3 files changed, 360 insertions, 1 deletions

diff --git a/src/Alpha_complex/test/Alpha_kernel_d_unit_test.cpp b/src/Alpha_complex/test/Alpha_kernel_d_unit_test.cpp
new file mode 100644
index 00000000..6da4c084
--- /dev/null
+++ b/src/Alpha_complex/test/Alpha_kernel_d_unit_test.cpp
@@ -0,0 +1,109 @@
+/*    This file is part of the Gudhi Library - https://gudhi.inria.fr/ - which is released under MIT.
+ *    See file LICENSE or go to https://gudhi.inria.fr/licensing/ for full license details.
+ *    Author(s):       Vincent Rouvreau
+ *
+ *    Copyright (C) 2020 Inria
+ *
+ *    Modification(s):
+ *      - YYYY/MM Author: Description of the modification
+ */
+
+#define BOOST_TEST_DYN_LINK
+#define BOOST_TEST_MODULE "alpha_kernel_d"
+#include <boost/test/unit_test.hpp>
+#include <boost/mpl/list.hpp>
+
+#include <CGAL/Epick_d.h>
+#include <CGAL/Epeck_d.h>
+#include <CGAL/NT_converter.h>
+
+#include <iostream>
+#include <vector>
+#include <utility>  // for std::pair
+
+#include <gudhi/Alpha_complex/Alpha_kernel_d.h>
+#include <gudhi/Unitary_tests_utils.h>
+
+// Use dynamic_dimension_tag for the user to be able to set dimension
+typedef CGAL::Epeck_d< CGAL::Dynamic_dimension_tag > Exact_kernel_d;
+// Use static dimension_tag for the user not to be able to set dimension
+typedef CGAL::Epeck_d< CGAL::Dimension_tag<4> > Exact_kernel_s;
+// Use dynamic_dimension_tag for the user to be able to set dimension
+typedef CGAL::Epick_d< CGAL::Dynamic_dimension_tag > Inexact_kernel_d;
+// Use static dimension_tag for the user not to be able to set dimension
+typedef CGAL::Epick_d< CGAL::Dimension_tag<4> > Inexact_kernel_s;
+// The triangulation uses the default instantiation of the TriangulationDataStructure template parameter
+
+typedef boost::mpl::list<Exact_kernel_d, Exact_kernel_s, Inexact_kernel_d, Inexact_kernel_s> list_of_kernel_variants;
+
+BOOST_AUTO_TEST_CASE_TEMPLATE(Alpha_kernel_d_dimension, TestedKernel, list_of_kernel_variants) {
+  // Test for a point (weighted or not) in 4d, that the dimension is 4.
+
+  Gudhi::alpha_complex::Alpha_kernel_d<TestedKernel, false> kernel;
+  std::vector<double> p0 {0., 1., 2., 3.};
+  typename TestedKernel::Point_d p0_d(p0.begin(), p0.end());
+
+  std::clog << "Dimension is " << kernel.get_dimension(p0_d) << std::endl;
+  BOOST_CHECK(kernel.get_dimension(p0_d) == 4);
+
+  Gudhi::alpha_complex::Alpha_kernel_d<TestedKernel, true> w_kernel;
+  typename TestedKernel::Weighted_point_d w_p0_d(p0_d, 10.);
+
+  std::clog << "Dimension is " << w_kernel.get_dimension(w_p0_d) << std::endl;
+  BOOST_CHECK(w_kernel.get_dimension(w_p0_d) == 4);
+}
+
+BOOST_AUTO_TEST_CASE_TEMPLATE(Alpha_kernel_d_sphere, TestedKernel, list_of_kernel_variants) {
+  // Test with 5 points on a 3-sphere, that get_sphere returns the same center and squared radius
+  // for dD unweighted and for dD weighted with all weights at 0.
