2021-09-12 09:37:33 +00:00
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/// \file X3DImporter_Postprocess.cpp
/// \brief Convert built scenegraph and objects to Assimp scenegraph.
/// \date 2015-2016
/// \author smal.root@gmail.com
# ifndef ASSIMP_BUILD_NO_X3D_IMPORTER
# include "X3DGeoHelper.h"
# include "X3DImporter.hpp"
// Header files, Assimp.
# include <assimp/StandardShapes.h>
# include <assimp/StringUtils.h>
# include <assimp/ai_assert.h>
// Header files, stdlib.
# include <algorithm>
# include <iterator>
# include <string>
namespace Assimp {
aiMatrix4x4 X3DImporter : : PostprocessHelper_Matrix_GlobalToCurrent ( ) const {
X3DNodeElementBase * cur_node ;
std : : list < aiMatrix4x4 > matr ;
aiMatrix4x4 out_matr ;
// starting walk from current element to root
cur_node = mNodeElementCur ;
if ( cur_node ! = nullptr ) {
do {
// if cur_node is group then store group transformation matrix in list.
if ( cur_node - > Type = = X3DElemType : : ENET_Group ) matr . push_back ( ( ( X3DNodeElementGroup * ) cur_node ) - > Transformation ) ;
cur_node = cur_node - > Parent ;
} while ( cur_node ! = nullptr ) ;
}
// multiplicate all matrices in reverse order
for ( std : : list < aiMatrix4x4 > : : reverse_iterator rit = matr . rbegin ( ) ; rit ! = matr . rend ( ) ; + + rit )
out_matr = out_matr * ( * rit ) ;
return out_matr ;
}
void X3DImporter : : PostprocessHelper_CollectMetadata ( const X3DNodeElementBase & pNodeElement , std : : list < X3DNodeElementBase * > & pList ) const {
// walk through childs and find for metadata.
for ( std : : list < X3DNodeElementBase * > : : const_iterator el_it = pNodeElement . Children . begin ( ) ; el_it ! = pNodeElement . Children . end ( ) ; + + el_it ) {
if ( ( ( * el_it ) - > Type = = X3DElemType : : ENET_MetaBoolean ) | | ( ( * el_it ) - > Type = = X3DElemType : : ENET_MetaDouble ) | |
( ( * el_it ) - > Type = = X3DElemType : : ENET_MetaFloat ) | | ( ( * el_it ) - > Type = = X3DElemType : : ENET_MetaInteger ) | |
( ( * el_it ) - > Type = = X3DElemType : : ENET_MetaString ) ) {
pList . push_back ( * el_it ) ;
} else if ( ( * el_it ) - > Type = = X3DElemType : : ENET_MetaSet ) {
PostprocessHelper_CollectMetadata ( * * el_it , pList ) ;
}
} // for(std::list<X3DNodeElementBase*>::const_iterator el_it = pNodeElement.Children.begin(); el_it != pNodeElement.Children.end(); el_it++)
}
bool X3DImporter : : PostprocessHelper_ElementIsMetadata ( const X3DElemType pType ) const {
if ( ( pType = = X3DElemType : : ENET_MetaBoolean ) | | ( pType = = X3DElemType : : ENET_MetaDouble ) | |
( pType = = X3DElemType : : ENET_MetaFloat ) | | ( pType = = X3DElemType : : ENET_MetaInteger ) | |
( pType = = X3DElemType : : ENET_MetaString ) | | ( pType = = X3DElemType : : ENET_MetaSet ) ) {
return true ;
} else {
return false ;
}
}
bool X3DImporter : : PostprocessHelper_ElementIsMesh ( const X3DElemType pType ) const {
if ( ( pType = = X3DElemType : : ENET_Arc2D ) | | ( pType = = X3DElemType : : ENET_ArcClose2D ) | |
( pType = = X3DElemType : : ENET_Box ) | | ( pType = = X3DElemType : : ENET_Circle2D ) | |
( pType = = X3DElemType : : ENET_Cone ) | | ( pType = = X3DElemType : : ENET_Cylinder ) | |
( pType = = X3DElemType : : ENET_Disk2D ) | | ( pType = = X3DElemType : : ENET_ElevationGrid ) | |
( pType = = X3DElemType : : ENET_Extrusion ) | | ( pType = = X3DElemType : : ENET_IndexedFaceSet ) | |
( pType = = X3DElemType : : ENET_IndexedLineSet ) | | ( pType = = X3DElemType : : ENET_IndexedTriangleFanSet ) | |
( pType = = X3DElemType : : ENET_IndexedTriangleSet ) | | ( pType = = X3DElemType : : ENET_IndexedTriangleStripSet ) | |
( pType = = X3DElemType : : ENET_PointSet ) | | ( pType = = X3DElemType : : ENET_LineSet ) | |
( pType = = X3DElemType : : ENET_Polyline2D ) | | ( pType = = X3DElemType : : ENET_Polypoint2D ) | |
( pType = = X3DElemType : : ENET_Rectangle2D ) | | ( pType = = X3DElemType : : ENET_Sphere ) | |
( pType = = X3DElemType : : ENET_TriangleFanSet ) | | ( pType = = X3DElemType : : ENET_TriangleSet ) | |
( pType = = X3DElemType : : ENET_TriangleSet2D ) | | ( pType = = X3DElemType : : ENET_TriangleStripSet ) ) {
return true ;
} else {
return false ;
}
}
void X3DImporter : : Postprocess_BuildLight ( const X3DNodeElementBase & pNodeElement , std : : list < aiLight * > & pSceneLightList ) const {
const X3DNodeElementLight & ne = * ( ( X3DNodeElementLight * ) & pNodeElement ) ;
aiMatrix4x4 transform_matr = PostprocessHelper_Matrix_GlobalToCurrent ( ) ;
