigned int y = 2; y < 16; y++)
{
for (unsigned int x = 2; x < 16; x++)
{
std::cout << result(it) << " ";
++it;
}
std::cout << std::endl;
}
board.clear();
result.selfDraw<Gray> ( board, 0, 16 );
board.saveSVG ( "image-postDT.svg" );
trace.info() << result << endl;
trace.endBlock();
return nbok == nb;
}
bool testDraw()
{
unsigned int nbok = 0;
unsigned int nb = 0;
trace.beginBlock ( "testDraw(): testing drawing commands." );
typedef SpaceND< 2 > Z2;
typedef Z2::Point Point;
typedef Point::Coordinate Coordinate;
typedef HyperRectDomain< Z2 > DomainType;
Point p1( -10, -10 );
Point p2( 10, 10 );
DomainType domain( p1, p2 );
// typedef DomainMetricAdjacency< DomainType, 1 > Adj4;
// typedef DomainMetricAdjacency< DomainType, 2 > Adj8;
typedef MetricAdjacency< Z2, 1 > MetricAdj4;
typedef MetricAdjacency< Z2, 2 > MetricAdj8;
typedef DomainAdjacency< DomainType, MetricAdj4 > Adj4;
typedef DomainAdjacency< DomainType, MetricAdj8 > Adj8;
typedef DigitalTopology< Adj4, Adj8 > DT48;
typedef DigitalTopology< Adj8, Adj4 > DT84;
typedef DigitalSetSelector < DomainType, MEDIUM_DS + HIGH_BEL_DS >::Type
MediumSet;
// typedef DigitalSetSelector< DomainType, SMALL_DS >::Type
// MediumSet;
typedef Object<DT48, MediumSet> ObjectType;
typedef Object<DT84, MediumSet> ObjectType84;
//typedef ObjectType::SmallSet SmallSet;
//typedef Object<DT48, SmallSet> SmallObjectType;
//typedef ObjectType::Size Size;
// Adj4 adj4( domain );
// Adj8 adj8( domain );
MetricAdj4 madj4;
MetricAdj8 madj8;
Adj4 adj4( domain, madj4 );
Adj8 adj8( domain, madj8 );
DT48 dt48( adj4, adj8, JORDAN_DT );
DT84 dt84( adj8, adj4, JORDAN_DT );
Coordinate r = 5;
double radius = (double) (r + 1);
Point c( 0, 0 );
Point l( r, 0 );
MediumSet disk( domain );
ostringstream sstr;
sstr << "Creating disk( r < " << radius << " ) ...";
trace.beginBlock ( sstr.str() );
for ( DomainType::ConstIterator it = domain.begin();
it != domain.end();
++it )
{
if ( (*it - c ).norm() < radius ) // 450.0
// insertNew is very important for vector container.
disk.insertNew( *it );
}
trace.endBlock();
trace.beginBlock ( "Testing Object instanciation and smart copy ..." );
ObjectType disk_object( dt48, disk );
ObjectType84 disk_object2( dt84, disk );
trace.endBlock();
trace.beginBlock ( "Testing export as SVG with libboard." );
Board2D board;
board.setUnit(Board::UCentimeter);
board << SetMode( domain.className(), "Grid" ) << domain;
board << disk_object;
board.saveSVG("disk-object.svg");
Board2D board2;
board2.setUnit(Board::UCentimeter);
board2 << SetMode( domain.className(), "Grid" ) << domain;
board2 << SetMode( disk_object.className(), "DrawAdjacencies" ) << disk_object;
board2.saveSVG("disk-object-adj.svg");
Board2D board3;
board3.setUnit( Board::UCentimeter );
board3 << SetMode( domain.className(), "Grid" ) << domain;
board3 << SetMode( disk_object2.className(), "DrawAdjacencies" ) << disk_object2;
board3.saveSVG("disk-object-adj-bis.svg");
trace.endBlock();
trace.endBlock();
return nbok == nb;
}
int main()
{
trace.beginBlock ( "Example distancetransform2D" );
//! [DTDef]
Z2i::Point a ( 0, 0 );
Z2i::Point b ( 127, 127);
//Input image with unsigned char values
typedef ImageSelector<Z2i::Domain, unsigned int>::Type Image;
Image image ( Z2i::Domain(a, b ));
//We fill the image with the 128 value
for ( Image::Iterator it = image.begin(), itend = image.end();it != itend; ++it)
(*it)=128;
//We generate 16 seeds with 0 values.
randomSeeds(image,16,0);
//! [DTDef]
//! [DTColormaps]
//Colormap used for the SVG output
typedef HueShadeColorMap<long int, 2> HueTwice;
typedef GrayscaleColorMap<unsigned char> Gray;
//! [DTColormaps]
//Input shape output
Board2D board;
board.setUnit ( LibBoard::Board::UCentimeter );
Display2DFactory::drawImage<Gray>(board, image, (unsigned int)0, (unsigned int)129);
board.saveSVG("inputShape.svg");
//! [DTPredicate]
//Point Predicate from random seed image
typedef SimpleThresholdForegroundPredicate<Image> PointPredicate;
PointPredicate predicate(image,0);
//! [DTPredicate]
//! [DTCompute]
typedef DistanceTransformation<Z2i::Space, PointPredicate, Z2i::L2Metric> DTL2;
typedef DistanceTransformation<Z2i::Space, PointPredicate, Z2i::L1Metric> DTL1;
DTL2 dtL2(image.domain(), predicate, Z2i::l2Metric);
DTL1 dtL1(image.domain(), predicate, Z2i::l1Metric);
//! [DTCompute]
DTL2::Value maxv2=0;
//We compute the maximum DT value on the L2 map
for ( DTL2::ConstRange::ConstIterator it = dtL2.constRange().begin(), itend = dtL2.constRange().end();it != itend; ++it)
if ( (*it) > maxv2) maxv2 = (*it);
DTL1::Value maxv1=0;
//We compute the maximum DT value on the L1 map
for ( DTL1::ConstRange::ConstIterator it = dtL1.constRange().begin(), itend = dtL1.constRange().end();it != itend; ++it)
if ( (*it) > maxv1) maxv1 = (*it);
trace.warning() << dtL2 << " maxValue= "<<maxv2<< endl;
board.clear();
Display2DFactory::drawImage<HueTwice>(board, dtL2, 0.0, maxv2 + 1);
board.saveSVG ( "example-DT-L2.svg" );
trace.warning() << dtL1 << " maxValue= "<<maxv1<< endl;
board.clear();
Display2DFactory::drawImage<HueTwice>(board, dtL1, 0.0, maxv1 + 1);
board.saveSVG ( "example-DT-L1.svg" );
//We compute the maximum DT value on the L2 map
for ( unsigned int j=0;j<33;j++)
{
for(unsigned int i=0; i<33; i++)
trace.info()<< dtL2(Z2i::Point(i,j)) << " ";
trace.info()<<std::endl;
}
trace.endBlock();
return 0;
}
int main( int argc, char** argv )
{
// parse command line ----------------------------------------------
po::options_description general_opt("Allowed options are: ");
general_opt.add_options()
("help,h", "display this message")
("input,i", po::value<std::string>(), "input FreemanChain file name")
("SDP", po::value<std::string>(), "Import a contour as a Sequence of Discrete Points (SDP format)")
("SFP", po::value<std::string>(), "Import a contour as a Sequence of Floating Points (SFP format)")
("drawContourPoint", po::value<double>(), "<size> display contour points as disk of radius <size>")
("fillContour", "fill the contours with default color (gray)")
("lineWidth", po::value<double>()->default_value(1.0), "Define the linewidth of the contour (SDP format)")
("drawPointOfIndex", po::value<int>(), "<index> Draw the contour point of index <index> (default 0) ")
("pointSize", po::value<double>()->default_value(2.0), "<size> Set the display point size of the point displayed by drawPointofIndex option (default 2.0) ")
("noXFIGHeader", " to exclude xfig header in the resulting output stream (no effect with option -outputFile).")
