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// Wild Magic Source Code
// David Eberly
// http://www.geometrictools.com
// Copyright (c) 1998-2007
//
// This library is free software; you can redistribute it and/or modify it
// under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation; either version 2.1 of the License, or (at
// your option) any later version. The license is available for reading at
// either of the locations:
// http://www.gnu.org/copyleft/lgpl.html
// http://www.geometrictools.com/License/WildMagicLicense.pdf
// The license applies to versions 0 through 4 of Wild Magic.
//
// Version: 4.0.0 (2006/06/28)
#include "Wm4FoundationPCH.h"
#include "Wm4Delaunay2.h"
#include "Wm4DelPolygonEdge.h"
#include "Wm4Mapper2.h"
#include "Wm4VEManifoldMesh.h"
#include "Wm4Query2Filtered.h"
#include "Wm4Query2Int64.h"
#include "Wm4Query2TInteger.h"
#include "Wm4Query2TRational.h"
namespace Wm4
{
//----------------------------------------------------------------------------
template <class Real>
Delaunay2<Real>::Delaunay2 (int iVertexQuantity, Vector2<Real>* akVertex,
Real fEpsilon, bool bOwner, Query::Type eQueryType)
:
Delaunay<Real>(iVertexQuantity,fEpsilon,bOwner,eQueryType),
m_kLineOrigin(Vector2<Real>::ZERO),
m_kLineDirection(Vector2<Real>::ZERO)
{
assert(akVertex);
m_akVertex = akVertex;
m_iUniqueVertexQuantity = 0;
m_akSVertex = nullptr;
m_pkQuery = nullptr;
m_iPathLast = -1;
m_aiPath = nullptr;
m_iLastEdgeV0 = -1;
m_iLastEdgeV1 = -1;
m_iLastEdgeOpposite = -1;
m_iLastEdgeOppositeIndex = -1;
Mapper2<Real> kMapper(m_iVertexQuantity,m_akVertex,m_fEpsilon);
if (kMapper.GetDimension() == 0)
{
// The values of m_iDimension, m_aiIndex, and m_aiAdjacent were
// already initialized by the Delaunay base class.
return;
}
if (kMapper.GetDimension() == 1)
{
// The set is (nearly) collinear. The caller is responsible for
// creating a Delaunay1 object.
m_iDimension = 1;
m_kLineOrigin = kMapper.GetOrigin();
m_kLineDirection = kMapper.GetDirection(0);
return;
}
m_iDimension = 2;
// Allocate storage for the input vertices and the supertriangle
// vertices.
m_akSVertex = WM4_NEW Vector2<Real>[m_iVertexQuantity+3];
int i;
if (eQueryType != Query::QT_RATIONAL && eQueryType != Query::QT_FILTERED)
{
// Transform the vertices to the square [0,1]^2.
m_kMin = kMapper.GetMin();
m_fScale = ((Real)1.0)/kMapper.GetMaxRange();
for (i = 0; i < m_iVertexQuantity; i++)
{
m_akSVertex[i] = (m_akVertex[i] - m_kMin)*m_fScale;
}
// Construct the supertriangle to contain [0,1]^2.
m_aiSV[0] = m_iVertexQuantity++;
m_aiSV[1] = m_iVertexQuantity++;
m_aiSV[2] = m_iVertexQuantity++;
m_akSVertex[m_aiSV[0]] = Vector2<Real>((Real)-1.0,(Real)-1.0);
m_akSVertex[m_aiSV[1]] = Vector2<Real>((Real)+4.0,(Real)-1.0);
m_akSVertex[m_aiSV[2]] = Vector2<Real>((Real)-1.0,(Real)+4.0);
Real fExpand;
if (eQueryType == Query::QT_INT64)
{
// Scale the vertices to the square [0,2^{16}]^2 to allow use of
// 64-bit integers for triangulation.
fExpand = (Real)(1 << 16);
m_pkQuery = WM4_NEW Query2Int64<Real>(m_iVertexQuantity,
m_akSVertex);
}
else if (eQueryType == Query::QT_INTEGER)
{
// Scale the vertices to the square [0,2^{20}]^2 to get more
// precision for TInteger than for 64-bit integers for
// triangulation.
