/**************************************************************************** * VCGLib o o * * Visual and Computer Graphics Library o o * * _ O _ * * Copyright(C) 2004 \/)\/ * * Visual Computing Lab /\/| * * ISTI - Italian National Research Council | * * \ * * All rights reserved. * * * * This program is free software; you can redistribute it and/or modify * * it under the terms of the GNU General Public License as published by * * the Free Software Foundation; either version 2 of the License, or * * (at your option) any later version. * * * * This program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU General Public License (http://www.gnu.org/licenses/gpl.txt) * * for more details. * * * ****************************************************************************/ /**************************************************************************** History $Log: not supported by cvs2svn $ Revision 1.17 2004/07/20 15:24:53 pietroni corrected NormalizedNormalV function... Revision 1.16 2004/07/15 11:25:01 ganovelli VFb moved to VFp, userbit to bitflag,setV, inclusion of pos.h Revision 1.15 2004/07/15 10:13:48 pietroni adde NormalizedNormalV funtion to compute the normal on a vertex Revision 1.14 2004/05/13 22:44:40 ganovelli syntax error (typo) Revision 1.13 2004/05/13 22:40:02 ganovelli default template parameters Revision 1.12 2004/05/13 12:49:22 pietroni no default template parameters... each one must be specified Revision 1.12 2004/05/10 13:31:13 ganovelli function for edge adjacency added $Log: not supported by cvs2svn $ Revision 1.17 2004/07/20 15:24:53 pietroni corrected NormalizedNormalV function... Revision 1.16 2004/07/15 11:25:01 ganovelli VFb moved to VFp, userbit to bitflag,setV, inclusion of pos.h Revision 1.15 2004/07/15 10:13:48 pietroni adde NormalizedNormalV funtion to compute the normal on a vertex Revision 1.14 2004/05/13 22:44:40 ganovelli syntax error (typo) Revision 1.13 2004/05/13 22:40:02 ganovelli default template parameters Revision 1.12 2004/05/13 12:49:22 pietroni no default template parameters... each one must be specified Revision 1.11 2004/05/10 13:31:13 ganovelli function for edge adjacency added Revision 1.10 2004/05/10 13:13:17 cignoni added void to Convert, corrected return object in VFp Revision 1.9 2004/05/06 15:28:10 pietroni changed names to VF topology function (was missed) Revision 1.8 2004/05/05 17:03:25 pietroni changed name to topology functions Revision 1.7 2004/04/28 11:37:14 pietroni *** empty log message *** Revision 1.6 2004/04/26 09:40:15 pietroni *** empty log message *** Revision 1.6 2004/04/23 14:55:06 pietroni conversion funtion Revision 1.5 2004/03/10 00:59:06 cignoni minor changes Revision 1.4 2004/03/03 16:07:57 cignoni Yet another cr lf mismatch Revision 1.3 2004/02/24 21:36:39 cignoni grouped documentation, changed typenames and reflection mechanism Revision 1.2 2004/02/13 02:09:39 cignoni First working release, with doxygen comment structure Revision 1.1 2004/02/10 01:11:28 cignoni Edited Comments and GPL license ****************************************************************************/ #ifndef VERTEX_TYPE #pragma message("\nYou should never directly include this file\_n") #else #include #include #include #include class DUMMYFACETYPE; class DUMMYEDGETYPE; class DUMMYTETRATYPE; namespace vcg { /** \ingroup vertex @name Vertex Class Vertex. This is the base class for definition of a vertex of the mesh. @param FLTYPE (Template Parameter) Specifies the scalar field of the vertex coordinate type. @param VFTYPE (Template Parameter) Specifies the type for the face, needed only for VF adjacency. */ template > class VERTEX_TYPE { public: /// The scalar type used to represent coords (i.e. float, double, ...) typedef FLTYPE ScalarType; /// The coordinate type used