("withProcessing", po::value<std::string>(), "Processing (used only when the input is a Freeman chain (--input)):\n\t DSS segmentation {DSS}\n\t Maximal segments {MS}\n\t Faithful Polygon {FP}\n\t Minimum Length Polygon {MLP}")
("outputFile,o", po::value<std::string>(), " <filename> save output file automatically according the file format extension.")
("outputStreamEPS", " specify eps for output stream format.")
("outputStreamSVG", " specify svg for output stream format.")
("outputStreamFIG", " specify fig for output stream format.")
("invertYaxis", " invertYaxis invert the Y axis for display contours (used only with --SDP)")
("backgroundImage", po::value<std::string>(), "backgroundImage <filename> : display image as background ")
("alphaBG", po::value<double>(), "alphaBG <value> 0-1.0 to display the background image in transparency (default 1.0), (transparency works only if cairo is available)")
("scale", po::value<double>(), "scale <value> 1: normal; >1 : larger ; <1 lower resolutions )");
bool parseOK=true;
po::variables_map vm;
try {
po::store(po::parse_command_line(argc, argv, general_opt), vm);
} catch(const std::exception& ex) {
parseOK=false;
trace.info()<< "Error checking program options: "<< ex.what()<< std::endl;
}
po::notify(vm);
if(!parseOK||vm.count("help")||argc<=1 || (!(vm.count("input")) && !(vm.count("SDP")) && !(vm.count("SFP"))&&
!(vm.count("backgroundImage")) ) )
{
trace.info()<< "Display discrete contours. " <<std::endl << "Basic usage: "<<std::endl
<< "\t displayContours [options] --input <fileName> "<<std::endl
<< general_opt << "\n";
return 0;
}
double lineWidth= vm["lineWidth"].as<double>();
bool filled = vm.count("fillContour");
double scale=1.0;
if(vm.count("scale")) {
scale = vm["scale"].as<double>();
}
Board2D aBoard;
aBoard.setUnit (0.05*scale, LibBoard::Board::UCentimeter);
double alpha=1.0;
if(vm.count("alphaBG")) {
alpha = vm["alphaBG"].as<double>();
}
if(vm.count("backgroundImage")) {
std::string imageName = vm["backgroundImage"].as<std::string>();
typedef ImageSelector<Z2i::Domain, unsigned char>::Type Image;
Image img = DGtal::GenericReader<Image>::import( imageName );
Z2i::Point ptInf = img.domain().lowerBound();
Z2i::Point ptSup = img.domain().upperBound();
unsigned int width = abs(ptSup[0]-ptInf[0]+1);
unsigned int height = abs(ptSup[1]-ptInf[1]+1);
aBoard.drawImage(imageName, 0-0.5,height-0.5, width, height, -1, alpha );
}
if(vm.count("input")) {
std::string fileName = vm["input"].as<std::string>();
std::vector< FreemanChain<int> > vectFc = PointListReader< Z2i::Point>:: getFreemanChainsFromFile<int> (fileName);
aBoard << CustomStyle( vectFc.at(0).className(),
new CustomColors( Color::Red , filled? Color::Gray: Color::None ) );
aBoard.setLineWidth (lineWidth);
for(unsigned int i=0; i<vectFc.size(); i++) {
aBoard << vectFc.at(i) ;
if(vm.count("drawPointOfIndex")) {
int index = vm["drawPointOfIndex"].as<int>();
double size = vm["pointSize"].as<double>();
aBoard.setPenColor(Color::Blue);
aBoard.fillCircle((double)(vectFc.at(i).getPoint(index)[0]), (double)(vectFc.at(i).getPoint(index)[1]), size);
}
if(vm.count("withProcessing")) {
std::string processingName = vm["withProcessing"].as<std::string>();
std::vector<Z2i::Point> vPts(vectFc.at(i).size()+1);
copy ( vectFc.at(i).begin(), vectFc.at(i).end(), vPts.begin() );
bool isClosed;
if ( vPts.at(0) == vPts.at(vPts.size()-1) ) {
isClosed = true;
vPts.pop_back();
} else isClosed = false;
if (processingName == "DSS") {
typedef ArithmeticalDSSComputer<std::vector<Z2i::Point>::iterator,int,4> DSS4;
typedef GreedySegmentation<DSS4> Decomposition4;
DSS4 computer;
Decomposition4 theDecomposition( vPts.begin(),vPts.end(),computer );
//for each segment
std::string className;
for ( Decomposition4::SegmentComputerIterator it = theDecomposition.begin();
it != theDecomposition.end(); ++it )
{
DSS4::Primitive segment(it->primitive());
aBoard << SetMode( segment.className(), "BoundingBox" );
className = segment.className() + "/BoundingBox";
aBoard << CustomStyle( className,
new CustomPenColor( DGtal::Color::Gray ) );
aBoard << segment; // draw each segment
}
} else if (processingName == "MS") {
typedef ArithmeticalDSSComputer<std::vector<Z2i::Point>::iterator,int,4> DSS4;
typedef SaturatedSegmentation<DSS4> Decomposition4;
//Segmentation
DSS4 computer;
Decomposition4 theDecomposition( vPts.begin(),vPts.end(),computer );
//for each segment
std::string className;
for ( Decomposition4::SegmentComputerIterator it = theDecomposition.begin();
it != theDecomposition.end(); ++it )
{
DSS4::Primitive segment(it->primitive());
aBoard << SetMode( segment.className(), "BoundingBox" );
className = segment.className() + "/BoundingBox";
aBoard << CustomStyle( className,
new CustomPenColor( DGtal::Color::Gray ) );
aBoard << segment; // draw each segment
}
} else if (processingName == "FP") {
typedef FP<std::vector<Z2i::Point>::iterator,int,4> FP;
FP theFP( vPts.begin(),vPts.end() );
aBoard << CustomStyle( theFP.className(),
new CustomPenColor( DGtal::Color::Black ) );
aBoard << theFP;
} else if (processingName == "MLP") {
typedef FP<std::vector<Z2i::Point>::iterator,int,4> FP;
FP theFP( vPts.begin(),vPts.end() );