fExpand = (Real)(1 << 20);
m_pkQuery = WM4_NEW Query2TInteger<Real>(m_iVertexQuantity,
m_akSVertex);
}
else // eQueryType == Query::QT_REAL
{
// No scaling for floating point.
fExpand = (Real)1.0;
m_pkQuery = WM4_NEW Query2<Real>(m_iVertexQuantity,m_akSVertex);
}
m_fScale *= fExpand;
for (i = 0; i < m_iVertexQuantity; i++)
{
m_akSVertex[i] *= fExpand;
}
}
else
{
// No transformation needed for exact rational arithmetic.
m_kMin = Vector2<Real>::ZERO;
m_fScale = (Real)1.0;
size_t uiSize = m_iVertexQuantity*sizeof(Vector2<Real>);
System::Memcpy(m_akSVertex,uiSize,m_akVertex,uiSize);
// Construct the supertriangle to contain [min,max].
Vector2<Real> kMin = kMapper.GetMin();
Vector2<Real> kMax = kMapper.GetMax();
Vector2<Real> kDelta = kMax - kMin;
Vector2<Real> kSMin = kMin - kDelta;
Vector2<Real> kSMax = kMax + kDelta*((Real)3.0);
m_aiSV[0] = m_iVertexQuantity++;
m_aiSV[1] = m_iVertexQuantity++;
m_aiSV[2] = m_iVertexQuantity++;
m_akSVertex[m_aiSV[0]] = kSMin;
m_akSVertex[m_aiSV[1]] = Vector2<Real>(kSMax[0],kSMin[1]);
m_akSVertex[m_aiSV[2]] = Vector2<Real>(kSMin[0],kSMax[1]);
if (eQueryType == Query::QT_RATIONAL)
{
m_pkQuery = WM4_NEW Query2TRational<Real>(m_iVertexQuantity,
m_akSVertex);
}
else // eQueryType == Query::QT_FILTERED
{
m_pkQuery = WM4_NEW Query2Filtered<Real>(m_iVertexQuantity,
m_akSVertex,m_fEpsilon);
}
}
DelTriangle<Real>* pkTri = WM4_NEW DelTriangle<Real>(m_aiSV[0],m_aiSV[1],
m_aiSV[2]);
m_kTriangle.insert(pkTri);
// Incrementally update the triangulation. The set of processed points
// is maintained to eliminate duplicates, either in the original input
// points or in the points obtained by snap rounding.
std::set<Vector2<Real> > kProcessed;
for (i = 0; i < m_iVertexQuantity-3; i++)
{
if (kProcessed.find(m_akSVertex[i]) == kProcessed.end())
{
Update(i);
kProcessed.insert(m_akSVertex[i]);
}
}
m_iUniqueVertexQuantity = (int)kProcessed.size();
// Remove triangles sharing a vertex of the supertriangle.
RemoveTriangles();
// Assign integer values to the triangles for use by the caller.
std::map<DelTriangle<Real>*,int> kPermute;
typename std::set<DelTriangle<Real>*>::iterator pkTIter =
m_kTriangle.begin();
for (i = 0; pkTIter != m_kTriangle.end(); pkTIter++)
{
pkTri = *pkTIter;
kPermute[pkTri] = i++;
}
kPermute[nullptr] = -1;
// Put Delaunay triangles into an array (vertices and adjacency info).
m_iSimplexQuantity = (int)m_kTriangle.size();
if (m_iSimplexQuantity > 0)
{
m_aiIndex = WM4_NEW int[3*m_iSimplexQuantity];
m_aiAdjacent = WM4_NEW int[3*m_iSimplexQuantity];
i = 0;
pkTIter = m_kTriangle.begin();
for (/**/; pkTIter != m_kTriangle.end(); pkTIter++)
{
pkTri = *pkTIter;
m_aiIndex[i] = pkTri->V[0];
m_aiAdjacent[i++] = kPermute[pkTri->A[0]];
m_aiIndex[i] = pkTri->V[1];
m_aiAdjacent[i++] = kPermute[pkTri->A[1]];
m_aiIndex[i] = pkTri->V[2];
m_aiAdjacent[i++] = kPermute[pkTri->A[2]];
}
assert(i == 3*m_iSimplexQuantity);
m_iPathLast = -1;
m_aiPath = WM4_NEW int[m_iSimplexQuantity+1];
}
// Restore the vertex count to the original (discards the vertices of the
// supertriangle).
