vcglib/wrap/io_trimesh/import_ply.h

855 lines
25 KiB
C++

/****************************************************************************
* 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 1.7 2004/06/11 17:09:41 ganovelli
inclusion of vector..minorchanges
Revision 1.6 2004/05/28 14:11:13 ganovelli
changes to comply io_mask moving in vcg::ply namesp
Revision 1.5 2004/05/12 10:19:30 ganovelli
new line added at the end of file
Revision 1.4 2004/05/04 02:36:07 ganovelli
#ifndef __VCGLIB_IMPORTERPLY added
Revision 1.3 2004/04/03 13:30:01 cignoni
missing include allocate.h
Revision 1.2 2004/03/09 21:26:47 cignoni
cr lf mismatch
Revision 1.1 2004/03/03 15:00:51 cignoni
Initial commit
****************************************************************************/
#ifndef __VCGLIB_IMPORTERPLY
#define __VCGLIB_IMPORTERPLY
#include<wrap/callback.h>
#include<wrap/ply/plylib.h>
#include<wrap/ply/io_mask.h>
#include<wrap/io_trimesh/io_ply.h>
#include<vcg/complex/trimesh/allocate.h>
#include <vector>
namespace vcg {
namespace tri {
namespace io {
template <class TYPE>
int PlyType () { return 0;}
template <> int PlyType <float >() { return ply::T_FLOAT; }
template <> int PlyType <double>() { return ply::T_DOUBLE; }
template <> int PlyType <int >() { return ply::T_INT; }
template <> int PlyType <short >() { return ply::T_SHORT; }
template <> int PlyType <unsigned char >() { return ply::T_UCHAR; }
/**
This class encapsulate a filter for opening ply meshes.
The ply file format is quite extensible...
*/
template <class OpenMeshType>
class ImporterPLY
{
public:
typedef ::vcg::ply::PropDescriptor PropDescriptor ;
typedef typename OpenMeshType::VertexPointer VertexPointer;
typedef typename OpenMeshType::ScalarType ScalarType;
typedef typename OpenMeshType::VertexType VertexType;
typedef typename OpenMeshType::FaceType FaceType;
typedef typename OpenMeshType::VertexIterator VertexIterator;
typedef typename OpenMeshType::FaceIterator FaceIterator;
//template <class T> int PlyType () { assert(0); return 0;}
#define MAX_USER_DATA 256
// Struttura ausiliaria per la lettura del file ply
struct LoadPly_FaceAux
{
unsigned char size;
int v[512];
int flags;
float q;
float tcoord[32];
unsigned char ntcoord;
int tcoordind;
float colors[32];
unsigned char ncolors;
unsigned char r;
unsigned char g;
unsigned char b;
unsigned char data[MAX_USER_DATA];
};
struct LoadPly_TristripAux
{
int size;
int *v;
unsigned char data[MAX_USER_DATA];
};
// Struttura ausiliaria per la lettura del file ply
template<class S>
struct LoadPly_VertAux
{
S p[3];
int flags;
float q;
unsigned char r;
unsigned char g;
unsigned char b;
unsigned char data[MAX_USER_DATA];
};
// Struttura ausiliaria caricamento camera
struct LoadPly_Camera
{
float view_px;
float view_py;
float view_pz;
float x_axisx;
float x_axisy;
float x_axisz;
float y_axisx;
float y_axisy;
float y_axisz;
float z_axisx;
float z_axisy;
float z_axisz;
float focal;
float scalex;
float scaley;
float centerx;
float centery;
int viewportx;