+
+  using Unweighted_kernel = Gudhi::alpha_complex::Alpha_kernel_d<TestedKernel, false>;
+  // Sphere: (x-1)² + (y-1)² + z² + t² = 1
+  // At least 5 points for a 3-sphere
+  std::vector<double> p0 {1., 0., 0., 0.};
+  std::vector<double> p1 {0., 1., 0., 0.};
+  std::vector<double> p2 {1., 1., 1., 0.};
+  std::vector<double> p3 {1., 1., 0., 1.};
+  std::vector<double> p4 {1., 1., -1., 0.};
+
+  using Point_d = typename Unweighted_kernel::Point_d;
+  std::vector<Point_d> unw_pts;
+  unw_pts.emplace_back(p0.begin(), p0.end());
+  unw_pts.emplace_back(p1.begin(), p1.end());
+  unw_pts.emplace_back(p2.begin(), p2.end());
+  unw_pts.emplace_back(p3.begin(), p3.end());
+  unw_pts.emplace_back(p4.begin(), p4.end());
+
+  Unweighted_kernel kernel;
+  auto unw_sphere = kernel.get_sphere(unw_pts.cbegin(), unw_pts.cend());
+
+  std::clog << "Center is " << unw_sphere.first << " - squared radius is " << unw_sphere.second << std::endl;
+
+  using Weighted_kernel = Gudhi::alpha_complex::Alpha_kernel_d<TestedKernel, true>;
+
+  using Weighted_point_d = typename Weighted_kernel::Weighted_point_d;
+  using Bare_point_d = typename Weighted_kernel::Bare_point_d;
+  std::vector<Weighted_point_d> w_pts;
+  w_pts.emplace_back(Bare_point_d(p0.begin(), p0.end()), 0.);
+  w_pts.emplace_back(Bare_point_d(p1.begin(), p1.end()), 0.);
+  w_pts.emplace_back(Bare_point_d(p2.begin(), p2.end()), 0.);
+  w_pts.emplace_back(Bare_point_d(p3.begin(), p3.end()), 0.);
+  w_pts.emplace_back(Bare_point_d(p4.begin(), p4.end()), 0.);
+
+  Weighted_kernel w_kernel;
+  auto w_sphere = w_kernel.get_sphere(w_pts.cbegin(), w_pts.cend());
+
+  std::clog << "Center is " << w_sphere.point() << " - squared radius is " << w_sphere.weight() << std::endl;
+
+  CGAL::NT_converter<typename Weighted_kernel::FT, double> cast_to_double;
+  // The results shall be the same with weights = 0.
+  GUDHI_TEST_FLOAT_EQUALITY_CHECK(cast_to_double(unw_sphere.second), cast_to_double(w_sphere.weight()));
+  BOOST_CHECK(unw_sphere.first == w_sphere.point());
+
+  auto unw_sq_rd = kernel.get_squared_radius(unw_pts.cbegin(), unw_pts.cend());
+  std::clog << "Squared radius is " << unw_sq_rd << std::endl;
+  GUDHI_TEST_FLOAT_EQUALITY_CHECK(cast_to_double(unw_sphere.second), cast_to_double(unw_sq_rd));
+  auto w_sq_rd = w_kernel.get_squared_radius(w_pts.cbegin(), w_pts.cend());
+  std::clog << "Squared radius is " << w_sq_rd << std::endl;
+  GUDHI_TEST_FLOAT_EQUALITY_CHECK(cast_to_double(w_sphere.weight()), cast_to_double(w_sq_rd));
+}
diff --git a/src/Alpha_complex/test/CMakeLists.txt b/src/Alpha_complex/test/CMakeLists.txt
index fe4b23e4..db5d840f 100644
--- a/src/Alpha_complex/test/CMakeLists.txt
+++ b/src/Alpha_complex/test/CMakeLists.txt
@@ -18,6 +18,10 @@ if (NOT CGAL_WITH_EIGEN3_VERSION VERSION_LESS 4.11.0)
   gudhi_add_boost_test(Alpha_complex_test_unit)
   gudhi_add_boost_test(Delaunay_complex_test_unit)
 
+endif (NOT CGAL_WITH_EIGEN3_VERSION VERSION_LESS 4.11.0)
+
+if (NOT CGAL_VERSION VERSION_LESS 4.11.0)
+
