Program Listing for File convex.hxx
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#ifndef COAL_SHAPE_CONVEX_HXX
#define COAL_SHAPE_CONVEX_HXX
#include <set>
#include <vector>
#include <iostream>
namespace coal {
template <typename PolygonT>
Convex<PolygonT>::Convex(std::shared_ptr<std::vector<Vec3s>> points_,
unsigned int num_points_,
std::shared_ptr<std::vector<PolygonT>> polygons_,
unsigned int num_polygons_)
: ConvexBase(), polygons(polygons_), num_polygons(num_polygons_) {
this->initialize(points_, num_points_);
this->fillNeighbors();
this->buildSupportWarmStart();
}
template <typename PolygonT>
Convex<PolygonT>::Convex(const Convex<PolygonT>& other)
: ConvexBase(other), num_polygons(other.num_polygons) {
if (other.polygons.get()) {
polygons.reset(new std::vector<PolygonT>(*(other.polygons)));
} else
polygons.reset();
}
template <typename PolygonT>
Convex<PolygonT>::~Convex() {}
template <typename PolygonT>
void Convex<PolygonT>::set(std::shared_ptr<std::vector<Vec3s>> points_,
unsigned int num_points_,
std::shared_ptr<std::vector<PolygonT>> polygons_,
unsigned int num_polygons_) {
ConvexBase::set(points_, num_points_);
this->num_polygons = num_polygons_;
this->polygons = polygons_;
this->fillNeighbors();
this->buildSupportWarmStart();
}
template <typename PolygonT>
Convex<PolygonT>* Convex<PolygonT>::clone() const {
return new Convex(*this);
}
template <typename PolygonT>
Matrix3s Convex<PolygonT>::computeMomentofInertia() const {
typedef typename PolygonT::size_type size_type;
typedef typename PolygonT::index_type index_type;
Matrix3s C = Matrix3s::Zero();
Matrix3s C_canonical;
C_canonical << 1 / 60.0, 1 / 120.0, 1 / 120.0, 1 / 120.0, 1 / 60.0, 1 / 120.0,
1 / 120.0, 1 / 120.0, 1 / 60.0;
if (!(points.get())) {
std::cerr
<< "Error in `Convex::computeMomentofInertia`! Convex has no vertices."
<< std::endl;
return C;
}
const std::vector<Vec3s>& points_ = *points;
if (!(polygons.get())) {
std::cerr
<< "Error in `Convex::computeMomentofInertia`! Convex has no polygons."
<< std::endl;
return C;
}
const std::vector<PolygonT>& polygons_ = *polygons;
for (unsigned int i = 0; i < num_polygons; ++i) {
const PolygonT& polygon = polygons_[i];
// compute the center of the polygon
Vec3s plane_center(0, 0, 0);
for (size_type j = 0; j < polygon.size(); ++j)
plane_center += points_[polygon[(index_type)j]];
plane_center /= polygon.size();
// compute the volume of tetrahedron making by neighboring two points, the
// plane center and the reference point (zero) of the convex shape
const Vec3s& v3 = plane_center;
for (size_type j = 0; j < polygon.size(); ++j) {
index_type e_first = polygon[static_cast<index_type>(j)];
index_type e_second =
polygon[static_cast<index_type>((j + 1) % polygon.size())];
const Vec3s& v1 = points_[e_first];
const Vec3s& v2 = points_[e_second];
Matrix3s A;
A << v1.transpose(), v2.transpose(),
v3.transpose(); // this is A' in the original document
C += A.transpose() * C_canonical * A * (v1.cross(v2)).dot(v3);
}
}
return C.trace() * Matrix3s::Identity() - C;
}
template <typename PolygonT>
Vec3s Convex<PolygonT>::computeCOM() const {
typedef typename PolygonT::size_type size_type;
typedef typename PolygonT::index_type index_type;
Vec3s com(0, 0, 0);
CoalScalar vol = 0;
if (!(points.get())) {
std::cerr << "Error in `Convex::computeCOM`! Convex has no vertices."
<< std::endl;
return com;
}
const std::vector<Vec3s>& points_ = *points;
if (!(polygons.get())) {
std::cerr << "Error in `Convex::computeCOM`! Convex has no polygons."