std::vector<FP::RealPoint> v( theFP.size() );
theFP.copyMLP( v.begin() );
//polyline to draw
std::vector<LibBoard::Point> polyline;
std::vector<FP::RealPoint>::const_iterator it = v.begin();
for ( ; it != v.end(); ++it) {
FP::RealPoint p = (*it);
polyline.push_back(LibBoard::Point(p[0],p[1]));
}
if (isClosed) {
FP::RealPoint p = (*v.begin());
polyline.push_back(LibBoard::Point(p[0],p[1]));
}
aBoard.setPenColor(DGtal::Color::Black);
aBoard.drawPolyline(polyline);
} else if (processingName == "MDCA") {
typedef KhalimskySpaceND<2,int> KSpace;
typedef GridCurve<KSpace> Curve;
Curve curve; //grid curve
curve.initFromPointsVector( vPts );
typedef Curve::IncidentPointsRange Range; //range
Range r = curve.getIncidentPointsRange(); //range
typedef Range::ConstCirculator ConstCirculator; //iterator
typedef StabbingCircleComputer<ConstCirculator> SegmentComputer; //segment computer
//typedef GeometricalDCA<ConstIterator> SegmentComputer; //segment computer
typedef SaturatedSegmentation<SegmentComputer> Segmentation;
//Segmentation theSegmentation( r.begin(), r.end(), SegmentComputer() );
Segmentation theSegmentation( r.c(), r.c(), SegmentComputer() );
theSegmentation.setMode("Last");
// board << curve;
Segmentation::SegmentComputerIterator it = theSegmentation.begin();
Segmentation::SegmentComputerIterator itEnd = theSegmentation.end();
Board2D otherBoard;
otherBoard.setPenColor(DGtal::Color::Black);
otherBoard << curve;
for ( ; it != itEnd; ++it ) {
aBoard << SetMode(SegmentComputer().className(), "") << (*it);
otherBoard << SetMode(SegmentComputer().className(), "") << (*it);
}
otherBoard.saveSVG("mdca.svg", Board2D::BoundingBox, 5000 );
}
}
}
}
if(vm.count("SDP") || vm.count("SFP")) {
bool drawPoints= vm.count("drawContourPoint");
bool invertYaxis = vm.count("invertYaxis");
double pointSize=1.0;
if(drawPoints) {
pointSize = vm["drawContourPoint"].as<double>();
}
std::vector<LibBoard::Point> contourPt;
if(vm.count("SDP")) {
std::string fileName = vm["SDP"].as<std::string>();
std::vector< Z2i::Point > contour =
PointListReader< Z2i::Point >::getPointsFromFile(fileName);
for(unsigned int j=0; j<contour.size(); j++) {
LibBoard::Point pt((double)(contour.at(j)[0]),
(invertYaxis? (double)(-contour.at(j)[1]+contour.at(0)[1]):(double)(contour.at(j)[1])));
contourPt.push_back(pt);
if(drawPoints) {
aBoard.fillCircle(pt.x, pt.y, pointSize);
}
}
}
if(vm.count("SFP")) {
std::string fileName = vm["SFP"].as<std::string>();
std::vector< PointVector<2,double> > contour =
PointListReader< PointVector<2,double> >::getPointsFromFile(fileName);
for(unsigned int j=0; j<contour.size(); j++) {
LibBoard::Point pt((double)(contour.at(j)[0]),
(invertYaxis? (double)(-contour.at(j)[1]+contour.at(0)[1]):(double)(contour.at(j)[1])));
contourPt.push_back(pt);
if(drawPoints) {
aBoard.fillCircle(pt.x, pt.y, pointSize);
}
}
}
aBoard.setPenColor(Color::Red);
aBoard.setFillColor(Color::Gray);
aBoard.setLineStyle (LibBoard::Shape::SolidStyle );
aBoard.setLineWidth (lineWidth);
if(!filled) {
aBoard.drawPolyline(contourPt);
} else {
aBoard.fillPolyline(contourPt);
}
if(vm.count("drawPointOfIndex")) {
int index = vm["drawPointOfIndex"].as<int>();
double size = vm["pointSize"].as<double>();
aBoard.fillCircle((double)(contourPt.at(index).x), (double)(contourPt.at(index).y), size);
}
}
if(vm.count("outputFile")) {
std::string outputFileName= vm["outputFile"].as<std::string>();
std::string extension = outputFileName.substr(outputFileName.find_last_of(".") + 1);
if(extension=="svg") {
aBoard.saveSVG(outputFileName.c_str());
}
#ifdef WITH_CAIRO
else if (extension=="eps") {
aBoard.saveCairo(outputFileName.c_str(),Board2D::CairoEPS );
} else if (extension=="pdf") {
aBoard.saveCairo(outputFileName.c_str(),Board2D::CairoPDF );
} else if (extension=="png") {
aBoard.saveCairo(outputFileName.c_str(),Board2D::CairoPNG );
}
#endif
else if(extension=="eps") {
aBoard.saveEPS(outputFileName.c_str());
} else if(extension=="fig") {
aBoard.saveFIG(outputFileName.c_str(),LibBoard::Board::BoundingBox, 10.0, !vm.count("noXFIGHeader") );
}
}
if (vm.count("outputStreamSVG")) {
aBoard.saveSVG(std::cout);
} else if (vm.count("outputStreamFIG")) {
aBoard.saveFIG(std::cout, LibBoard::Board::BoundingBox, 10.0, !vm.count("noXFIGHeader"));
} else if (vm.count("outputStreamEPS")) {
aBoard.saveEPS(std::cout);
}
}
bool testCellDrawOnBoard()
{
typedef typename KSpace::Integer Integer;
typedef typename KSpace::Cell Cell;
typedef typename KSpace::SCell SCell;
typedef typename KSpace::Point Point;
typedef typename KSpace::DirIterator DirIterator;
typedef typename KSpace::Cells Cells;
typedef typename KSpace::SCells SCells;
typedef SpaceND<2, Integer> Z2;
typedef HyperRectDomain<Z2> Domain;
unsigned int nbok = 0;
unsigned int nb = 0;
trace.beginBlock ( "Testing cell draw on digital board ..." );
KSpace K;
int xlow[ 4 ] = { -3, -3 };
int xhigh[ 4 ] = { 5, 3 };
Point low( xlow );
Point high( xhigh );
bool space_ok = K.init( low, high, true );
Domain domain( low, high );
Board2D board;
board.setUnit( LibBoard::Board::UCentimeter );
board << SetMode( domain.className(), "Paving" )
<< domain;
int spel[ 2 ] = { 1, 1 }; // pixel 0,0