aiLight * new_light = new aiLight ;
new_light - > mName = ne . ID ;
new_light - > mColorAmbient = ne . Color * ne . AmbientIntensity ;
new_light - > mColorDiffuse = ne . Color * ne . Intensity ;
new_light - > mColorSpecular = ne . Color * ne . Intensity ;
switch ( pNodeElement . Type ) {
case X3DElemType : : ENET_DirectionalLight :
new_light - > mType = aiLightSource_DIRECTIONAL ;
new_light - > mDirection = ne . Direction , new_light - > mDirection * = transform_matr ;
break ;
case X3DElemType : : ENET_PointLight :
new_light - > mType = aiLightSource_POINT ;
new_light - > mPosition = ne . Location , new_light - > mPosition * = transform_matr ;
new_light - > mAttenuationConstant = ne . Attenuation . x ;
new_light - > mAttenuationLinear = ne . Attenuation . y ;
new_light - > mAttenuationQuadratic = ne . Attenuation . z ;
break ;
case X3DElemType : : ENET_SpotLight :
new_light - > mType = aiLightSource_SPOT ;
new_light - > mPosition = ne . Location , new_light - > mPosition * = transform_matr ;
new_light - > mDirection = ne . Direction , new_light - > mDirection * = transform_matr ;
new_light - > mAttenuationConstant = ne . Attenuation . x ;
new_light - > mAttenuationLinear = ne . Attenuation . y ;
new_light - > mAttenuationQuadratic = ne . Attenuation . z ;
new_light - > mAngleInnerCone = ne . BeamWidth ;
new_light - > mAngleOuterCone = ne . CutOffAngle ;
break ;
default :
throw DeadlyImportError ( " Postprocess_BuildLight. Unknown type of light: " + ai_to_string ( pNodeElement . Type ) + " . " ) ;
}
pSceneLightList . push_back ( new_light ) ;
}
void X3DImporter : : Postprocess_BuildMaterial ( const X3DNodeElementBase & pNodeElement , aiMaterial * * pMaterial ) const {
// check argument
if ( pMaterial = = nullptr ) throw DeadlyImportError ( " Postprocess_BuildMaterial. pMaterial is nullptr. " ) ;
if ( * pMaterial ! = nullptr ) throw DeadlyImportError ( " Postprocess_BuildMaterial. *pMaterial must be nullptr. " ) ;
* pMaterial = new aiMaterial ;
aiMaterial & taimat = * * pMaterial ; // creating alias for convenience.
// at this point pNodeElement point to <Appearance> node. Walk through childs and add all stored data.
for ( std : : list < X3DNodeElementBase * > : : const_iterator el_it = pNodeElement . Children . begin ( ) ; el_it ! = pNodeElement . Children . end ( ) ; + + el_it ) {
if ( ( * el_it ) - > Type = = X3DElemType : : ENET_Material ) {
aiColor3D tcol3 ;
float tvalf ;
X3DNodeElementMaterial & tnemat = * ( ( X3DNodeElementMaterial * ) * el_it ) ;
tcol3 . r = tnemat . AmbientIntensity , tcol3 . g = tnemat . AmbientIntensity , tcol3 . b = tnemat . AmbientIntensity ;
taimat . AddProperty ( & tcol3 , 1 , AI_MATKEY_COLOR_AMBIENT ) ;
taimat . AddProperty ( & tnemat . DiffuseColor , 1 , AI_MATKEY_COLOR_DIFFUSE ) ;
taimat . AddProperty ( & tnemat . EmissiveColor , 1 , AI_MATKEY_COLOR_EMISSIVE ) ;
taimat . AddProperty ( & tnemat . SpecularColor , 1 , AI_MATKEY_COLOR_SPECULAR ) ;
tvalf = 1 ;
taimat . AddProperty ( & tvalf , 1 , AI_MATKEY_SHININESS_STRENGTH ) ;
taimat . AddProperty ( & tnemat . Shininess , 1 , AI_MATKEY_SHININESS ) ;
tvalf = 1.0f - tnemat . Transparency ;
taimat . AddProperty ( & tvalf , 1 , AI_MATKEY_OPACITY ) ;
} // if((*el_it)->Type == X3DElemType::ENET_Material)
else if ( ( * el_it ) - > Type = = X3DElemType : : ENET_ImageTexture ) {
X3DNodeElementImageTexture & tnetex = * ( ( X3DNodeElementImageTexture * ) * el_it ) ;
aiString url_str ( tnetex . URL . c_str ( ) ) ;
int mode = aiTextureOp_Multiply ;
taimat . AddProperty ( & url_str , AI_MATKEY_TEXTURE_DIFFUSE ( 0 ) ) ;
taimat . AddProperty ( & tnetex . RepeatS , 1 , AI_MATKEY_MAPPINGMODE_U_DIFFUSE ( 0 ) ) ;
taimat . AddProperty ( & tnetex . RepeatT , 1 , AI_MATKEY_MAPPINGMODE_V_DIFFUSE ( 0 ) ) ;
taimat . AddProperty ( & mode , 1 , AI_MATKEY_TEXOP_DIFFUSE ( 0 ) ) ;
} // else if((*el_it)->Type == X3DElemType::ENET_ImageTexture)
else if ( ( * el_it ) - > Type = = X3DElemType : : ENET_TextureTransform ) {
aiUVTransform trans ;
X3DNodeElementTextureTransform & tnetextr = * ( ( X3DNodeElementTextureTransform * ) * el_it ) ;
trans . mTranslation = tnetextr . Translation - tnetextr . Center ;
trans . mScaling = tnetextr . Scale ;
trans . mRotation = tnetextr . Rotation ;
taimat . AddProperty ( & trans , 1 , AI_MATKEY_UVTRANSFORM_DIFFUSE ( 0 ) ) ;
} // else if((*el_it)->Type == X3DElemType::ENET_TextureTransform)
} // for(std::list<X3DNodeElementBase*>::const_iterator el_it = pNodeElement.Children.begin(); el_it != pNodeElement.Children.end(); el_it++)