m_iVertexQuantity -= 3;
pkTIter = m_kTriangle.begin();
for (/**/; pkTIter != m_kTriangle.end(); ++pkTIter)
{
WM4_DELETE *pkTIter;
}
}
//----------------------------------------------------------------------------
template <class Real>
Delaunay2<Real>::~Delaunay2 ()
{
WM4_DELETE m_pkQuery;
WM4_DELETE[] m_akSVertex;
WM4_DELETE[] m_aiPath;
if (m_bOwner)
{
WM4_DELETE[] m_akVertex;
}
}
//----------------------------------------------------------------------------
template <class Real>
const Vector2<Real>* Delaunay2<Real>::GetVertices () const
{
return m_akVertex;
}
//----------------------------------------------------------------------------
template <class Real>
int Delaunay2<Real>::GetUniqueVertexQuantity () const
{
return m_iUniqueVertexQuantity;
}
//----------------------------------------------------------------------------
template <class Real>
const Vector2<Real>& Delaunay2<Real>::GetLineOrigin () const
{
return m_kLineOrigin;
}
//----------------------------------------------------------------------------
template <class Real>
const Vector2<Real>& Delaunay2<Real>::GetLineDirection () const
{
return m_kLineDirection;
}
//----------------------------------------------------------------------------
template <class Real>
Delaunay1<Real>* Delaunay2<Real>::GetDelaunay1 () const
{
assert(m_iDimension == 1);
if (m_iDimension != 1)
{
return nullptr;
}
Real* afProjection = WM4_NEW Real[m_iVertexQuantity];
for (int i = 0; i < m_iVertexQuantity; i++)
{
Vector2<Real> kDiff = m_akVertex[i] - m_kLineOrigin;
afProjection[i] = m_kLineDirection.Dot(kDiff);
}
return WM4_NEW Delaunay1<Real>(m_iVertexQuantity,afProjection,m_fEpsilon,
true,m_eQueryType);
}
//----------------------------------------------------------------------------
template <class Real>
bool Delaunay2<Real>::GetHull (int& riEQuantity, int*& raiIndex)
{
assert(m_iDimension == 2);
if (m_iDimension != 2)
{
return false;
}
riEQuantity = 0;
raiIndex = nullptr;
// Count the number of edges that are not shared by two triangles.
int i, iAdjQuantity = 3*m_iSimplexQuantity;
for (i = 0; i < iAdjQuantity; i++)
{
if (m_aiAdjacent[i] == -1)
{
riEQuantity++;
}
}
assert(riEQuantity > 0);
if (riEQuantity == 0)
{
return false;
}
// Enumerate the edges.
raiIndex = WM4_NEW int[2*riEQuantity];
int* piIndex = raiIndex;
for (i = 0; i < iAdjQuantity; i++)
{
if (m_aiAdjacent[i] == -1)
{
int iTri = i/3, j = i%3;
*piIndex++ = m_aiIndex[3*iTri+j];
*piIndex++ = m_aiIndex[3*iTri+((j+1)%3)];
}
}
return true;
}
//----------------------------------------------------------------------------
template <class Real>
int Delaunay2<Real>::GetContainingTriangle (const Vector2<Real>& rkP) const
{
assert(m_iDimension == 2);
if (m_iDimension != 2)
{
return -1;
}
// convert to scaled coordinates
Vector2<Real> kXFrmP = (rkP - m_kMin)*m_fScale;
// start at first triangle in mesh
int iIndex = (m_iPathLast >= 0 ? m_aiPath[m_iPathLast] : 0);
m_iPathLast = -1;
m_iLastEdgeV0 = -1;
m_iLastEdgeV1 = -1;
m_iLastEdgeOpposite = -1;
m_iLastEdgeOppositeIndex = -1;
// use triangle edges as binary separating lines
for (int i = 0; i < m_iSimplexQuantity; i++)
{
m_aiPath[++m_iPathLast] = iIndex;
int* aiV = &m_aiIndex[3*iIndex];
if (m_pkQuery->ToLine(kXFrmP,aiV[0],aiV[1]) > 0)
{
iIndex = m_aiAdjacent[3*iIndex];
if (iIndex == -1)
{
m_iLastEdgeV0 = aiV[0];
