/* Copyright (c) 2006, Michael Kazhdan and Matthew Bolitho All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. Neither the name of the Johns Hopkins University nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #ifndef GEOMETRY_INCLUDED #define GEOMETRY_INCLUDED #include #include #include #include #include "Hash.h" template Real Random(void); template< class Real > struct Point3D { Real coords[3]; Point3D( void ) { coords[0] = coords[1] = coords[2] = Real(0); } Point3D( Real v ) { coords[0] = coords[1] = coords[2] = v; } template< class _Real > Point3D( _Real v0 , _Real v1 , _Real v2 ){ coords[0] = Real(v0) , coords[1] = Real(v1) , coords[2] = Real(v2); } template< class _Real > Point3D( const Point3D< _Real >& p ){ coords[0] = Real( p[0] ) , coords[1] = Real( p[1] ) , coords[2] = Real( p[2] ); } inline Real& operator[] ( int i ) { return coords[i]; } inline const Real& operator[] ( int i ) const { return coords[i]; } inline Point3D operator - ( void ) const { Point3D q ; q.coords[0] = -coords[0] , q.coords[1] = -coords[1] , q.coords[2] = -coords[2] ; return q; } template< class _Real > inline Point3D& operator += ( Point3D< _Real > p ){ coords[0] += Real(p.coords[0]) , coords[1] += Real(p.coords[1]) , coords[2] += Real(p.coords[2]) ; return *this; } template< class _Real > inline Point3D operator + ( Point3D< _Real > p ) const { Point3D q ; q.coords[0] = coords[0] + Real(p.coords[0]) , q.coords[1] = coords[1] + Real(p.coords[1]) , q.coords[2] = coords[2] + Real(p.coords[2]) ; return q; } template< class _Real > inline Point3D& operator *= ( _Real r ) { coords[0] *= Real(r) , coords[1] *= Real(r) , coords[2] *= Real(r) ; return *this; } template< class _Real > inline Point3D operator * ( _Real r ) const { Point3D q ; q.coords[0] = coords[0] * Real(r) , q.coords[1] = coords[1] * Real(r) , q.coords[2] = coords[2] * Real(r) ; return q; } template< class _Real > inline Point3D& operator -= ( Point3D< _Real > p ){ return ( (*this)+=(-p) ); } template< class _Real > inline Point3D operator - ( Point3D< _Real > p ) const { return (*this)+(-p); } template< class _Real > inline Point3D& operator /= ( _Real r ){ return ( (*this)*=Real(1./r) ); } template< class _Real > inline Point3D operator / ( _Real r ) const { return (*this) * ( Real(1.)/r ); } static Real Dot( const Point3D< Real >& p1 , const Point3D< Real >& p2 ){ return p1.coords[0]*p2.coords[0] + p1.coords[1]*p2.coords[1] + p1.coords[2]*p2.coords[2]; } template< class Real1 , class Real2 > static Real Dot( const Point3D< Real1 >& p1 , const Point3D< Real2 >& p2 ){ return Real( p1.coords[0]*p2.coords[0] + p1.coords[1]*p2.coords[1] + p1.coords[2]*p2.coords[2] ); } }; template< class Real > struct XForm3x3 { Real coords[3][3]; XForm3x3( void ) { for( int i=0 ; i<3 ; i++ ) for( int j=0 ; j<3 ; j++ ) coords[i][j] = Real(0.); } static XForm3x3 Identity( void ) { XForm3x3 xForm; xForm(0,0) = xForm(1,1) = xForm(2,2) = Real(1.); return xForm; } Real& operator() ( int i , int j ){ return coords[i][j]; } const Real& operator() ( int i , int j ) const { return coords[i][j]; } template< class _Real > Point3D< _Real > operator * ( const Point3D< _Real >& p ) const { Point3D< _Real > q; for( int i=0 ; i<3 ; i++ ) for( int j=0 ; j<3 ; j++ ) q[i] += _Real( coords[j][i] * p[j] ); return q; } XForm3x3 operator * ( const XForm3x3& m ) const { XForm3x3 n; for( int i=0 ; i<3 ; i++ ) for( int j=0 ; j<3 ; j++ ) for( int k=0 ; k<3 ; k++ ) n.coords[i][j] += m.coords[i][k]*coords[k][j]; return n; } XForm3x3 transpose( void ) const { XForm3x3 xForm; for( int