}
void X3DImporter : : Postprocess_BuildMesh ( const X3DNodeElementBase & pNodeElement , aiMesh * * pMesh ) const {
// check argument
if ( pMesh = = nullptr ) throw DeadlyImportError ( " Postprocess_BuildMesh. pMesh is nullptr. " ) ;
if ( * pMesh ! = nullptr ) throw DeadlyImportError ( " Postprocess_BuildMesh. *pMesh must be nullptr. " ) ;
/************************************************************************************************************************************/
/************************************************************ Geometry2D ************************************************************/
/************************************************************************************************************************************/
if ( ( pNodeElement . Type = = X3DElemType : : ENET_Arc2D ) | | ( pNodeElement . Type = = X3DElemType : : ENET_ArcClose2D ) | |
( pNodeElement . Type = = X3DElemType : : ENET_Circle2D ) | | ( pNodeElement . Type = = X3DElemType : : ENET_Disk2D ) | |
( pNodeElement . Type = = X3DElemType : : ENET_Polyline2D ) | | ( pNodeElement . Type = = X3DElemType : : ENET_Polypoint2D ) | |
( pNodeElement . Type = = X3DElemType : : ENET_Rectangle2D ) | | ( pNodeElement . Type = = X3DElemType : : ENET_TriangleSet2D ) ) {
X3DNodeElementGeometry2D & tnemesh = * ( ( X3DNodeElementGeometry2D * ) & pNodeElement ) ; // create alias for convenience
std : : vector < aiVector3D > tarr ;
tarr . reserve ( tnemesh . Vertices . size ( ) ) ;
for ( std : : list < aiVector3D > : : iterator it = tnemesh . Vertices . begin ( ) ; it ! = tnemesh . Vertices . end ( ) ; + + it )
tarr . push_back ( * it ) ;
* pMesh = StandardShapes : : MakeMesh ( tarr , static_cast < unsigned int > ( tnemesh . NumIndices ) ) ; // create mesh from vertices using Assimp help.
return ; // mesh is build, nothing to do anymore.
}
/************************************************************************************************************************************/
/************************************************************ Geometry3D ************************************************************/
/************************************************************************************************************************************/
//
// Predefined figures
//
if ( ( pNodeElement . Type = = X3DElemType : : ENET_Box ) | | ( pNodeElement . Type = = X3DElemType : : ENET_Cone ) | |
( pNodeElement . Type = = X3DElemType : : ENET_Cylinder ) | | ( pNodeElement . Type = = X3DElemType : : ENET_Sphere ) ) {
X3DNodeElementGeometry3D & tnemesh = * ( ( X3DNodeElementGeometry3D * ) & pNodeElement ) ; // create alias for convenience
std : : vector < aiVector3D > tarr ;
tarr . reserve ( tnemesh . Vertices . size ( ) ) ;
for ( std : : list < aiVector3D > : : iterator it = tnemesh . Vertices . begin ( ) ; it ! = tnemesh . Vertices . end ( ) ; + + it )
tarr . push_back ( * it ) ;
* pMesh = StandardShapes : : MakeMesh ( tarr , static_cast < unsigned int > ( tnemesh . NumIndices ) ) ; // create mesh from vertices using Assimp help.
return ; // mesh is build, nothing to do anymore.
}
//
// Parametric figures
//
if ( pNodeElement . Type = = X3DElemType : : ENET_ElevationGrid ) {
X3DNodeElementElevationGrid & tnemesh = * ( ( X3DNodeElementElevationGrid * ) & pNodeElement ) ; // create alias for convenience
// at first create mesh from existing vertices.
* pMesh = X3DGeoHelper : : make_mesh ( tnemesh . CoordIdx , tnemesh . Vertices ) ;
// copy additional information from children
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Color )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColor * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_ColorRGBA )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColorRGBA * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Normal )
X3DGeoHelper : : add_normal ( * * pMesh , ( ( X3DNodeElementNormal * ) * ch_it ) - > Value , tnemesh . NormalPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_TextureCoordinate )
X3DGeoHelper : : add_tex_coord ( * * pMesh , ( ( X3DNodeElementTextureCoordinate * ) * ch_it ) - > Value ) ;
else
throw DeadlyImportError ( " Postprocess_BuildMesh. Unknown child of ElevationGrid: " + ai_to_string ( ( * ch_it ) - > Type ) + " . " ) ;
} // for(std::list<X3DNodeElementBase*>::iterator ch_it = tnemesh.Children.begin(); ch_it != tnemesh.Children.end(); ++ch_it)
return ; // mesh is build, nothing to do anymore.
