OpenSceneGraph/src/osg/Geometry.cpp

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/* -*-c++-*- OpenSceneGraph - Copyright (C) 1998-2005 Robert Osfield
*
* This library is open source and may be redistributed and/or modified under
* the terms of the OpenSceneGraph Public License (OSGPL) version 0.0 or
* (at your option) any later version. The full license is in LICENSE file
* included with this distribution, and on the openscenegraph.org website.
*
* This library 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
* OpenSceneGraph Public License for more details.
*/
#include <osg/Geometry>
#include <osg/Notify>
using namespace osg;
const Geometry::ArrayData Geometry::s_InvalidArrayData;
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#if 1
class DrawVertex
{
public:
DrawVertex(const Array* vertices,const IndexArray* indices):
_vertices(vertices),
_indices(indices)
{
_verticesType = _vertices?_vertices->getType():Array::ArrayType;
_indicesType = _indices?_indices->getType():Array::ArrayType;
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}
inline unsigned int index(unsigned int pos)
{
switch(_indicesType)
{
case(Array::ByteArrayType): return (*static_cast<const ByteArray*>(_indices))[pos];
case(Array::ShortArrayType): return (*static_cast<const ShortArray*>(_indices))[pos];
case(Array::IntArrayType): return (*static_cast<const IntArray*>(_indices))[pos];
case(Array::UByteArrayType): return (*static_cast<const UByteArray*>(_indices))[pos];
case(Array::UShortArrayType): return (*static_cast<const UShortArray*>(_indices))[pos];
case(Array::UIntArrayType): return (*static_cast<const UIntArray*>(_indices))[pos];
default: return 0;
}
}
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inline void operator () (unsigned int pos)
{
if (_indices) pos = index(pos);
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switch(_verticesType)
{
case(Array::Vec3ArrayType):
apply((*(static_cast<const Vec3Array*>(_vertices)))[pos]);
break;
case(Array::Vec2ArrayType):
apply((*(static_cast<const Vec2Array*>(_vertices)))[pos]);
break;
case(Array::Vec4ArrayType):
apply((*(static_cast<const Vec4Array*>(_vertices)))[pos]);
break;
default:
break;
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}
}
inline void apply(const Vec2& v) { glVertex2fv(v.ptr()); }
inline void apply(const Vec3& v) { glVertex3fv(v.ptr()); }
inline void apply(const Vec4& v) { glVertex4fv(v.ptr()); }
const Array* _vertices;
const IndexArray* _indices;
Array::Type _verticesType;
Array::Type _indicesType;
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};
#else
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class DrawVertex : public osg::ConstValueVisitor
{
public:
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DrawVertex(const Array* vertices,const IndexArray* indices):
_vertices(vertices),
_indices(indices) {}
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inline void operator () (unsigned int pos)
{
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if (_indices) _vertices->accept(_indices->index(pos),*this);
else _vertices->accept(pos,*this);
}
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virtual void apply(const Vec2& v) { glVertex2fv(v.ptr()); }
virtual void apply(const Vec3& v) { glVertex3fv(v.ptr()); }
virtual void apply(const Vec4& v) { glVertex4fv(v.ptr()); }
const Array* _vertices;
const IndexArray* _indices;
};
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#endif
class DrawNormal
{
public:
DrawNormal(const Array* normals,const IndexArray* indices):
_normals(normals),
_indices(indices)
{
_normalsType = normals?normals->getType():Array::ArrayType;
}
void operator () (unsigned int pos)
{
switch(_normalsType)
{
case (Array::Vec3ArrayType):
{
const Vec3Array& normals = *static_cast<const Vec3Array*>(_normals);
if (_indices) glNormal3fv(normals[_indices->index(pos)].ptr());
else glNormal3fv(normals[pos].ptr());
}
break;
case (Array::Vec3sArrayType):
{
const Vec3sArray& normals = *static_cast<const Vec3sArray*>(_normals);
if (_indices) glNormal3sv(normals[_indices->index(pos)].ptr());
else glNormal3sv(normals[pos].ptr());
}
break;
case (Array::Vec4sArrayType):
{
const Vec4sArray& normals = *static_cast<const Vec4sArray*>(_normals);
if (_indices) glNormal3sv(normals[_indices->index(pos)].ptr());
else glNormal3sv(normals[pos].ptr());
}
break;
case (Array::Vec3bArrayType):
{
const Vec3bArray& normals = *static_cast<const Vec3bArray*>(_normals);
if (_indices) glNormal3bv((const GLbyte*)normals[_indices->index(pos)].ptr());
else glNormal3bv((const GLbyte*)normals[pos].ptr());
}
break;
case (Array::Vec4bArrayType):
{
const Vec4bArray& normals = *static_cast<const Vec4bArray*>(_normals);
if (_indices) glNormal3bv((const GLbyte*)normals[_indices->index(pos)].ptr());
else glNormal3bv((const GLbyte*)normals[pos].ptr());
}
break;
default:
break;
}
}
const Array* _normals;
const IndexArray* _indices;
Array::Type _normalsType;
};
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#if 1
class DrawColor
{
public:
DrawColor(const Array* colors,const IndexArray* indices):
_colors(colors),
_indices(indices)
{
_colorsType = _colors?_colors->getType():Array::ArrayType;
_indicesType = _indices?_indices->getType():Array::ArrayType;
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}
inline unsigned int index(unsigned int pos)
{
switch(_indicesType)
{
case(Array::ByteArrayType): return (*static_cast<const ByteArray*>(_indices))[pos];
case(Array::ShortArrayType): return (*static_cast<const ShortArray*>(_indices))[pos];
case(Array::IntArrayType): return (*static_cast<const IntArray*>(_indices))[pos];
case(Array::UByteArrayType): return (*static_cast<const UByteArray*>(_indices))[pos];
case(Array::UShortArrayType): return (*static_cast<const UShortArray*>(_indices))[pos];
case(Array::UIntArrayType): return (*static_cast<const UIntArray*>(_indices))[pos];
default: return 0;
}
}
inline void operator () (unsigned int pos)
{
if (_indices) pos = index(pos);
switch(_colorsType)
{
case(Array::Vec4ArrayType):
apply((*static_cast<const Vec4Array*>(_colors))[pos]);
break;
case(Array::Vec4ubArrayType):
apply((*static_cast<const Vec4ubArray*>(_colors))[pos]);
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break;
case(Array::Vec3ArrayType):
apply((*static_cast<const Vec3Array*>(_colors))[pos]);
break;
default:
break;
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}
}
inline void apply(const Vec4ub& v) { glColor4ubv(v.ptr()); }
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inline void apply(const Vec3& v) { glColor3fv(v.ptr()); }
inline void apply(const Vec4& v) { glColor4fv(v.ptr()); }
const Array* _colors;
const IndexArray* _indices;
Array::Type _colorsType;
Array::Type _indicesType;
};
#else
class DrawColor : public osg::ConstValueVisitor
{
public:
DrawColor(const Array* colors,const IndexArray* indices):
_colors(colors),
_indices(indices) {}
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inline void operator () (unsigned int pos)
{
if (_indices) _colors->accept(_indices->index(pos),*this);
else _colors->accept(pos,*this);
}
virtual void apply(const UVec4b& v) { glColor4ubv(v.ptr()); }
virtual void apply(const Vec3& v) { glColor3fv(v.ptr()); }
virtual void apply(const Vec4& v) { glColor4fv(v.ptr()); }
const Array* _colors;
const IndexArray* _indices;
};
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#endif
class DrawVertexAttrib : public osg::Referenced, public osg::ConstValueVisitor
{
public:
DrawVertexAttrib(const Drawable::Extensions * extensions,unsigned int vertAttribIndex,GLboolean normalized,const Array* attribcoords,const IndexArray* indices):