int viewporty;
float k1;
float k2;
float k3;
float k4;
};
static const PropDescriptor &VertDesc(int i)
{
const static PropDescriptor pv[9]={
{"vertex", "x", ply::T_FLOAT, PlyType<ScalarType>(),offsetof(LoadPly_VertAux<ScalarType>,p[0]),0,0,0,0,0},
{"vertex", "y", ply::T_FLOAT, PlyType<ScalarType>(),offsetof(LoadPly_VertAux<ScalarType>,p[1]),0,0,0,0,0},
{"vertex", "z", ply::T_FLOAT, PlyType<ScalarType>(),offsetof(LoadPly_VertAux<ScalarType>,p[2]),0,0,0,0,0},
{"vertex", "flags", ply::T_INT, ply::T_INT, offsetof(LoadPly_VertAux<ScalarType>,flags),0,0,0,0,0},
{"vertex", "quality", ply::T_FLOAT, ply::T_FLOAT, offsetof(LoadPly_VertAux<ScalarType>,q),0,0,0,0,0},
{"vertex", "red" , ply::T_UCHAR, ply::T_UCHAR, offsetof(LoadPly_VertAux<ScalarType>,r),0,0,0,0,0},
{"vertex", "green", ply::T_UCHAR, ply::T_UCHAR, offsetof(LoadPly_VertAux<ScalarType>,g),0,0,0,0,0},
{"vertex", "blue" , ply::T_UCHAR, ply::T_UCHAR, offsetof(LoadPly_VertAux<ScalarType>,b),0,0,0,0,0},
{"vertex", "confidence",ply::T_FLOAT, ply::T_FLOAT, offsetof(LoadPly_VertAux<ScalarType>,q),0,0,0,0,0},
};
return pv[i];
}
static const PropDescriptor &FaceDesc(int i)
{
const static PropDescriptor qf[10]=
{
{"face", "vertex_indices", ply::T_INT, ply::T_INT, offsetof(LoadPly_FaceAux,v), 1,0,ply::T_UCHAR,ply::T_UCHAR,offsetof(LoadPly_FaceAux,size) },
{"face", "flags", ply::T_INT, ply::T_INT, offsetof(LoadPly_FaceAux,flags), 0,0,0,0,0},
{"face", "quality", ply::T_FLOAT, ply::T_FLOAT, offsetof(LoadPly_FaceAux,q), 0,0,0,0,0},
{"face", "texcoord", ply::T_FLOAT, ply::T_FLOAT, offsetof(LoadPly_FaceAux,tcoord), 1,0,ply::T_UCHAR,ply::T_UCHAR,offsetof(LoadPly_FaceAux,ntcoord) },
{"face", "color", ply::T_FLOAT, ply::T_FLOAT, offsetof(LoadPly_FaceAux,colors), 1,0,ply::T_UCHAR,ply::T_UCHAR,offsetof(LoadPly_FaceAux,ncolors) },
{"face", "texnumber", ply::T_INT, ply::T_INT, offsetof(LoadPly_FaceAux,tcoordind), 0,0,0,0,0},
{"face", "red" , ply::T_UCHAR, ply::T_UCHAR, offsetof(LoadPly_FaceAux,r), 0,0,0,0,0},
{"face", "green", ply::T_UCHAR, ply::T_UCHAR, offsetof(LoadPly_FaceAux,g), 0,0,0,0,0},
{"face", "blue" , ply::T_UCHAR, ply::T_UCHAR, offsetof(LoadPly_FaceAux,b), 0,0,0,0,0},
{"face", "vertex_index", ply::T_INT, ply::T_INT, offsetof(LoadPly_FaceAux,v), 1,0,ply::T_UCHAR,ply::T_CHAR,offsetof(LoadPly_FaceAux,size) },
};
return qf[i];
}
static const PropDescriptor &TristripDesc(int i)
{
const static PropDescriptor qf[1]=
{
{"tristrips","vertex_indices", ply::T_INT, ply::T_INT, offsetof(LoadPly_TristripAux,v), 1,1,ply::T_INT,ply::T_INT,offsetof(LoadPly_TristripAux,size) },
};
return qf[i];
}
static const PropDescriptor &CameraDesc(int i)
{
const static PropDescriptor cad[23] =
{
{"camera","view_px",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,view_px),0,0,0,0,0},
{"camera","view_py",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,view_py),0,0,0,0,0},
{"camera","view_pz",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,view_pz),0,0,0,0,0},
{"camera","x_axisx",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,x_axisx),0,0,0,0,0},