} // if(pNodeElement.Type == X3DElemType::ENET_ElevationGrid)
//
// Indexed primitives sets
//
if ( pNodeElement . Type = = X3DElemType : : ENET_IndexedFaceSet ) {
X3DNodeElementIndexedSet & tnemesh = * ( ( X3DNodeElementIndexedSet * ) & pNodeElement ) ; // create alias for convenience
// at first search for <Coordinate> node and create mesh.
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
* pMesh = X3DGeoHelper : : make_mesh ( tnemesh . CoordIndex , ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value ) ;
}
}
// copy additional information from children
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Color )
X3DGeoHelper : : add_color ( * * pMesh , tnemesh . CoordIndex , tnemesh . ColorIndex , ( ( X3DNodeElementColor * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_ColorRGBA )
X3DGeoHelper : : add_color ( * * pMesh , tnemesh . CoordIndex , tnemesh . ColorIndex , ( ( X3DNodeElementColorRGBA * ) * ch_it ) - > Value ,
tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
} // skip because already read when mesh created.
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Normal )
X3DGeoHelper : : add_normal ( * * pMesh , tnemesh . CoordIndex , tnemesh . NormalIndex , ( ( X3DNodeElementNormal * ) * ch_it ) - > Value ,
tnemesh . NormalPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_TextureCoordinate )
X3DGeoHelper : : add_tex_coord ( * * pMesh , tnemesh . CoordIndex , tnemesh . TexCoordIndex , ( ( X3DNodeElementTextureCoordinate * ) * ch_it ) - > Value ) ;
else
throw DeadlyImportError ( " Postprocess_BuildMesh. Unknown child of IndexedFaceSet: " + ai_to_string ( ( * ch_it ) - > Type ) + " . " ) ;
} // for(std::list<X3DNodeElementBase*>::iterator ch_it = tnemesh.Children.begin(); ch_it != tnemesh.Children.end(); ++ch_it)
return ; // mesh is build, nothing to do anymore.
} // if(pNodeElement.Type == X3DElemType::ENET_IndexedFaceSet)
if ( pNodeElement . Type = = X3DElemType : : ENET_IndexedLineSet ) {
X3DNodeElementIndexedSet & tnemesh = * ( ( X3DNodeElementIndexedSet * ) & pNodeElement ) ; // create alias for convenience
// at first search for <Coordinate> node and create mesh.
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
* pMesh = X3DGeoHelper : : make_mesh ( tnemesh . CoordIndex , ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value ) ;
}
}
// copy additional information from children
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
ai_assert ( * pMesh ) ;
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Color )
X3DGeoHelper : : add_color ( * * pMesh , tnemesh . CoordIndex , tnemesh . ColorIndex , ( ( X3DNodeElementColor * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_ColorRGBA )
X3DGeoHelper : : add_color ( * * pMesh , tnemesh . CoordIndex , tnemesh . ColorIndex , ( ( X3DNodeElementColorRGBA * ) * ch_it ) - > Value ,
tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
} // skip because already read when mesh created.
else
throw DeadlyImportError ( " Postprocess_BuildMesh. Unknown child of IndexedLineSet: " + ai_to_string ( ( * ch_it ) - > Type ) + " . " ) ;
} // for(std::list<X3DNodeElementBase*>::iterator ch_it = tnemesh.Children.begin(); ch_it != tnemesh.Children.end(); ++ch_it)
return ; // mesh is build, nothing to do anymore.
} // if(pNodeElement.Type == X3DElemType::ENET_IndexedLineSet)
if ( ( pNodeElement . Type = = X3DElemType : : ENET_IndexedTriangleSet ) | |
( pNodeElement . Type = = X3DElemType : : ENET_IndexedTriangleFanSet ) | |
( pNodeElement . Type = = X3DElemType : : ENET_IndexedTriangleStripSet ) ) {
X3DNodeElementIndexedSet & tnemesh = * ( ( X3DNodeElementIndexedSet * ) & pNodeElement ) ; // create alias for convenience
// at first search for <Coordinate> node and create mesh.
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
* pMesh = X3DGeoHelper : : make_mesh ( tnemesh . CoordIndex , ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value ) ;
}
}
// copy additional information from children
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
ai_assert ( * pMesh ) ;
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Color )
X3DGeoHelper : : add_color ( * * pMesh , tnemesh . CoordIndex , tnemesh . ColorIndex , ( ( X3DNodeElementColor * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_ColorRGBA )
X3DGeoHelper : : add_color ( * * pMesh , tnemesh . CoordIndex , tnemesh . ColorIndex , ( ( X3DNodeElementColorRGBA * ) * ch_it ) - > Value ,
tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
} // skip because already read when mesh created.
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Normal )
X3DGeoHelper : : add_normal ( * * pMesh , tnemesh . CoordIndex , tnemesh . NormalIndex , ( ( X3DNodeElementNormal * ) * ch_it ) - > Value ,
tnemesh . NormalPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_TextureCoordinate )
X3DGeoHelper : : add_tex_coord ( * * pMesh , tnemesh . CoordIndex , tnemesh . TexCoordIndex , ( ( X3DNodeElementTextureCoordinate * ) * ch_it ) - > Value ) ;
else
throw DeadlyImportError ( " Postprocess_BuildMesh. Unknown child of IndexedTriangleSet or IndexedTriangleFanSet, or \
IndexedTriangleStripSet : " +
ai_to_string ( ( * ch_it ) - > Type ) + " . " ) ;
} // for(std::list<X3DNodeElementBase*>::iterator ch_it = tnemesh.Children.begin(); ch_it != tnemesh.Children.end(); ++ch_it)
return ; // mesh is build, nothing to do anymore.
