netgen/libsrc/geom2d/csg2d.hpp

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#ifndef NETGEN_CSG2D_HPP_INCLUDED
#define NETGEN_CSG2D_HPP_INCLUDED
#include <variant>
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#include "geometry2d.hpp"
namespace netgen
{
using namespace ngcore;
using netgen::Point;
using netgen::Vec;
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using Spline = SplineSeg3<2>;
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using netgen::Box;
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inline double Area(const Point<2>& P, const Point<2>& Q, const Point<2>& R)
{
return (Q[0]-P[0]) * (R[1]-P[1]) - (Q[1]-P[1]) * (R[0]-P[0]);
}
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// compute weight of spline such that p lies on it
void ComputeWeight( Spline & s, Point<2> p );
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enum IntersectionType
{ // types of intersection (detected in the first phase)
NO_INTERSECTION = 0,
X_INTERSECTION,
T_INTERSECTION_Q,
T_INTERSECTION_P,
V_INTERSECTION,
X_OVERLAP,
T_OVERLAP_Q,
T_OVERLAP_P,
V_OVERLAP
};
enum IntersectionLabel
{ // for the classification of intersection vertices in the second phase
NONE,
CROSSING,
BOUNCING,
LEFT_ON,
RIGHT_ON,
ON_ON,
ON_LEFT,
ON_RIGHT,
DELAYED_CROSSING,
DELAYED_BOUNCING
};
enum EntryExitLabel
{ // for marking intersection vertices as "entry" or "exit"
EXIT,
ENTRY,
NEITHER
};
enum IteratorType
{
SOURCE,
INTERSECTION,
CROSSING_INTERSECTION,
ALL
};
inline constexpr const double MAXH_DEFAULT{1e99};
inline const string BC_DEFAULT{""};
inline const string MAT_DEFAULT{""};
struct EdgeInfo
{
optional<Point<2>> control_point = nullopt; // for spline segments
double maxh = MAXH_DEFAULT;
string bc = BC_DEFAULT;
EdgeInfo() = default;
EdgeInfo(Point<2> p) : control_point(p) {}
EdgeInfo(double h) : maxh(h) {}
EdgeInfo(string s) : bc(s) {}
EdgeInfo(optional<Point<2>> p, double h, string s)
: control_point(p), maxh(h), bc(s)
{}
void Assign( EdgeInfo other )
{
if(other.control_point != nullopt)
control_point = other.control_point;
if(other.bc != BC_DEFAULT)
bc = other.bc;
if(other.maxh != MAXH_DEFAULT)
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maxh = min(maxh, other.maxh);
}
};
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struct Vertex : Point<2>
{
Vertex (Point<2> p) : Point<2>(p) {}
Vertex (const Vertex & v) : Point<2>(v)
{
spline = v.spline;
info = v.info;
is_source = true;
}
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Vertex * prev = nullptr;
Vertex * next = nullptr;
unique_ptr<Vertex> pnext = nullptr;
Vertex * neighbour = nullptr; // same vertex in other polygon (at intersections)
double lam = -1.0;
bool is_intersection = false;
bool is_source = false;
IntersectionLabel label = NONE; // type of intersection vertex
EntryExitLabel enex = NEITHER; // entry/exit "flag"
// In case the edge this - next is curved, store the spline information here
optional<Spline> spline = nullopt;
EdgeInfo info;
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DLL_HEADER Vertex * Insert(Point<2> p, double lam = -1.0);
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void Link( Vertex * v )
{
neighbour = v;
v->neighbour = this;
is_intersection = true;
v->is_intersection = true;
}
};
struct VertexIterator
{
struct iterator
{
iterator(Vertex* root, IteratorType IterType) :
root(root), V(NULL), iterType(IterType)
{
if (root == NULL)
return;
if (nextVertex() == NULL) // no (source/intersection) vertex found
root = V = NULL; // -> mark iterator as "end"
}
const iterator& operator++()
{
nextVertex();
return *this;
}
Vertex* operator*()
{
return V;
}
bool operator!=(const iterator& other) const
{
return (root != other.root) || (V != other.V);
}
private:
Vertex* root;
Vertex* V;
IteratorType iterType;
//
// find the next vertex
// if iterType is ALL, then it is just the next vertex
// if iterType is SOURCE, then it is the next source vertex
// if iterType is INTERSECTION, then it is the next intersection vertex
// if iterType is CROSSING_INTERSECTION, then it is the next intersection vertex with CROSSING label
//
Vertex* nextVertex()
{
bool nextFound = false;
if (V == NULL)
{ // find first (source/intersection) vertex
V = root;
switch(iterType)
{
case ALL:
nextFound = true;
break;
case SOURCE:
if (V->is_source)
nextFound = true;
break;
case INTERSECTION:
if (V->is_intersection)
nextFound = true;
break;
case CROSSING_INTERSECTION:
if (V->is_intersection && (V->label == CROSSING))
nextFound = true;
break;
}
}
while (!nextFound)
{ // find next (source/intersection) vertex
switch(iterType)
{
case ALL:
V = V->next;
break;
case SOURCE:
do {
V = V->next;
} while (!V->is_source && V != root);
break;
case INTERSECTION:
do {
V = V->next;
} while (!V->is_intersection && V != root);
break;
case CROSSING_INTERSECTION:
do {
V = V->next;
} while ( ( !V->is_intersection || (V->label != CROSSING) ) && V != root);
break;
}
if (V == root)
{ // back at the root vertex?