{"camera","x_axisy",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,x_axisy),0,0,0,0,0},
{"camera","x_axisz",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,x_axisz),0,0,0,0,0},
{"camera","y_axisx",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,y_axisx),0,0,0,0,0},
{"camera","y_axisy",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,y_axisy),0,0,0,0,0},
{"camera","y_axisz",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,y_axisz),0,0,0,0,0},
{"camera","z_axisx",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,z_axisx),0,0,0,0,0},
{"camera","z_axisy",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,z_axisy),0,0,0,0,0},
{"camera","z_axisz",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,z_axisz),0,0,0,0,0},
{"camera","focal" ,ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,focal ),0,0,0,0,0},
{"camera","scalex" ,ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,scalex ),0,0,0,0,0},
{"camera","scaley" ,ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,scaley ),0,0,0,0,0},
{"camera","centerx",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,centerx),0,0,0,0,0},
{"camera","centery",ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,centery),0,0,0,0,0},
{"camera","viewportx",ply::T_INT,ply::T_INT ,offsetof(LoadPly_Camera,viewportx),0,0,0,0,0},
{"camera","viewporty",ply::T_INT,ply::T_INT ,offsetof(LoadPly_Camera,viewporty),0,0,0,0,0},
{"camera","k1" ,ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,k1 ),0,0,0,0,0},
{"camera","k2" ,ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,k2 ),0,0,0,0,0},
{"camera","k3" ,ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,k3 ),0,0,0,0,0},
{"camera","k4" ,ply::T_FLOAT,ply::T_FLOAT,offsetof(LoadPly_Camera,k4 ),0,0,0,0,0}
};
return cad[i];
}
/// Standard call for knowing the meaning of an error code
static const char *ErrorMsg(int error)
{
const char * ply_error_msg[] =
{
"No errors",
"Can't open file",
"Header not found",
"Eof in header",
"Format not found",
"Syntax error on header",
"Property without element",
"Bad type name",
"Element not found",
"Property not found",
"Bad type on addtoread",
"Incompatible type",
"Bad cast",
"No vertex field found",
"No face field found",
"Unespected eof",
"Face with more than 3 vertices",
"Bad vertex index in face",
"Face with no 6 texture coordinates",
"Number of color differ from vertices"
};
if(error>PlyInfo::E_MAXPLYINFOERRORS || error<0) return "Unknown error";
else return ply_error_msg[error];
};
/// Standard call for reading a mesh
static int Open( OpenMeshType &m, const char * filename, CallBackPos *cb=0)
{
PlyInfo pi;
pi.cb=cb;
return Open(m, filename, pi);
}
/// Read a mesh and store in loadmask the loaded field
static int Open( OpenMeshType &m, const char * filename, int & loadmask, CallBackPos *cb =0)
{
PlyInfo pi;
pi.mask=loadmask;
return Open(m, filename,pi);
loadmask=pi.mask;
}
/// read a mesh with all the possible option specified in the PlyInfo obj.