} // if((pNodeElement.Type == X3DElemType::ENET_IndexedTriangleFanSet) || (pNodeElement.Type == X3DElemType::ENET_IndexedTriangleStripSet))
if ( pNodeElement . Type = = X3DElemType : : ENET_Extrusion ) {
X3DNodeElementIndexedSet & tnemesh = * ( ( X3DNodeElementIndexedSet * ) & pNodeElement ) ; // create alias for convenience
* pMesh = X3DGeoHelper : : make_mesh ( tnemesh . CoordIndex , tnemesh . Vertices ) ;
return ; // mesh is build, nothing to do anymore.
} // if(pNodeElement.Type == X3DElemType::ENET_Extrusion)
//
// Primitives sets
//
if ( pNodeElement . Type = = X3DElemType : : ENET_PointSet ) {
X3DNodeElementSet & tnemesh = * ( ( X3DNodeElementSet * ) & pNodeElement ) ; // create alias for convenience
// at first search for <Coordinate> node and create mesh.
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
std : : vector < aiVector3D > vec_copy ;
vec_copy . reserve ( ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value . size ( ) ) ;
for ( std : : list < aiVector3D > : : const_iterator it = ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value . begin ( ) ;
it ! = ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value . end ( ) ; + + it ) {
vec_copy . push_back ( * it ) ;
}
* pMesh = StandardShapes : : MakeMesh ( vec_copy , 1 ) ;
}
}
// copy additional information from children
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
ai_assert ( * pMesh ) ;
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Color )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColor * ) * ch_it ) - > Value , true ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_ColorRGBA )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColorRGBA * ) * ch_it ) - > Value , true ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
} // skip because already read when mesh created.
else
throw DeadlyImportError ( " Postprocess_BuildMesh. Unknown child of PointSet: " + ai_to_string ( ( * ch_it ) - > Type ) + " . " ) ;
} // for(std::list<X3DNodeElementBase*>::iterator ch_it = tnemesh.Children.begin(); ch_it != tnemesh.Children.end(); ++ch_it)
return ; // mesh is build, nothing to do anymore.
} // if(pNodeElement.Type == X3DElemType::ENET_PointSet)
if ( pNodeElement . Type = = X3DElemType : : ENET_LineSet ) {
X3DNodeElementSet & tnemesh = * ( ( X3DNodeElementSet * ) & pNodeElement ) ; // create alias for convenience
// at first search for <Coordinate> node and create mesh.
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
* pMesh = X3DGeoHelper : : make_mesh ( tnemesh . CoordIndex , ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value ) ;
}
}
// copy additional information from children
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
ai_assert ( * pMesh ) ;
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Color )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColor * ) * ch_it ) - > Value , true ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_ColorRGBA )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColorRGBA * ) * ch_it ) - > Value , true ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
} // skip because already read when mesh created.
else
throw DeadlyImportError ( " Postprocess_BuildMesh. Unknown child of LineSet: " + ai_to_string ( ( * ch_it ) - > Type ) + " . " ) ;
} // for(std::list<X3DNodeElementBase*>::iterator ch_it = tnemesh.Children.begin(); ch_it != tnemesh.Children.end(); ++ch_it)
return ; // mesh is build, nothing to do anymore.
} // if(pNodeElement.Type == X3DElemType::ENET_LineSet)
if ( pNodeElement . Type = = X3DElemType : : ENET_TriangleFanSet ) {
X3DNodeElementSet & tnemesh = * ( ( X3DNodeElementSet * ) & pNodeElement ) ; // create alias for convenience
// at first search for <Coordinate> node and create mesh.
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
* pMesh = X3DGeoHelper : : make_mesh ( tnemesh . CoordIndex , ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value ) ;
}
}
// copy additional information from children
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( nullptr = = * pMesh ) {
break ;
}
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Color )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColor * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_ColorRGBA )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColorRGBA * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
} // skip because already read when mesh created.
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Normal )
X3DGeoHelper : : add_normal ( * * pMesh , tnemesh . CoordIndex , tnemesh . NormalIndex , ( ( X3DNodeElementNormal * ) * ch_it ) - > Value ,
tnemesh . NormalPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_TextureCoordinate )
X3DGeoHelper : : add_tex_coord ( * * pMesh , tnemesh . CoordIndex , tnemesh . TexCoordIndex , ( ( X3DNodeElementTextureCoordinate * ) * ch_it ) - > Value ) ;
else
throw DeadlyImportError ( " Postprocess_BuildMesh. Unknown child of TrianlgeFanSet: " + ai_to_string ( ( * ch_it ) - > Type ) + " . " ) ;
} // for(std::list<X3DNodeElementBase*>::iterator ch_it = tnemesh.Children.begin(); ch_it != tnemesh.Children.end(); ++ch_it)
return ; // mesh is build, nothing to do anymore.
