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author | vrouvrea <vrouvrea@636b058d-ea47-450e-bf9e-a15bfbe3eedb> | 2016-04-08 12:28:04 +0000 |
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committer | vrouvrea <vrouvrea@636b058d-ea47-450e-bf9e-a15bfbe3eedb> | 2016-04-08 12:28:04 +0000 |
commit | 8b26dea17912abc00aee9e13984ef8cbfe076b0f (patch) | |
tree | 420adf59e7d1d133c3f8838ca9c82525a57df6d8 /src/Alpha_complex/test/Alpha_complex_unit_test.cpp | |
parent | 0ca1fbeb35a9a681320186f63a7cf26256ebf05a (diff) | |
parent | 635eda52786951558d820b06bb18b9f6d54dc89a (diff) |
Merge of Alpha complex feature
git-svn-id: svn+ssh://scm.gforge.inria.fr/svnroot/gudhi/trunk@1108 636b058d-ea47-450e-bf9e-a15bfbe3eedb
Former-commit-id: 05bfd7eb76782dd6e5cab03a746cac4aeacb91de
Diffstat (limited to 'src/Alpha_complex/test/Alpha_complex_unit_test.cpp')
-rw-r--r-- | src/Alpha_complex/test/Alpha_complex_unit_test.cpp | 243 |
1 files changed, 243 insertions, 0 deletions
diff --git a/src/Alpha_complex/test/Alpha_complex_unit_test.cpp b/src/Alpha_complex/test/Alpha_complex_unit_test.cpp new file mode 100644 index 00000000..80b39924 --- /dev/null +++ b/src/Alpha_complex/test/Alpha_complex_unit_test.cpp @@ -0,0 +1,243 @@ +/* This file is part of the Gudhi Library. The Gudhi library + * (Geometric Understanding in Higher Dimensions) is a generic C++ + * library for computational topology. + * + * Author(s): Vincent Rouvreau + * + * Copyright (C) 2015 INRIA Saclay (France) + * + * 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/>. + */ + +#define BOOST_TEST_DYN_LINK +#define BOOST_TEST_MODULE "alpha_complex" +#include <boost/test/unit_test.hpp> + +#include <CGAL/Delaunay_triangulation.h> +#include <CGAL/Epick_d.h> + +#include <cmath> // float comparison +#include <limits> +#include <string> +#include <vector> + +#include <gudhi/Alpha_complex.h> + +// Use dynamic_dimension_tag for the user to be able to set dimension +typedef CGAL::Epick_d< CGAL::Dynamic_dimension_tag > Kernel_d; +// The triangulation uses the default instantiation of the TriangulationDataStructure template parameter + +BOOST_AUTO_TEST_CASE(ALPHA_DOC_OFF_file) { + // ---------------------------------------------------------------------------- + // + // Init of an alpha-complex from a OFF file + // + // ---------------------------------------------------------------------------- + std::string off_file_name("alphacomplexdoc.off"); + double max_alpha_square_value = 60.0; + std::cout << "========== OFF FILE NAME = " << off_file_name << " - alpha²=" << + max_alpha_square_value << "==========" << std::endl; + + Gudhi::alphacomplex::Alpha_complex<Kernel_d> alpha_complex_from_file(off_file_name, max_alpha_square_value); + + const int DIMENSION = 2; + std::cout << "alpha_complex_from_file.dimension()=" << alpha_complex_from_file.dimension() << std::endl; + BOOST_CHECK(alpha_complex_from_file.dimension() == DIMENSION); + + const int NUMBER_OF_VERTICES = 7; + std::cout << "alpha_complex_from_file.num_vertices()=" << alpha_complex_from_file.num_vertices() << std::endl; + BOOST_CHECK(alpha_complex_from_file.num_vertices() == NUMBER_OF_VERTICES); + + const int NUMBER_OF_SIMPLICES = 25; + std::cout << "alpha_complex_from_file.num_simplices()=" << alpha_complex_from_file.num_simplices() << std::endl; + BOOST_CHECK(alpha_complex_from_file.num_simplices() == NUMBER_OF_SIMPLICES); + +} + +BOOST_AUTO_TEST_CASE(ALPHA_DOC_OFF_file_filtered) { + // ---------------------------------------------------------------------------- + // + // Init of an alpha-complex from a OFF file + // + // ---------------------------------------------------------------------------- + std::string