Point kp( spel );
Cell uspel = K.uCell( kp );
board << uspel
<< low << high
<< K.uIncident( uspel, 0, false )
<< K.uIncident( uspel, 1, false );
int spel2[ 2 ] = { 5, 1 }; // pixel 2,0
Point kp2( spel2 );
SCell sspel2 = K.sCell( kp2, K.POS );
board << CustomStyle( sspel2.className(),
new CustomPen( Color( 200, 0, 0 ),
Color( 255, 100, 100 ),
2.0,
Board2D::Shape::SolidStyle ) )
<< sspel2
<< K.sIncident( sspel2, 0, K.sDirect( sspel2, 0 ) )
<< K.sIncident( sspel2, 1, K.sDirect( sspel2, 0 ) );
board.saveEPS( "cells-1.eps" );
board.saveSVG( "cells-1.svg" );
trace.endBlock();
board.clear();
board << domain;
SCell slinel0 = K.sIncident( sspel2, 0, K.sDirect( sspel2, 0 ) );
SCell spointel01 = K.sIncident( slinel0, 1, K.sDirect( slinel0, 1 ) );
board << CustomStyle( sspel2.className(),
new CustomColors( Color( 200, 0, 0 ),
Color( 255, 100, 100 ) ) )
<< sspel2
<< CustomStyle( slinel0.className(),
new CustomColors( Color( 0, 200, 0 ),
Color( 100, 255, 100 ) ) )
<< slinel0
<< CustomStyle( spointel01.className(),
new CustomColors( Color( 0, 0, 200 ),
Color( 100, 100, 255 ) ) )
<< spointel01;
board.saveEPS( "cells-3.eps" );
board.saveSVG( "cells-3.svg" );
return ((space_ok) && (nbok == nb));
}
/**
* Simple test to illustrate the border extraction of a simple 2D
* object considering different topologies.
*
*/
bool testObjectBorder()
{
trace.beginBlock ( "Testing Object Borders in 2D ..." );
typedef int Integer; // choose your digital line here.
typedef SpaceND<2> Z2; // Z^2
typedef Z2::Point Point;
typedef MetricAdjacency<Z2, 1> Adj4; // 4-adjacency type
typedef MetricAdjacency<Z2, 2> Adj8; // 8-adjacency type
typedef DigitalTopology< Adj8, Adj4 > DT8_4; //8,4 topology type
typedef HyperRectDomain< Z2 > Domain;
typedef Domain::ConstIterator DomainConstIterator;
typedef DigitalSetSelector < Domain, BIG_DS + HIGH_BEL_DS >::Type DigitalSet;
typedef Object<DT8_4, DigitalSet> ObjectType;
Point p1( -20, -10 );
Point p2( 20, 10 );
Domain domain( p1, p2 );
Adj4 adj4; // instance of 4-adjacency
Adj8 adj8; // instance of 8-adjacency
DT8_4 dt8_4(adj8, adj4, JORDAN_DT );
Point c( 0, 0 );
//We construct a simple 3-bubbles set
DigitalSet bubble_set( domain );
for ( DomainConstIterator it = domain.begin(); it != domain.end(); ++it )
{
int x = (*it)[0];
int y = (*it)[1];
if (( x*x + y*y < 82) ||
( (x - 14)*(x - 14) + (y + 1)*(y + 1) < 17) ||
( (x + 14)*(x + 14) + (y - 1)*(y - 1) < 17) )
bubble_set.insertNew( *it);
}
ObjectType bubble( dt8_4, bubble_set );
//Connectedness Check
if (bubble.computeConnectedness() == ObjectType::CONNECTED)
trace.info() << "The object is (8,4)connected." << endl;
else
trace.info() << "The object is not (8,4)connected." << endl;
//Border Computation
ObjectType bubbleBorder = bubble.border();
if (bubbleBorder.computeConnectedness() == ObjectType::CONNECTED)
trace.info() << "The object (8,4) border is connected." << endl;
else
trace.info() << "The object (8,4) border is not connected." << endl;
//Board Export
Board2D board;
board.setUnit(Board::UCentimeter);
board << DrawDomainGrid() << domain << bubble_set;
board.saveSVG("bubble-set.svg");
board << DrawObjectAdjacencies()
// << DrawWithCustomStyle<SelfDrawStyleCustom>()
<< CustomStyle( "Object", new MyObjectStyleCustom )
<< bubbleBorder;
board.saveSVG("bubble-object-border.svg");
board.clear();
//////////////////////:
//the same with the reverse topology
typedef Object<DT8_4::ReverseTopology, DigitalSet> ObjectType48;
DT8_4::ReverseTopology dt4_8 = dt8_4.reverseTopology();
ObjectType48 bubble2( dt4_8, bubble_set );
//Border Computation
ObjectType48 bubbleBorder2 = bubble2.border();
if (bubbleBorder2.computeConnectedness() == ObjectType48::CONNECTED)
trace.info() << "The object (4,8) border is connected." << endl;
else
trace.info() << "The object (4,8) border is not connected." << endl;
domain.selfDrawAsGrid(board);
bubble_set.selfDraw(board);
board << DrawObjectAdjacencies()
<< CustomStyle( "Object", new MyObjectStyleCustom )
<< bubbleBorder2;
board.saveSVG("bubble-object-border-48.svg");
//We split the border according to its components
vector<ObjectType48> borders(30);
unsigned int nbComponents;
vector<ObjectType48>::iterator it = borders.begin();
nbComponents = bubbleBorder2.writeComponents( it );
trace.info() << "The Bubble object has " << nbComponents << " (4,8)-connected components" << endl;
bool flag = true;
for (unsigned int k = 0;k < nbComponents ; k++)
{
if (flag)
board << DrawObjectAdjacencies() << CustomStyle( "Object", new MyObjectStyleCustom ) << borders[k];
else
board << DrawObjectAdjacencies() << CustomStyle( "Object", new MyObjectStyleCustom ) << borders[k];
flag = !flag;
}
board.saveSVG("bubble-object-color-borders-48.svg");
trace.endBlock();
return true;
}
int main()
{
trace.beginBlock ( "Example distancetransform2D" );
//! [DTDef]
Z2i::Point a ( 0, 0 );
Z2i::Point b ( 127, 127);
//Input image with unsigned char values
typedef ImageSelector<Z2i::Domain, unsigned int>::Type Image;
Image image ( Z2i::Domain(a, b ));
//We fill the image with the 128 value
for ( Image::Iterator it = image.begin(), itend = image.end();it != itend; ++it)
(*it)=128;
//We generate 16 seeds with 0 values.