_vertAttribIndex(vertAttribIndex),
_normalized(normalized),
_extensions(extensions),
_attribcoords(attribcoords),
_indices(indices),
_index(0) {;}
inline void applyAndIncrement() { operator()(_index++); }
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inline void operator () (unsigned int pos)
{
if (_indices) _attribcoords->accept(_indices->index(pos),*this);
else _attribcoords->accept(pos,*this);
}
virtual void apply(const GLshort& s)
{
_extensions->glVertexAttrib1s( _vertAttribIndex, s );
}
virtual void apply(const GLfloat& f)
{
_extensions->glVertexAttrib1f( _vertAttribIndex, f );
}
virtual void apply(const Vec4ub& v)
{
if( _normalized )
{
_extensions->glVertexAttrib4Nubv( _vertAttribIndex, v.ptr() );
}
else
{
_extensions->glVertexAttrib4ubv( _vertAttribIndex, v.ptr() );
}
}
virtual void apply(const Vec2& v)
{
_extensions->glVertexAttrib2fv( _vertAttribIndex, v.ptr() );
}
virtual void apply(const Vec3& v)
{
_extensions->glVertexAttrib3fv( _vertAttribIndex, v.ptr() );
}
virtual void apply(const Vec4& v)
{
_extensions->glVertexAttrib4fv( _vertAttribIndex, v.ptr() );
}
unsigned int _vertAttribIndex;
GLboolean _normalized;
const Drawable::Extensions* _extensions;
const Array* _attribcoords;
const IndexArray* _indices;
unsigned int _index;
};
class DrawTexCoord : public osg::Referenced, public osg::ConstValueVisitor
{
public:
DrawTexCoord(const Array* texcoords,const IndexArray* indices):
_texcoords(texcoords),
_indices(indices) {}
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inline void operator () (unsigned int pos)
{
if (_indices) _texcoords->accept(_indices->index(pos),*this);
else _texcoords->accept(pos,*this);
}
virtual void apply(const GLfloat& v){ glTexCoord1f(v); }
virtual void apply(const Vec2& v) { glTexCoord2fv(v.ptr()); }
virtual void apply(const Vec3& v) { glTexCoord3fv(v.ptr()); }
virtual void apply(const Vec4& v) { glTexCoord4fv(v.ptr()); }
const Array* _texcoords;
const IndexArray* _indices;
};
class DrawMultiTexCoord : public osg::Referenced, public osg::ConstValueVisitor
{
public:
DrawMultiTexCoord(GLenum target,const Array* texcoords,const IndexArray* indices,
const Drawable::Extensions * extensions):
_target(target),
_texcoords(texcoords),
_indices(indices),
_extensions(extensions) {}
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inline void operator () (unsigned int pos)
{
if (_indices) _texcoords->accept(_indices->index(pos),*this);
else _texcoords->accept(pos,*this);
}
virtual void apply(const GLfloat& v){ _extensions->glMultiTexCoord1f(_target,v); }
virtual void apply(const Vec2& v) { _extensions->glMultiTexCoord2fv(_target,v.ptr()); }
virtual void apply(const Vec3& v) { _extensions->glMultiTexCoord3fv(_target,v.ptr()); }
virtual void apply(const Vec4& v) { _extensions->glMultiTexCoord4fv(_target,v.ptr()); }
GLenum _target;
const Array* _texcoords;
const IndexArray* _indices;
const Drawable::Extensions * _extensions;
};
class DrawSecondaryColor : public osg::ConstValueVisitor
{
public:
DrawSecondaryColor(const Array* colors,const IndexArray* indices,
const Drawable::Extensions * extensions):
_colors(colors),
_indices(indices),
_extensions(extensions)
{}
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inline void operator () (unsigned int pos)
{
if (_indices) _colors->accept(_indices->index(pos),*this);
else _colors->accept(pos,*this);
}
virtual void apply(const Vec4ub& v) { _extensions->glSecondaryColor3ubv(v.ptr()); }
virtual void apply(const Vec3& v) { _extensions->glSecondaryColor3fv(v.ptr()); }
virtual void apply(const Vec4& v) { _extensions->glSecondaryColor3fv(v.ptr()); }
const Array* _colors;
const IndexArray* _indices;
const Drawable::Extensions * _extensions;
};
class DrawFogCoord : public osg::ConstValueVisitor
{
public:
DrawFogCoord(const Array* fogcoords,const IndexArray* indices,const Drawable::Extensions * extensions):
_fogcoords(fogcoords),
_indices(indices),
_extensions(extensions) {}
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inline void operator () (unsigned int pos)
{
if (_indices) _fogcoords->accept(_indices->index(pos),*this);
else _fogcoords->accept(pos,*this);
}
virtual void apply(const GLfloat& v) { _extensions->glFogCoordfv(&v); }
const Array* _fogcoords;
const IndexArray* _indices;
const Drawable::Extensions * _extensions;
};
Geometry::ArrayData::ArrayData(const ArrayData& data,const CopyOp& copyop):
array(copyop(data.array.get())),
indices(dynamic_cast<osg::IndexArray*>(copyop(data.indices.get()))),
binding(data.binding),
normalize(data.normalize),
offset(data.offset)
{
}
Geometry::Vec3ArrayData::Vec3ArrayData(const Vec3ArrayData& data,const CopyOp& copyop):
array(dynamic_cast<osg::Vec3Array*>(copyop(data.array.get()))),
indices(dynamic_cast<osg::IndexArray*>(copyop(data.indices.get()))),
binding(data.binding),
normalize(data.normalize),
offset(data.offset)
{
}
Geometry::Geometry()
{
_fastPath = false;
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_fastPathHint = true;
}
Geometry::Geometry(const Geometry& geometry,const CopyOp& copyop):
Drawable(geometry,copyop),
_vertexData(geometry._vertexData,copyop),
_normalData(geometry._normalData,copyop),
_colorData(geometry._colorData,copyop),
_secondaryColorData(geometry._secondaryColorData,copyop),
_fogCoordData(geometry._fogCoordData,copyop),
_fastPath(geometry._fastPath),
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_fastPathHint(geometry._fastPathHint)
{
for(PrimitiveSetList::const_iterator pitr=geometry._primitives.begin();
pitr!=geometry._primitives.end();
++pitr)
{
PrimitiveSet* primitive = copyop(pitr->get());
if (primitive) _primitives.push_back(primitive);
}
for(ArrayList::const_iterator titr=geometry._texCoordList.begin();
titr!=geometry._texCoordList.end();
++titr)
{
_texCoordList.push_back(*titr);
}
for(ArrayList::const_iterator vitr=geometry._vertexAttribList.begin();
vitr!=geometry._vertexAttribList.end();
++vitr)
{
_vertexAttribList.push_back(*vitr);
}
}
Geometry::~Geometry()
{
// do dirty here to keep the getGLObjectSizeHint() estimate on the ball
dirtyDisplayList();
// no need to delete, all automatically handled by ref_ptr :-)
}
bool Geometry::empty() const
{
if (!_primitives.empty()) return false;
if (!_vertexData.empty()) return false;
if (!_normalData.empty()) return false;
if (!_colorData.empty()) return false;
if (!_secondaryColorData.empty()) return false;
if (!_fogCoordData.empty()) return false;
if (!_texCoordList.empty()) return false;
if (!_vertexAttribList.empty()) return false;
return true;
}
void Geometry::setNormalBinding(AttributeBinding ab)
{
if (_normalData.binding == ab) return;
_normalData.binding = ab;
computeFastPathsUsed();
dirtyDisplayList();
}
void Geometry::setColorBinding(AttributeBinding ab)
{
if (_colorData.binding == ab) return;
_colorData.binding = ab;
computeFastPathsUsed();
dirtyDisplayList();
}
void Geometry::setSecondaryColorBinding(AttributeBinding ab)
{
if (_secondaryColorData.binding == ab) return;
_secondaryColorData.binding = ab;
computeFastPathsUsed();
dirtyDisplayList();
}
void Geometry::setFogCoordBinding(AttributeBinding ab)
{
if (_fogCoordData.binding == ab) return;
_fogCoordData.binding = ab;
computeFastPathsUsed();
dirtyDisplayList();
}
void Geometry::setTexCoordData(unsigned int unit,const ArrayData& arrayData)
{
if (_texCoordList.size()<=unit)
_texCoordList.resize(unit+1);
_texCoordList[unit] = arrayData;
}
Geometry::ArrayData& Geometry::getTexCoordData(unsigned int unit)
{
if (_texCoordList.size()<=unit)
_texCoordList.resize(unit+1);
return _texCoordList[unit];
}