   add_executable ( Alpha_complex_3d_test_unit Alpha_complex_3d_unit_test.cpp )
   target_link_libraries(Alpha_complex_3d_test_unit ${CGAL_LIBRARY})
   add_executable ( Weighted_alpha_complex_3d_test_unit Weighted_alpha_complex_3d_unit_test.cpp )
@@ -38,4 +42,21 @@ if (NOT CGAL_WITH_EIGEN3_VERSION VERSION_LESS 4.11.0)
   gudhi_add_boost_test(Periodic_alpha_complex_3d_test_unit)
   gudhi_add_boost_test(Weighted_periodic_alpha_complex_3d_test_unit)
 
-endif (NOT CGAL_WITH_EIGEN3_VERSION VERSION_LESS 4.11.0)
+endif (NOT CGAL_VERSION VERSION_LESS 4.11.0)
+
+if (NOT CGAL_WITH_EIGEN3_VERSION VERSION_LESS 5.1.0)
+  add_executable ( Alpha_kernel_d_test_unit Alpha_kernel_d_unit_test.cpp )
+  target_link_libraries(Alpha_kernel_d_test_unit ${CGAL_LIBRARY})
+  if (TBB_FOUND)
+    target_link_libraries(Alpha_kernel_d_test_unit ${TBB_LIBRARIES})
+  endif()
+  gudhi_add_boost_test(Alpha_kernel_d_test_unit)
+  
+  add_executable ( Weighted_alpha_complex_test_unit Weighted_alpha_complex_unit_test.cpp )
+  target_link_libraries(Weighted_alpha_complex_test_unit ${CGAL_LIBRARY})
+  if (TBB_FOUND)
+    target_link_libraries(Weighted_alpha_complex_test_unit ${TBB_LIBRARIES})
+  endif()
+  gudhi_add_boost_test(Weighted_alpha_complex_test_unit)
+
+endif (NOT CGAL_WITH_EIGEN3_VERSION VERSION_LESS 5.1.0)
\ No newline at end of file
diff --git a/src/Alpha_complex/test/Weighted_alpha_complex_unit_test.cpp b/src/Alpha_complex/test/Weighted_alpha_complex_unit_test.cpp
new file mode 100644
index 00000000..d267276c
--- /dev/null
+++ b/src/Alpha_complex/test/Weighted_alpha_complex_unit_test.cpp
@@ -0,0 +1,229 @@
+/*    This file is part of the Gudhi Library - https://gudhi.inria.fr/ - which is released under MIT.
+ *    See file LICENSE or go to https://gudhi.inria.fr/licensing/ for full license details.
+ *    Author(s):       Vincent Rouvreau
+ *
+ *    Copyright (C) 2020 Inria
+ *
+ *    Modification(s):
+ *      - YYYY/MM Author: Description of the modification
+ */
+
+#define BOOST_TEST_DYN_LINK
+#define BOOST_TEST_MODULE "weighted_alpha_complex"
+#include <boost/test/unit_test.hpp>
+#include <boost/mpl/list.hpp>
+
+#include <CGAL/Epick_d.h>
+#include <CGAL/Epeck_d.h>
+
+#include <cmath>  // float comparison
+#include <vector>
+#include <random>
+#include <array>
+#include <cmath> // for std::fabs
+
+#include <gudhi/Alpha_complex.h>
+#include <gudhi/Alpha_complex_3d.h>
+#include <gudhi/Simplex_tree.h>
+#include <gudhi/Unitary_tests_utils.h>
+
+using list_of_exact_kernel_variants = boost::mpl::list<CGAL::Epeck_d< CGAL::Dynamic_dimension_tag >,
+                                                       CGAL::Epeck_d< CGAL::Dimension_tag<4> >
+                                                       > ;
+
+BOOST_AUTO_TEST_CASE_TEMPLATE(Zero_weighted_alpha_complex, Kernel, list_of_exact_kernel_variants) {
+  // Check that in exact mode for static dimension 4 the code for dD unweighted and for dD weighted with all weights
+  // 0 give exactly the same simplex tree (simplices and filtration values).