i=0 ; i<3 ; i++ ) for( int j=0 ; j<3 ; j++ ) xForm( i , j ) = coords[j][i]; return xForm; } Real subDeterminant( int i , int j ) const { int i1 = (i+1)%3 , i2 = (i+2)%3; int j1 = (j+1)%3 , j2 = (j+2)%3; return coords[i1][j1] * coords[i2][j2] - coords[i1][j2] * coords[i2][j1]; } Real determinant( void ) const { return coords[0][0] * subDeterminant( 0 , 0 ) + coords[1][0] * subDeterminant( 1 , 0 ) + coords[2][0] * subDeterminant( 2 , 0 ); } XForm3x3 inverse( void ) const { XForm3x3 xForm; Real d = determinant(); for( int i=0 ; i<3 ; i++ ) for( int j=0 ; j<3 ;j++ ) xForm.coords[j][i] = subDeterminant( i , j ) / d; return xForm; } }; template< class Real > struct XForm4x4 { Real coords[4][4]; XForm4x4( void ) { for( int i=0 ; i<4 ; i++ ) for( int j=0 ; j<4 ; j++ ) coords[i][j] = Real(0.); } static XForm4x4 Identity( void ) { XForm4x4 xForm; xForm(0,0) = xForm(1,1) = xForm(2,2) = xForm(3,3) = Real(1.); return xForm; } Real& operator() ( int i , int j ){ return coords[i][j]; } const Real& operator() ( int i , int j ) const { return coords[i][j]; } template< class _Real > Point3D< _Real > operator * ( const Point3D< _Real >& p ) const { Point3D< _Real > q; for( int i=0 ; i<3 ; i++ ) { for( int j=0 ; j<3 ; j++ ) q[i] += (_Real)( coords[j][i] * p[j] ); q[i] += (_Real)coords[3][i]; } return q; } XForm4x4 operator * ( const XForm4x4& m ) const { XForm4x4 n; for( int i=0 ; i<4 ; i++ ) for( int j=0 ; j<4 ; j++ ) for( int k=0 ; k<4 ; k++ ) n.coords[i][j] += m.coords[i][k]*coords[k][j]; return n; } XForm4x4 transpose( void ) const { XForm4x4 xForm; for( int i=0 ; i<4 ; i++ ) for( int j=0 ; j<4 ; j++ ) xForm( i , j ) = coords[j][i]; return xForm; } Real subDeterminant( int i , int j ) const { XForm3x3< Real > xForm; int ii[] = { (i+1)%4 , (i+2)%4 , (i+3)%4 } , jj[] = { (j+1)%4 , (j+2)%4 , (j+3)%4 }; for( int _i=0 ; _i<3 ; _i++ ) for( int _j=0 ; _j<3 ; _j++ ) xForm( _i , _j ) = coords[ ii[_i] ][ jj[_j] ]; return xForm.determinant(); } Real determinant( void ) const { return coords[0][0] * subDeterminant( 0 , 0 ) - coords[1][0] * subDeterminant( 1 , 0 ) + coords[2][0] * subDeterminant( 2 , 0 ) - coords[3][0] * subDeterminant( 3 , 0 ); } XForm4x4 inverse( void ) const { XForm4x4 xForm; Real d = determinant(); for( int i=0 ; i<4 ; i++ ) for( int j=0 ; j<4 ;j++ ) if( (i+j)%2==0 ) xForm.coords[j][i] = subDeterminant( i , j ) / d; else xForm.coords[j][i] = -subDeterminant( i , j ) / d; return xForm; } }; template Point3D RandomBallPoint(void); template Point3D RandomSpherePoint(void); template double Length(const Point3D& p); template double SquareLength(const Point3D& p); template double Distance(const Point3D& p1,const Point3D& p2); template double SquareDistance(const Point3D& p1,const Point3D& p2); template void CrossProduct(const Point3D& p1,const Point3D& p2,Point3D& p); class Edge{ public: double p[2][2]; double Length(void) const{ double d[2]; d[0]=p[0][0]-p[1][0]; d[1]=p[0][1]-p[1][1]; return sqrt(d[0]*d[0]+d[1]*d[1]); } }; class Triangle{ public: double p[3][3]; double Area(void) const{ double v1[3] , v2[3] , v[3]; for( int d=0 ; d<3 ; d++ ) { v1[d] = p[1][d] - p[0][d]; v2[d] = p[2][d] - p[0][d]; } v[0] = v1[1]*v2[2] - v1[2]*v2[1]; v[1] = -v1[0]*v2[2] + v1[2]*v2[0]; v[2] = v1[0]*v2[1] - v1[1]*v2[0]; return sqrt( v[0]*v[0] + v[1]*v[1] + v[2]*v[2] ) / 2; } double AspectRatio(void) const{ double d=0; int i,j; for(i=0;i<3;i++){ for(i=0;i<3;i++) for(j=0;j<3;j++){d+=(p[(i+1)%3][j]-p[i][j])*(p[(i+1)%3][j]-p[i][j]);} } return Area()/d; } }; class CoredPointIndex { public: int index; char inCore; int operator == (const CoredPointIndex& cpi) const {return (index==cpi.index) && (inCore==cpi.inCore);}; int operator != (const CoredPointIndex& cpi) const {return (index!