const Geometry::ArrayData& Geometry::getTexCoordData(unsigned int unit) const
{
if (_texCoordList.size()<=unit)
return s_InvalidArrayData;
return _texCoordList[unit];
}
void Geometry::setTexCoordArray(unsigned int unit,Array* array)
{
getTexCoordData(unit).binding = BIND_PER_VERTEX;
getTexCoordData(unit).array = array;
computeFastPathsUsed();
dirtyDisplayList();
}
Array* Geometry::getTexCoordArray(unsigned int unit)
{
if (unit<_texCoordList.size()) return _texCoordList[unit].array.get();
else return 0;
}
const Array* Geometry::getTexCoordArray(unsigned int unit) const
{
if (unit<_texCoordList.size()) return _texCoordList[unit].array.get();
else return 0;
}
void Geometry::setTexCoordIndices(unsigned int unit,IndexArray* array)
{
getTexCoordData(unit).indices = array;
computeFastPathsUsed();
dirtyDisplayList();
}
IndexArray* Geometry::getTexCoordIndices(unsigned int unit)
{
if (unit<_texCoordList.size()) return _texCoordList[unit].indices.get();
else return 0;
}
const IndexArray* Geometry::getTexCoordIndices(unsigned int unit) const
{
if (unit<_texCoordList.size()) return _texCoordList[unit].indices.get();
else return 0;
}
void Geometry::setVertexAttribData(unsigned int index, const Geometry::ArrayData& attrData)
{
if (_vertexAttribList.size()<=index)
_vertexAttribList.resize(index+1);
_vertexAttribList[index] = attrData;
computeFastPathsUsed();
dirtyDisplayList();
}
Geometry::ArrayData& Geometry::getVertexAttribData(unsigned int index)
{
if (_vertexAttribList.size()<=index)
_vertexAttribList.resize(index+1);
return _vertexAttribList[index];
}
const Geometry::ArrayData& Geometry::getVertexAttribData(unsigned int index) const
{
if (_vertexAttribList.size()<=_vertexAttribList.size())
return s_InvalidArrayData;
return _vertexAttribList[index];
}
void Geometry::setVertexAttribArray(unsigned int index, Array* array)
{
getVertexAttribData(index).array = array;
computeFastPathsUsed();
dirtyDisplayList();
}
Array *Geometry::getVertexAttribArray(unsigned int index)
{
if (index<_vertexAttribList.size()) return _vertexAttribList[index].array.get();
else return 0;
}
const Array *Geometry::getVertexAttribArray(unsigned int index) const
{
if (index<_vertexAttribList.size()) return _vertexAttribList[index].array.get();
else return 0;
}
void Geometry::setVertexAttribIndices(unsigned int index,IndexArray* array)
{
getVertexAttribData(index).indices = array;
computeFastPathsUsed();
dirtyDisplayList();
}
IndexArray* Geometry::getVertexAttribIndices(unsigned int index)
{
if (index<_vertexAttribList.size()) return _vertexAttribList[index].indices.get();
else return 0;
}
const IndexArray* Geometry::getVertexAttribIndices(unsigned int index) const
{
if (index<_vertexAttribList.size()) return _vertexAttribList[index].indices.get();
else return 0;
}
void Geometry::setVertexAttribBinding(unsigned int index,AttributeBinding ab)
{
if (getVertexAttribData(index).binding == ab)
return;
getVertexAttribData(index).binding = ab;
computeFastPathsUsed();
dirtyDisplayList();
}
Geometry::AttributeBinding Geometry::getVertexAttribBinding(unsigned int index) const
{
if (index<_vertexAttribList.size()) return _vertexAttribList[index].binding;
else return BIND_OFF;
}
void Geometry::setVertexAttribNormalize(unsigned int index,GLboolean norm)
{
getVertexAttribData(index).normalize = norm;
dirtyDisplayList();
}
GLboolean Geometry::getVertexAttribNormalize(unsigned int index) const
{
if (index<_vertexAttribList.size()) return _vertexAttribList[index].normalize;
else return GL_FALSE;
}
bool Geometry::addPrimitiveSet(PrimitiveSet* primitiveset)
{
if (primitiveset)
{
_primitives.push_back(primitiveset);
dirtyDisplayList();
dirtyBound();
return true;
}
notify(WARN)<<"Warning: invalid index i or primitiveset passed to osg::Geometry::addPrimitiveSet(i,primitiveset), ignoring call."<<std::endl;
return false;
}
bool Geometry::setPrimitiveSet(unsigned int i,PrimitiveSet* primitiveset)
{
if (i<_primitives.size() && primitiveset)
{
_primitives[i] = primitiveset;
dirtyDisplayList();
dirtyBound();
return true;
}
notify(WARN)<<"Warning: invalid index i or primitiveset passed to osg::Geometry::setPrimitiveSet(i,primitiveset), ignoring call."<<std::endl;
return false;
}
bool Geometry::insertPrimitiveSet(unsigned int i,PrimitiveSet* primitiveset)
{
if (primitiveset)
{
if (i<_primitives.size())
{
_primitives.insert(_primitives.begin()+i,primitiveset);
dirtyDisplayList();
dirtyBound();
return true;
}
else if (i==_primitives.size())
{
return addPrimitiveSet(primitiveset);
}
}
notify(WARN)<<"Warning: invalid index i or primitiveset passed to osg::Geometry::insertPrimitiveSet(i,primitiveset), ignoring call."<<std::endl;
return false;
}
bool Geometry::removePrimitiveSet(unsigned int i, unsigned int numElementsToRemove)
{
if (i<_primitives.size() && numElementsToRemove>0)
{
if (i+numElementsToRemove<=_primitives.size())
{
_primitives.erase(_primitives.begin()+i,_primitives.begin()+i+numElementsToRemove);
}
else
{
// asking to delete too many elements, report a warning, and delete to
// the end of the primitive list.
notify(WARN)<<"Warning: osg::Geometry::removePrimitiveSet(i,numElementsToRemove) has been asked to remove more elements than are available,"<<std::endl;
notify(WARN)<<" removing on from i to the end of the list of primitive sets."<<std::endl;
_primitives.erase(_primitives.begin()+i,_primitives.end());
}
dirtyDisplayList();
dirtyBound();
return true;
}
notify(WARN)<<"Warning: invalid index i passed to osg::Geometry::removePrimitiveSet(i,numElementsToRemove), ignoring call."<<std::endl;
return false;
}
unsigned int Geometry::getPrimitiveSetIndex(const PrimitiveSet* primitiveset) const
{
for (unsigned int primitiveSetIndex=0;primitiveSetIndex<_primitives.size();++primitiveSetIndex)
{
if (_primitives[primitiveSetIndex]==primitiveset) return primitiveSetIndex;
}
return _primitives.size(); // node not found.
}
bool Geometry::computeFastPathsUsed()
{
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static bool s_DisableFastPathInDisplayLists = getenv("OSG_DISABLE_FAST_PATH_IN_DISPLAY_LISTS")!=0;
if (_useDisplayList && s_DisableFastPathInDisplayLists)
{
osg::notify(osg::DEBUG_INFO)<<"Geometry::computeFastPathsUsed() - Disabling fast paths in display lists"<<std::endl;
_fastPath = false;
return _fastPath;
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// check to see if fast path can be used.
//
_fastPath = true;
if (_vertexData.indices.valid()) _fastPath = false;
else if (_normalData.binding==BIND_PER_PRIMITIVE || (_normalData.binding==BIND_PER_VERTEX && _normalData.indices.valid())) _fastPath = false;
else if (_colorData.binding==BIND_PER_PRIMITIVE || (_colorData.binding==BIND_PER_VERTEX && _colorData.indices.valid())) _fastPath = false;
else if (_secondaryColorData.binding==BIND_PER_PRIMITIVE || (_secondaryColorData.binding==BIND_PER_VERTEX && _secondaryColorData.indices.valid())) _fastPath = false;
else if (_fogCoordData.binding==BIND_PER_PRIMITIVE || (_fogCoordData.binding==BIND_PER_VERTEX && _fogCoordData.indices.valid())) _fastPath = false;
else
{
for( unsigned int va = 0; va < _vertexAttribList.size(); ++va )
{
if (_vertexAttribList[va].binding==BIND_PER_PRIMITIVE)
{
_fastPath = false;
break;
}
else
{
const Array * array = _vertexAttribList[va].array.get();
const IndexArray * idxArray = _vertexAttribList[va].indices.get();
if( _vertexAttribList[va].binding==BIND_PER_VERTEX &&
array && array->getNumElements()>0 &&
idxArray && idxArray->getNumElements()>0 )
{
_fastPath = false;
break;
}
}
}
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// Set up tex coords if required.