<< std::endl;
return com;
}
const std::vector<PolygonT>& polygons_ = *polygons;
for (unsigned int i = 0; i < num_polygons; ++i) {
const PolygonT& polygon = polygons_[i];
// compute the center of the polygon
Vec3s plane_center(0, 0, 0);
for (size_type j = 0; j < polygon.size(); ++j)
plane_center += points_[polygon[(index_type)j]];
plane_center /= polygon.size();
// compute the volume of tetrahedron making by neighboring two points, the
// plane center and the reference point (zero) of the convex shape
const Vec3s& v3 = plane_center;
for (size_type j = 0; j < polygon.size(); ++j) {
index_type e_first = polygon[static_cast<index_type>(j)];
index_type e_second =
polygon[static_cast<index_type>((j + 1) % polygon.size())];
const Vec3s& v1 = points_[e_first];
const Vec3s& v2 = points_[e_second];
CoalScalar d_six_vol = (v1.cross(v2)).dot(v3);
vol += d_six_vol;
com += (points_[e_first] + points_[e_second] + plane_center) * d_six_vol;
}
}
return com / (vol * 4); // here we choose zero as the reference
}
template <typename PolygonT>
CoalScalar Convex<PolygonT>::computeVolume() const {
typedef typename PolygonT::size_type size_type;
typedef typename PolygonT::index_type index_type;
CoalScalar vol = 0;
if (!(points.get())) {
std::cerr << "Error in `Convex::computeVolume`! Convex has no vertices."
<< std::endl;
return vol;
}
const std::vector<Vec3s>& points_ = *points;
if (!(polygons.get())) {
std::cerr << "Error in `Convex::computeVolume`! Convex has no polygons."
<< std::endl;
return vol;
}
const std::vector<PolygonT>& polygons_ = *polygons;
for (unsigned int i = 0; i < num_polygons; ++i) {
const PolygonT& polygon = polygons_[i];
// compute the center of the polygon
Vec3s plane_center(0, 0, 0);
for (size_type j = 0; j < polygon.size(); ++j)
plane_center += points_[polygon[(index_type)j]];
plane_center /= polygon.size();
// compute the volume of tetrahedron making by neighboring two points, the
// plane center and the reference point (zero point) of the convex shape
const Vec3s& v3 = plane_center;
for (size_type j = 0; j < polygon.size(); ++j) {
index_type e_first = polygon[static_cast<index_type>(j)];
index_type e_second =
polygon[static_cast<index_type>((j + 1) % polygon.size())];
const Vec3s& v1 = points_[e_first];
const Vec3s& v2 = points_[e_second];
CoalScalar d_six_vol = (v1.cross(v2)).dot(v3);
vol += d_six_vol;
}
}
return vol / 6;
}
template <typename PolygonT>
void Convex<PolygonT>::fillNeighbors() {
neighbors.reset(new std::vector<Neighbors>(num_points));
typedef typename PolygonT::size_type size_type;
typedef typename PolygonT::index_type index_type;
std::vector<std::set<index_type>> nneighbors(num_points);
unsigned int c_nneighbors = 0;
if (!(polygons.get())) {
std::cerr << "Error in `Convex::fillNeighbors`! Convex has no polygons."
<< std::endl;
}
const std::vector<PolygonT>& polygons_ = *polygons;
for (unsigned int l = 0; l < num_polygons; ++l) {
const PolygonT& polygon = polygons_[l];
const size_type n = polygon.size();
for (size_type j = 0; j < polygon.size(); ++j) {
size_type i = (j == 0) ? n - 1 : j - 1;
size_type k = (j == n - 1) ? 0 : j + 1;
index_type pi = polygon[(index_type)i], pj = polygon[(index_type)j],
pk = polygon[(index_type)k];
// Update neighbors of pj;
if (nneighbors[pj].count(pi) == 0) {
c_nneighbors++;
nneighbors[pj].insert(pi);
}
if (nneighbors[pj].count(pk) == 0) {
c_nneighbors++;
nneighbors[pj].insert(pk);
}
}
}
nneighbors_.reset(new std::vector<unsigned int>(c_nneighbors));
unsigned int* p_nneighbors = nneighbors_->data();
std::vector<Neighbors>& neighbors_ = *neighbors;
for (unsigned int i = 0; i < num_points; ++i) {
Neighbors& n = neighbors_[i];
if (nneighbors[i].size() >= (std::numeric_limits<unsigned char>::max)())
COAL_THROW_PRETTY("Too many neighbors.", std::logic_error);
n.count_ = (unsigned char)nneighbors[i].size();
n.n_ = p_nneighbors;
p_nneighbors =
std::copy(nneighbors[i].begin(), nneighbors[i].end(), p_nneighbors);
}
assert(p_nneighbors == nneighbors_->data() + c_nneighbors);
}
} // namespace coal
#endif