=cpi.index) || (inCore!=cpi.inCore);}; }; class EdgeIndex{ public: int idx[2]; }; class CoredEdgeIndex { public: CoredPointIndex idx[2]; }; class TriangleIndex{ public: int idx[3]; }; class TriangulationEdge { public: TriangulationEdge(void); int pIndex[2]; int tIndex[2]; }; class TriangulationTriangle { public: TriangulationTriangle(void); int eIndex[3]; }; template class Triangulation { public: std::vector > points; std::vector edges; std::vector triangles; int factor( int tIndex,int& p1,int& p2,int& p3); double area(void); double area( int tIndex ); double area( int p1 , int p2 , int p3 ); int flipMinimize( int eIndex); int addTriangle( int p1 , int p2 , int p3 ); protected: hash_map edgeMap; static long long EdgeIndex( int p1 , int p2 ); double area(const Triangle& t); }; template void EdgeCollapse(const Real& edgeRatio,std::vector& triangles,std::vector< Point3D >& positions,std::vector >* normals); template void TriangleCollapse(const Real& edgeRatio,std::vector& triangles,std::vector >& positions,std::vector >* normals); struct CoredVertexIndex { int idx; bool inCore; }; template< class Vertex > class CoredMeshData { public: std::vector< Vertex > inCorePoints; virtual void resetIterator( void ) = 0; virtual int addOutOfCorePoint( const Vertex& p ) = 0; virtual int addOutOfCorePoint_s( const Vertex& p ) = 0; virtual int addPolygon_s( const std::vector< CoredVertexIndex >& vertices ) = 0; virtual int addPolygon_s( const std::vector< int >& vertices ) = 0; virtual int nextOutOfCorePoint( Vertex& p )=0; virtual int nextPolygon( std::vector< CoredVertexIndex >& vertices ) = 0; virtual int outOfCorePointCount(void)=0; virtual int polygonCount( void ) = 0; }; template< class Vertex > class CoredVectorMeshData : public CoredMeshData< Vertex > { std::vector< Vertex > oocPoints; std::vector< std::vector< int > > polygons; int polygonIndex; int oocPointIndex; public: CoredVectorMeshData(void); void resetIterator(void); int addOutOfCorePoint( const Vertex& p ); int addOutOfCorePoint_s( const Vertex& p ); int addPolygon_s( const std::vector< CoredVertexIndex >& vertices ); int addPolygon_s( const std::vector< int >& vertices ); int nextOutOfCorePoint( Vertex& p ); int nextPolygon( std::vector< CoredVertexIndex >& vertices ); int outOfCorePointCount(void); int polygonCount( void ); }; class BufferedReadWriteFile { bool tempFile; FILE* _fp; char *_buffer , _fileName[1024]; size_t _bufferIndex , _bufferSize; public: BufferedReadWriteFile( char* fileName=NULL , int bufferSize=(1<<20) ); ~BufferedReadWriteFile( void ); bool write( const void* data , size_t size ); bool read ( void* data , size_t size ); void reset( void ); }; template< class Vertex > class CoredFileMeshData : public CoredMeshData< Vertex > { char pointFileName[1024] , polygonFileName[1024]; BufferedReadWriteFile *oocPointFile , *polygonFile; int oocPoints , polygons; public: CoredFileMeshData( void ); ~CoredFileMeshData( void ); void resetIterator( void ); int addOutOfCorePoint( const Vertex& p ); int addOutOfCorePoint_s( const Vertex& p ); int addPolygon_s( const std::vector< CoredVertexIndex >& vertices ); int addPolygon_s( const std::vector< int >& vertices ); int nextOutOfCorePoint( Vertex& p ); int nextPolygon( std::vector< CoredVertexIndex >& vertices ); int outOfCorePointCount( void ); int polygonCount( void ); }; #include "Geometry.inl" #endif // GEOMETRY_INCLUDED