root = V = NULL; // -> mark iterator as "end"
return(V);
}
switch(iterType)
{
case ALL:
nextFound = true;
break;
case SOURCE:
if (V->is_source)
nextFound = true;
break;
case INTERSECTION:
if (V->is_intersection)
nextFound = true;
break;
case CROSSING_INTERSECTION:
if (V->is_intersection && (V->label == CROSSING))
nextFound = true;
break;
}
}
return(V);
}
};
public:
VertexIterator() : root(NULL) {};
iterator begin() { return iterator(root, iterType); }
iterator end() { return iterator(NULL, iterType); }
Vertex* root;
IteratorType iterType;
};
struct Edge
{
Vertex * v0 = nullptr;
Vertex * v1 = nullptr;
Edge (Vertex* v, Vertex* w) : v0(v), v1(w) { };
};
struct EdgeIterator
{
struct iterator
{
iterator(Vertex* root, IteratorType IterType) :
root(root), one(NULL), two(NULL), iterType(IterType)
{
if (root == NULL)
return;
if (nextEdge() == NULL) // no source edge found
root = one = two = NULL; // -> mark iterator as "end"
}
const iterator& operator++() { nextEdge(); return *this; }
Edge operator*()
{
return Edge(one,two);
}
bool operator!=(const iterator& other) const
{
return (root != other.root) || (one != other.one) || (two != other.two);
}
private:
Vertex* root;
Vertex* one;
Vertex* two;
IteratorType iterType;
//
// find the next vertex, starting at curr
// if iterType is ALL, then it is just the next vertex
// if iterType is SOURCE, then it is the next source vertex
//
Vertex* nextVertex(Vertex* curr)
{
if (curr == NULL)
return(NULL);
switch(iterType)
{
case ALL:
curr = curr->next;
break;
case SOURCE:
do {
curr = curr->next;
} while (!curr->is_source);
break;
default:
;
}
return(curr);
}
//
// find the next edge
//
Vertex* nextEdge()
{
if (root == NULL) // empty polygon?
return (NULL);
if (one == NULL)
{ // find one (source) vertex
one = root; // note: root is always a (source) vertex
two = nextVertex(one);
if (two == one) // just one (source) vertex
return(NULL); // -> no (source) edges
return(one);
}
if (two == root)
{ // back at the root vertex?