+
+  // Random points construction
+  using Point_d = typename Kernel::Point_d;
+  std::vector<Point_d> points;
+  std::uniform_real_distribution<double> rd_pts(-10., 10.);
+  std::random_device rand_dev;
+  std::mt19937 rand_engine(rand_dev());
+  for (int idx = 0; idx < 20; idx++) {
+    std::vector<double> point {rd_pts(rand_engine), rd_pts(rand_engine), rd_pts(rand_engine), rd_pts(rand_engine)};
+    points.emplace_back(point.begin(), point.end());
+  }
+  
+  // Alpha complex from points
+  Gudhi::alpha_complex::Alpha_complex<Kernel, false> alpha_complex_from_points(points);
+  Gudhi::Simplex_tree<> simplex;
+  Gudhi::Simplex_tree<>::Filtration_value infty = std::numeric_limits<Gudhi::Simplex_tree<>::Filtration_value>::infinity();
+  BOOST_CHECK(alpha_complex_from_points.create_complex(simplex, infty, true));
+  std::clog << "Iterator on alpha complex simplices in the filtration order, with [filtration value]:"
+            << std::endl;
+  for (auto f_simplex : simplex.filtration_simplex_range()) {
+    std::clog << "   ( ";
+    for (auto vertex : simplex.simplex_vertex_range(f_simplex)) {
+      std::clog << vertex << " ";
+    }
+    std::clog << ") -> " << "[" << simplex.filtration(f_simplex) << "] " << std::endl;
+  }
+
+  // Alpha complex from zero weighted points
+  std::vector<typename Kernel::FT> weights(20, 0.);
+  Gudhi::alpha_complex::Alpha_complex<Kernel, true> alpha_complex_from_zero_weighted_points(points, weights);
+  Gudhi::Simplex_tree<> zw_simplex;
+  BOOST_CHECK(alpha_complex_from_zero_weighted_points.create_complex(zw_simplex, infty, true));
+
+  std::clog << "Iterator on zero weighted alpha complex simplices in the filtration order, with [filtration value]:"
+            << std::endl;
+  for (auto f_simplex : zw_simplex.filtration_simplex_range()) {
+    std::clog << "   ( ";
+    for (auto vertex : zw_simplex.simplex_vertex_range(f_simplex)) {
+      std::clog << vertex << " ";
+    }
+    std::clog << ") -> " << "[" << zw_simplex.filtration(f_simplex) << "] " << std::endl;
+  }
+
+  BOOST_CHECK(zw_simplex == simplex);
+}
+
+template <typename Point_d>
+bool cgal_3d_point_sort (Point_d a,Point_d b) {
+  if (a[0] != b[0])
+    return a[0] < b[0];
+  if (a[1] != b[1])
+    return a[1] < b[1];
+  return a[2] < b[2];
+}
+
+BOOST_AUTO_TEST_CASE(Weighted_alpha_complex_3d_comparison) {
+  // check that for random weighted 3d points in safe mode the 3D and dD codes give the same result with some tolerance
+
+  // Random points construction
+  using Kernel_dD = CGAL::Epeck_d< CGAL::Dimension_tag<3> >;
+  using Bare_point_d = typename Kernel_dD::Point_d;
+  using Weighted_point_d = typename Kernel_dD::Weighted_point_d;
+  std::vector<Weighted_point_d> w_points_d;
+
+  using Exact_weighted_alpha_complex_3d =
+    Gudhi::alpha_complex::Alpha_complex_3d<Gudhi::alpha_complex::complexity::EXACT, true, false>;
+  using Bare_point_3 = typename Exact_weighted_alpha_complex_3d::Bare_point_3;
+  using Weighted_point_3 = typename Exact_weighted_alpha_complex_3d::Weighted_point_3;
+  std::vector<Weighted_point_3> w_points_3;