m_iLastEdgeV1 = aiV[1];
m_iLastEdgeOpposite = aiV[2];
m_iLastEdgeOppositeIndex = 2;
return -1;
}
continue;
}
if (m_pkQuery->ToLine(kXFrmP,aiV[1],aiV[2]) > 0)
{
iIndex = m_aiAdjacent[3*iIndex+1];
if (iIndex == -1)
{
m_iLastEdgeV0 = aiV[1];
m_iLastEdgeV1 = aiV[2];
m_iLastEdgeOpposite = aiV[0];
m_iLastEdgeOppositeIndex = 0;
return -1;
}
continue;
}
if (m_pkQuery->ToLine(kXFrmP,aiV[2],aiV[0]) > 0)
{
iIndex = m_aiAdjacent[3*iIndex+2];
if (iIndex == -1)
{
m_iLastEdgeV0 = aiV[2];
m_iLastEdgeV1 = aiV[0];
m_iLastEdgeOpposite = aiV[1];
m_iLastEdgeOppositeIndex = 1;
return -1;
}
continue;
}
m_iLastEdgeV0 = -1;
m_iLastEdgeV1 = -1;
m_iLastEdgeOpposite = -1;
m_iLastEdgeOppositeIndex = -1;
return iIndex;
}
return -1;
}
//----------------------------------------------------------------------------
template <class Real>
int Delaunay2<Real>::GetPathLast () const
{
return m_iPathLast;
}
//----------------------------------------------------------------------------
template <class Real>
const int* Delaunay2<Real>::GetPath () const
{
return m_aiPath;
}
//----------------------------------------------------------------------------
template <class Real>
int Delaunay2<Real>::GetLastEdge (int& riV0, int& riV1, int& riV2) const
{
riV0 = m_iLastEdgeV0;
riV1 = m_iLastEdgeV1;
riV2 = m_iLastEdgeOpposite;
return m_iLastEdgeOppositeIndex;
}
//----------------------------------------------------------------------------
template <class Real>
bool Delaunay2<Real>::GetVertexSet (int i, Vector2<Real> akV[3]) const
{
assert(m_iDimension == 2);
if (m_iDimension != 2)
{
return false;
}
if (0 <= i && i < m_iSimplexQuantity)
{
akV[0] = m_akVertex[m_aiIndex[3*i ]];
akV[1] = m_akVertex[m_aiIndex[3*i+1]];
akV[2] = m_akVertex[m_aiIndex[3*i+2]];
return true;
}
return false;
}
//----------------------------------------------------------------------------
template <class Real>
bool Delaunay2<Real>::GetIndexSet (int i, int aiIndex[3]) const
{
assert(m_iDimension == 2);
if (m_iDimension != 2)
{
return false;
}
if (0 <= i && i < m_iSimplexQuantity)
{
aiIndex[0] = m_aiIndex[3*i ];
aiIndex[1] = m_aiIndex[3*i+1];
aiIndex[2] = m_aiIndex[3*i+2];
return true;
}
return false;
}
//----------------------------------------------------------------------------
template <class Real>
bool Delaunay2<Real>::GetAdjacentSet (int i, int aiAdjacent[3]) const
{
assert(m_iDimension == 2);
if (m_iDimension != 2)
{
return false;
}
if (0 <= i && i < m_iSimplexQuantity)
{
aiAdjacent[0] = m_aiAdjacent[3*i ];
aiAdjacent[1] = m_aiAdjacent[3*i+1];
aiAdjacent[2] = m_aiAdjacent[3*i+2];
return true;
}
return false;
}
//----------------------------------------------------------------------------
template <class Real>
bool Delaunay2<Real>::GetBarycentricSet (int i, const Vector2<Real>& rkP,
Real afBary[3]) const
{
assert(m_iDimension == 2);
if (m_iDimension != 2)
{
return false;
}
if (0 <= i && i < m_iSimplexQuantity)
{
Vector2<Real> kV0 = m_akVertex[m_aiIndex[3*i ]];
Vector2<Real> kV1 = m_akVertex[m_aiIndex[3*i+1]];
Vector2<Real> kV2 = m_akVertex[m_aiIndex[3*i+2]];
rkP.GetBarycentrics(kV0,kV1,kV2,afBary);
return true;
}
return false;
}
//----------------------------------------------------------------------------
template <class Real>
void Delaunay2<Real>::Update (int i)
{
// Locate the triangle containing vertex i.