//
for(unsigned int unit=0;unit<_texCoordList.size();++unit)
{
const ArrayData& texcoordData = _texCoordList[unit];
if (texcoordData.array.valid() && texcoordData.array->getNumElements()>0)
{
if (texcoordData.indices.valid())
{
if (texcoordData.indices->getNumElements()>0)
{
_fastPath = false;
break;
}
}
}
}
_supportsVertexBufferObjects = _fastPath;
//_supportsVertexBufferObjects = false;
//_useVertexBufferObjects = false;
return _fastPath;
}
unsigned int Geometry::getGLObjectSizeHint() const
{
unsigned int totalSize = 0;
if (_vertexData.array.valid()) totalSize += _vertexData.array->getTotalDataSize();
if (_normalData.array.valid()) totalSize += _normalData.array->getTotalDataSize();
if (_colorData.array.valid()) totalSize += _colorData.array->getTotalDataSize();
if (_secondaryColorData.array.valid()) totalSize += _secondaryColorData.array->getTotalDataSize();
if (_fogCoordData.array.valid()) totalSize += _fogCoordData.array->getTotalDataSize();
unsigned int unit;
for(unit=0;unit<_texCoordList.size();++unit)
{
const Array* array = _texCoordList[unit].array.get();
if (array) totalSize += array->getTotalDataSize();
}
bool handleVertexAttributes = true;
if (handleVertexAttributes)
{
unsigned int index;
for( index = 0; index < _vertexAttribList.size(); ++index )
{
const Array* array = _vertexAttribList[index].array.get();
if (array) totalSize += array->getTotalDataSize();
}
}
for(PrimitiveSetList::const_iterator itr=_primitives.begin();
itr!=_primitives.end();
++itr)
{
totalSize += 4*(*itr)->getNumIndices();
}
// do a very simply mapping of display list size proportional to vertex datasize.
return totalSize;
}
void Geometry::drawImplementation(State& state) const
{
// osg::notify(osg::NOTICE)<<"Geometry::drawImplementation"<<std::endl;
if (_internalOptimizedGeometry.valid())
{
_internalOptimizedGeometry->drawImplementation(state);
return;
}
const Extensions* extensions = getExtensions(state.getContextID(),true);
if( !( ( _vertexData.array.valid() && _vertexData.array->getNumElements() != 0 ) ||
( _vertexAttribList.size() > 0 &&
_vertexAttribList[0].array.valid() &&
_vertexAttribList[0].array->getNumElements() != 0 ) ) )
{
return;
}
if( ( _vertexData.indices.valid() && _vertexData.indices->getNumElements() == 0 ) ||
( _vertexAttribList.size() > 0 &&
_vertexAttribList[0].indices.valid() &&
_vertexAttribList[0].indices->getNumElements() == 0 ) )
{
return;
}
DrawNormal drawNormal(_normalData.array.get(),_normalData.indices.get());
DrawColor drawColor(_colorData.array.get(),_colorData.indices.get());
DrawSecondaryColor drawSecondaryColor(_secondaryColorData.array.get(),_secondaryColorData.indices.get(),extensions);
DrawFogCoord drawFogCoord(_fogCoordData.array.get(),_fogCoordData.indices.get(),extensions);
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// Set up secondary color if required.
//
AttributeBinding secondaryColorBinding = _secondaryColorData.binding;
if (secondaryColorBinding!=BIND_OFF && !extensions->isSecondaryColorSupported())
{
// switch off if not supported or have a valid data.
secondaryColorBinding = BIND_OFF;
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// Set up fog coord if required.
//
AttributeBinding fogCoordBinding = _fogCoordData.binding;
if (fogCoordBinding!=BIND_OFF && !extensions->isFogCoordSupported())
{
// switch off if not supported or have a valid data.
fogCoordBinding = BIND_OFF;
}
unsigned int normalIndex = 0;
unsigned int colorIndex = 0;
unsigned int secondaryColorIndex = 0;
unsigned int fogCoordIndex = 0;
#if USE_DEFAULT_NORMAL
// if no values are defined for normal and color provide some defaults...
if (_normalData.binding==BIND_OFF) glNormal3f(0.0f,0.0f,1.0f);
#endif
#if USE_DEFAULT_COLOUR
if (_colorData.binding==BIND_OFF) glColor4f(1.0f,1.0f,1.0f,1.0f);
#endif
typedef std::vector< ref_ptr<DrawVertexAttrib> > DrawVertexAttribList;
typedef std::map< Geometry::AttributeBinding, DrawVertexAttribList> DrawVertexAttribMap;
DrawVertexAttribMap drawVertexAttribMap;
bool vertexVertexAttributesSupported = extensions->isVertexProgramSupported();
bool handleVertexAttributes = (!_vertexAttribList.empty() && vertexVertexAttributesSupported);
bool usingVertexBufferObjects = _useVertexBufferObjects && state.isVertexBufferObjectSupported();
if (areFastPathsUsed())
{
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// fast path.
//
if (usingVertexBufferObjects)
{
//
// Vertex Buffer Object path for defining vertex arrays.
//
GLuint& buffer = _vboList[state.getContextID()];
if (!buffer)
{
//std::cout << "creating VertexBuffer "<<buffer<<std::endl;
extensions->glGenBuffers(1, &buffer);
extensions->glBindBuffer(GL_ARRAY_BUFFER_ARB,buffer);
//std::cout << " gen VertexBuffer "<<buffer<<std::endl;
// compute total size and offsets required.
unsigned long totalSize = 0;
_vertexData.offset = 0;
if (_vertexData.array.valid()) totalSize += _vertexData.array->getTotalDataSize();
_normalData.offset = totalSize;
if (_normalData.array.valid()) totalSize += _normalData.array->getTotalDataSize();
_colorData.offset = totalSize;
if (_colorData.array.valid()) totalSize += _colorData.array->getTotalDataSize();
_secondaryColorData.offset = totalSize;
if (_secondaryColorData.array.valid()) totalSize += _secondaryColorData.array->getTotalDataSize();
_fogCoordData.offset = totalSize;
if (_fogCoordData.array.valid()) totalSize += _fogCoordData.array->getTotalDataSize();
unsigned int unit;
for(unit=0;unit<_texCoordList.size();++unit)
{
_texCoordList[unit].offset = totalSize;
const Array* array = _texCoordList[unit].array.get();
if (array)
totalSize += array->getTotalDataSize();
}
if( handleVertexAttributes )
{
unsigned int index;
for( index = 0; index < _vertexAttribList.size(); ++index )
{
_vertexAttribList[unit].offset = totalSize;
const Array* array = _vertexAttribList[index].array.get();
const AttributeBinding ab = _vertexAttribList[index].binding;
if( ab == BIND_PER_VERTEX && array )
{
totalSize += array->getTotalDataSize();
}
}
}
// allocated the buffer space, but leave the copy to be done per vertex array below
extensions->glBufferData(GL_ARRAY_BUFFER_ARB,totalSize, 0, GL_STATIC_DRAW_ARB);
//std::cout << " Created VertexBuffer "<<buffer<<" size="<<totalSize<<std::endl;
//
// copy the data
//
if( _vertexData.array.valid() )
extensions->glBufferSubData(GL_ARRAY_BUFFER_ARB, _vertexData.offset, _vertexData.array->getTotalDataSize(),_vertexData.array->getDataPointer());
if (_normalData.binding==BIND_PER_VERTEX)
extensions->glBufferSubData(GL_ARRAY_BUFFER_ARB, _normalData.offset, _normalData.array->getTotalDataSize(),_normalData.array->getDataPointer());
if (_colorData.binding==BIND_PER_VERTEX)
extensions->glBufferSubData(GL_ARRAY_BUFFER_ARB, _colorData.offset, _colorData.array->getTotalDataSize(),_colorData.array->getDataPointer());
if (secondaryColorBinding==BIND_PER_VERTEX)
extensions->glBufferSubData(GL_ARRAY_BUFFER_ARB, _secondaryColorData.offset, _secondaryColorData.array->getTotalDataSize(),_secondaryColorData.array->getDataPointer());
if (fogCoordBinding==BIND_PER_VERTEX)
extensions->glBufferSubData(GL_ARRAY_BUFFER_ARB, _fogCoordData.offset, _fogCoordData.array->getTotalDataSize(),_fogCoordData.array->getDataPointer());