+
+  std::uniform_real_distribution<double> rd_pts(-10., 10.);
+  std::uniform_real_distribution<double> rd_wghts(-0.5, 0.5);
+  std::random_device rand_dev;
+  std::mt19937 rand_engine(rand_dev());
+  for (int idx = 0; idx < 20; idx++) {
+    std::vector<double> point {rd_pts(rand_engine), rd_pts(rand_engine), rd_pts(rand_engine)};
+    double weight = rd_wghts(rand_engine);
+    w_points_d.emplace_back(Bare_point_d(point.begin(), point.end()), weight);
+    w_points_3.emplace_back(Bare_point_3(point[0], point[1], point[2]), weight);
+  }
+
+  // Structures necessary for comparison
+  using Points = std::vector<std::array<double,3>>;
+  using Points_and_filtrations = std::map<Points, double>;
+  Points_and_filtrations pts_fltr_dD;
+  Points_and_filtrations pts_fltr_3d;
+
+  // Weighted alpha complex for dD version
+  Gudhi::alpha_complex::Alpha_complex<Kernel_dD, true> alpha_complex_dD_from_weighted_points(w_points_d);
+  Gudhi::Simplex_tree<> w_simplex_d;
+  BOOST_CHECK(alpha_complex_dD_from_weighted_points.create_complex(w_simplex_d));
+
+  std::clog << "Iterator on weighted alpha complex dD simplices in the filtration order, with [filtration value]:"
+            << std::endl;
+  for (auto f_simplex : w_simplex_d.filtration_simplex_range()) {
+    Points points;
+    for (auto vertex : w_simplex_d.simplex_vertex_range(f_simplex)) {
+      CGAL::NT_converter<Kernel_dD::RT, double> cgal_converter;
+      Bare_point_d pt = alpha_complex_dD_from_weighted_points.get_point(vertex).point();
+      points.push_back({cgal_converter(pt[0]), cgal_converter(pt[1]), cgal_converter(pt[2])});
+    }
+    std::clog << "   ( ";
+    std::sort (points.begin(), points.end());
+    for (auto point : points) {
+      std::clog << point[0] << " " << point[1] << " " << point[2] << " | ";
+    }
+    std::clog << ") -> " << "[" << w_simplex_d.filtration(f_simplex) << "] ";
+    std::clog << std::endl;
+    pts_fltr_dD[points] = w_simplex_d.filtration(f_simplex);
+  }
+
+  // Weighted alpha complex for 3D version
+  Exact_weighted_alpha_complex_3d alpha_complex_3D_from_weighted_points(w_points_3);
+  Gudhi::Simplex_tree<> w_simplex_3;
+  BOOST_CHECK(alpha_complex_3D_from_weighted_points.create_complex(w_simplex_3));
+
+  std::clog << "Iterator on weighted alpha complex 3D simplices in the filtration order, with [filtration value]:"
+            << std::endl;
+  for (auto f_simplex : w_simplex_3.filtration_simplex_range()) {
+    Points points;
+    for (auto vertex : w_simplex_3.simplex_vertex_range(f_simplex)) {
+      Bare_point_3 pt = alpha_complex_3D_from_weighted_points.get_point(vertex).point();
+      CGAL::NT_converter<Exact_weighted_alpha_complex_3d::Kernel::RT, double> cgal_converter;
+      points.push_back({cgal_converter(pt[0]), cgal_converter(pt[1]), cgal_converter(pt[2])});
+    }
+    std::clog << "   ( ";
+    std::sort (points.begin(), points.end());
+    for (auto point : points) {
+      std::clog << point[0] << " " << point[1] << " " << point[2] << " | ";
+    }