to represent the point (i.e. Point3f, Point3d, ...) typedef Point3 CoordType; typedef Point3 NormalType; /// The type base of the vertex, useful for recovering the original typename after user subclassing typedef VERTEX_TYPE BaseVertexType; /// The type of the face pointed by the vertex if vertex edge topology is present typedef VETYPE EdgeType; /// The type base of the vertex, useful for recovering the original typename after user subclassing typedef VFTYPE FaceType; /***********************************************/ /** @name Vertex Coords blah blah **/ //@{ protected: /// Spatial coordinates of the vertex CoordType _p; public: /// Return the spatial coordinate of the vertex inline CoordType & P() { assert( (_flags & DELETED) == 0 ); assert( (_flags & NOTREAD) == 0 ); assert( (_flags & NOTWRITE) == 0 ); return _p; } /// Return the constant spatial coordinate of the vertex inline const CoordType & P() const { assert( (_flags & DELETED) == 0 ); assert( (_flags & NOTREAD) == 0 ); return _p; } /// Return the constant spatial coordinate of the vertex inline const CoordType & cP() const { assert( (_flags & DELETED) == 0 ); assert( (_flags & NOTREAD) == 0 ); return _p; } /// Return the spatial coordinate of the vertex, senza effettuare controlli sul flag inline CoordType & UberP() { return _p; } /// Return the constant spatial coordinate of the vertex, senza effettuare controlli sul flag inline const CoordType & UberP() const { return _p; } //@} /***********************************************/ /** @name Vertex Flags For each vertex we store a set of boolean values packed in a int. The default value for each flag is 0. Most commonly used flags are the \a deleted and the \a selected ones. Users can ask and dispose for a bit for their own purposes with the vcg::VertexFull::NewUserBit() and vcg::VertexFull::DeleteUserBit() functions. The value returned by these functions has to be passed to the vcg::VertexFull::SetUserBit() vcg::VertexFull::ClearUserBit() and vcg::VertexFull::IsUserBit() functions to check and modify the obtained bit flag. **/ //@{ protected: /// This are the flags of vertex, the default (reasonable) value is 0 int _flags; public: /// Return the vector of _flags inline int & Flags () { assert( (_flags & DELETED) == 0 ); assert( (_flags & NOTREAD) == 0 ); return _flags; } /// Return the vector of _flags, senza effettuare controlli sui bit inline int & UberFlags () { return _flags; } inline const int UberFlags() const { return _flags; } /// checks if the vertex is deleted bool IsD() const {return (_flags & DELETED) != 0;} /// checks if the vertex is readable bool IsR() const {return (_flags & NOTREAD) == 0;} /// checks if the vertex is modifiable bool IsW() const {return (_flags & NOTWRITE)== 0;} /// This funcion checks whether the vertex is both readable and modifiable bool IsRW() const {return (_flags & (NOTREAD | NOTWRITE)) == 0;} /// checks if the vertex is Modified bool IsS() const {return (_flags & SELECTED) != 0;} /// checks if the vertex is readable bool IsB() const {return (_flags & BORDER) != 0;} /// checks if the vertex is visited bool IsV() const {return (_flags & VISITED) != 0;} /** Set the flag value @param flagp Valore da inserire nel flag */ void SetFlags(int flagp) {_flags=flagp;} /** Set the flag value @param flagp Valore da inserire nel flag */ void ClearFlags() {_flags=0;} /// deletes the vertex from the mesh void SetD() {_flags |=DELETED;} /// un-delete a vertex void ClearD() {_flags &=(~DELETED);} /// marks the vertex as readable void SetR() {_flags &=(~NOTREAD);} /// marks the vertex as not readable void ClearR() {_flags |=NOTREAD;} /// marks the vertex as writable void ClearW() {_flags |=NOTWRITE;} /// marks the vertex as not writable void SetW() {_flags &=(~NOTWRITE);} /// select the