static int Open( OpenMeshType &m, const char * filename, PlyInfo &pi )
{
assert(filename!=0);
std::vector<VertexPointer> index;
LoadPly_FaceAux fa;
LoadPly_TristripAux tsa;
LoadPly_VertAux<ScalarType> va;
pi.mask = 0;
bool multit = false; // true if texture has a per face int spec the texture index
va.flags = 42;
pi.status = ::vcg::ply::E_NOERROR;
// init defaults
VertexType tv;
tv.UberFlags() = 0;
if( VertexType::HasQuality() ) tv.Q()=1.0;
if( VertexType::HasColor() ) tv.C()=Color4b(Color4b::White);
FaceType tf;
tf.UberFlags() = 0;
if( FaceType::HasFaceQuality() ) tf.Q()=1.0;
if( FaceType::HasWedgeColor() ) tf.WC(0)=tf.WC(1)=tf.WC(2)=Color4b(Color4b::White);
if( FaceType::HasFaceColor() ) tf.C()=Color4b(Color4b::White);
// Descrittori delle strutture
//bool isvflags = false; // Il file contiene i flags
// The main descriptor of the ply file
vcg::ply::PlyFile pf;
// Open the file and parse the header
if( pf.Open(filename,vcg::ply::PlyFile::MODE_READ)==-1 )
{
pi.status = pf.GetError();
return pi.status;
}
pi.header = pf.GetHeader();
// Descrittori della camera
{ // Check that all the camera properties are present.
bool found = true;
for(int i=0;i<23;++i)
{
if( pf.AddToRead(CameraDesc(i))==-1 ) {
found = false;
break;
}
}
if(found) pi.mask |= ply::PLYMask::PM_CAMERA;
}
// Descrittori dati standard (vertex coord e faces)
if( pf.AddToRead(VertDesc(0))==-1 ) { pi.status = PlyInfo::E_NO_VERTEX; return pi.status; }
if( pf.AddToRead(VertDesc(1))==-1 ) { pi.status = PlyInfo::E_NO_VERTEX; return pi.status; }
if( pf.AddToRead(VertDesc(2))==-1 ) { pi.status = PlyInfo::E_NO_VERTEX; return pi.status; }
if( pf.AddToRead(FaceDesc(0))==-1 ) // Se fallisce si prova anche la sintassi di rapidform con index al posto di indices
if( pf.AddToRead(FaceDesc(9))==-1 )
if(pf.AddToRead(TristripDesc(0))==-1) // Se fallisce tutto si prova a vedere se ci sono tristrip alla levoy.
{ pi.status = PlyInfo::E_NO_FACE; return pi.status; }
// Descrittori facoltativi dei flags
if( pf.AddToRead(VertDesc(3))!=-1 )
pi.mask |= ply::PLYMask::PM_VERTFLAGS;
if( VertexType::HasQuality() )
{
if( pf.AddToRead(VertDesc(4))!=-1 ||
pf.AddToRead(VertDesc(8))!=-1 )
pi.mask |= ply::PLYMask::PM_VERTQUALITY;
}
if( VertexType::HasColor() )
{
if( pf.AddToRead(VertDesc(5))!=-1 )
{
pf.AddToRead(VertDesc(6));
pf.AddToRead(VertDesc(7));
pi.mask |= ply::PLYMask::PM_VERTCOLOR;
}
}
// se ci sono i flag per vertice ci devono essere anche i flag per faccia
if( pf.AddToRead(FaceDesc(1))!=-1 )
pi.mask |= ply::PLYMask::PM_FACEFLAGS;
if( FaceType::HasFaceQuality())
{
if( pf.AddToRead(FaceDesc(2))!=-1 )
pi.mask |= ply::PLYMask::PM_FACEQUALITY;
}
if( FaceType::HasFaceColor() )
{
if( pf.AddToRead(FaceDesc(6))!=-1 )
{
pf.AddToRead(FaceDesc(7));
pf.AddToRead(FaceDesc(8));
pi.mask |= ply::PLYMask::PM_FACECOLOR;
}
}
if( FaceType::HasWedgeTexture() )
{
if( pf.AddToRead(FaceDesc(3))!=-1 )
{
if(pf.AddToRead(FaceDesc(5))==0) {
multit=true; // try to read also the multi texture indicies
pi.mask |= ply::PLYMask::PM_WEDGTEXMULTI;
}
pi.mask |= ply::PLYMask::PM_WEDGTEXCOORD;
}
}
if( FaceType::HasWedgeColor() || FaceType::HasFaceColor() || VertexType::HasColor())
{
if( pf.AddToRead(FaceDesc(4))!=-1 )
{
pi.mask |= ply::PLYMask::PM_WEDGCOLOR;
}
}
// Descrittori definiti dall'utente,
std::vector<PropDescriptor> VPV(pi.vdn); // property descriptor relative al tipo LoadPly_VertexAux
std::vector<PropDescriptor> FPV(pi.fdn); // property descriptor relative al tipo LoadPly_FaceAux
if(pi.vdn>0){
// Compute the total size needed to load additional per vertex data.