for(unit=0;unit<_texCoordList.size();++unit)
{
const Array* array = _texCoordList[unit].array.get();
if (array)
extensions->glBufferSubData(GL_ARRAY_BUFFER_ARB, _texCoordList[unit].offset, array->getTotalDataSize(), array->getDataPointer());
}
if( handleVertexAttributes )
{
unsigned int index;
for( index = 0; index < _vertexAttribList.size(); ++index )
{
const Array* array = _vertexAttribList[index].array.get();
const AttributeBinding ab = _vertexAttribList[index].binding;
if( ab == BIND_PER_VERTEX && array )
{
extensions->glBufferSubData(GL_ARRAY_BUFFER_ARB, _vertexAttribList[index].offset, array->getTotalDataSize(), array->getDataPointer());
}
}
}
}
//std::cout << "binding VertexBuffer "<<buffer<<std::endl;
extensions->glBindBuffer(GL_ARRAY_BUFFER_ARB,buffer);
if( _vertexData.array.valid() )
state.setVertexPointer(_vertexData.array->getDataSize(),_vertexData.array->getDataType(),0,(const GLvoid*)_vertexData.offset);
else
state.disableVertexPointer();
if (_normalData.binding==BIND_PER_VERTEX && _normalData.array.valid())
state.setNormalPointer(GL_FLOAT,0,(const GLvoid*)_normalData.offset);
else
state.disableNormalPointer();
if (_colorData.binding==BIND_PER_VERTEX && _colorData.array.valid())
state.setColorPointer(_colorData.array->getDataSize(),_colorData.array->getDataType(),0,(const GLvoid*)_colorData.offset);
else
state.disableColorPointer();
if (secondaryColorBinding==BIND_PER_VERTEX && _secondaryColorData.array.valid())
state.setSecondaryColorPointer(_secondaryColorData.array->getDataSize(),_secondaryColorData.array->getDataType(),0,(const GLvoid*)_secondaryColorData.offset);
else
state.disableSecondaryColorPointer();
if (fogCoordBinding==BIND_PER_VERTEX && _fogCoordData.array.valid())
state.setFogCoordPointer(GL_FLOAT,0,(const GLvoid*)_fogCoordData.offset);
else
state.disableFogCoordPointer();
unsigned int unit;
for(unit=0;unit<_texCoordList.size();++unit)
{
const Array* array = _texCoordList[unit].array.get();
if (array)
state.setTexCoordPointer(unit,array->getDataSize(),array->getDataType(),0,(const GLvoid*)_texCoordList[unit].offset);
else
state.disableTexCoordPointer(unit);
}
state.disableTexCoordPointersAboveAndIncluding(unit);
if( handleVertexAttributes )
{
unsigned int index;
for( index = 0; index < _vertexAttribList.size(); ++index )
{
const Array* array = _vertexAttribList[index].array.get();
const AttributeBinding ab = _vertexAttribList[index].binding;
if( ab == BIND_PER_VERTEX && array )
{
state.setVertexAttribPointer( index, array->getDataSize(), array->getDataType(),
_vertexAttribList[index].normalize, 0, (const GLvoid*)_vertexAttribList[index].offset );
}
else
{
if( array )
{
const IndexArray* indexArray = _vertexAttribList[index].indices.get();
if( indexArray && indexArray->getNumElements() > 0 )
{
drawVertexAttribMap[ab].push_back(
new DrawVertexAttrib(extensions,index,_vertexAttribList[index].normalize,array,indexArray) );
}
else
{
drawVertexAttribMap[ab].push_back(
new DrawVertexAttrib(extensions,index,_vertexAttribList[index].normalize,array,0) );
}
}
state.disableVertexAttribPointer( index );
}
}
state.disableVertexAttribPointersAboveAndIncluding( index );
}
else if (vertexVertexAttributesSupported)
{
state.disableVertexAttribPointersAboveAndIncluding( 0 );
}
}
else
{
//std::cout << "none VertexBuffer path"<<std::endl;
//
// None Vertex Buffer Object path for defining vertex arrays.
//
if( _vertexData.array.valid() )
state.setVertexPointer(_vertexData.array->getDataSize(),_vertexData.array->getDataType(),0,_vertexData.array->getDataPointer());
else
state.disableVertexPointer();
if (_normalData.binding==BIND_PER_VERTEX && _normalData.array.valid())
state.setNormalPointer(_normalData.array->getDataType(),0,_normalData.array->getDataPointer());
else
state.disableNormalPointer();
if (_colorData.binding==BIND_PER_VERTEX && _colorData.array.valid())
state.setColorPointer(_colorData.array->getDataSize(),_colorData.array->getDataType(),0,_colorData.array->getDataPointer());
else
state.disableColorPointer();
if (secondaryColorBinding==BIND_PER_VERTEX && _secondaryColorData.array.valid())
state.setSecondaryColorPointer(_secondaryColorData.array->getDataSize(),_secondaryColorData.array->getDataType(),0,_secondaryColorData.array->getDataPointer());
else
state.disableSecondaryColorPointer();
if (fogCoordBinding==BIND_PER_VERTEX && _fogCoordData.array.valid())
state.setFogCoordPointer(GL_FLOAT,0,_fogCoordData.array->getDataPointer());
else
state.disableFogCoordPointer();
unsigned int unit;
for(unit=0;unit<_texCoordList.size();++unit)
{
const Array* array = _texCoordList[unit].array.get();
if (array)
state.setTexCoordPointer(unit,array->getDataSize(),array->getDataType(),0,array->getDataPointer());
else
state.disableTexCoordPointer(unit);
}
state.disableTexCoordPointersAboveAndIncluding(unit);
if( handleVertexAttributes )
{
unsigned int index;
for( index = 0; index < _vertexAttribList.size(); ++index )
{
const Array* array = _vertexAttribList[index].array.get();
const AttributeBinding ab = _vertexAttribList[index].binding;
if( ab == BIND_PER_VERTEX && array )
{
state.setVertexAttribPointer( index, array->getDataSize(), array->getDataType(),
_vertexAttribList[index].normalize, 0, array->getDataPointer() );
}
else
{
if( array )
{
const IndexArray* indexArray = _vertexAttribList[index].indices.get();
if( indexArray && indexArray->getNumElements() > 0 )
{
drawVertexAttribMap[ab].push_back(
new DrawVertexAttrib(extensions,index,_vertexAttribList[index].normalize,array,indexArray) );
}
else
{
drawVertexAttribMap[ab].push_back(
new DrawVertexAttrib(extensions,index,_vertexAttribList[index].normalize,array,0) );
}
}
state.disableVertexAttribPointer( index );
}
}
state.disableVertexAttribPointersAboveAndIncluding( index );
}
else if (vertexVertexAttributesSupported)
{
state.disableVertexAttribPointersAboveAndIncluding( 0 );
}
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// pass the overall binding values onto OpenGL.
//
if (_normalData.binding==BIND_OVERALL) drawNormal(normalIndex++);
if (_colorData.binding==BIND_OVERALL) drawColor(colorIndex++);
if (secondaryColorBinding==BIND_OVERALL) drawSecondaryColor(secondaryColorIndex++);
if (fogCoordBinding==BIND_OVERALL) drawFogCoord(fogCoordIndex++);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_OVERALL];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// draw the primitives themselves.
//
for(PrimitiveSetList::const_iterator itr=_primitives.begin();
itr!=_primitives.end();
++itr)
{
if (_normalData.binding==BIND_PER_PRIMITIVE_SET) drawNormal(normalIndex++);
if (_colorData.binding==BIND_PER_PRIMITIVE_SET) drawColor(colorIndex++);
if (secondaryColorBinding==BIND_PER_PRIMITIVE_SET) drawSecondaryColor(secondaryColorIndex++);
if (fogCoordBinding==BIND_PER_PRIMITIVE_SET) drawFogCoord(fogCoordIndex++);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_PRIMITIVE_SET];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
(*itr)->draw(state, usingVertexBufferObjects);
}
if (usingVertexBufferObjects)
{
extensions->glBindBuffer(GL_ARRAY_BUFFER_ARB,0);
}
}
else
{
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// slow path.