} // if(pNodeElement.Type == X3DElemType::ENET_TriangleFanSet)
if ( pNodeElement . Type = = X3DElemType : : ENET_TriangleSet ) {
X3DNodeElementSet & tnemesh = * ( ( X3DNodeElementSet * ) & pNodeElement ) ; // create alias for convenience
// at first search for <Coordinate> node and create mesh.
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
std : : vector < aiVector3D > vec_copy ;
vec_copy . reserve ( ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value . size ( ) ) ;
for ( std : : list < aiVector3D > : : const_iterator it = ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value . begin ( ) ;
it ! = ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value . end ( ) ; + + it ) {
vec_copy . push_back ( * it ) ;
}
* pMesh = StandardShapes : : MakeMesh ( vec_copy , 3 ) ;
}
}
// copy additional information from children
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
ai_assert ( * pMesh ) ;
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Color )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColor * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_ColorRGBA )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColorRGBA * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
} // skip because already read when mesh created.
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Normal )
X3DGeoHelper : : add_normal ( * * pMesh , tnemesh . CoordIndex , tnemesh . NormalIndex , ( ( X3DNodeElementNormal * ) * ch_it ) - > Value ,
tnemesh . NormalPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_TextureCoordinate )
X3DGeoHelper : : add_tex_coord ( * * pMesh , tnemesh . CoordIndex , tnemesh . TexCoordIndex , ( ( X3DNodeElementTextureCoordinate * ) * ch_it ) - > Value ) ;
else
throw DeadlyImportError ( " Postprocess_BuildMesh. Unknown child of TrianlgeSet: " + ai_to_string ( ( * ch_it ) - > Type ) + " . " ) ;
} // for(std::list<X3DNodeElementBase*>::iterator ch_it = tnemesh.Children.begin(); ch_it != tnemesh.Children.end(); ++ch_it)
return ; // mesh is build, nothing to do anymore.
} // if(pNodeElement.Type == X3DElemType::ENET_TriangleSet)
if ( pNodeElement . Type = = X3DElemType : : ENET_TriangleStripSet ) {
X3DNodeElementSet & tnemesh = * ( ( X3DNodeElementSet * ) & pNodeElement ) ; // create alias for convenience
// at first search for <Coordinate> node and create mesh.
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
* pMesh = X3DGeoHelper : : make_mesh ( tnemesh . CoordIndex , ( ( X3DNodeElementCoordinate * ) * ch_it ) - > Value ) ;
}
}
// copy additional information from children
for ( std : : list < X3DNodeElementBase * > : : iterator ch_it = tnemesh . Children . begin ( ) ; ch_it ! = tnemesh . Children . end ( ) ; + + ch_it ) {
ai_assert ( * pMesh ) ;
if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Color )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColor * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_ColorRGBA )
X3DGeoHelper : : add_color ( * * pMesh , ( ( X3DNodeElementColorRGBA * ) * ch_it ) - > Value , tnemesh . ColorPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Coordinate ) {
} // skip because already read when mesh created.
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_Normal )
X3DGeoHelper : : add_normal ( * * pMesh , tnemesh . CoordIndex , tnemesh . NormalIndex , ( ( X3DNodeElementNormal * ) * ch_it ) - > Value ,
tnemesh . NormalPerVertex ) ;
else if ( ( * ch_it ) - > Type = = X3DElemType : : ENET_TextureCoordinate )
X3DGeoHelper : : add_tex_coord ( * * pMesh , tnemesh . CoordIndex , tnemesh . TexCoordIndex , ( ( X3DNodeElementTextureCoordinate * ) * ch_it ) - > Value ) ;
else
throw DeadlyImportError ( " Postprocess_BuildMesh. Unknown child of TriangleStripSet: " + ai_to_string ( ( * ch_it ) - > Type ) + " . " ) ;
} // for(std::list<X3DNodeElementBase*>::iterator ch_it = tnemesh.Children.begin(); ch_it != tnemesh.Children.end(); ++ch_it)
return ; // mesh is build, nothing to do anymore.
} // if(pNodeElement.Type == X3DElemType::ENET_TriangleStripSet)
throw DeadlyImportError ( " Postprocess_BuildMesh. Unknown mesh type: " + ai_to_string ( pNodeElement . Type ) + " . " ) ;
}
void X3DImporter : : Postprocess_BuildNode ( const X3DNodeElementBase & pNodeElement , aiNode & pSceneNode , std : : list < aiMesh * > & pSceneMeshList ,
std : : list < aiMaterial * > & pSceneMaterialList , std : : list < aiLight * > & pSceneLightList ) const {
std : : list < X3DNodeElementBase * > : : const_iterator chit_begin = pNodeElement . Children . begin ( ) ;
std : : list < X3DNodeElementBase * > : : const_iterator chit_end = pNodeElement . Children . end ( ) ;
std : : list < aiNode * > SceneNode_Child ;
std : : list < unsigned int > SceneNode_Mesh ;
// At first read all metadata
Postprocess_CollectMetadata ( pNodeElement , pSceneNode ) ;
// check if we have deal with grouping node. Which can contain transformation or switch
if ( pNodeElement . Type = = X3DElemType : : ENET_Group ) {
const X3DNodeElementGroup & tne_group = * ( ( X3DNodeElementGroup * ) & pNodeElement ) ; // create alias for convenience
pSceneNode . mTransformation = tne_group . Transformation ;
if ( tne_group . UseChoice ) {
// If Choice is less than zero or greater than the number of nodes in the children field, nothing is chosen.
if ( ( tne_group . Choice < 0 ) | | ( ( size_t ) tne_group . Choice > = pNodeElement . Children . size ( ) ) ) {
chit_begin = pNodeElement . Children . end ( ) ;
chit_end = pNodeElement . Children . end ( ) ;
} else {
for ( size_t i = 0 ; i < ( size_t ) tne_group . Choice ; i + + )
+ + chit_begin ; // forward iterator to chosen node.
chit_end = chit_begin ;
+ + chit_end ; // point end iterator to next element after chosen node.