randomSeeds(image,16,0);
//! [DTDef]
//Input shape output
typedef GrayscaleColorMap<Image::Value> Gray;
Board2D board;
board.setUnit ( LibBoard::Board::UCentimeter );
Display2DFactory::drawImage<Gray>(board, image, (unsigned int)0, (unsigned int)129);
board.saveSVG("inputShape.svg");
//! [DTPredicate]
//Point Predicate from random seed image
typedef functors::SimpleThresholdForegroundPredicate<Image> PointPredicate;
PointPredicate predicate(image,0);
//! [DTPredicate]
//! [DTCompute]
typedef DistanceTransformation<Z2i::Space, PointPredicate, Z2i::L2Metric> DTL2;
typedef DistanceTransformation<Z2i::Space, PointPredicate, Z2i::L1Metric> DTL1;
DTL2 dtL2(image.domain(), predicate, Z2i::l2Metric);
DTL1 dtL1(image.domain(), predicate, Z2i::l1Metric);
//! [DTCompute]
DTL2::Value maxv2=0;
//We compute the maximum DT value on the L2 map
for ( DTL2::ConstRange::ConstIterator it = dtL2.constRange().begin(), itend = dtL2.constRange().end();it != itend; ++it)
if ( (*it) > maxv2) maxv2 = (*it);
DTL1::Value maxv1=0;
//We compute the maximum DT value on the L1 map
for ( DTL1::ConstRange::ConstIterator it = dtL1.constRange().begin(), itend = dtL1.constRange().end();it != itend; ++it)
if ( (*it) > maxv1) maxv1 = (*it);
//! [DTColormaps]
//Colormap used for the SVG output
typedef HueShadeColorMap<DTL2::Value, 2> HueTwice;
//! [DTColormaps]
trace.warning() << dtL2 << " maxValue= "<<maxv2<< endl;
board.clear();
Display2DFactory::drawImage<HueTwice>(board, dtL2, 0.0, maxv2 + 1);
board.saveSVG ( "example-DT-L2.svg" );
trace.warning() << dtL1 << " maxValue= "<<maxv1<< endl;
board.clear();
Display2DFactory::drawImage<HueTwice>(board, dtL1, 0.0, maxv1 + 1);
board.saveSVG ( "example-DT-L1.svg" );
//Explicit export with ticked colormap
//We compute the maximum DT value on the L2 map
board.clear();
TickedColorMap<double, GradientColorMap<double> > ticked(0.0,maxv2, Color::White);
ticked.addRegularTicks(5, 0.5);
ticked.finalize();
ticked.colormap()->addColor( Color::Red );
ticked.colormap()->addColor( Color::Black );
for ( DTL2::Domain::ConstIterator it = dtL2.domain().begin(), itend = dtL2.domain().end();it != itend; ++it)
{
board<< CustomStyle((*it).className(),new CustomColors(ticked(dtL2(*it)),ticked(dtL2(*it))));
board << *it;
}
board.saveSVG("example-DT-L2-ticked.svg");
trace.endBlock();
return 0;
}
bool testDisconnectedCurve()
{
typedef int Coordinate;
typedef PointVector<2,Coordinate> Point;
typedef ArithmeticalDSS<std::vector<Point>::iterator,Coordinate,4> PrimitiveType;
typedef MaximalSegments<PrimitiveType> DecompositionType;
std::vector<Point> curve;
curve.push_back(Point(0,0));
curve.push_back(Point(1,0));
curve.push_back(Point(1,1));
curve.push_back(Point(2,1));
curve.push_back(Point(3,2));
curve.push_back(Point(4,2));
curve.push_back(Point(5,2));
curve.push_back(Point(6,2));
curve.push_back(Point(6,3));
curve.push_back(Point(6,4));
curve.push_back(Point(7,4));
curve.push_back(Point(8,4));
curve.push_back(Point(9,3));
curve.push_back(Point(9,2));
curve.push_back(Point(10,2));
curve.push_back(Point(11,2));
//Segmentation
trace.beginBlock("Tangential cover of disconnected digital curves");
PrimitiveType primitive;
DecompositionType theDecomposition(curve.begin(), curve.end(), primitive, false);
// Draw the pixels
Board2D aBoard;
aBoard.setUnit(Board::UCentimeter);
aBoard << SetMode("PointVector", "Grid");
for (std::vector<Point>::iterator it = curve.begin(); it != curve.end(); ++it) {
aBoard << (*it);
}
//for each segment
unsigned int compteur = 0;
DecompositionType::SegmentIterator i = theDecomposition.begin();
for ( ; i != theDecomposition.end(); ++i) {
compteur++;
trace.info() << "Segment " << compteur << std::endl;
PrimitiveType segment(*i);
trace.info() << segment << std::endl; //standard output
aBoard << SetMode( "ArithmeticalDSS", "Points" )
<< segment; // draw each segment
aBoard << SetMode( "ArithmeticalDSS", "BoundingBox" )
<< segment; // draw each segment
}
aBoard.saveSVG("specialCase.svg");
trace.endBlock();
return (compteur==5);
}
/**
* Example of a test. To be completed.
