Commit before merging in Python branch:
* converted more examples: poincare, rips, some fitness
* two generators for Rips complexes
* ChainWrapper uses stl algorithms for everything,
added CountingBackInserter and switched SizeStorage to use operators
* retabbing files along the way
* added #957a (namespace dionysus)
#include <utilities/log.h>
#include "alphashapes3d.h"
#include <topology/filtration.h>
#include <iostream>
#include <fstream>
struct SimplexWithDistance: public AlphaSimplex3D
{
SimplexWithDistance(const SimplexWithDistance& s): AlphaSimplex3D(s) { distance = s.distance; }
SimplexWithDistance(const AlphaSimplex3D& s): AlphaSimplex3D(s) { }
SimplexWithDistance(const AlphaSimplex3D::Parent& s): AlphaSimplex3D(s) { }
SimplexWithDistance(const AlphaSimplex3D& s, const Point& p): AlphaSimplex3D(s) { set_distance(p); }
void set_distance(const Point& p)
{
AlphaSimplex3D::VertexContainer::const_iterator cur = vertices().begin();
K::Vector_3 v = ((*cur)->point() - p);
RealValue min_distance = v*v;
while (cur != vertices().end())
{
v = ((*cur)->point() - p);
min_distance = std::min(v*v, min_distance);
++cur;
}
distance = min_distance;
}
RealValue distance;
};
typedef std::vector<SimplexWithDistance> SimplexVector;
typedef Filtration<SimplexWithDistance> RadiusFiltration;
struct RadiusOrder
{
bool operator()(const SimplexWithDistance& first, const SimplexWithDistance& second) const
{
if (first.distance == second.distance)
return (first.dimension() < second.dimension());
else
return (first.distance > second.distance);
}
};
int main(int argc, char** argv)
{
#ifdef LOGGING
rlog::RLogInit(argc, argv);
stdoutLog.subscribeTo( RLOG_CHANNEL("info") );
stdoutLog.subscribeTo( RLOG_CHANNEL("error") );
stdoutLog.subscribeTo( RLOG_CHANNEL("topology/filtration") );
//stdoutLog.subscribeTo( RLOG_CHANNEL("topology/cycle") );
#endif
std::istream& in = std::cin;
std::ofstream point_vineyard("point_vineyard.vrt");
double x,y,z;
Delaunay Dt;
while(in)
{
in >> x >> y >> z;
Point p(x,y,z);
Dt.insert(p);
}
rInfo("Delaunay triangulation computed");
AlphaSimplex3DVector alpha_ordering;
fill_alpha_order(Dt, alpha_ordering);
// Compute r-filtration for each distinct alpha
Point p(0,0,0);
RadiusOrder ro;
SimplexVector radius_ordering;
for (AlphaSimplex3DVector::const_iterator cur = alpha_ordering.begin(); cur != alpha_ordering.end(); ++cur)
{
radius_ordering.push_back(*cur);
radius_ordering.back().set_distance(p);
if (boost::next(cur)->alpha() == cur->alpha())
continue;
double current_alpha = CGAL::to_double(cur->value());
rInfo("Current alpha: %f", current_alpha);
std::sort(radius_ordering.begin(), radius_ordering.end(), ro);
rInfo("Radius ordering size: %i", radius_ordering.size());
RadiusFiltration rf;
for (SimplexVector::const_iterator cur = radius_ordering.begin(); cur != radius_ordering.end(); ++cur)
rf.append(*cur);
rf.fill_simplex_index_map();
rInfo("Simplex index map filled");
rf.pair_simplices(rf.begin(), rf.end());
rInfo("Pairing computed");
for (RadiusFiltration::const_Index cur = rf.begin(); cur != rf.end(); ++cur)
{
if (!cur->sign()) continue;
RealValue d1 = cur->distance;
//if (cur == cur->pair())
// rInfo("Unpaired %d %f", cur->dimension(), CGAL::to_double(d1));
RealValue d2 = cur->pair()->distance;
if (d1 == d2) continue;
point_vineyard << CGAL::to_double(d1) << ' ' << CGAL::to_double(d2) << ' ' << current_alpha << std::endl;
}
}
point_vineyard.close();
}