DelTriangle<Real>* pkTri = GetContainingTriangle(i);
// Locate and remove the triangles forming the insertion polygon.
std::stack<DelTriangle<Real>*> kStack;
VEManifoldMesh kPolygon(nullptr,DelPolygonEdge<Real>::ECreator);
kStack.push(pkTri);
pkTri->OnStack = true;
int j, iV0, iV1;
DelPolygonEdge<Real>* pkEdge;
while (!kStack.empty())
{
pkTri = kStack.top();
kStack.pop();
pkTri->OnStack = false;
for (j = 0; j < 3; j++)
{
DelTriangle<Real>* pkAdj = pkTri->A[j];
if (pkAdj)
{
// Detach triangle and adjacent triangle from each other.
int iNullIndex = pkTri->DetachFrom(j,pkAdj);
if (pkAdj->IsInsertionComponent(i,pkTri,m_pkQuery,m_aiSV))
{
if (!pkAdj->OnStack)
{
// Adjacent triangle inside insertion polygon.
kStack.push(pkAdj);
pkAdj->OnStack = true;
}
}
else
{
// Adjacent triangle outside insertion polygon.
iV0 = pkTri->V[j];
iV1 = pkTri->V[(j+1)%3];
pkEdge = (DelPolygonEdge<Real>*)kPolygon.InsertEdge(iV0,
iV1);
pkEdge->NullIndex = iNullIndex;
pkEdge->Tri = pkAdj;
}
}
else
{
// The triangle is in the insertion polygon, but the adjacent
// one does not exist. This means one of two things:
// (1) We are at an edge of the supertriangle, and that edge
// is part of the insertion polygon.
// (2) We are at an edge that was recently shared by the
// triangle and the adjacent, but we detached those
// triangles from each other. These edges should be
// ignored.
iV0 = pkTri->V[j];
if (IsSupervertex(iV0))
{
iV1 = pkTri->V[(j+1)%3];
if (IsSupervertex(iV1))
{
pkEdge = (DelPolygonEdge<Real>*)kPolygon.InsertEdge(
iV0,iV1);
pkEdge->NullIndex = -1;
pkEdge->Tri = nullptr;
}
}
}
}
m_kTriangle.erase(pkTri);
WM4_DELETE pkTri;
}
// Insert the new triangles formed by the input point and the edges of
// the insertion polygon.
const VEManifoldMesh::EMap& rkEMap = kPolygon.GetEdges();
assert(rkEMap.size() >= 3 && kPolygon.IsClosed());
typename VEManifoldMesh::EMapCIterator pkEIter;
for (pkEIter = rkEMap.begin(); pkEIter != rkEMap.end(); pkEIter++)
{
pkEdge = (DelPolygonEdge<Real>*)pkEIter->second;
// Create and insert the new triangle.
pkTri = WM4_NEW DelTriangle<Real>(i,pkEdge->V[0],pkEdge->V[1]);
m_kTriangle.insert(pkTri);
// Establish the adjacency links across the polygon edge.
pkTri->A[1] = pkEdge->Tri;
if (pkEdge->Tri)
{
pkEdge->Tri->A[pkEdge->NullIndex] = pkTri;
}
// Update the edge's triangle pointer to point to the newly created
// triangle. This information is used later to establish the links
// between the new triangles.
pkEdge->Tri = pkTri;
}
// Establish the adjacency links between the new triangles.
DelPolygonEdge<Real>* pkAdjEdge;
for (pkEIter = rkEMap.begin(); pkEIter != rkEMap.end(); pkEIter++)
{
pkEdge = (DelPolygonEdge<Real>*)pkEIter->second;
pkAdjEdge = (DelPolygonEdge<Real>*)pkEdge->E[0];
pkEdge->Tri->A[0] = pkAdjEdge->Tri;
pkAdjEdge = (DelPolygonEdge<Real>*)pkEdge->E[1];
pkEdge->Tri->A[2] = pkAdjEdge->Tri;
}
}
//----------------------------------------------------------------------------
template <class Real>
DelTriangle<Real>* Delaunay2<Real>::GetContainingTriangle (int i) const
{
// Locate which triangle in the current mesh contains vertex i. By
// construction, there must be such a triangle (the vertex cannot be
// outside the supertriangle).