size_t totsz=0;
for(int i=0;i<pi.vdn;i++){
VPV[i] = pi.VertexData[i];
VPV[i].offset1=offsetof(LoadPly_VertAux<ScalarType>,data)+totsz;
totsz+=pi.VertexData[i].memtypesize();
if( pf.AddToRead(VPV[i])==-1 ) { pi.status = pf.GetError(); return pi.status; }
}
if(totsz > MAX_USER_DATA)
{
pi.status = vcg::ply::E_BADTYPE;
return pi.status;
}
}
if(pi.fdn>0){
size_t totsz=0;
for(int i=0;i<pi.fdn;i++){
FPV[i] = pi.FaceData[i];
FPV[i].offset1=offsetof(LoadPly_FaceAux,data)+totsz;
totsz+=pi.FaceData[i].memtypesize();
if( pf.AddToRead(FPV[i])==-1 ) { pi.status = pf.GetError(); return pi.status; }
}
if(totsz > MAX_USER_DATA)
{
pi.status = vcg::ply::E_BADTYPE;
return pi.status;
}
}
/**************************************************************/
/* Main Reading Loop */
/**************************************************************/
m.Clear();
for(int i=0;i<int(pf.elements.size());i++)
{
int n = pf.ElemNumber(i);
if( !strcmp( pf.ElemName(i),"camera" ) )
{
pf.SetCurElement(i);
LoadPly_Camera ca;
for(int j=0;j<n;++j)
{
if( pf.Read( (void *)&(ca) )==-1 )
{
pi.status = PlyInfo::E_SHORTFILE;
return pi.status;
}
//camera.valid = true;
//camera.view_p[0] = ca.view_px;
//camera.view_p[1] = ca.view_py;
//camera.view_p[2] = ca.view_pz;
//camera.x_axis[0] = ca.x_axisx;
//camera.x_axis[1] = ca.x_axisy;
//camera.x_axis[2] = ca.x_axisz;
//camera.y_axis[0] = ca.y_axisx;
//camera.y_axis[1] = ca.y_axisy;
//camera.y_axis[2] = ca.y_axisz;
//camera.z_axis[0] = ca.z_axisx;
//camera.z_axis[1] = ca.z_axisy;
//camera.z_axis[2] = ca.z_axisz;
//camera.f = ca.focal;
//camera.s[0] = ca.scalex;
//camera.s[1] = ca.scaley;
//camera.c[0] = ca.centerx;
//camera.c[1] = ca.centery;
//camera.viewport[0] = ca.viewportx;
//camera.viewport[1] = ca.viewporty;
//camera.k[0] = ca.k1;
//camera.k[1] = ca.k2;
//camera.k[2] = ca.k3;
//camera.k[3] = ca.k4;
}
}
else if( !strcmp( pf.ElemName(i),"vertex" ) )
{
int j;
pf.SetCurElement(i);
VertexIterator vi=Allocator<OpenMeshType>::AddVertices(m,n);
for(j=0;j<n;++j)
{
if(pi.cb && (j%1000)==0) pi.cb(j*50/n,"Vertex Loading");
(*vi).UberFlags()=0;
if( pf.Read( (void *)&(va) )==-1 )
{
pi.status = PlyInfo::E_SHORTFILE;
return pi.status;
}
(*vi).P()[0] = va.p[0];
(*vi).P()[1] = va.p[1];