}
} // if(tne_group.UseChoice)
} // if(pNodeElement.Type == X3DElemType::ENET_Group)
// Reserve memory for fast access and check children.
for ( std : : list < X3DNodeElementBase * > : : const_iterator it = chit_begin ; it ! = chit_end ; + + it ) { // in this loop we do not read metadata because it's already read at begin.
if ( ( * it ) - > Type = = X3DElemType : : ENET_Group ) {
// if child is group then create new node and do recursive call.
aiNode * new_node = new aiNode ;
new_node - > mName = ( * it ) - > ID ;
new_node - > mParent = & pSceneNode ;
SceneNode_Child . push_back ( new_node ) ;
Postprocess_BuildNode ( * * it , * new_node , pSceneMeshList , pSceneMaterialList , pSceneLightList ) ;
} else if ( ( * it ) - > Type = = X3DElemType : : ENET_Shape ) {
// shape can contain only one geometry and one appearance nodes.
Postprocess_BuildShape ( * ( ( X3DNodeElementShape * ) * it ) , SceneNode_Mesh , pSceneMeshList , pSceneMaterialList ) ;
} else if ( ( ( * it ) - > Type = = X3DElemType : : ENET_DirectionalLight ) | | ( ( * it ) - > Type = = X3DElemType : : ENET_PointLight ) | |
( ( * it ) - > Type = = X3DElemType : : ENET_SpotLight ) ) {
Postprocess_BuildLight ( * ( ( X3DNodeElementLight * ) * it ) , pSceneLightList ) ;
} else if ( ! PostprocessHelper_ElementIsMetadata ( ( * it ) - > Type ) ) // skip metadata
{
throw DeadlyImportError ( " Postprocess_BuildNode. Unknown type: " + ai_to_string ( ( * it ) - > Type ) + " . " ) ;
}
} // for(std::list<X3DNodeElementBase*>::const_iterator it = chit_begin; it != chit_end; it++)
// copy data about children and meshes to aiNode.
if ( ! SceneNode_Child . empty ( ) ) {
std : : list < aiNode * > : : const_iterator it = SceneNode_Child . begin ( ) ;
pSceneNode . mNumChildren = static_cast < unsigned int > ( SceneNode_Child . size ( ) ) ;
pSceneNode . mChildren = new aiNode * [ pSceneNode . mNumChildren ] ;
for ( size_t i = 0 ; i < pSceneNode . mNumChildren ; i + + )
pSceneNode . mChildren [ i ] = * it + + ;
}
if ( ! SceneNode_Mesh . empty ( ) ) {
std : : list < unsigned int > : : const_iterator it = SceneNode_Mesh . begin ( ) ;
pSceneNode . mNumMeshes = static_cast < unsigned int > ( SceneNode_Mesh . size ( ) ) ;
pSceneNode . mMeshes = new unsigned int [ pSceneNode . mNumMeshes ] ;
for ( size_t i = 0 ; i < pSceneNode . mNumMeshes ; i + + )
pSceneNode . mMeshes [ i ] = * it + + ;
}
// that's all. return to previous deals
}
void X3DImporter : : Postprocess_BuildShape ( const X3DNodeElementShape & pShapeNodeElement , std : : list < unsigned int > & pNodeMeshInd ,
std : : list < aiMesh * > & pSceneMeshList , std : : list < aiMaterial * > & pSceneMaterialList ) const {
aiMaterial * tmat = nullptr ;
aiMesh * tmesh = nullptr ;
X3DElemType mesh_type = X3DElemType : : ENET_Invalid ;
unsigned int mat_ind = 0 ;
for ( std : : list < X3DNodeElementBase * > : : const_iterator it = pShapeNodeElement . Children . begin ( ) ; it ! = pShapeNodeElement . Children . end ( ) ; + + it ) {
if ( PostprocessHelper_ElementIsMesh ( ( * it ) - > Type ) ) {
Postprocess_BuildMesh ( * * it , & tmesh ) ;
if ( tmesh ! = nullptr ) {
// if mesh successfully built then add data about it to arrays
pNodeMeshInd . push_back ( static_cast < unsigned int > ( pSceneMeshList . size ( ) ) ) ;
pSceneMeshList . push_back ( tmesh ) ;
// keep mesh type. Need above for texture coordinate generation.
mesh_type = ( * it ) - > Type ;
}
} else if ( ( * it ) - > Type = = X3DElemType : : ENET_Appearance ) {
Postprocess_BuildMaterial ( * * it , & tmat ) ;
if ( tmat ! = nullptr ) {
// if material successfully built then add data about it to array
mat_ind = static_cast < unsigned int > ( pSceneMaterialList . size ( ) ) ;
pSceneMaterialList . push_back ( tmat ) ;
}
}
} // for(std::list<X3DNodeElementBase*>::const_iterator it = pShapeNodeElement.Children.begin(); it != pShapeNodeElement.Children.end(); it++)
// associate read material with read mesh.