root = one = two = NULL; // -> mark iterator as "end"
return(NULL);
}
one = two;
two = nextVertex(one);
return (one);
}
};
public:
EdgeIterator() : root(NULL) {};
iterator begin() { return iterator(root, iterType); }
iterator end() { return iterator(NULL, iterType); }
Vertex* root;
IteratorType iterType;
};
inline int CalcSide( const Point<2> & p0, const Point<2> & p1, const Point<2> & r )
{
if ( (p0[1] < r[1]) != (p1[1] < r[1]) )
{
if (p0[0] >= r[0])
{
if (p1[0] > r[0])
return 2 * (p1[1] > p0[1]) - 1;
else
if ( (Area(p0,p1,r) > 0) == (p1[1] > p0[1]) )
return 2 * (p1[1] > p0[1]) - 1;
}
else
{
if (p1[0] > r[0])
if ( (Area(p0,p1,r) > 0) == (p1[1] > p0[1]) )
return 2 * (p1[1] > p0[1]) - 1;
}
}
return 0;
}
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struct Loop
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{
unique_ptr<Vertex> first = nullptr;
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unique_ptr<Box<2>> bbox = nullptr;
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Loop() = default;
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Loop(const Loop & p)
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: first(nullptr)
{
for(auto v : p.Vertices(ALL))
AppendVertex(*v);
}
Loop(Loop && p) = default;
Loop & operator=(Loop && p) = default;
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Loop & operator=(const Loop & p)
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{
// static Timer t("Loop::operator="); RegionTimer rt(t);
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first = nullptr;
if(p.first)
{
size_t n = p.Size();
Array<unique_ptr<Vertex>> new_verts(n);
{
size_t i = 0;
for(const auto v : p.Vertices(ALL))
new_verts[i++] = make_unique<Vertex>(*v);
}
for(auto i : IntRange(n-1))
{
Vertex * v = new_verts[i].get();
Vertex * vn = new_verts[i+1].get();
v->next = vn;
vn->prev = v;
}
Vertex * vfirst = new_verts[0].get();
Vertex * vlast = new_verts[n-1].get();
vfirst->prev = vlast;
vlast->next = vfirst;
for(auto i : IntRange(1,n))
new_verts[n-1-i]->pnext = std::move(new_verts[n-i]);
first = std::move(new_verts[0]);
}
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bbox = nullptr;
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return *this;
}
void Clear()
{
first = nullptr;
}
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Vertex & AppendVertex(const Vertex & v)
{
auto & vnew = Append( static_cast<Point<2>>(v), true );
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vnew.info = v.info;
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if(v.spline)
vnew.spline = *v.spline;
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if(bbox)
bbox->Add(v);
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return vnew;
}
Vertex & Append(Point<2> p, bool source = false)
{
Vertex * vnew;
if(first==nullptr)
{
first = make_unique<Vertex>(p);
first->next = first.get();
first->prev = first.get();
vnew = first.get();
}
else
{
vnew = first->prev->Insert(p);
}
vnew->is_source = source;
// cout << "size after " << Size() << endl;
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if(bbox)
bbox->Add(p);
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return *vnew;
}
void Remove (Vertex* v)
{
v->prev->next = v->next;
v->next->prev = v->prev;
if(first.get() == v)
first = std::move(v->pnext);
else
v->prev->pnext = std::move(v->pnext);
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bbox.reset();
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}
bool IsInside( Point<2> r ) const;
bool IsLeftInside( const Vertex & p0 );
bool IsRightInside( const Vertex & p0 );
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EdgeIterator Edges(IteratorType iterType) const
{
EdgeIterator it;
it.iterType = iterType;
it.root = first.get();
return it;
}
VertexIterator Vertices(IteratorType iterType, Vertex* first_ = nullptr) const
{
VertexIterator it;
it.iterType = iterType;
it.root = (first_ == nullptr) ? first.get() : first_;
return it;
}
//
// check, if all vertices have the ON_ON label
//
bool allOnOn()
{
for (Vertex* v : Vertices(ALL))
if (v->label != ON_ON)
return(false);
return(true);
}
//
// check, if the polygon does not contain any crossing intersection vertex
// or crossing intersection chain or (if we want to compute the union instead
// of the intersection) a bouncing vertex or a bouncing intersection chain
//
bool noCrossingVertex(bool union_case = false)
{
for (Vertex* v : Vertices(ALL))
if (v->is_intersection)
{
if ( (v->label == CROSSING) || (v->label == DELAYED_CROSSING) )
return(false);
if (union_case && ( (v->label == BOUNCING) || (v->label == DELAYED_BOUNCING) ) )
return(false);
}
return(true);
}
//
// return a non-intersection point
//
Point<2> getNonIntersectionPoint()
{
for (Vertex* v : Vertices(ALL))
if (!v->is_intersection)
return *v;
// no non-intersection vertex found -> find suitable edge midpoint
for (Vertex* v : Vertices(ALL))
// make sure that edge from V to V->next is not collinear with other polygon
if ( (v->next->neighbour != v->neighbour->prev) && (v->next->neighbour != v->neighbour->next) )
// return edge midpoint
return Center(*v, *v->next);
throw Exception("no point found");
}
//
// return and insert a non-intersection vertex
//
Vertex* getNonIntersectionVertex()