off_file_name("alphacomplexdoc.off"); + double max_alpha_square_value = 59.0; + std::cout << "========== OFF FILE NAME = " << off_file_name << " - alpha²=" << + max_alpha_square_value << "==========" << std::endl; + + // Use of the default dynamic kernel + Gudhi::alphacomplex::Alpha_complex<> alpha_complex_from_file(off_file_name, max_alpha_square_value); + + const int DIMENSION = 2; + std::cout << "alpha_complex_from_file.dimension()=" << alpha_complex_from_file.dimension() << std::endl; + BOOST_CHECK(alpha_complex_from_file.dimension() == DIMENSION); + + const int NUMBER_OF_VERTICES = 7; + std::cout << "alpha_complex_from_file.num_vertices()=" << alpha_complex_from_file.num_vertices() << std::endl; + BOOST_CHECK(alpha_complex_from_file.num_vertices() == NUMBER_OF_VERTICES); + + const int NUMBER_OF_SIMPLICES = 23; + std::cout << "alpha_complex_from_file.num_simplices()=" << alpha_complex_from_file.num_simplices() << std::endl; + BOOST_CHECK(alpha_complex_from_file.num_simplices() == NUMBER_OF_SIMPLICES); +} + +bool are_almost_the_same(float a, float b) { + return std::fabs(a - b) < std::numeric_limits<float>::epsilon(); +} + +// Use dynamic_dimension_tag for the user to be able to set dimension +typedef CGAL::Epick_d< CGAL::Dimension_tag<4> > Kernel_s; +typedef Kernel_s::Point_d Point; +typedef std::vector<Point> Vector_of_points; + + +bool is_point_in_list(Vector_of_points points_list, Point point) { + for (auto& point_in_list : points_list) { + if (point_in_list == point) { + return true; // point found + } + } + return false; // point not found +} + +BOOST_AUTO_TEST_CASE(Alpha_complex_from_points) { + // ---------------------------------------------------------------------------- + // Init of a list of points + // ---------------------------------------------------------------------------- + Vector_of_points points; + std::vector<double> coords = { 0.0, 0.0, 0.0, 1.0 }; + points.push_back(Point(coords.begin(), coords.end())); + coords = { 0.0, 0.0, 1.0, 0.0 }; + points.push_back(Point(coords.begin(), coords.end())); + coords = { 0.0, 1.0, 0.0, 0.0 }; + points.push_back(Point(coords.begin(), coords.end())); + coords = { 1.0, 0.0, 0.0, 0.0 }; + points.push_back(Point(coords.begin(), coords.end())); + + // ---------------------------------------------------------------------------- + // Init of an alpha complex from the list of points + // ---------------------------------------------------------------------------- + Gudhi::alphacomplex::Alpha_complex<Kernel_s> alpha_complex_from_points(points); + + std::cout << "========== Alpha_complex_from_points ==========" << std::endl; + + // Another way to check num_simplices + std::cout << "Iterator on alpha complex simplices in the filtration order, with [filtration value]:" << std::endl; + int num_simplices = 0; + for (auto f_simplex : alpha_complex_from_points.filtration_simplex_range()) { + num_simplices++; + std::cout << " ( "; + for (auto vertex : alpha_complex_from_points.simplex_vertex_range(f_simplex)) { + std::cout << vertex << " "; + } + std::cout << ") -> " << "[" << alpha_complex_from_points.filtration(f_simplex) << "] "; + std::cout << std::endl; + } + BOOST_CHECK(num_simplices == 15); + std::cout << "alpha_complex_from_points.num_simplices()=" << alpha_complex_from_points.num_simplices() << std::endl; + BOOST_CHECK(alpha_complex_from_points.num_simplices() == 15); + + std::cout << "alpha_complex_from_points.dimension()=" << alpha_complex_from_points.dimension() << std::endl; + BOOST_CHECK(alpha_complex_from_points.dimension() == 4); + std::cout << "alpha_complex_from_points.num_vertices()=" << alpha_complex_from_points.num_vertices() << std::endl; + BOOST_CHECK(alpha_complex_from_points.num_vertices() == 4); + + for (auto f_simplex : alpha_complex_from_points.filtration_simplex_range()) { + switch (alpha_complex_from_points.dimension(f_simplex)) { + case 0: + BOOST_CHECK(are_almost_the_same(alpha_complex_from_points.filtration(f_simplex), 0.0)); + break; + case 1: + BOOST_CHECK(are_almost_the_same(alpha_complex_from_points.filtration(f_simplex), 1.0/2.0)); + break; + case 2: + BOOST_CHECK(are_almost_the_same(alpha_complex_from_points.filtration(f_simplex), 2.0/3.0)); + break; + case 3: + BOOST_CHECK(are_almost_the_same(alpha_complex_from_points.filtration(f_simplex), 3.0/4.0)); + break; + default: + BOOST_CHECK(false); // Shall not happen + break; + } + } + + Point p0 = alpha_complex_from_points.get_point(0); + std::cout << "alpha_complex_from_points.get_point(0)=" << p0 << std::endl; + BOOST_CHECK(4 == p0.dimension()); + BOOST_CHECK(is_point_in_list(points, p0)); + + Point p1 = alpha_complex_from_points.get_point(1); + std::cout << "alpha_complex_from_points.get_point(1)=" << p1 << std::endl; + BOOST_CHECK(4 == p1.dimension()); + BOOST_CHECK(is_point_in_list(points, p1)); + + Point p2 = alpha_complex_from_points.get_point(2); + std::cout << "alpha_complex_from_points.get_point(2)=" << p2 << std::endl; + BOOST_CHECK(4 == p2.dimension()); + BOOST_CHECK(is_point_in_list(points, p2)); + + Point p3 = alpha_complex_from_points.get_point(3); + std::cout << "alpha_complex_from_points.get_point(3)=" << p3 << std::endl; + BOOST_CHECK(4 == p3.dimension()); + BOOST_CHECK(is_point_in_list(points, p3)); + + // Test to the limit + BOOST_CHECK_THROW (alpha_complex_from_points.get_point(4), std::out_of_range); + BOOST_CHECK_THROW (alpha_complex_from_points.get_point(-1), std::out_of_range); + BOOST_CHECK_THROW (alpha_complex_from_points.get_point(1234), std::out_of_range); + + // Test after prune_above_filtration + bool modified = alpha_complex_from_points.prune_above_filtration(0.6); + if (modified) { + alpha_complex_from_points.initialize_filtration(); + } + BOOST_CHECK(modified); + + // Another way to check num_simplices + std::cout << "Iterator on alpha complex simplices in the filtration order, with [filtration value]:" << std::endl; + num_simplices = 0; + for (auto f_simplex : alpha_complex_from_points.filtration_simplex_range()) { + num_simplices++; + std::cout << " ( "; + for (auto vertex : alpha_complex_from_points.simplex_vertex_range(f_simplex)) { + std::cout << vertex << " "; + } + std::cout << ") -> " << "[" << alpha_complex_from_points.filtration(f_simplex) << "] "; + std::cout << std::endl; + } + BOOST_CHECK(num_simplices == 10); + std::cout << "alpha_complex_from_points.num_simplices()=" << alpha_complex_from_points.num_simplices() << std::endl; + BOOST_CHECK(alpha_complex_from_points.num_simplices() == 10); + + std::cout << "alpha_complex_from_points.dimension()=" << alpha_complex_from_points.dimension() << std::endl; + BOOST_CHECK(alpha_complex_from_points.dimension() == 4); + std::cout << "alpha_complex_from_points.num_vertices()=" << alpha_complex_from_points.num_vertices() << std::endl; + BOOST_CHECK(alpha_complex_from_points.num_vertices() == 4); + + for (auto f_simplex : alpha_complex_from_points.filtration_simplex_range()) { + switch (alpha_complex_from_points.dimension(f_simplex)) { + case 0: + BOOST_CHECK(are_almost_the_same(alpha_complex_from_points.filtration(f_simplex), 0.0)); + break; + case 1: + BOOST_CHECK(are_almost_the_same(alpha_complex_from_points.filtration(f_simplex), 1.0/2.0)); + break; + default: + BOOST_CHECK(false); // Shall not happen + break; + } + } + +} |