(*vi).P()[2] = va.p[2];
if( pi.mask & ply::PLYMask::PM_VERTFLAGS )
(*vi).UberFlags() = va.flags;
if( pi.mask & ply::PLYMask::PM_VERTQUALITY )
(*vi).Q() = va.q;
if( pi.mask & ply::PLYMask::PM_VERTCOLOR )
{
(*vi).C()[0] = va.r;
(*vi).C()[1] = va.g;
(*vi).C()[2] = va.b;
(*vi).C()[3] = 255;
}
for(int k=0;k<pi.vdn;k++)
memcpy((char *)(&*vi) + pi.VertexData[k].offset1,
(char *)(&va) + VPV[k].offset1,
VPV[k].memtypesize());
++vi;
}
index.resize(n);
for(j=0,vi=m.vert.begin();j<n;++j,++vi)
index[j] = &*vi;
}
else if( !strcmp( pf.ElemName(i),"face") )/************************************************************/
{
int j;
FaceIterator fi=Allocator<OpenMeshType>::AddFaces(m,n);
pf.SetCurElement(i);
for(j=0;j<n;++j)
{
int k;
if(pi.cb && (j%1000)==0) pi.cb(50+j*50/n,"Face Loading");
if( pf.Read(&fa)==-1 )
{
pi.status = PlyInfo::E_SHORTFILE;
return pi.status;
}
if(fa.size!=3)
{
pi.status = PlyInfo::E_NO_3VERTINFACE;
return pi.status;
}
for(k=0;k<3;++k)
{
if( fa.v[k]<0 || fa.v[k]>=m.vn )
{
pi.status = PlyInfo::E_BAD_VERT_INDEX;
return pi.status;
}
(*fi).V(k) = index[ fa.v[k] ];
}
if( pi.mask & ply::PLYMask::PM_FACEFLAGS )
{
(*fi).UberFlags() = fa.flags;
}
if( pi.mask & ply::PLYMask::PM_FACEQUALITY )
{
(*fi).Q() = fa.q;
}
if( pi.mask & ply::PLYMask::PM_FACECOLOR )
{
(*fi).C()[0] = fa.r;
(*fi).C()[1] = fa.g;
(*fi).C()[2] = fa.b;
(*fi).C()[3] = 255;
}
if( pi.mask & ply::PLYMask::PM_WEDGTEXCOORD )
{
for(int k=0;k<3;++k)
{
(*fi).WT(k).u() = fa.tcoord[k*2+0];
(*fi).WT(k).v() = fa.tcoord[k*2+1];
if(multit) (*fi).WT(k).n() = fa.tcoordind;
}
}
if( pi.mask & ply::PLYMask::PM_WEDGCOLOR )
{
if(FaceType::HasWedgeColor()){
for(int k=0;k<3;++k)
{
(*fi).WC(k)[0] = (unsigned char)(fa.colors[k*3+0]*255);
(*fi).WC(k)[1] = (unsigned char)(fa.colors[k*3+1]*255);
(*fi).WC(k)[2] = (unsigned char)(fa.colors[k*3+2]*255);
}
}
if(FaceType::HasFaceColor()){
{
(*fi).C()[0] = (unsigned char)((fa.colors[0*3+0]*255+fa.colors[1*3+0]*255+fa.colors[2*3+0]*255)/3.0f);
(*fi).C()[1] = (unsigned char)((fa.colors[0*3+1]*255+fa.colors[1*3+1]*255+fa.colors[2*3+1]*255)/3.0f);
(*fi).C()[2] = (unsigned char)((fa.colors[0*3+2]*255+fa.colors[1*3+2]*255+fa.colors[2*3+2]*255)/3.0f);
}
}
}
for(k=0;k<pi.fdn;k++)