vertex void SetS() {_flags |=SELECTED;} /// Un-select a vertex void ClearS() {_flags &= ~SELECTED;} /// Set vertex as ob border void SetB() {_flags |=BORDER;} void ClearB() {_flags &=~BORDER;} /// checks if the vertex is visited void ClearV() {_flags &= ~VISITED;} /// checks if the vertex is visited void SetV() {_flags |=VISITED;} /// Return the first bit that is not still used static int &LastBitFlag() { static int b =USER0; return b; } /// allocate a bit among the flags that can be used by user. static inline int NewBitFlag() { LastBitFlag()=LastBitFlag()<<1; return LastBitFlag(); } // de-allocate a bit among the flags that can be used by user. static inline bool DeleteBitFlag(int bitval) { if(LastBitFlag()==bitval) { LastBitFlag()= LastBitFlag()>>1; return true; } assert(0); return false; } /// This function checks if the given user bit is true bool IsUserBit(int userBit){return (_flags & userBit) != 0;} /// This function set the given user bit void SetUserBit(int userBit){_flags |=userBit;} /// This function clear the given user bit void ClearUserBit(int userBit){_flags &= (~userBit);} //@} /***********************************************/ /** @name Vertex Texture Coords blah blah **/ //@{ #ifdef __VCGLIB_VERTEX_VT protected: TCTYPE _t; #endif public: TCTYPE & T() { #ifdef __VCGLIB_VERTEX_VT return _t; #else assert(0); return *(TCTYPE*)(&_flags); #endif } const TCTYPE & T() const { #ifdef __VCGLIB_VERTEX_VT return _t; #else assert(0); return *(TCTYPE*)(&_flags); #endif } //@} /***********************************************/ /** @name Per vertex Color blah blah **/ //@{ #ifdef __VCGLIB_VERTEX_VC protected: Color4b _c; #endif public: Color4b & C() { #ifdef __VCGLIB_VERTEX_VC return _c; #else assert(0); return *(Color4b*)(&_flags); #endif } const Color4b & C() const { #ifdef __VCGLIB_VERTEX_VC return _c; #else return Color4b(Color4b::White); #endif } //@} /***********************************************/ /** @name Vertex Quality blah blah **/ //@{ #ifdef __VCGLIB_VERTEX_VQ protected: float _q; #endif public: float & Q() { #ifdef __VCGLIB_VERTEX_VQ return _q; #else assert(0); return *(float*)(&_flags); #endif } const float & Q() const { #ifdef __VCGLIB_VERTEX_VQ return _q; #else return 1; #endif } //@} /** @name Vertex-Edge Adjacency blah blah **/ //@{ #if ((defined __VCGLIB_VERTEX_EA) || (defined __VCGLIB_VERTEX_EAS)) // Puntatore ad un edge appartenente alla stella del vertice, implementa l'adiacenza vertice-edge protected: EdgeType *_ep; int _ei; #endif public: inline EdgeType * & Ep() { #if ((defined __VCGLIB_VERTEX_EA) || (defined __VCGLIB_VERTEX_EAS)) return _ep; #else assert(0);// you are probably trying to use VF topology in a vertex without it return *((EdgeType **)(_flags)); #endif } inline const EdgeType * & Ep() const { #if ((defined __VCGLIB_VERTEX_EA) || (defined __VCGLIB_VERTEX_EAS)) return _ep; #else assert(0);// you are probably trying to use VF topology in a vertex without it return (EdgeType *)this; #endif } inline int & Ei() { #if ((defined __VCGLIB_VERTEX_EA) || (defined __VCGLIB_VERTEX_EAS)) return _ei; #else assert(0);// you are probably trying to use VF topology in a vertex without it return _flags; #endif } inline const int & Ei() const { #if ((defined __VCGLIB_VERTEX_EA) || (defined __VCGLIB_VERTEX_EAS)) return _ei; #else assert(0);// you are probably trying to use VF topology in a vertex without it return (void *)this; #endif } //@} /***********************************************/ /** @name Vertex-Face Adjacency blah blah **/ //@{ #if ((defined __VCGLIB_VERTEX_AF) || (defined __VCGLIB_VERTEX_AFS)) // Puntatore ad una faccia appartenente alla stella del vertice, implementa l'adiacenza vertice-faccia protected: VFTYPE *_vfb; int _vfi; #endif public: inline VFTYPE * & VFp() { #if ((defined __VCGLIB_VERTEX_AF) || (defined __VCGLIB_VERTEX_AFS)) return _vfb; #else assert(0);// you are probably trying to use VF topology in a vertex without it static VFTYPE *dum; return dum; #endif } inline const VFTYPE * & VFp() const { #if ((defined __VCGLIB_VERTEX_AF) || (defined __VCGLIB_VERTEX_AFS)) return _vfb; #else assert(0);// you are probably trying to use VF topology in a vertex without it return (VFTYPE *)this; #endif } inline int & VFi() { #if ((defined __VCGLIB_VERTEX_AF) || (defined __VCGLIB_VERTEX_AFS)) return _vfi; #else assert(0);// you are probably trying to use VF topology in a vertex without it return _flags; #endif } inline const int & VFi() const { #if ((defined __VCGLIB_VERTEX_AF) || (defined __VCGLIB_VERTEX_AFS)) return _vfi; #else assert(0);// you are probably trying to use VF topology in a vertex without it return (void *)this; #endif } //@} /***********************************************/ /** @name Vertex-Tetrahedron Adjacency blah blah **/ //@{ #if ((defined __VCGLIB_VERTEX_AT) || (defined __VCGLIB_VERTEX_ATS)) // Pointer to first tetrahedron of the start implements the Vertex-Tetrahedron Topology protected: VTTYPE *_vtb; int _vti; #endif public: inline VTTYPE * & VTb() { #if ((defined __VCGLIB_VERTEX_AT) || (defined __VCGLIB_VERTEX_ATS)) return _vtb; #else assert(0);// you are probably trying to use VF topology in a vertex without it return *((VTTYPE **)(_flags)); #endif } inline const VTTYPE * & VTb() const { #if ((defined __VCGLIB_VERTEX_AT) || (defined __VCGLIB_VERTEX_ATS)) return _vtb; #else assert(0);// you are probably trying to use VF topology in a vertex without it return (VTTYPE *)this; #endif } inline int & VTi() { #if ((defined __VCGLIB_VERTEX_AT) || (defined __VCGLIB_VERTEX_ATS)) return _vti; #else assert(0);// you are probably trying to use VF topology in a vertex without it return _flags; #endif } inline const int & VTi() const { #if ((defined __VCGLIB_VERTEX_AT) || (defined __VCGLIB_VERTEX_ATS)) return _vti; #else assert(0);// you are probably trying to use VF topology in a vertex without it return (void *)this; #endif } //@} /***********************************************/ /** @name Vertex Incremental Mark blah blah **/ //@{ #ifdef __VCGLIB_VERTEX_VM protected: /// The incremental vertex mark int _imark; #endif // Mark public: #ifdef __VCGLIB_VERTEX_VM /// This function return the vertex incremental mark inline int & IMark() { assert( (_flags & DELETED) == 0 ); assert( (_flags & NOTREAD) == 0 ); assert( (_flags & NOTWRITE) == 0 ); return _imark; } /// This function return the constant vertex incremental mark inline const int & IMark() const { assert( (_flags & DELETED) == 0 ); assert( (_flags & NOTREAD) == 0 ); return _imark; } #endif /// Initialize the _imark system of the vertex inline void InitIMark() { #ifdef __VCGLIB_VERTEX_VM _imark = 0; #endif } //@} /***********************************************/ /** @name Vertex Normal blah blah **/ //@{ #ifdef __VCGLIB_VERTEX_VN protected: CoordType _n; #endif public: /// Return the vertex normal inline CoordType & N() { assert( (_flags & DELETED) == 0 ); assert( (_flags & NOTREAD) == 0 ); assert( (_flags & NOTWRITE) == 0 ); #ifdef __VCGLIB_VERTEX_VN return _n; #else assert(0); return *(CoordType *)this; #endif } /// Return the constant vertex normal inline const CoordType & N() const { assert( (_flags & DELETED) == 0 ); assert( (_flags & NOTREAD) == 0 ); #ifdef __VCGLIB_VERTEX_VN return _n; #else assert(0); return *(CoordType *)this; #endif } inline const CoordType cN() const { assert( (_flags & DELETED) == 0 ); assert( (_flags & NOTREAD) == 0 ); #ifdef __VCGLIB_VERTEX_VN return _n; #else return CoordType(0,0,0); #endif } /// Return the Normal of the vertex inline CoordType & UberN() { #ifdef __VCGLIB_VERTEX_VN return _n; #else