/***************************************************************************
M-ZZ: Morozov zigzag implementation
Copyright (C) 2009-2012 Dmitriy Morozov
Adapted from its original version ("rips-zigzag.cpp" in
the Dionysus library) by Steve Oudot (2012).
Changelog (2012-11-22):
- the barcode is now output on a log scale and in a format that is
compatible with the Matlab layer of the PLEX 2.5 library,
- the barcode representation is now by closed intervals instead of
half-open intervals.
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
***************************************************************************/
#include <topology/rips.h>
#include <topology/zigzag-persistence.h>
#include <utilities/types.h>
#include <utilities/containers.h>
#include <geometry/l2distance.h> // Point, PointContainer, L2DistanceType, read_points
#include <geometry/distances.h>
#include <utilities/log.h>
#include <utilities/memory.h> // for report_memory()
#include <utilities/timer.h>
#include <map>
#include <cmath>
#include <fstream>
#include <stack>
#include <cstdlib>
#include <boost/tuple/tuple.hpp>
#include <boost/program_options.hpp>
#include <boost/progress.hpp>
#ifdef COUNTERS
static Counter* cComplexSize = GetCounter("rips/size");
static Counter* cOperations = GetCounter("rips/operations");
#endif // COUNTERS
typedef PairwiseDistances<PointContainer, L2Distance> PairDistances;
typedef PairDistances::DistanceType DistanceType;
typedef PairDistances::IndexType Vertex;
typedef Simplex<Vertex> Smplx;
typedef std::vector<Smplx> SimplexVector;
typedef std::list<Smplx> SimplexList;
typedef std::set<Smplx, Smplx::VertexDimensionComparison> SimplexSet;
typedef std::vector<Vertex> VertexVector;
typedef std::vector<DistanceType> EpsilonVector;
typedef std::vector<std::pair<Vertex, Vertex> > EdgeVector;
typedef Rips<PairDistances, Smplx> RipsGenerator;
typedef RipsGenerator::Evaluator SimplexEvaluator;
struct BirthInfo;
typedef ZigzagPersistence<BirthInfo> Zigzag;
typedef Zigzag::SimplexIndex Index;
typedef Zigzag::Death Death;
typedef std::map<Smplx, Index,
Smplx::VertexDimensionComparison> Complex;
typedef Zigzag::ZColumn Boundary;
typedef std::vector<std::list<std::pair<double, double> > > IntervalsVector;
// Information we need to know when a class dies
struct BirthInfo
{
BirthInfo(DistanceType dist = DistanceType(), Dimension dim = Dimension()):
distance(dist), dimension(dim) {}
DistanceType distance;
Dimension dimension;
};
// Forward declarations of auxilliary functions
// Note: min_value is used only for log-scale, so set it up to zero by default
void write_intervals(std::ostream& out, const IntervalsVector& intervals, int skeleton_dimension, bool logscale, double min_value=0);
void report_death(IntervalsVector& intervals, Death d, DistanceType epsilon, DistanceType birthEpsilon, Dimension skeleton_dimension);
void make_boundary(const Smplx& s, Complex& c, const Zigzag& zz, Boundary& b);
std::ostream& operator<<(std::ostream& out, const BirthInfo& bi);
void process_command_line_options(int argc,
char* argv[],
unsigned& skeleton_dimension,
float& multiplier,
bool& logscale,
std::string& infilename,
std::string& outfilename);
int main(int argc, char* argv[])
{
#ifdef LOGGING
rlog::RLogInit(argc, argv);
stderrLog.subscribeTo( RLOG_CHANNEL("error") );
#endif
Timer total, remove, add, ec, vc;
total.start();
#if 0
SetFrequency(cOperations, 25000);
SetTrigger(cOperations, cComplexSize);
#endif
unsigned skeleton_dimension;
float multiplier;
std::string infilename, outfilename;
bool logscale = false;
process_command_line_options(argc, argv, skeleton_dimension, multiplier, logscale, infilename, outfilename);
// Read in points
PointContainer points;
read_points(infilename, points);
std::cout << "Number of points: " << points.size() << std::endl;
// Create output file
std::ofstream out(outfilename.c_str());
// Create pairwise distances
PairDistances distances(points);
// Create intervals DS
IntervalsVector intervals(skeleton_dimension);
// for (int i=0; i<skeleton_dimension; i++)
// intervals[i] = new std::list<std::pair<double, double> > ();
// Order vertices and epsilons (in maxmin fashion)
VertexVector vertices;
EpsilonVector epsilons;
EdgeVector edges;
{
EpsilonVector dist(distances.size(), Infinity);
vertices.push_back(distances.begin());
//epsilons.push_back(Infinity);
while (vertices.size() < distances.size())
{
for (Vertex v = distances.begin(); v != distances.end(); ++v)
dist[v] = std::min(dist[v], distances(v, vertices.back()));