memcpy((char *)(&(*fi)) + pi.FaceData[k].offset1,
(char *)(&fa) + FPV[k].offset1,
FPV[k].memtypesize());
++fi;
}
}else if( !strcmp( pf.ElemName(i),"tristrips") )//////////////////// LETTURA TRISTRIP DI STANFORD
{
int j;
pf.SetCurElement(i);
int numvert_tmp = m.vert.size();
for(j=0;j<n;++j)
{
int k;
if(pi.cb && (j%1000)==0) pi.cb(50+j*50/n,"Tristrip Face Loading");
if( pf.Read(&tsa)==-1 )
{
pi.status = PlyInfo::E_SHORTFILE;
return pi.status;
}
int remainder=0;
//int startface=m.face.size();
for(k=0;k<tsa.size-2;++k)
{
if(pi.cb && (k%1000)==0) pi.cb(50+k*50/tsa.size,"Tristrip Face Loading");
if(tsa.v[k]<0 || tsa.v[k]>=numvert_tmp ) {
pi.status = PlyInfo::E_BAD_VERT_INDEX;
return pi.status;
}
if(tsa.v[k+2]==-1)
{
k+=2;
if(k%2) remainder=0;
else remainder=1;
continue;
}
tf.V(0) = index[ tsa.v[k+0] ];
tf.V(1) = index[ tsa.v[k+1] ];
tf.V(2) = index[ tsa.v[k+2] ];
if((k+remainder)%2) math::Swap (tf.V(0), tf.V(1) );
m.face.push_back( tf );
}
}
}
else
{
// Skippaggio elementi non gestiti
int n = pf.ElemNumber(i);
pf.SetCurElement(i);
for(int j=0;j<n;j++)
{
if( pf.Read(0)==-1)
{
pi.status = PlyInfo::E_SHORTFILE;
return pi.status;
}
}
}
}
// // Parsing texture names
//textures.clear();
//normalmaps.clear();
//for(int co=0;co<int(pf.comments.size());++co)
//{
// const char * TFILE = "TextureFile";
// const char * NFILE = "TextureNormalFile";
// const char * c = pf.comments[co];
// char buf[256];
// int i,j,n;
// if( !strncmp(c,TFILE,strlen(TFILE)) )
// {
// strcpy(buf,c+strlen(TFILE)+1);
// n = strlen(buf);
// for(i=j=0;i<n;i++)
// if( buf[i]!=' ' && buf[i]!='\t' && buf[i]>32 && buf[i]<125 ) buf[j++] = buf[i];
//
// buf[j] = 0;
// char buf2[255];
// __interpret_texture_name( buf,filename,buf2 );
// textures.push_back( xstring(buf2) );
// }
// if( !strncmp(c,NFILE,strlen(NFILE)) )
// {
// strcpy(buf,c+strlen(NFILE)+1);
// n = strlen(buf);
// for(i=j=0;i<n;i++)
// if( buf[i]!=' ' && buf[i]!='\t' && buf[i]>32 && buf[i]<125 ) buf[j++] = buf[i];
//
// buf[j] = 0;
// char buf2[255];
// __interpret_texture_name( buf,filename,buf2 );
// normalmaps.push_back( xstring(buf2) );
// }
//}
// vn and fn should be correct but if someone wrongly saved some deleted elements they can be wrong.