assert(0); return *(CoordType *)this; #endif } /// Return the constant normal of the vertex inline const CoordType & UberN() const { #ifdef __VCGLIB_VERTEX_VN return _n; #else assert(0); return *(CoordType *)this; #endif } //@} /***********************************************/ /** @name Reflection Functions Static functions that give information about the current vertex type. Reflection is a mechanism making it possible to investigate yourself. Reflection is used to investigate format of objects at runtime, invoke methods and access fields of these objects. Here we provide static const functions that are resolved at compile time and they give information about the data (normal, color etc.) supported by the current vertex type. **/ //@{ static bool HasNormal() { #ifdef __VCGLIB_VERTEX_VN return true; #else return false; #endif } static bool HasColor() { #ifdef __VCGLIB_VERTEX_VC return true; #else return false; #endif } static bool HasMark() { #ifdef __VCGLIB_VERTEX_VM return true; #else return false; #endif } static bool HasQuality() { #ifdef __VCGLIB_VERTEX_VQ return true; #else return false; #endif } static bool HasTexture() { #ifdef __VCGLIB_VERTEX_VT return true; #else return false; #endif } static bool HasVFAdjacency() { #ifdef __VCGLIB_VERTEX_AF return true; #else return false; #endif } static bool HasVTAdjacency() { #ifdef __VCGLIB_VERTEX_AT return true; #else return false; #endif } static bool HasVEAdjacency() { #ifdef __VCGLIB_VERTEX_EA return true; #else return false; #endif } //@} /***********************************************/ /** @Conversion to other vertex **/ //@{ template inline void Convert( VERT_TYPE &v ) { P()=v.P(); Flags()=v.Flags(); if ((HasNormal())&&(v.HasNormal())) N()=v.N(); if ((HasColor())&&(v.HasColor())) C()=v.C(); #ifdef __VCGLIB_VERTEX_VM if ((HasMark())&&(v.HasMark())) IMark()=v.IMark(); #endif if ((HasQuality())&&(v.HasQuality())) Q()=v.Q(); if ((HasTexture())&&(v.HasTexture())) T()=v.T(); } //@} enum { // This bit indicate that the vertex is deleted from the mesh DELETED = 0x0001, // cancellato // This bit indicate that the vertex of the mesh is not readable NOTREAD = 0x0002, // non leggibile (ma forse modificabile) // This bit indicate that the vertex is not modifiable NOTWRITE = 0x0004, // non modificabile (ma forse leggibile) // This bit indicate that the vertex is modified MODIFIED = 0x0008, // modificato // This bit can be used to mark the visited vertex VISITED = 0x0010, // Visited // This bit can be used to select SELECTED = 0x0020, // Selection flag // Border Flag BORDER = 0x0100, // First user bit USER0 = 0x0200 // Fisrt user bit }; /** Return the i-th spatial value of the vertex coordinate. @param i Index of the spatial vertex coordinate (x=0 y=1 z=2). */ inline ScalarType & operator [] ( const int i ){ assert(i>=0 && i<3); return P().V(i); } /** Return the i-th spatial value of the const vertex coordinate. @param i Index of the spatial vertex coordinate (x=0 y=1 z=2). */ inline const FLTYPE & operator [] ( const int i ) const { assert(i>=0 && i<3); return P().V(i); } /// Operator to compare two vertices using lexicographic order inline bool operator < ( const VERTEX_TYPE & ve) const { return _p < ve._p; } inline VERTEX_TYPE() { #ifdef _DEBUG _flags=0; #endif }; }; template typename VERTEX_TYPE::CoordType NormalizedNormalV(VERTEX_TYPE *v) { if (!v->HasVFAdjacency()) { assert(0); return (VERTEX_TYPE::CoordType (0,0,0)); } else { vcg::face::VFIterator VFi=vcg::face::VFIterator(); VFi.f=v->VFp(); VFi.z=v->VFi(); typename VERTEX_TYPE::CoordType N= typename VERTEX_TYPE::CoordType(0,0,0); int i=0; while (!VFi.End()) { N+=VFi.f->NormalizedNormal(); i++; VFi++; } return ((typename VERTEX_TYPE::CoordType) N/(typename VERTEX_TYPE::CoordType::ScalarType)i); } } } // end namespace #endif