#ifndef SIMPLEX_MESH_POISSON_H
#define SIMPLEX_MESH_POISSON_H
#include <Eigen/Sparse>
#include <Ziran/Math/Geometry/SimplexMesh.h>
#include <Ziran/Math/Linear/KrylovSolvers.h>
#include <Ziran/Math/Linear/Minres.h>
#include <algorithm>
/**
This is a class that solves poisson equation -\nabla u = f.
Discretization: mat* x =b.
**/
namespace ZIRAN {
template <class T, int dim>
class SimplexMeshPoisson {
public:
typedef Vector<T, dim> TV;
typedef Matrix<T, dim, dim> TM;
typedef Vector<T, Eigen::Dynamic> VEC;
SimplexMesh<dim>& tet_mesh;
StdVector<TV>& X;
StdVector<T> element_measure;
StdVector<T> b_scale;
StdVector<Eigen::Matrix<T, dim, dim + 1>> grad_N;
T unit_simplex_measure;
Eigen::SparseMatrix<T, Eigen::RowMajor> mat;
int n; //The total number of dofs
VEC& x;
VEC& b;
StdVector<int>& dirichlet;
StdVector<T>& dirichlet_value;
SimplexMeshPoisson(SimplexMesh<dim>& mesh,
StdVector<TV>& X,
VEC& x,
VEC& b,
StdVector<int>& dirichlet_in,
StdVector<T>& dirichlet_value_in)
: tet_mesh(mesh)
, X(X)
, element_measure(mesh.numberElements())
, b_scale(mesh.numberElements())
, grad_N(mesh.numberElements())
, n(X.size())
, x(x)
, b(b)
, dirichlet(dirichlet_in)
, dirichlet_value(dirichlet_value_in)
{
ZIRAN_ASSERT(n > 0);
T d_factorial = (T)1;
for (int i = 0; i < dim; i++)
d_factorial *= (T)(i + 1);
T unit_simplex_measure = (T)1 / d_factorial;
//set up Dm_inverse and interpolating function derivatives (wrt rest configuration)
TM dm;
T scale = (T)1 / (T)((dim + 1) * (dim + 2));
for (size_t e = 0; e < tet_mesh.numberElements(); e++) {
dS(e, dm);
element_measure[e] = unit_simplex_measure * dm.determinant();
b_scale[e] = element_measure[e] * scale;
TM dm_inv_trans = dm.inverse().transpose();
grad_N[e] << -dm_inv_trans.rowwise().sum(), dm_inv_trans;
}
//build matrix
mat.resize(n, n);
mat.reserve(Eigen::VectorXi::Constant(n, 27).transpose());
for (size_t e = 0; e < tet_mesh.numberElements(); e++) {
for (int i = 0; i <= dim; i++) {
for (int j = 0; j <= dim; j++) {
mat.coeffRef(tet_mesh.index(e, i), tet_mesh.index(e, j)) += grad_N[e].col(i).dot(grad_N[e].col(j)) * element_measure[e];
}
}
}
mat.makeCompressed();
initialize_x();
}
void initialize_x()
{
x.setZero();
for (size_t i = 0; i < dirichlet.size(); i++)
x(dirichlet[i]) = dirichlet_value[i];
}
void dS(const size_t element, TM& result)
{
for (int i = 0; i < dim; i++)
result.col(i) = X[tet_mesh.index(element, i + 1)] - X[tet_mesh.index(element, 0)];
}
//set b based on the analytic rhs
void setRHS(const VEC& rhs)
{
b.resize(X.size());
b.setZero();
for (size_t e = 0; e < tet_mesh.numberElements(); e++) {
for (int i = 0; i <= dim; i++) {
for (int j = 0; j <= dim; j++) {
T this_scale = b_scale[e] * ((i == j) + 1);
b(tet_mesh.index(e, i)) += this_scale * rhs(tet_mesh.index(e, j));
}
}
}
}
int solve()
{
EigenSparseKrylovMatrix<T, VEC> eska(mat);
DirichletDofProjection<VEC> projection_function(dirichlet);
eska.setProjection(projection_function);
JacobiPreconditioner<VEC> preconditioner(mat);
eska.setPreconditioner(preconditioner);
Minres<T, EigenSparseKrylovMatrix<T, VEC>, VEC> minres(10000);
return minres.solve(eska, x, b, false);
}
//after solving the poission for \u(x), get \grad \u(x) for each tetrahedron
void findGradient(StdVector<Vector<T, dim>>& gradPhi)
{
gradPhi.resize(tet_mesh.numberElements());
for (size_t e = 0; e < tet_mesh.numberElements(); e++) {
gradPhi[e].setZero();
for (int i = 0; i <= dim; i++)
gradPhi[e] += x(tet_mesh.index(e, i)) * grad_N[e].col(i);
}
}
//after solving the poission for \u(x), get normalized \grad \u(x) for each tetrahedron
void findNormalizedGradient(StdVector<Vector<T, dim>>& gradPhi)
{
gradPhi.resize(tet_mesh.numberElements());
for (size_t e = 0; e < tet_mesh.numberElements(); e++) {
gradPhi[e].setZero();
for (int i = 0; i <= dim; i++)
gradPhi[e] += x(tet_mesh.index(e, i)) * grad_N[e].col(i);
if (gradPhi[e].norm() < 16 * std::numeric_limits<T>::epsilon())
gradPhi[e].setZero();
else
gradPhi[e].normalize();
}
}
};
} // namespace ZIRAN
#endif