m.vn = 0;
VertexIterator vi;
for(vi=m.vert.begin();vi!=m.vert.end();++vi)
if( ! (*vi).IsD() )
++m.vn;
m.fn = 0;
FaceIterator fi;
for(fi=m.face.begin();fi!=m.face.end();++fi)
if( ! (*fi).IsD() )
++m.fn;
return 0;
}
// Caricamento camera da un ply
int LoadCamera(const char * filename)
{
vcg::ply::PlyFile pf;
if( pf.Open(filename,vcg::ply::PlyFile::MODE_READ)==-1 )
{
pi.status = pf.GetError();
return pi.status;
}
bool found = true;
int i;
for(i=0;i<23;++i)
{
if( pf.AddToRead(CameraDesc(i))==-1 )
{
found = false;
break;
}
}
if(!found)
return pi.status;
for(i=0;i<int(pf.elements.size());i++)
{
int n = pf.ElemNumber(i);
if( !strcmp( pf.ElemName(i),"camera" ) )
{
pf.SetCurElement(i);
LoadPly_Camera ca;
for(int j=0;j<n;++j)
{
if( pf.Read( (void *)&(ca) )==-1 )
{
pi.status = PlyInfo::E_SHORTFILE;
return pi.status;
}
camera.valid = true;
camera.view_p[0] = ca.view_px;
camera.view_p[1] = ca.view_py;
camera.view_p[2] = ca.view_pz;
camera.x_axis[0] = ca.x_axisx;
camera.x_axis[1] = ca.x_axisy;
camera.x_axis[2] = ca.x_axisz;
camera.y_axis[0] = ca.y_axisx;
camera.y_axis[1] = ca.y_axisy;
camera.y_axis[2] = ca.y_axisz;
camera.z_axis[0] = ca.z_axisx;
camera.z_axis[1] = ca.z_axisy;
camera.z_axis[2] = ca.z_axisz;
camera.f = ca.focal;
camera.s[0] = ca.scalex;
camera.s[1] = ca.scaley;
camera.c[0] = ca.centerx;
camera.c[1] = ca.centery;
camera.viewport[0] = ca.viewportx;
camera.viewport[1] = ca.viewporty;
camera.k[0] = ca.k1;
camera.k[1] = ca.k2;
camera.k[2] = ca.k3;
camera.k[3] = ca.k4;
}
break;
}
}
return 0;
}
bool LoadMask(const char * filename, int &mask)
{
mask=0;
vcg::ply::PlyFile pf;
if( pf.Open(filename,vcg::ply::PlyFile::MODE_READ)==-1 )
{
pi.status = pf.GetError();
return false;
}
if( pf.AddToRead(VertDesc(0))!=-1 &&
pf.AddToRead(VertDesc(1))!=-1 &&
pf.AddToRead(VertDesc(2))!=-1 ) mask |= ply::PLYMask::PM_VERTCOORD;
if( pf.AddToRead(VertDesc(3))!=-1 ) mask |= ply::PLYMask::PM_VERTFLAGS;
if( pf.AddToRead(VertDesc(4))!=-1 ) mask |= ply::PLYMask::PM_VERTQUALITY;
if( pf.AddToRead(VertDesc(8))!=-1 ) mask |= ply::PLYMask::PM_VERTQUALITY;
if( ( pf.AddToRead(VertDesc(5))!=-1 ) &&
( pf.AddToRead(VertDesc(6))!=-1 ) &&
( pf.AddToRead(VertDesc(7))!=-1 ) ) mask |= ply::PLYMask::PM_VERTCOLOR;
if( pf.AddToRead(FaceDesc(0))!=-1 ) mask |= ply::PLYMask::PM_FACEINDEX;
if( pf.AddToRead(FaceDesc(1))!=-1 ) mask |= ply::PLYMask::PM_FACEFLAGS;
if( pf.AddToRead(FaceDesc(2))!=-1 ) mask |= ply::PLYMask::PM_FACEQUALITY;
if( pf.AddToRead(FaceDesc(3))!=-1 ) mask |= ply::PLYMask::PM_WEDGTEXCOORD;
if( pf.AddToRead(FaceDesc(5))!=-1 ) mask |= ply::PLYMask::PM_WEDGTEXMULTI;
if( pf.AddToRead(FaceDesc(4))!=-1 ) mask |= ply::PLYMask::PM_WEDGCOLOR;
if( ( pf.AddToRead(FaceDesc(6))!=-1 ) &&
( pf.AddToRead(FaceDesc(7))!=-1 ) &&
( pf.AddToRead(FaceDesc(8))!=-1 ) ) mask |= ply::PLYMask::PM_FACECOLOR;
return true;
}
}; // end class
} // end namespace tri
} // end namespace io
} // end namespace vcg
#endif