EpsilonVector::const_iterator max = std::max_element(dist.begin(), dist.end());
vertices.push_back(max - dist.begin());
epsilons.push_back(*max);
}
epsilons.push_back(0);
}
rInfo("Point and epsilon ordering:");
for (unsigned i = 0; i < vertices.size(); ++i)
rInfo(" %4d: %4d - %f", i, vertices[i], epsilons[i]);
// Generate and sort all the edges
for (unsigned i = 0; i != vertices.size(); ++i)
for (unsigned j = i+1; j != vertices.size(); ++j)
{
Vertex u = vertices[i];
Vertex v = vertices[j];
if (distances(u,v) <= multiplier*epsilons[j-1])
edges.push_back(std::make_pair(u,v));
}
std::sort(edges.begin(), edges.end(), RipsGenerator::ComparePair(distances));
std::cout << "Total participating edges: " << edges.size() << std::endl;
for (EdgeVector::const_iterator cur = edges.begin(); cur != edges.end(); ++cur)
rDebug(" (%d, %d) %f", cur->first, cur->second, distances(cur->first, cur->second));
// Construct zigzag
Complex complex;
Zigzag zz;
RipsGenerator rips(distances);
SimplexEvaluator size(distances);
// Insert vertices (initial complex is just a disjoint union of vertices)
for (unsigned i = 0; i != vertices.size(); ++i)
{
// Add a vertex
Smplx sv; sv.add(vertices[i]);
rDebug("Adding %s", tostring(sv).c_str());
add.start();
complex.insert(std::make_pair(sv,
zz.add(Boundary(),
BirthInfo(0, 0)).first));
add.stop();
//rDebug("Newly born cycle order: %d", complex[sv]->low->order);
CountNum(cComplexSize, 0);
Count(cComplexSize);
Count(cOperations);
}
rInfo("Commencing computation");
boost::progress_display show_progress(vertices.size());
unsigned ce = 0; // index of the current one past last edge in the complex
for (unsigned stage = 0; stage != vertices.size() - 1; ++stage)
{
unsigned i = vertices.size() - 1 - stage;
// std::cout << "Current stage " << stage << " "
// << vertices[i] << " " << epsilons[i-1] << ": "
// << multiplier*epsilons[i-1] << std::endl;
/* Increase epsilon */
// Record the cofaces of all the simplices that need to be removed and reinserted
SimplexSet cofaces;
rDebug(" Cofaces size: %d", cofaces.size());
// Add anything else that needs to be inserted into the complex
while (ce < edges.size())
{
Vertex u,v;
boost::tie(u,v) = edges[ce];
if (distances(u,v) <= multiplier*epsilons[i-1])
++ce;
else
break;
rDebug(" Recording cofaces of edges[%d]=(%d, %d) with size=%f", (ce-1), u, v, distances(u,v));
ec.start();
rips.edge_cofaces(u, v,
skeleton_dimension,
multiplier*epsilons[i-1],
make_insert_functor(cofaces),
vertices.begin(),
vertices.begin() + i + 1);
ec.stop();
}
rDebug(" Recorded new cofaces to add");
// Insert all the cofaces
rDebug(" Cofaces size: %d", cofaces.size());
for (SimplexSet::const_iterator cur = cofaces.begin(); cur != cofaces.end(); ++cur)
{
Index idx; Death d; Boundary b;
rDebug(" Adding %s, its size %f", tostring(*cur).c_str(), size(*cur));
make_boundary(*cur, complex, zz, b);
add.start();
boost::tie(idx, d) = zz.add(b,
BirthInfo(epsilons[i-1], cur->dimension()));
add.stop();
//if (!d) rDebug("Newly born cycle order: %d", complex[*cur]->low->order);
CountNum(cComplexSize, cur->dimension());
Count(cComplexSize);
Count(cOperations);
AssertMsg(zz.check_consistency(), "Zigzag representation must be consistent after removing a simplex");
complex.insert(std::make_pair(*cur, idx));
report_death(intervals, d, epsilons[i-1], epsilons[i], skeleton_dimension);
}
rInfo("Increased epsilon; complex size: %d", complex.size());
report_memory();
/* Remove the vertex */
cofaces.clear();
rDebug(" Cofaces size: %d", cofaces.size());
vc.start();
rips.vertex_cofaces(vertices[i],
skeleton_dimension,
multiplier*epsilons[i-1],
make_insert_functor(cofaces),
vertices.begin(),
vertices.begin() + i + 1);
vc.stop();
rDebug(" Computed cofaces of the vertex, their number: %d", cofaces.size());
for (SimplexSet::const_reverse_iterator cur = cofaces.rbegin(); cur != (SimplexSet::const_reverse_iterator)cofaces.rend(); ++cur)
{
rDebug(" Removing: %s", tostring(*cur).c_str());
Complex::iterator si = complex.find(*cur);
remove.start();
Death d = zz.remove(si->second,
BirthInfo(epsilons[i-1], cur->dimension() - 1));
remove.stop();
complex.erase(si);
CountNumBy(cComplexSize, cur->dimension(), -1);
CountBy(cComplexSize, -1);
Count(cOperations);
AssertMsg(zz.check_consistency(), "Zigzag representation must be consistent after removing a simplex");
report_death(intervals, d, epsilons[i-1], epsilons[i], skeleton_dimension);
}
rInfo("Removed vertex; complex size: %d", complex.size());
for (Complex::const_iterator cur = complex.begin(); cur != complex.end(); ++cur)