DelTriangle<Real>* pkTri = *m_kTriangle.begin();
int iTQuantity = (int)m_kTriangle.size();
for (int iT = 0; iT < iTQuantity; iT++)
{
int* aiV = pkTri->V;
if (m_pkQuery->ToLine(i,aiV[0],aiV[1]) > 0)
{
pkTri = pkTri->A[0];
if (!pkTri)
{
break;
}
continue;
}
if (m_pkQuery->ToLine(i,aiV[1],aiV[2]) > 0)
{
pkTri = pkTri->A[1];
if (!pkTri)
{
break;
}
continue;
}
if (m_pkQuery->ToLine(i,aiV[2],aiV[0]) > 0)
{
pkTri = pkTri->A[2];
if (!pkTri)
{
break;
}
continue;
}
return pkTri;
}
assert(false);
return nullptr;
}
//----------------------------------------------------------------------------
template <class Real>
void Delaunay2<Real>::RemoveTriangles ()
{
// Identify those triangles sharing a vertex of the supertriangle.
std::set<DelTriangle<Real>*> kRemoveTri;
DelTriangle<Real>* pkTri;
typename std::set<DelTriangle<Real>*>::iterator pkTIter =
m_kTriangle.begin();
for (/**/; pkTIter != m_kTriangle.end(); pkTIter++)
{
pkTri = *pkTIter;
for (int j = 0; j < 3; j++)
{
if (IsSupervertex(pkTri->V[j]))
{
kRemoveTri.insert(pkTri);
break;
}
}
}
// Remove the triangles from the mesh.
pkTIter = kRemoveTri.begin();
for (/**/; pkTIter != kRemoveTri.end(); pkTIter++)
{
pkTri = *pkTIter;
for (int j = 0; j < 3; j++)
{
// Break the links with adjacent triangles.
DelTriangle<Real>* pkAdj = pkTri->A[j];
if (pkAdj)
{
for (int k = 0; k < 3; k++)
{
if (pkAdj->A[k] == pkTri)
{
pkAdj->A[k] = nullptr;
break;
}
}
}
}
m_kTriangle.erase(pkTri);
WM4_DELETE pkTri;
}
}
//----------------------------------------------------------------------------
template <class Real>
bool Delaunay2<Real>::IsSupervertex (int i) const
{
for (int j = 0; j < 3; j++)
{
if (i == m_aiSV[j])
{
return true;
}
}
return false;
}
//----------------------------------------------------------------------------
template <class Real>
Delaunay2<Real>::Delaunay2 (const char* acFilename)
:
Delaunay<Real>(0,(Real)0.0,false,Query::QT_REAL)
{
m_akVertex = nullptr;
m_akSVertex = nullptr;
m_pkQuery = nullptr;
m_aiPath = nullptr;
bool bLoaded = Load(acFilename);
assert(bLoaded);
(void)bLoaded; // avoid warning in Release build
}
//----------------------------------------------------------------------------
template <class Real>
bool Delaunay2<Real>::Load (const char* acFilename)
{
FILE* pkIFile = System::Fopen(acFilename,"rb");
if (!pkIFile)
{
return false;
}
Delaunay<Real>::Load(pkIFile);
WM4_DELETE m_pkQuery;
WM4_DELETE[] m_akSVertex;
WM4_DELETE[] m_aiPath;
if (m_bOwner)
{
WM4_DELETE[] m_akVertex;
}
m_bOwner = true;
m_akVertex = WM4_NEW Vector2<Real>[m_iVertexQuantity];
m_akSVertex = WM4_NEW Vector2<Real>[m_iVertexQuantity+3];
m_aiPath = WM4_NEW int[m_iSimplexQuantity+1];
System::Read4le(pkIFile,1,&m_iUniqueVertexQuantity);
System::Read4le(pkIFile,3,m_aiSV);
System::Read4le(pkIFile,1,&m_iPathLast);
System::Read4le(pkIFile,1,&m_iLastEdgeV0);
System::Read4le(pkIFile,1,&m_iLastEdgeV1);
System::Read4le(pkIFile,1,&m_iLastEdgeOpposite);
System::Read4le(pkIFile,1,&m_iLastEdgeOppositeIndex);
System::Read4le(pkIFile,m_iSimplexQuantity+1,m_aiPath);
size_t uiSize = sizeof(Real);
int iVQ = 2*m_iVertexQuantity, iSVQ = 2*(m_iVertexQuantity + 3);