//
typedef std::vector< ref_ptr<DrawMultiTexCoord> > DrawTexCoordList;
DrawTexCoordList drawTexCoordList;
drawTexCoordList.reserve(_texCoordList.size());
// fallback if multitexturing not supported.
ref_ptr<DrawTexCoord> drawTextCoord;
if (extensions->isMultiTexSupported() && _texCoordList.size()>1)
{
// multitexture supported..
for(unsigned int unit=0;unit!=_texCoordList.size();++unit)
{
const ArrayData& texcoordData = _texCoordList[unit];
if (texcoordData.array.valid() && texcoordData.array->getNumElements()>0)
{
if (texcoordData.indices.valid() && texcoordData.indices->getNumElements()>0)
{
drawTexCoordList.push_back(new DrawMultiTexCoord(GL_TEXTURE0+unit,texcoordData.array.get(),texcoordData.indices.get(),
extensions));
}
else
{
drawTexCoordList.push_back(new DrawMultiTexCoord(GL_TEXTURE0+unit,texcoordData.array.get(),0,
extensions));
}
}
}
}
else
{
if (!_texCoordList.empty())
{
const ArrayData& texcoordData = _texCoordList[0];
if (texcoordData.array.valid() && texcoordData.array->getNumElements()>0)
{
if (texcoordData.indices.valid())
{
if (texcoordData.indices->getNumElements()>0)
{
drawTextCoord = new DrawTexCoord(texcoordData.array.get(),texcoordData.indices.get());
}
}
else
{
drawTextCoord = new DrawTexCoord(texcoordData.array.get(),0);
}
}
}
}
if(handleVertexAttributes)
{
unsigned int index;
for( index = 1; index < _vertexAttribList.size(); ++index )
{
const ArrayData& vertAttribData = _vertexAttribList[index];
if( vertAttribData.array.valid() && vertAttribData.array->getNumElements() > 0 )
{
if( vertAttribData.indices.valid() && vertAttribData.indices->getNumElements() > 0 )
{
drawVertexAttribMap[vertAttribData.binding].push_back(
new DrawVertexAttrib(extensions,index,vertAttribData.normalize,vertAttribData.array.get(),vertAttribData.indices.get() ));
}
else
{
drawVertexAttribMap[vertAttribData.binding].push_back(
new DrawVertexAttrib(extensions,index,vertAttribData.normalize,vertAttribData.array.get(),0) );
}
}
}
}
// disable all the vertex arrays in the slow path as we are
// sending everything using glVertex etc.
state.disableAllVertexArrays();
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// pass the overall binding values onto OpenGL.
//
if (_normalData.binding==BIND_OVERALL) drawNormal(normalIndex++);
if (_colorData.binding==BIND_OVERALL) drawColor(colorIndex++);
if (secondaryColorBinding==BIND_OVERALL) drawSecondaryColor(secondaryColorIndex++);
if (fogCoordBinding==BIND_OVERALL) drawFogCoord(fogCoordIndex++);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_OVERALL];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
// set up vertex functor.
DrawVertex drawVertex(_vertexData.array.get(),_vertexData.indices.get());
bool useVertexAttrib = _vertexAttribList.size() > 0 &&
_vertexAttribList[0].array.valid() &&
_vertexAttribList[0].indices->getNumElements();
ref_ptr<DrawVertexAttrib> drawVertexAttribZero;
if( useVertexAttrib )
{
drawVertexAttribZero = new DrawVertexAttrib(extensions,0,
_vertexAttribList[0].normalize,_vertexAttribList[0].array.get(),
_vertexAttribList[0].indices.get());
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// draw the primitives themselves.
//
for(PrimitiveSetList::const_iterator itr=_primitives.begin();
itr!=_primitives.end();
++itr)
{
if (_normalData.binding==BIND_PER_PRIMITIVE_SET) drawNormal(normalIndex++);
if (_colorData.binding==BIND_PER_PRIMITIVE_SET) drawColor(colorIndex++);
if (secondaryColorBinding==BIND_PER_PRIMITIVE_SET) drawSecondaryColor(secondaryColorIndex++);
if (fogCoordBinding==BIND_PER_PRIMITIVE_SET) drawFogCoord(fogCoordIndex++);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_PRIMITIVE_SET];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
const PrimitiveSet* primitiveset = itr->get();
GLenum mode=primitiveset->getMode();
unsigned int primLength;
switch(mode)
{
case(GL_POINTS): primLength=1; break;
case(GL_LINES): primLength=2; break;
case(GL_TRIANGLES): primLength=3; break;
case(GL_QUADS): primLength=4; break;
default: primLength=0; break; // compute later when =0.
}
// draw primtives by the more flexible "slow" path,
// sending OpenGL glBegin/glVertex.../glEnd().
switch(primitiveset->getType())
{
case(PrimitiveSet::DrawArraysPrimitiveType):
{
if (primLength==0) primLength=primitiveset->getNumIndices();
const DrawArrays* drawArray = static_cast<const DrawArrays*>(primitiveset);
glBegin(mode);
unsigned int primCount=0;
unsigned int indexEnd = drawArray->getFirst()+drawArray->getCount();
for(unsigned int vindex=drawArray->getFirst();
vindex<indexEnd;
++vindex,++primCount)
{
if ((primCount%primLength)==0)
{
if (_normalData.binding==BIND_PER_PRIMITIVE) drawNormal(normalIndex++);
if (_colorData.binding==BIND_PER_PRIMITIVE) drawColor(colorIndex++);
if (secondaryColorBinding==BIND_PER_PRIMITIVE) drawSecondaryColor(secondaryColorIndex++);
if (fogCoordBinding==BIND_PER_PRIMITIVE) drawFogCoord(fogCoordIndex++);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_PRIMITIVE];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
}
if (_normalData.binding==BIND_PER_VERTEX) drawNormal(vindex);
if (_colorData.binding==BIND_PER_VERTEX) drawColor(vindex);
if (secondaryColorBinding==BIND_PER_VERTEX) drawSecondaryColor(vindex);
if (fogCoordBinding==BIND_PER_VERTEX) drawFogCoord(vindex);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_VERTEX];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
for(DrawTexCoordList::iterator texItr=drawTexCoordList.begin();
texItr!=drawTexCoordList.end();
++texItr)
{
(*(*texItr))(vindex);
}
if (drawTextCoord.valid()) (*drawTextCoord)(vindex);
if( useVertexAttrib )
{
(*drawVertexAttribZero)(vindex);
}
else
{
drawVertex(vindex);
}
}
glEnd();
break;
}
case(PrimitiveSet::DrawArrayLengthsPrimitiveType):
{
const DrawArrayLengths* drawArrayLengths = static_cast<const DrawArrayLengths*>(primitiveset);
unsigned int vindex=drawArrayLengths->getFirst();
for(DrawArrayLengths::const_iterator primItr=drawArrayLengths->begin();
primItr!=drawArrayLengths->end();
++primItr)
{
unsigned int localPrimLength;
if (primLength==0) localPrimLength=*primItr;
else localPrimLength=primLength;
glBegin(mode);
for(GLsizei primCount=0;primCount<*primItr;++primCount)
{
if ((primCount%localPrimLength)==0)
{
if (_normalData.binding==BIND_PER_PRIMITIVE) drawNormal(normalIndex++);
if (_colorData.binding==BIND_PER_PRIMITIVE) drawColor(colorIndex++);
if (secondaryColorBinding==BIND_PER_PRIMITIVE) drawSecondaryColor(secondaryColorIndex++);
if (fogCoordBinding==BIND_PER_PRIMITIVE) drawFogCoord(fogCoordIndex++);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_PRIMITIVE];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
}
if (_normalData.binding==BIND_PER_VERTEX) drawNormal(vindex);
if (_colorData.binding==BIND_PER_VERTEX) drawColor(vindex);
if (secondaryColorBinding==BIND_PER_VERTEX) drawSecondaryColor(vindex);
if (fogCoordBinding==BIND_PER_VERTEX) drawFogCoord(vindex);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_VERTEX];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
for(DrawTexCoordList::iterator texItr=drawTexCoordList.begin();
texItr!=drawTexCoordList.end();
++texItr)
{
(*(*texItr))(vindex);
}
if (drawTextCoord.valid()) (*drawTextCoord)(vindex);
if( useVertexAttrib )
{
(*drawVertexAttribZero)(vindex);
}
else
{
drawVertex(vindex);
}
++vindex;
}
glEnd();
}
break;
}
case(PrimitiveSet::DrawElementsUBytePrimitiveType):
{
if (primLength==0) primLength=primitiveset->getNumIndices();
const DrawElementsUByte* drawElements = static_cast<const DrawElementsUByte*>(primitiveset);
glBegin(mode);
unsigned int primCount=0;
for(DrawElementsUByte::const_iterator primItr=drawElements->begin();
primItr!=drawElements->end();
++primCount,++primItr)
{
if ((primCount%primLength)==0)
{
if (_normalData.binding==BIND_PER_PRIMITIVE) drawNormal(normalIndex++);
if (_colorData.binding==BIND_PER_PRIMITIVE) drawColor(colorIndex++);
if (secondaryColorBinding==BIND_PER_PRIMITIVE) drawSecondaryColor(secondaryColorIndex++);
