netgen/libsrc/include/nginterface_v2.hpp
2018-05-01 21:26:47 +02:00

329 lines
6.9 KiB
C++

#ifndef NGINTERFACE_V2
#define NGINTERFACE_V2
/**************************************************************************/
/* File: nginterface_v2.hpp */
/* Author: Joachim Schoeberl */
/* Date: May 09 */
/**************************************************************************/
/*
C++ interface to Netgen
*/
namespace netgen
{
static constexpr int POINTINDEX_BASE = 1;
struct T_EDGE2
{
// int orient:1;
// int nr:31; // 0-based
int nr; // 0-based
};
struct T_FACE2
{
// int orient:3;
// int nr:29; // 0-based
int nr; // 0-based
};
class Ng_Element
{
class Ng_Points
{
public:
size_t num;
const int * ptr;
size_t Size() const { return num; }
int operator[] (size_t i) const { return ptr[i]-POINTINDEX_BASE; }
};
class Ng_Vertices
{
public:
size_t num;
const int * ptr;
size_t Size() const { return num; }
int operator[] (size_t i) const { return ptr[i]-POINTINDEX_BASE; }
};
class Ng_Edges
{
public:
size_t num;
const T_EDGE2 * ptr;
size_t Size() const { return num; }
int operator[] (size_t i) const { return ptr[i].nr; }
};
class Ng_Faces
{
public:
size_t num;
const T_FACE2 * ptr;
size_t Size() const { return num; }
int operator[] (size_t i) const { return ptr[i].nr; }
};
class Ng_Facets
{
public:
size_t num;
int base;
const int * ptr;
size_t Size() const { return num; }
int operator[] (size_t i) const { return ptr[i]-base; }
};
public:
NG_ELEMENT_TYPE type;
int index; // material / boundary condition
const string * mat; // material / boundary label
NG_ELEMENT_TYPE GetType() const { return type; }
int GetIndex() const { return index-1; }
Ng_Points points; // all points
Ng_Vertices vertices;
Ng_Edges edges;
Ng_Faces faces;
Ng_Facets facets;
bool is_curved;
};
class Ng_Point
{
double * pt;
public:
Ng_Point (double * apt) : pt(apt) { ; }
double operator[] (size_t i)
{ return pt[i]; }
operator const double * () { return pt; }
};
template <int DIM> class Ng_Node;
template <>
class Ng_Node<0>
{
class Ng_Elements
{
public:
size_t ne;
const int * ptr;
size_t Size() const { return ne; }
int operator[] (size_t i) const { return ptr[i]; }
};
public:
Ng_Elements elements;
Ng_Elements bnd_elements;
};
template <>
class Ng_Node<1>
{
class Ng_Vertices
{
public:
const int * ptr;
size_t Size() const { return 2; }
int operator[] (size_t i) const { return ptr[i]-POINTINDEX_BASE; }
};
public:
Ng_Vertices vertices;
};
template <>
class Ng_Node<2>
{
class Ng_Vertices
{
public:
size_t nv;
const int * ptr;
size_t Size() const { return nv; }
int operator[] (size_t i) const { return ptr[i]-POINTINDEX_BASE; }
};
class Ng_Edges
{
public:
size_t ned;
const int * ptr;
size_t Size() const { return ned; }
int operator[] (size_t i) const { return ptr[i]-1; }
};
public:
Ng_Vertices vertices;
Ng_Edges edges;
int surface_el; // -1 if face not on surface
};
class Mesh;
inline void DummyTaskManager2 (function<void(int,int)> func)
{ func(0,1); }
inline void DummyTracer2 (string, bool) { ; }
class DLL_HEADER Ngx_Mesh
{
private:
shared_ptr<Mesh> mesh;
public:
// Ngx_Mesh () { ; }
// Ngx_Mesh(class Mesh * amesh) : mesh(amesh) { ; }
Ngx_Mesh(shared_ptr<Mesh> amesh = NULL);
void LoadMesh (const string & filename);
void LoadMesh (istream & str);
void SaveMesh (ostream & str) const;
void UpdateTopology ();
void DoArchive (ngstd::Archive & archive);
virtual ~Ngx_Mesh();
bool Valid () { return mesh != NULL; }
int GetDimension() const;
int GetNLevels() const;
int GetNElements (int dim) const;
int GetNNodes (int nt) const;
Ng_Point GetPoint (int nr) const;
template <int DIM>
Ng_Element GetElement (size_t nr) const;
template <int DIM>
int GetElementIndex (size_t nr) const;
/// material/boundary label of region, template argument is co-dimension
template <int DIM>
const string & GetMaterialCD (int region_nr) const;
/// Curved Elements:
/// elnr .. element nr
/// xi..... DIM_EL local coordinates
/// x ..... DIM_SPACE global coordinates
/// dxdxi...DIM_SPACE x DIM_EL Jacobian matrix (row major storage)
template <int DIM_EL, int DIM_SPACE>
void ElementTransformation (int elnr,
const double * xi,
double * x,
double * dxdxi) const;
/// Curved Elements:
/// elnr .. element nr
/// npts .. number of points
/// xi..... DIM_EL local coordinates
/// sxi ... step xi
/// x ..... DIM_SPACE global coordinates
/// dxdxi...DIM_SPACE x DIM_EL Jacobian matrix (row major storage)
template <int DIM_EL, int DIM_SPACE, typename T>
void MultiElementTransformation (int elnr, int npts,
const T * xi, size_t sxi,
T * x, size_t sx,
T * dxdxi, size_t sdxdxi) const;
template <int DIM>
const Ng_Node<DIM> GetNode (int nr) const;
template <int DIM>
int GetNNodes ();
// returns domain numbers of domains next to boundary bnr -> (domin, domout)
// 3D only
// std::pair<int,int> GetBoundaryNeighbouringDomains (int bnr);
void Curve (int order);
void Refine (NG_REFINEMENT_TYPE reftype,
void (*taskmanager)(function<void(int,int)>) = &DummyTaskManager2,
void (*tracer)(string, bool) = &DummyTracer2);
void GetParentNodes (int ni, int * parents) const;
int GetParentElement (int ei) const;
int GetParentSElement (int ei) const;
// Find element of point, returns local coordinates
template <int DIM>
int FindElementOfPoint
(double * p, double * lami,
bool build_searchtrees = false,
int * const indices = NULL, int numind = 0) const;
#ifdef PARALLEL
std::tuple<int,int*> GetDistantProcs (int nodetype, int locnum) const;
#endif
shared_ptr<Mesh> GetMesh () const { return mesh; }
shared_ptr<Mesh> SelectMesh () const;
};
DLL_HEADER Ngx_Mesh * LoadMesh (const string & filename);
}
#ifdef HAVE_NETGEN_SOURCES
#include <meshing.hpp>
namespace netgen
{
#ifdef __GNUC__
#define NGX_INLINE __attribute__ ((__always_inline__)) inline
#else
#define NGX_INLINE inline
#endif
#include <nginterface_v2_impl.hpp>
}
#endif
#endif