*
*/
bool testGetSetVal()
{
unsigned int nbok = 0;
unsigned int nb = 0;
typedef SpaceND<2> SpaceType;
typedef HyperRectDomain<SpaceType> TDomain;
typedef TDomain::Point Point;
Board2D board;
typedef HueShadeColorMap<unsigned char,2> HueTwice;
board.setUnit(LibBoard::Board::UCentimeter);
//Default image selector = STLVector
typedef ImageContainerByHashTree<TDomain, int > Image;
typedef ImageContainerBySTLVector<TDomain, int> ImageVector;
Point a( 1,1 );
Point b ( 50,50 );
Point c(15,15);
Point d(128,128);
Point l(0,0);
Point u(255,255);
trace.beginBlock ( "Image init" );
///Domain characterized by points
Image myImage ( 3, 8, 0 );
ImageVector myImageV(TDomain(l,u));
trace.info() << myImage;
trace.endBlock();
trace.beginBlock("SetVal");
for( a[1] = 0; a[1] < 256; a[1]++)
for( a[0] = 0; a[0] < 256; a[0]++)
{
if ( pow((double)(a[0]-128),3.0) - pow((double)(a[1]-128),3.0) < pow(32.0,3.0))
{
myImage.setValue(a, 30);
myImageV.setValue(a,30);
}
else
if ( pow((double)(a[0]-128),3.0) - pow((double)(a[1]-128),3.0) < pow(64.0,3.0))
{
myImage.setValue(a, 10);
myImageV.setValue(a,10);
}
}
trace.endBlock();
bool result=true;
trace.beginBlock("GetVal consistency test");
for( a[1] = 0; a[1] < 256; a[1]++)
for( a[0] = 0; a[0] < 256; a[0]++)
{
if ( pow((a[0]-128),3.0) - pow((a[1]-128),3.0) < pow(32,3.0))
result = result && (myImage(a) == 30);
else
if ( pow((a[0]-128),3.0) - pow((a[1]-128),3.0) < pow(64,3.0))
result = result && (myImage(a) == 10);
}
trace.endBlock();
if (result)
trace.info() << "Get/Set test passed"<<endl;
else
trace.error() << "Get/Set test error"<<endl;
nbok += result ? 1 : 0;
nb++;
trace.info() << myImage;
trace.info() << myImageV;
drawImage<HueTwice>(board, myImage, 0, 255);
board.saveSVG( "hashtree.svg" );
board.clear();
drawImage<HueTwice>(board, myImageV, 0, 255);
board.saveSVG( "hashtree-vector.svg" );
///Domain characterized by points
Image myImage2 ( 5, 8, 0 );
trace.beginBlock("SetVal (keysize=5)");
for( a[1] = 0; a[1] < 256; a[1]++)
for( a[0] = 0; a[0] < 256; a[0]++)
{
if ( pow((a[0]-128),3.0) - pow((a[1]-128),3.0) < pow(32,3.0))
myImage2.setValue(a, 30);
else
if ( pow((a[0]-128),3.0) - pow((a[1]-128),3.0) < pow(64,3.0))
myImage2.setValue(a, 10);
}
trace.endBlock();
result=true;
trace.beginBlock("GetVal consistency test (keysize=5)");
for( a[1] = 0; a[1] < 256; a[1]++)
for( a[0] = 0; a[0] < 256; a[0]++)
{
if ( pow((a[0]-128),3.0) - pow((a[1]-128),3.0) < pow(32,3.0))
result = result && (myImage2(a) == 30);
else
if ( pow((a[0]-128),3.0) - pow((a[1]-128),3.0) < pow(64,3.0))
result = result && (myImage2(a) == 10);
}
trace.endBlock();
if (result)
trace.info() << "Get/Set test passed"<<endl;
else
trace.error() << "Get/Set test error"<<endl;
nbok += result ? 1 : 0;
nb++;
trace.warning() << "(" << nbok << "/" << nb << ") "
<< "true == true" << std::endl;
return nbok == nb;
}
/**
* Simple test of Board2D. Illustrates the border extraction of a
* simple 2D object considering different topologies.
*
*/
bool testBoard2D()
{
trace.beginBlock ( "Testing Board2D with Object Borders in 2D ..." );
typedef int Integer; // choose your digital line here.
typedef SpaceND<2> Z2; // Z^2
typedef Z2::Point Point;
typedef MetricAdjacency<Z2, 1> Adj4; // 4-adjacency type
typedef MetricAdjacency<Z2, 2> Adj8; // 8-adjacency type
typedef DigitalTopology< Adj8, Adj4 > DT8_4; //8,4 topology type
typedef HyperRectDomain< Z2 > Domain;
typedef Domain::ConstIterator DomainConstIterator;
typedef DigitalSetSelector < Domain, BIG_DS + HIGH_BEL_DS >::Type DigitalSet;
typedef Object<DT8_4, DigitalSet> ObjectType;
Point p1( -20, -10 );
Point p2( 20, 10 );
Domain domain( p1, p2 );
Adj4 adj4; // instance of 4-adjacency
Adj8 adj8; // instance of 8-adjacency
DT8_4 dt8_4(adj8, adj4, JORDAN_DT );
Point c( 0, 0 );
//We construct a simple 3-bubbles set
DigitalSet bubble_set( domain );
for ( DomainConstIterator it = domain.begin(); it != domain.end(); ++it )
{
int x = (*it)[0];
int y = (*it)[1];
if (( x*x + y*y < 82) ||
( (x - 14)*(x - 14) + (y + 1)*(y + 1) < 17) ||
( (x + 14)*(x + 14) + (y - 1)*(y - 1) < 17) )
bubble_set.insertNew( *it);
}
ObjectType bubble( dt8_4, bubble_set );
//Connectedness Check
if (bubble.computeConnectedness() == ObjectType::CONNECTED)
trace.info() << "The object is (8,4)connected." << endl;
else
trace.info() << "The object is not (8,4)connected." << endl;
//Border Computation
ObjectType bubbleBorder = bubble.border();
if (bubbleBorder.computeConnectedness() == ObjectType::CONNECTED)
trace.info() << "The object (8,4) border is connected." << endl;
else
trace.info() << "The object (8,4) border is not connected." << endl;
//Board Export
Board2D board;
board.setUnit(Board::UCentimeter);
board << DrawDomainGrid()
<< CustomStyle( domain.styleName(), new MyDrawStyleCustomGreen )
<< domain
<< CustomStyle( bubble_set.styleName(), new MyDrawStyleCustomRed )
<< bubble_set;
board.saveSVG("bubble-set-dgtalboard.svg");
board << DrawObjectAdjacencies( true )
<< CustomStyle( bubbleBorder.styleName(), new MyDrawStyleCustomBlue )
<< bubbleBorder;
board.saveSVG("bubble-object-border-dgtalboard.svg");
board.clear();
trace.endBlock();
return true;
}
int main()
{
//! [DTDef]
using namespace std;
using namespace DGtal;
using namespace Z2i;
Point a ( 0, 0 );
Point b ( 32, 16);
//Input image with unsigned char values
typedef ImageSelector<Domain, unsigned int>::Type Image;
Image image ( Domain(a, b ));
//We fill the image with the 128 value
for ( Image::Iterator it = image.begin(), itend = image.end();it != itend; ++it)
(*it)=128;
//We add 3 seeds with 0 values.
image.setValue(Point(16,2), 0);
image.setValue(Point(2,11), 0);
image.setValue(Point(30,15), 0);
//! [DTDef]
trace.beginBlock ( "Example toricdomainvolumetric" );
//Input shape output
typedef GrayscaleColorMap<Image::Value> Gray;
Board2D board;
board.setUnit ( LibBoard::Board::UCentimeter );
Display2DFactory::drawImage<Gray>(board, image, (unsigned int)0, (unsigned int)129);
board.saveSVG("toric-inputShape.svg");
//! [DTPredicate]
//Point Predicate from random seed image
typedef functors::SimpleThresholdForegroundPredicate<Image> PointPredicate;
PointPredicate predicate(image,0);
//! [DTPredicate]
//! [DTComputeToric]
typedef DistanceTransformation<Space, PointPredicate, L2Metric> DTL2;
typedef DistanceTransformation<Space, PointPredicate, L2Metric> DTL2Toric;
//Regular 2D domain
DTL2 dtL2(image.domain(), predicate, l2Metric);
//Full toric 2D domain
DTL2Toric dtL2Toric(image.domain(), predicate, l2Metric, {{true, true}} );
//! [DTComputeToric]
//! [DTComputePartialToric]
typedef DistanceTransformation<Space, PointPredicate, L2Metric> DTL2ToricX;
typedef DistanceTransformation<Space, PointPredicate, L2Metric> DTL2ToricY;
// 2D domain that is periodic along the first dimension.