if (fogCoordBinding==BIND_PER_PRIMITIVE) drawFogCoord(fogCoordIndex++);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_PRIMITIVE];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
}
unsigned int vindex=*primItr;
if (_normalData.binding==BIND_PER_VERTEX) drawNormal(vindex);
if (_colorData.binding==BIND_PER_VERTEX) drawColor(vindex);
if (secondaryColorBinding==BIND_PER_VERTEX) drawSecondaryColor(vindex);
if (fogCoordBinding==BIND_PER_VERTEX) drawFogCoord(vindex);
if ( extensions->isVertexProgramSupported() )
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_VERTEX];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
for(DrawTexCoordList::iterator texItr=drawTexCoordList.begin();
texItr!=drawTexCoordList.end();
++texItr)
{
(*(*texItr))(vindex);
}
if (drawTextCoord.valid()) (*drawTextCoord)(vindex);
if( useVertexAttrib )
{
(*drawVertexAttribZero)(vindex);
}
else
{
drawVertex(vindex);
}
}
glEnd();
break;
}
case(PrimitiveSet::DrawElementsUShortPrimitiveType):
{
if (primLength==0) primLength=primitiveset->getNumIndices();
const DrawElementsUShort* drawElements = static_cast<const DrawElementsUShort*>(primitiveset);
glBegin(mode);
unsigned int primCount=0;
for(DrawElementsUShort::const_iterator primItr=drawElements->begin();
primItr!=drawElements->end();
++primCount,++primItr)
{
if ((primCount%primLength)==0)
{
if (_normalData.binding==BIND_PER_PRIMITIVE) drawNormal(normalIndex++);
if (_colorData.binding==BIND_PER_PRIMITIVE) drawColor(colorIndex++);
if (secondaryColorBinding==BIND_PER_PRIMITIVE) drawSecondaryColor(secondaryColorIndex++);
if (fogCoordBinding==BIND_PER_PRIMITIVE) drawFogCoord(fogCoordIndex++);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_PRIMITIVE];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
}
unsigned int vindex=*primItr;
if (_normalData.binding==BIND_PER_VERTEX) drawNormal(vindex);
if (_colorData.binding==BIND_PER_VERTEX) drawColor(vindex);
if (secondaryColorBinding==BIND_PER_VERTEX) drawSecondaryColor(vindex);
if (fogCoordBinding==BIND_PER_VERTEX) drawFogCoord(vindex);
if (handleVertexAttributes)
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_VERTEX];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
for(DrawTexCoordList::iterator texItr=drawTexCoordList.begin();
texItr!=drawTexCoordList.end();
++texItr)
{
(*(*texItr))(vindex);
}
if (drawTextCoord.valid()) (*drawTextCoord)(vindex);
if( useVertexAttrib )
{
(*drawVertexAttribZero)(vindex);
}
else
{
drawVertex(vindex);
}
}
glEnd();
break;
}
case(PrimitiveSet::DrawElementsUIntPrimitiveType):
{
if (primLength==0) primLength=primitiveset->getNumIndices();
const DrawElementsUInt* drawElements = static_cast<const DrawElementsUInt*>(primitiveset);
glBegin(mode);
unsigned int primCount=0;
for(DrawElementsUInt::const_iterator primItr=drawElements->begin();
primItr!=drawElements->end();
++primCount,++primItr)
{
if ((primCount%primLength)==0)
{
if (_normalData.binding==BIND_PER_PRIMITIVE) drawNormal(normalIndex++);
if (_colorData.binding==BIND_PER_PRIMITIVE) drawColor(colorIndex++);
if (secondaryColorBinding==BIND_PER_PRIMITIVE) drawSecondaryColor(secondaryColorIndex++);
if (fogCoordBinding==BIND_PER_PRIMITIVE) drawFogCoord(fogCoordIndex++);
if ( extensions->isVertexProgramSupported() )
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_PRIMITIVE];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
}
unsigned int vindex=*primItr;
if (_normalData.binding==BIND_PER_VERTEX) drawNormal(vindex);
if (_colorData.binding==BIND_PER_VERTEX) drawColor(vindex);
if (secondaryColorBinding==BIND_PER_VERTEX) drawSecondaryColor(vindex);
if (fogCoordBinding==BIND_PER_VERTEX) drawFogCoord(vindex);
if ( extensions->isVertexProgramSupported() )
{
DrawVertexAttribList &list = drawVertexAttribMap[BIND_PER_VERTEX];
for( unsigned int i = 0; i < list.size(); ++i )
{
list[i]->applyAndIncrement();
}
}
for(DrawTexCoordList::iterator texItr=drawTexCoordList.begin();
texItr!=drawTexCoordList.end();
++texItr)
{
(*(*texItr))(vindex);
}
if (drawTextCoord.valid()) (*drawTextCoord)(vindex);
if( useVertexAttrib )
{
(*drawVertexAttribZero)(vindex);
}
else
{
drawVertex(vindex);
}
}
glEnd();
break;
}
default:
{
break;
}
}
}
}
}
class AttributeFunctorArrayVisitor : public ArrayVisitor
{
public:
AttributeFunctorArrayVisitor(Drawable::AttributeFunctor& af):
_af(af) {}
virtual ~AttributeFunctorArrayVisitor() {}
virtual void apply(ByteArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(ShortArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(IntArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(UByteArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(UShortArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(UIntArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(Vec4ubArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(FloatArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(Vec2Array& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(Vec3Array& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(Vec4Array& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
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inline void applyArray(Drawable::AttributeType type,Array* array)
{
if (array)
{
_type = type;
array->accept(*this);
}
}
Drawable::AttributeFunctor& _af;
Drawable::AttributeType _type;
};
void Geometry::accept(AttributeFunctor& af)
{
AttributeFunctorArrayVisitor afav(af);
afav.applyArray(VERTICES,_vertexData.array.get());
afav.applyArray(NORMALS,_normalData.array.get());
afav.applyArray(COLORS,_colorData.array.get());
afav.applyArray(SECONDARY_COLORS,_secondaryColorData.array.get());
afav.applyArray(FOG_COORDS,_fogCoordData.array.get());
for(unsigned unit=0;unit<_texCoordList.size();++unit)
{
afav.applyArray((AttributeType)(TEXTURE_COORDS_0+unit),_texCoordList[unit].array.get());
}
for(unsigned int index=0; index<_vertexAttribList.size(); ++index)
{
afav.applyArray(index,_vertexAttribList[index].array.get());
}
}
class ConstAttributeFunctorArrayVisitor : public ConstArrayVisitor
{
public:
ConstAttributeFunctorArrayVisitor(Drawable::ConstAttributeFunctor& af):
_af(af) {}
virtual ~ConstAttributeFunctorArrayVisitor() {}
virtual void apply(const ByteArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(const ShortArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(const IntArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(const UByteArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(const UShortArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(const UIntArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(const Vec4ubArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(const FloatArray& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(const Vec2Array& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(const Vec3Array& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
virtual void apply(const Vec4Array& array) { if (!array.empty()) _af.apply(_type,array.size(),&(array.front())); }
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inline void applyArray(Drawable::AttributeType type,const Array* array)
{
if (array)
{
_type = type;
array->accept(*this);
}
}
Drawable::ConstAttributeFunctor& _af;
Drawable::AttributeType _type;
};
void Geometry::accept(ConstAttributeFunctor& af) const
{
ConstAttributeFunctorArrayVisitor afav(af);
afav.applyArray(VERTICES,_vertexData.array.get());
afav.applyArray(NORMALS,_normalData.array.get());
afav.applyArray(COLORS,_colorData.array.get());
afav.applyArray(SECONDARY_COLORS,_secondaryColorData.array.get());
afav.applyArray(FOG_COORDS,_fogCoordData.array.get());
for(unsigned unit=0;unit<_texCoordList.size();++unit)
{
afav.applyArray((AttributeType)(TEXTURE_COORDS_0+unit),_texCoordList[unit].array.get());
}
for(unsigned int index=0; index<_vertexAttribList.size(); ++index)
{
afav.applyArray(index,_vertexAttribList[index].array.get());
}
}
void Geometry::accept(PrimitiveFunctor& functor) const
{
if (!_vertexData.array.valid() || _vertexData.array->getNumElements()==0) return;
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if (!_vertexData.indices.valid())
{