if (uiSize == 4)
{
System::Read4le(pkIFile,iVQ,m_akVertex);
System::Read4le(pkIFile,iSVQ,m_akSVertex);
System::Read4le(pkIFile,2,(Real*)m_kMin);
System::Read4le(pkIFile,1,&m_fScale);
System::Read4le(pkIFile,2,(Real*)m_kLineOrigin);
System::Read4le(pkIFile,2,(Real*)m_kLineDirection);
}
else // iSize == 8
{
System::Read8le(pkIFile,iVQ,m_akVertex);
System::Read8le(pkIFile,iSVQ,m_akSVertex);
System::Read8le(pkIFile,2,(Real*)m_kMin);
System::Read8le(pkIFile,1,&m_fScale);
System::Read8le(pkIFile,2,(Real*)m_kLineOrigin);
System::Read8le(pkIFile,2,(Real*)m_kLineDirection);
}
System::Fclose(pkIFile);
switch (m_eQueryType)
{
case Query::QT_INT64:
m_pkQuery = WM4_NEW Query2Int64<Real>(m_iVertexQuantity,m_akSVertex);
break;
case Query::QT_INTEGER:
m_pkQuery = WM4_NEW Query2TInteger<Real>(m_iVertexQuantity,
m_akSVertex);
break;
case Query::QT_RATIONAL:
m_pkQuery = WM4_NEW Query2TRational<Real>(m_iVertexQuantity,
m_akSVertex);
break;
case Query::QT_REAL:
m_pkQuery = WM4_NEW Query2<Real>(m_iVertexQuantity,m_akSVertex);
break;
case Query::QT_FILTERED:
m_pkQuery = WM4_NEW Query2Filtered<Real>(m_iVertexQuantity,
m_akSVertex,m_fEpsilon);
break;
}
return true;
}
//----------------------------------------------------------------------------
template <class Real>
bool Delaunay2<Real>::Save (const char* acFilename) const
{
FILE* pkOFile = System::Fopen(acFilename,"wb");
if (!pkOFile)
{
return false;
}
Delaunay<Real>::Save(pkOFile);
System::Write4le(pkOFile,1,&m_iUniqueVertexQuantity);
System::Write4le(pkOFile,3,m_aiSV);
System::Write4le(pkOFile,1,&m_iPathLast);
System::Write4le(pkOFile,1,&m_iLastEdgeV0);
System::Write4le(pkOFile,1,&m_iLastEdgeV1);
System::Write4le(pkOFile,1,&m_iLastEdgeOpposite);
System::Write4le(pkOFile,1,&m_iLastEdgeOppositeIndex);
System::Write4le(pkOFile,m_iSimplexQuantity+1,m_aiPath);
size_t uiSize = sizeof(Real);
int iVQ = 2*m_iVertexQuantity, iSVQ = 2*(m_iVertexQuantity + 3);
if (uiSize == 4)
{
System::Write4le(pkOFile,iVQ,m_akVertex);
System::Write4le(pkOFile,iSVQ,m_akSVertex);
System::Write4le(pkOFile,2,(const Real*)m_kMin);
System::Write4le(pkOFile,1,&m_fScale);
System::Write4le(pkOFile,2,(const Real*)m_kLineOrigin);
System::Write4le(pkOFile,2,(const Real*)m_kLineDirection);
}
else // iSize == 8
{
System::Write8le(pkOFile,iVQ,m_akVertex);
System::Write8le(pkOFile,iSVQ,m_akSVertex);
System::Write8le(pkOFile,2,(const Real*)m_kMin);
System::Write8le(pkOFile,1,&m_fScale);
System::Write8le(pkOFile,2,(const Real*)m_kLineOrigin);
System::Write8le(pkOFile,2,(const Real*)m_kLineDirection);
}
System::Fclose(pkOFile);
return true;
}
//----------------------------------------------------------------------------
//----------------------------------------------------------------------------
// explicit instantiation
//----------------------------------------------------------------------------
template WM4_FOUNDATION_ITEM
class Delaunay2<float>;
template WM4_FOUNDATION_ITEM
class Delaunay2<double>;
//----------------------------------------------------------------------------
}
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