DTL2ToricX dtL2ToricX( image.domain(), predicate, l2Metric, {{true, false}} );
// 2D domain that is periodic along the second dimension.
DTL2ToricY dtL2ToricY( image.domain(), predicate, l2Metric, {{false, true}} );
//! [DTComputePartialToric]
//We compute the maximum DT value on the L2 map
const DTL2::Value maxv2 = * (std::max_element(dtL2.constRange().begin(), dtL2.constRange().end()));
const DTL2Toric::Value maxvtoric = * (std::max_element(dtL2Toric.constRange().begin(), dtL2Toric.constRange().end()));
const DTL2ToricX::Value maxvtoricX = * (std::max_element(dtL2ToricX.constRange().begin(), dtL2ToricX.constRange().end()));
const DTL2ToricY::Value maxvtoricY = * (std::max_element(dtL2ToricY.constRange().begin(), dtL2ToricY.constRange().end()));
// Color map based on the maximal value for all maps (in order to compare results with similar colors).
const auto maxvall = std::max( { maxv2, maxvtoric, maxvtoricX, maxvtoricY } );
//! [DTColormaps]
//Colormap used for the SVG output
typedef HueShadeColorMap<DTL2::Value, 1> HueTwice;
//! [DTColormaps]
trace.warning() << "DT maxValue= " << maxv2 << endl;
board.clear();
Display2DFactory::drawImage<HueTwice>(board, dtL2, 0.0, maxvall + 1);
board.saveSVG ( "toric-example-DT-L2.svg" );
trace.warning() << "Full toric maxValue= " << maxvtoric << endl;
board.clear();
Display2DFactory::drawImage<HueTwice>(board, dtL2Toric, 0.0, maxvall + 1);
board.saveSVG ( "toric-example-DT-L2-toric.svg" );
trace.warning() << "1th dimension periodic maxValue= " << maxvtoricX << endl;
board.clear();
Display2DFactory::drawImage<HueTwice>(board, dtL2ToricX, 0.0, maxvall + 1);
board.saveSVG ( "toric-example-DT-L2-toricX.svg" );
trace.warning() << "2nd dimension periodic maxValue= " << maxvtoricY << endl;
board.clear();
Display2DFactory::drawImage<HueTwice>(board, dtL2ToricY, 0.0, maxvall + 1);
board.saveSVG ( "toric-example-DT-L2-toricY.svg" );
//Explicit export with ticked colormap
//We compute the maximum DT value on the L2 map
TickedColorMap<double, GradientColorMap<double> > ticked(0.0,maxv2, Color::White);
ticked.addRegularTicks(3, 0.5);
ticked.finalize();
ticked.colormap()->addColor( Color::Red );
ticked.colormap()->addColor( Color::Black );
board.clear();
for ( auto it = dtL2.domain().begin(), itend = dtL2.domain().end();it != itend; ++it)
{
board<< CustomStyle((*it).className(),new CustomColors(ticked(dtL2(*it)),ticked(dtL2(*it))));
board << *it;
}
board.saveSVG("toric-example-DT-L2-ticked.svg");
board.clear();
for ( auto it = dtL2Toric.domain().begin(), itend = dtL2Toric.domain().end();it != itend; ++it)
{
board<< CustomStyle((*it).className(),new CustomColors(ticked(dtL2Toric(*it)),ticked(dtL2Toric(*it))));
board << *it;
}
board.saveSVG("toric-example-DT-L2-ticked-toric.svg");
board.clear();
for ( auto it = dtL2ToricX.domain().begin(), itend = dtL2ToricX.domain().end();it != itend; ++it)
{
board<< CustomStyle((*it).className(),new CustomColors(ticked(dtL2ToricX(*it)),ticked(dtL2ToricX(*it))));
board << *it;
}
board.saveSVG("toric-example-DT-L2-ticked-toricX.svg");
board.clear();
for ( auto it = dtL2ToricY.domain().begin(), itend = dtL2ToricY.domain().end();it != itend; ++it)
{
board<< CustomStyle((*it).className(),new CustomColors(ticked(dtL2ToricY(*it)),ticked(dtL2ToricY(*it))));
board << *it;
}
board.saveSVG("toric-example-DT-L2-ticked-toricY.svg");
//Voronoi vector output
board.clear();
board << dtL2.domain();
for ( auto it = dtL2.domain().begin(), itend = dtL2.domain().end();it != itend; ++it)
if ( dtL2.getVoronoiVector(*it) != *it )
Display2DFactory::draw(board,dtL2.getVoronoiVector(*it) - (*it), (*it));
board.saveSVG("toric-example-Voro-L2.svg");
board.clear();
board << dtL2Toric.domain();
for ( auto it = dtL2Toric.domain().begin(), itend = dtL2Toric.domain().end();it != itend; ++it)
if ( dtL2Toric.getVoronoiVector(*it) != *it )
Display2DFactory::draw(board, dtL2Toric.getVoronoiVector(*it) - (*it), (*it));
board.saveSVG("toric-example-Voro-L2-toric.svg");
board.clear();
board << dtL2Toric.domain();
for ( auto it = dtL2Toric.domain().begin(), itend = dtL2Toric.domain().end();it != itend; ++it)
if ( dtL2Toric.getVoronoiVector(*it) != *it )
Display2DFactory::draw(board, dtL2Toric.projectPoint(dtL2Toric.getVoronoiVector(*it)) - (*it), (*it));
board.saveSVG("toric-example-Voro-L2-toric-projected.svg");
board.clear();
board << dtL2ToricX.domain();
for ( auto it = dtL2ToricX.domain().begin(), itend = dtL2ToricX.domain().end();it != itend; ++it)
if ( dtL2ToricX.getVoronoiVector(*it) != *it )
Display2DFactory::draw(board, dtL2ToricX.getVoronoiVector(*it) - (*it), (*it));
board.saveSVG("toric-example-Voro-L2-toricX.svg");
board.clear();
board << dtL2ToricY.domain();
for ( auto it = dtL2ToricY.domain().begin(), itend = dtL2ToricY.domain().end();it != itend; ++it)
if ( dtL2ToricY.getVoronoiVector(*it) != *it )
Display2DFactory::draw(board, dtL2ToricY.getVoronoiVector(*it) - (*it), (*it));