rDebug(" %s", tostring(cur->first).c_str());
report_memory();
++show_progress;
}
// Remove the last vertex
AssertMsg(complex.size() == 1, "Only one vertex must remain");
remove.start();
Death d = zz.remove(complex.begin()->second, BirthInfo(epsilons[0], -1));
remove.stop();
complex.erase(complex.begin());
if (!d) AssertMsg(false, "The vertex must have died");
report_death(intervals, d, epsilons[0], epsilons[0], skeleton_dimension);
CountNumBy(cComplexSize, 0, -1);
CountBy(cComplexSize, -1);
Count(cOperations);
rInfo("Removed vertex; complex size: %d", complex.size());
++show_progress;
total.stop();
remove.check("Remove timer ");
add.check ("Add timer ");
ec.check ("Edge coface timer ");
vc.check ("Vertex coface timer ");
total.check ("Total timer ");
std::cout << "Writing intervals...";
// Note (hack): use epsilons[vertices.size()-2]/2 as minimal value for the log-scale intervals to avoid intervals starting at -infinity and thus a scaling effect
write_intervals(out, intervals, skeleton_dimension, logscale, epsilons[vertices.size()-2]/2);
std::cout << " done." << std::endl;
}
const double LOG2 = std::log(2.0);
double log2(double x) {
return std::log(x) / LOG2;
}
void write_intervals(std::ostream& out, const IntervalsVector& intervals, int skeleton_dimension, bool logscale, double min_value) {
out << "I = { ";
for (int d = 0; d<skeleton_dimension; d++) {
out << "[ ";
for (std::list<std::pair<double,double> >::const_iterator pit = intervals[d].begin(); pit != intervals[d].end(); pit++)
if (logscale)
out << "[" << log2(std::max(pit->first, min_value)) << ";" << log2(std::max(pit->second, min_value)) << "] ";
else
out << "[" << pit->first << ";" << pit->second << "] ";
// add dummy interval if intervals list is empty
if (intervals[d].empty())
out << "[0;0] ";
out << "] ,";
}
out << "} ";
}
void report_death(IntervalsVector& intervals, Death d, DistanceType epsilon, DistanceType birthEpsilon, Dimension skeleton_dimension)
{
// std::cerr << " d = " << d;
// if (d)
// std::cerr << " d->dim = " << d->dimension
// << " d->dist = " << d->distance;
// std::cerr << " epsilon = " << epsilon << std::endl;
if (d && ((d->distance - epsilon) != 0) && (d->dimension < skeleton_dimension))
intervals[d->dimension].push_back(std::pair<double,double>(d->distance, birthEpsilon));
}
void make_boundary(const Smplx& s, Complex& c, const Zigzag& zz, Boundary& b)
{
rDebug(" Boundary of <%s>", tostring(s).c_str());
for (Smplx::BoundaryIterator cur = s.boundary_begin(); cur != s.boundary_end(); ++cur)
{
b.append(c[*cur], zz.cmp);
rDebug(" %d", c[*cur]->order);
}
}
std::ostream& operator<<(std::ostream& out, const BirthInfo& bi)
{ return (out << bi.distance); }
void process_command_line_options(int argc,
char* argv[],
unsigned& skeleton_dimension,
float& multiplier,
bool& logscale,
std::string& infilename,
std::string& outfilename)
{
namespace po = boost::program_options;
po::options_description hidden("Hidden options");
hidden.add_options()
("input-file", po::value<std::string>(&infilename), "Point set whose Rips zigzag we want to compute")
("output-file", po::value<std::string>(&outfilename), "Location to save persistence pairs");
po::options_description visible("Allowed options", 100);
visible.add_options()
("help,h", "produce help message")
("dim,d", po::value<unsigned>(&skeleton_dimension)->default_value(3), "maximal dimension of the Rips complex")
("rho,r", po::value<float>(&multiplier)->default_value(3), "multiplier rho used in the Rips parameter")
( "logscale,l" , po::value( &logscale )->zero_tokens(), "outputs interval bounds on log_2 scale" ) ;
#if LOGGING
std::vector<std::string> log_channels;
visible.add_options()
("log,l", po::value< std::vector<std::string> >(&log_channels), "log channels to turn on (info, debug, etc)");
#endif
po::positional_options_description pos;
pos.add("input-file", 1);
pos.add("output-file", 2);
po::options_description all; all.add(visible).add(hidden);
po::variables_map vm;
po::store(po::command_line_parser(argc, argv).
options(all).positional(pos).run(), vm);
po::notify(vm);
#if LOGGING
for (std::vector<std::string>::const_iterator cur = log_channels.begin(); cur != log_channels.end(); ++cur)
stderrLog.subscribeTo( RLOG_CHANNEL(cur->c_str()) );
/**
* Interesting channels
* "info", "debug", "topology/persistence"
*/
#endif
if (vm.count("help") || !vm.count("input-file") || !vm.count("output-file"))
{
std::cout << "Usage: " << argv[0] << " [options] input-file output-file" << std::endl;
std::cout << visible << std::endl;
std::abort();
}
}