+    std::clog << ") -> " << "[" << w_simplex_3.filtration(f_simplex) << "] " << std::endl;
+    pts_fltr_3d[points] = w_simplex_d.filtration(f_simplex);
+  }
+
+  // Compares structures
+  auto d3_itr = pts_fltr_3d.begin();
+  auto dD_itr = pts_fltr_dD.begin();
+  for (; d3_itr != pts_fltr_3d.end() && dD_itr != pts_fltr_dD.end(); ++d3_itr) {
+    if (d3_itr->first != dD_itr->first) {
+      for(auto point : d3_itr->first)
+        std::clog << point[0] << " " << point[1] << " " << point[2] << " | ";
+      std::clog << " versus ";
+      for(auto point : dD_itr->first)
+        std::clog << point[0] << " " << point[1] << " " << point[2] << " | ";
+      std::clog << std::endl;
+      BOOST_CHECK(false);
+    }
+    // In safe mode, relative error is less than 1e-5 (can be changed with set_relative_precision_of_to_double)
+    if (std::fabs(d3_itr->second - dD_itr->second) > 1e-5 * (std::fabs(d3_itr->second) + std::fabs(dD_itr->second))) {
+      std::clog << d3_itr->second << " versus " << dD_itr->second << " diff "
+                << std::fabs(d3_itr->second - dD_itr->second) << std::endl;
+      BOOST_CHECK(false);
+    }
+    ++dD_itr;
+  }
+}
+
+using list_of_1d_kernel_variants = boost::mpl::list<CGAL::Epeck_d< CGAL::Dynamic_dimension_tag >,
+                                                    CGAL::Epeck_d< CGAL::Dimension_tag<1>>,
+                                                    CGAL::Epick_d< CGAL::Dynamic_dimension_tag >,
+                                                    CGAL::Epick_d< CGAL::Dimension_tag<1>>
+                                                    >;
+
+BOOST_AUTO_TEST_CASE_TEMPLATE(Weighted_alpha_complex_non_visible_points, Kernel, list_of_1d_kernel_variants) {
+  // check that for 2 closed weighted 1-d points, one with a high weight to hide the second one with a small weight,
+  // that the point with a small weight has the same high filtration value than the edge formed by the 2 points
+  using Point_d = typename Kernel::Point_d;
+  std::vector<Point_d> points;
+  std::vector<double> p1 {0.};
+  points.emplace_back(p1.begin(), p1.end());
+  // closed enough points
+  std::vector<double> p2 {0.1};
+  points.emplace_back(p2.begin(), p2.end());
+  std::vector<typename Kernel::FT> weights {100., 0.01};
+
+  Gudhi::alpha_complex::Alpha_complex<Kernel, true> alpha_complex(points, weights);
+  Gudhi::Simplex_tree<> stree;
+  BOOST_CHECK(alpha_complex.create_complex(stree));
+
+  std::clog << "Iterator on weighted alpha complex simplices in the filtration order, with [filtration value]:"
+            << std::endl;
+  for (auto f_simplex : stree.filtration_simplex_range()) {
+    std::clog << "   ( ";
+    for (auto vertex : stree.simplex_vertex_range(f_simplex)) {
+      std::clog << vertex << " ";
+    }
+    std::clog << ") -> " << "[" << stree.filtration(f_simplex) << "] " << std::endl;
+  }
+
+  BOOST_CHECK(stree.filtration(stree.find({0})) == -100.);
+  BOOST_CHECK(stree.filtration(stree.find({1})) == stree.filtration(stree.find({0, 1})));
+  BOOST_CHECK(stree.filtration(stree.find({1})) > 100000);
+}
\ No newline at end of file