if ( ( tmesh ! = nullptr ) & & ( tmat ! = nullptr ) ) {
tmesh - > mMaterialIndex = mat_ind ;
// Check texture mapping. If material has texture but mesh has no texture coordinate then try to ask Assimp to generate texture coordinates.
if ( ( tmat - > GetTextureCount ( aiTextureType_DIFFUSE ) ! = 0 ) & & ! tmesh - > HasTextureCoords ( 0 ) ) {
int32_t tm ;
aiVector3D tvec3 ;
switch ( mesh_type ) {
case X3DElemType : : ENET_Box :
tm = aiTextureMapping_BOX ;
break ;
case X3DElemType : : ENET_Cone :
case X3DElemType : : ENET_Cylinder :
tm = aiTextureMapping_CYLINDER ;
break ;
case X3DElemType : : ENET_Sphere :
tm = aiTextureMapping_SPHERE ;
break ;
default :
tm = aiTextureMapping_PLANE ;
break ;
} // switch(mesh_type)
tmat - > AddProperty ( & tm , 1 , AI_MATKEY_MAPPING_DIFFUSE ( 0 ) ) ;
} // if((tmat->GetTextureCount(aiTextureType_DIFFUSE) != 0) && !tmesh->HasTextureCoords(0))
} // if((tmesh != nullptr) && (tmat != nullptr))
}
void X3DImporter : : Postprocess_CollectMetadata ( const X3DNodeElementBase & pNodeElement , aiNode & pSceneNode ) const {
std : : list < X3DNodeElementBase * > meta_list ;
size_t meta_idx ;
PostprocessHelper_CollectMetadata ( pNodeElement , meta_list ) ; // find metadata in current node element.
if ( ! meta_list . empty ( ) ) {
if ( pSceneNode . mMetaData ! = nullptr ) {
throw DeadlyImportError ( " Postprocess. MetaData member in node are not nullptr. Something went wrong. " ) ;
}
// copy collected metadata to output node.
pSceneNode . mMetaData = aiMetadata : : Alloc ( static_cast < unsigned int > ( meta_list . size ( ) ) ) ;
meta_idx = 0 ;
for ( std : : list < X3DNodeElementBase * > : : const_iterator it = meta_list . begin ( ) ; it ! = meta_list . end ( ) ; + + it , + + meta_idx ) {
X3DNodeElementMeta * cur_meta = ( X3DNodeElementMeta * ) * it ;
// due to limitations we can add only first element of value list.
// Add an element according to its type.
if ( ( * it ) - > Type = = X3DElemType : : ENET_MetaBoolean ) {
if ( ( ( X3DNodeElementMetaBoolean * ) cur_meta ) - > Value . size ( ) > 0 )
2021-09-15 12:49:46 +00:00
pSceneNode . mMetaData - > Set ( static_cast < unsigned int > ( meta_idx ) , cur_meta - > Name , * ( ( ( X3DNodeElementMetaBoolean * ) cur_meta ) - > Value . begin ( ) ) = = true ) ;
2021-09-12 09:37:33 +00:00
} else if ( ( * it ) - > Type = = X3DElemType : : ENET_MetaDouble ) {
if ( ( ( X3DNodeElementMetaDouble * ) cur_meta ) - > Value . size ( ) > 0 )
pSceneNode . mMetaData - > Set ( static_cast < unsigned int > ( meta_idx ) , cur_meta - > Name , ( float ) * ( ( ( X3DNodeElementMetaDouble * ) cur_meta ) - > Value . begin ( ) ) ) ;
} else if ( ( * it ) - > Type = = X3DElemType : : ENET_MetaFloat ) {
if ( ( ( X3DNodeElementMetaFloat * ) cur_meta ) - > Value . size ( ) > 0 )
pSceneNode . mMetaData - > Set ( static_cast < unsigned int > ( meta_idx ) , cur_meta - > Name , * ( ( ( X3DNodeElementMetaFloat * ) cur_meta ) - > Value . begin ( ) ) ) ;
} else if ( ( * it ) - > Type = = X3DElemType : : ENET_MetaInteger ) {
if ( ( ( X3DNodeElementMetaInt * ) cur_meta ) - > Value . size ( ) > 0 )
pSceneNode . mMetaData - > Set ( static_cast < unsigned int > ( meta_idx ) , cur_meta - > Name , * ( ( ( X3DNodeElementMetaInt * ) cur_meta ) - > Value . begin ( ) ) ) ;
} else if ( ( * it ) - > Type = = X3DElemType : : ENET_MetaString ) {
if ( ( ( X3DNodeElementMetaString * ) cur_meta ) - > Value . size ( ) > 0 ) {
aiString tstr ( ( ( X3DNodeElementMetaString * ) cur_meta ) - > Value . begin ( ) - > data ( ) ) ;
pSceneNode . mMetaData - > Set ( static_cast < unsigned int > ( meta_idx ) , cur_meta - > Name , tstr ) ;
}
} else {
throw DeadlyImportError ( " Postprocess. Unknown metadata type. " ) ;
} // if((*it)->Type == X3DElemType::ENET_Meta*) else
} // for(std::list<X3DNodeElementBase*>::const_iterator it = meta_list.begin(); it != meta_list.end(); it++)
} // if( !meta_list.empty() )
}
} // namespace Assimp
# endif // !ASSIMP_BUILD_NO_X3D_IMPORTER