{
for (Vertex* v : Vertices(ALL))
if (!v->is_intersection)
return(v);
// no non-intersection vertex found -> generate and return temporary vertex
for (Vertex* v : Vertices(ALL))
// make sure that edge from V to V->next is not collinear with other polygon
if ( (v->next->neighbour != v->neighbour->prev) && (v->next->neighbour != v->neighbour->next) )
{
// add edge midpoint as temporary vertex
auto p = Center(*v, *v->next);
return v->Insert(p);
}
return(NULL);
}
void SetBC(string bc)
{
for(auto v : Vertices(ALL))
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v->info.bc = bc;
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}
size_t Size() const
{
if(first==nullptr) return 0;
size_t cnt = 0;
for(auto v : Vertices(ALL))
cnt++;
return cnt;
}
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const Box<2> & GetBoundingBox()
{
if(bbox==nullptr)
{
static Timer tall("Loop::GetBoundingBox"); RegionTimer rt(tall);
bbox = make_unique<Box<2>>(Box<2>::EMPTY_BOX);
for(auto v : Vertices(ALL))
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{
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bbox->Add(*v);
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if(v->spline)
bbox->Add(v->spline->TangentPoint());
}
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}
return *bbox;
}
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};
struct Solid2d
{
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Array<Loop> polys;
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string name = MAT_DEFAULT;
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Solid2d() = default;
Solid2d(string name_) : name(name_) {}
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DLL_HEADER Solid2d(const Array<std::variant<Point<2>, EdgeInfo>> & points, string name_=MAT_DEFAULT, string bc_=BC_DEFAULT);
Solid2d(Solid2d && other) = default;
Solid2d(const Solid2d & other) = default;
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DLL_HEADER Solid2d operator+(const Solid2d & other) const;
DLL_HEADER Solid2d operator*(const Solid2d & other) const;
DLL_HEADER Solid2d operator-(const Solid2d & other) const;
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Solid2d& operator=(Solid2d && other) = default;
Solid2d& operator=(const Solid2d & other) = default;
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DLL_HEADER Solid2d& operator+=(const Solid2d & other);
DLL_HEADER Solid2d& operator*=(const Solid2d & other);
DLL_HEADER Solid2d& operator-=(const Solid2d & other);
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void Append( const Loop & poly )
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{
polys.Append(poly);
}
bool IsInside( Point<2> r ) const;
bool IsLeftInside( const Vertex & p0 );
bool IsRightInside( const Vertex & p0 );
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template<typename TFunc>
Solid2d & Transform( const TFunc & func )
{
for(auto & poly : polys)
for(auto v : poly.Vertices(ALL))
{
auto p = func(*v);
(*v)[0] = p[0];
(*v)[1] = p[1];
if(v->spline)
{
auto &s = *v->spline;
auto pmid = func(s.GetPoint(0.5));
s = Spline(func(s.StartPI()), func(s.TangentPoint()), func(s.EndPI()));
ComputeWeight(s, pmid);
}
}
return *this;
}
Solid2d & Move( Vec<2> v );
Solid2d & Scale( double sx, double sy=0.0 );
Solid2d & RotateRad( double ang, Point<2> center = {0,0} );
Solid2d & RotateDeg( double ang, Point<2> center = {0,0} )
{
return RotateRad( ang/180.*M_PI );
}
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Solid2d & BC(string bc)
{
for(auto & p : polys)
for(auto v : p.Vertices(ALL))
v->info.bc = bc;
return *this;
}
Solid2d & Maxh(double maxh)
{
for(auto & p : polys)
for(auto v : p.Vertices(ALL))
v->info.maxh = maxh;
return *this;
}
Solid2d & Mat(string mat)
{
name = mat;
return *this;
}
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Box<2> GetBoundingBox() const;
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};
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class CSG2d
{
public:
Array<Solid2d> solids;
void Add ( Solid2d s )
{
solids.Append(s);
}
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DLL_HEADER shared_ptr<netgen::SplineGeometry2d> GenerateSplineGeometry();
DLL_HEADER shared_ptr<netgen::Mesh> GenerateMesh(MeshingParameters & mp);
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};
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DLL_HEADER Solid2d Circle( Point<2> center, double r, string name="", string bc="");
DLL_HEADER Solid2d Rectangle( Point<2> p0, Point<2> p1, string mat=MAT_DEFAULT, string bc=BC_DEFAULT );
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DLL_HEADER void AddIntersectionPoints ( Solid2d & s1, Solid2d & s2 );
DLL_HEADER Solid2d ClipSolids ( const Solid2d & s1, const Solid2d & s2, char op);
DLL_HEADER Solid2d ClipSolids ( const Solid2d & s1, Solid2d && s2, char op);
DLL_HEADER Solid2d ClipSolids ( Solid2d && s1, const Solid2d & s2, char op);
DLL_HEADER Solid2d ClipSolids ( Solid2d && s1, Solid2d && s2, char op);
DLL_HEADER IntersectionType intersect(const Point<2> P1, const Point<2> P2, const Point<2> Q1, const Point<2> Q2, double& alpha, double& beta);
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}
#endif // NETGEN_CSG2D_HPP_INCLUDED