board.saveSVG("toric-example-Voro-L2-toricY.svg");
trace.endBlock();
return 0;
}
bool testSurfelAdjacency()
{
typedef typename KSpace::Integer Integer;
typedef typename KSpace::Cell Cell;
typedef typename KSpace::SCell SCell;
typedef typename KSpace::Point Point;
typedef typename KSpace::DirIterator DirIterator;
typedef typename KSpace::Cells Cells;
typedef typename KSpace::SCells SCells;
unsigned int nbok = 0;
unsigned int nb = 0;
trace.beginBlock ( "Testing block KSpace instantiation and scan ..." );
KSpace K;
int xlow[ 4 ] = { -3, -3, -3, -3 };
int xhigh[ 4 ] = { 5, 3, 3, 3 };
Point low( xlow );
Point high( xhigh );
bool space_ok = K.init( low, high, true );
nbok += space_ok ? 1 : 0;
nb++;
trace.info() << "(" << nbok << "/" << nb << ") "
<< "K.init( low, high )" << std::endl;
trace.info() << "K.dim()=" << K.dimension << endl;
trace.endBlock();
trace.beginBlock ( "Testing surfel adjacency ..." );
SurfelAdjacency<KSpace::dimension> SAdj( true );
for ( Dimension i = 0; i < K.dimension; ++i )
for ( Dimension j = 0; j < K.dimension; ++j )
if ( i != j )
trace.info() << "(" << i << "," << j << ")="
<< ( SAdj.getAdjacency( i, j ) ? "i2e" : "e2i" );
trace.info() << endl;
trace.endBlock();
int spel[ 4 ] = { 1, 1, 1, 1 }; // pixel
Point kp( spel );
SCell sspel = K.sCell( kp, K.POS );
trace.beginBlock ( "Testing surfel directness ..." );
for ( Dimension k = 0; k < K.dimension; ++k )
{
SCell surfel = K.sIncident( sspel, k, true );
SCell innerspel = K.sDirectIncident( surfel, K.sOrthDir( surfel ) );
trace.info() << "spel=" << sspel << " surfel=" << surfel
<< " innerspel=" << innerspel << endl;
nbok += sspel == innerspel ? 1 : 0;
nb++;
trace.info() << "(" << nbok << "/" << nb << ") "
<< "spel == innerspel" << std::endl;
surfel = K.sIncident( sspel, k, false );
innerspel = K.sDirectIncident( surfel, K.sOrthDir( surfel ) );
trace.info() << "spel=" << sspel << " surfel=" << surfel
<< " innerspel=" << innerspel << endl;
nbok += sspel == innerspel ? 1 : 0;
nb++;
trace.info() << "(" << nbok << "/" << nb << ") "
<< "spel == innerspel" << std::endl;
}
trace.endBlock();
SurfelNeighborhood<KSpace> SN;
trace.beginBlock ( "Testing surfel neighborhood ..." );
SCell surfel = K.sIncident( sspel, 0, false );
SN.init( &K, &SAdj, surfel );
trace.info() << "surfel =" << surfel << endl;
trace.info() << "follower1(+)=" << SN.follower1( 1, true ) << endl;
trace.info() << "follower2(+)=" << SN.follower2( 1, true ) << endl;
trace.info() << "follower3(+)=" << SN.follower3( 1, true ) << endl;
trace.info() << "follower1(-)=" << SN.follower1( 1, false ) << endl;
trace.info() << "follower2(-)=" << SN.follower2( 1, false ) << endl;
trace.info() << "follower3(-)=" << SN.follower3( 1, false ) << endl;
trace.endBlock();
trace.beginBlock ( "Testing surface tracking ..." );
typedef SpaceND< KSpace::dimension, Integer > Space;
typedef HyperRectDomain<Space> Domain;
typedef typename DigitalSetSelector< Domain, BIG_DS+HIGH_BEL_DS >::Type DigitalSet;
Domain domain( low, high );
DigitalSet shape_set( domain );
SetPredicate<DigitalSet> shape_set_predicate( shape_set );
int center[ 4 ] = { 1, 0, 0, 0 }; // pixel
Point pcenter( center );
Shapes<Domain>::addNorm1Ball( shape_set, pcenter, 1 );
trace.info() << "surfel = " << surfel << endl;
SCell other1, other2;
SN.getAdjacentOnDigitalSet( other1, shape_set, 1, K.sDirect( surfel, 1 ) );
SN.getAdjacentOnDigitalSet( other2, shape_set, 1, !K.sDirect( surfel, 1 ) );
trace.info() << "directNext = " << other1 << endl;
trace.info() << "indirectNext= " << other2 << endl;
std::set<SCell> bdry;
// surfel = Surfaces<KSpace>::findABel( K, shape_set );
Surfaces<KSpace>::trackBoundary( bdry,
K, SAdj, shape_set_predicate, surfel );
trace.info() << "tracking finished, size=" << bdry.size()
<< ", should be " << 2*K.dimension*(2*K.dimension-1) << endl;
nbok += bdry.size() == ( 2*K.dimension*(2*K.dimension-1) ) ? 1 : 0;
nb++;
trace.info() << "(" << nbok << "/" << nb << ") "
<< "bdry.size() == ( 2*K.dimension*(2*K.dimension-1) )"
<< std::endl;
std::set<SCell> bdry_direct;
Surfaces<KSpace>::trackClosedBoundary( bdry_direct,
K, SAdj, shape_set_predicate, surfel );
trace.info() << "fast direct tracking finished, size=" << bdry_direct.size()
<< ", should be " << 2*K.dimension*(2*K.dimension-1) << endl;
nbok += bdry_direct.size() == ( 2*K.dimension*(2*K.dimension-1) ) ? 1 : 0;
nb++;
trace.info() << "(" << nbok << "/" << nb << ") "
<< "bdry_direct.size() == ( 2*K.dimension*(2*K.dimension-1) )"
<< std::endl;
trace.endBlock();
if ( K.dimension == 2 )
{
Board2D board;
board.setUnit( LibBoard::Board::UCentimeter );
board << SetMode( domain.className(), "Paving" )
<< domain;
for ( typename std::set<SCell>::const_iterator it = bdry_direct.begin(),
it_end = bdry_direct.end(); it != it_end; ++it )
board << *it;
board.saveEPS( "cells-2.eps" );
board.saveSVG( "cells-2.svg" );
}
return nbok == nb;
}