switch(_vertexData.array->getType())
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{
case(Array::Vec2ArrayType):
functor.setVertexArray(_vertexData.array->getNumElements(),static_cast<const Vec2*>(_vertexData.array->getDataPointer()));
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break;
case(Array::Vec3ArrayType):
functor.setVertexArray(_vertexData.array->getNumElements(),static_cast<const Vec3*>(_vertexData.array->getDataPointer()));
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break;
case(Array::Vec4ArrayType):
functor.setVertexArray(_vertexData.array->getNumElements(),static_cast<const Vec4*>(_vertexData.array->getDataPointer()));
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break;
default:
notify(WARN)<<"Warning: Geometry::accept(PrimtiveFunctor&) cannot handle Vertex Array type"<<_vertexData.array->getType()<<std::endl;
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return;
}
for(PrimitiveSetList::const_iterator itr=_primitives.begin();
itr!=_primitives.end();
++itr)
{
(*itr)->accept(functor);
}
}
else
{
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const Vec2Array* vec2Array = 0;
const Vec3Array* vec3Array = 0;
const Vec4Array* vec4Array = 0;
Array::Type type = _vertexData.array->getType();
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switch(type)
{
case(Array::Vec2ArrayType):
vec2Array = static_cast<const Vec2Array*>(_vertexData.array.get());
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break;
case(Array::Vec3ArrayType):
vec3Array = static_cast<const Vec3Array*>(_vertexData.array.get());
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break;
case(Array::Vec4ArrayType):
vec4Array = static_cast<const Vec4Array*>(_vertexData.array.get());
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break;
default:
notify(WARN)<<"Warning: Geometry::accept(PrimtiveFunctor&) cannot handle Vertex Array type"<<_vertexData.array->getType()<<std::endl;
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return;
}
for(PrimitiveSetList::const_iterator itr=_primitives.begin();
itr!=_primitives.end();
++itr)
{
const PrimitiveSet* primitiveset = itr->get();
GLenum mode=primitiveset->getMode();
switch(primitiveset->getType())
{
case(PrimitiveSet::DrawArraysPrimitiveType):
{
const DrawArrays* drawArray = static_cast<const DrawArrays*>(primitiveset);
functor.begin(mode);
unsigned int indexEnd = drawArray->getFirst()+drawArray->getCount();
for(unsigned int vindex=drawArray->getFirst();
vindex<indexEnd;
++vindex)
{
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switch(type)
{
case(Array::Vec2ArrayType):
functor.vertex((*vec2Array)[_vertexData.indices->index(vindex)]);
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break;
case(Array::Vec3ArrayType):
functor.vertex((*vec3Array)[_vertexData.indices->index(vindex)]);
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break;
case(Array::Vec4ArrayType):
functor.vertex((*vec4Array)[_vertexData.indices->index(vindex)]);
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break;
default:
break;
}
}
functor.end();
break;
}
case(PrimitiveSet::DrawArrayLengthsPrimitiveType):
{
const DrawArrayLengths* drawArrayLengths = static_cast<const DrawArrayLengths*>(primitiveset);
unsigned int vindex=drawArrayLengths->getFirst();
for(DrawArrayLengths::const_iterator primItr=drawArrayLengths->begin();
primItr!=drawArrayLengths->end();
++primItr)
{
functor.begin(mode);
for(GLsizei primCount=0;primCount<*primItr;++primCount)
{
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switch(type)
{
case(Array::Vec2ArrayType):
functor.vertex((*vec2Array)[_vertexData.indices->index(vindex)]);
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break;
case(Array::Vec3ArrayType):
functor.vertex((*vec3Array)[_vertexData.indices->index(vindex)]);
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break;
case(Array::Vec4ArrayType):
functor.vertex((*vec4Array)[_vertexData.indices->index(vindex)]);
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break;
default:
break;
}
++vindex;
}
functor.end();
}
break;
}
case(PrimitiveSet::DrawElementsUBytePrimitiveType):
{
const DrawElementsUByte* drawElements = static_cast<const DrawElementsUByte*>(primitiveset);
functor.begin(mode);
unsigned int primCount=0;
for(DrawElementsUByte::const_iterator primItr=drawElements->begin();
primItr!=drawElements->end();
++primCount,++primItr)
{
unsigned int vindex=*primItr;
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switch(type)
{
case(Array::Vec2ArrayType):
functor.vertex((*vec2Array)[_vertexData.indices->index(vindex)]);
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break;
case(Array::Vec3ArrayType):
functor.vertex((*vec3Array)[_vertexData.indices->index(vindex)]);
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break;
case(Array::Vec4ArrayType):
functor.vertex((*vec4Array)[_vertexData.indices->index(vindex)]);
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break;
default:
break;
}
}
functor.end();
break;
}
case(PrimitiveSet::DrawElementsUShortPrimitiveType):
{
const DrawElementsUShort* drawElements = static_cast<const DrawElementsUShort*>(primitiveset);
functor.begin(mode);
for(DrawElementsUShort::const_iterator primItr=drawElements->begin();
primItr!=drawElements->end();
++primItr)
{
unsigned int vindex=*primItr;
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switch(type)
{
case(Array::Vec2ArrayType):
functor.vertex((*vec2Array)[_vertexData.indices->index(vindex)]);
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break;
case(Array::Vec3ArrayType):
functor.vertex((*vec3Array)[_vertexData.indices->index(vindex)]);
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break;
case(Array::Vec4ArrayType):
functor.vertex((*vec4Array)[_vertexData.indices->index(vindex)]);
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break;
default:
break;
}
}
functor.end();
break;
}
case(PrimitiveSet::DrawElementsUIntPrimitiveType):
{
const DrawElementsUInt* drawElements = static_cast<const DrawElementsUInt*>(primitiveset);
functor.begin(mode);
for(DrawElementsUInt::const_iterator primItr=drawElements->begin();
primItr!=drawElements->end();
++primItr)
{
unsigned int vindex=*primItr;
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switch(type)
{
case(Array::Vec2ArrayType):
functor.vertex((*vec2Array)[_vertexData.indices->index(vindex)]);
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break;
case(Array::Vec3ArrayType):
functor.vertex((*vec3Array)[_vertexData.indices->index(vindex)]);
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break;
case(Array::Vec4ArrayType):
functor.vertex((*vec4Array)[_vertexData.indices->index(vindex)]);
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break;
default:
break;
}
}
functor.end();
break;
}
default:
{
break;
}
}
}
}
return;
}
void Geometry::accept(PrimitiveIndexFunctor& functor) const
{
if (!_vertexData.array.valid() || _vertexData.array->getNumElements()==0) return;
switch(_vertexData.array->getType())
{
case(Array::Vec2ArrayType):
functor.setVertexArray(_vertexData.array->getNumElements(),static_cast<const Vec2*>(_vertexData.array->getDataPointer()));
break;
case(Array::Vec3ArrayType):
functor.setVertexArray(_vertexData.array->getNumElements(),static_cast<const Vec3*>(_vertexData.array->getDataPointer()));
break;
case(Array::Vec4ArrayType):
functor.setVertexArray(_vertexData.array->getNumElements(),static_cast<const Vec4*>(_vertexData.array->getDataPointer()));
break;
default:
notify(WARN)<<"Warning: Geometry::accept(PrimtiveIndexFunctor&) cannot handle Vertex Array type"<<_vertexData.array->getType()<<std::endl;
return;
}
if (!_vertexData.indices.valid())
{
for(PrimitiveSetList::const_iterator itr=_primitives.begin();
itr!=_primitives.end();
++itr)
{
(*itr)->accept(functor);
}
}
else
{
for(PrimitiveSetList::const_iterator itr=_primitives.begin();
itr!=_primitives.end();
++itr)
{
const PrimitiveSet* primitiveset = itr->get();
GLenum mode=primitiveset->getMode();
switch(primitiveset->getType())
{
case(PrimitiveSet::DrawArraysPrimitiveType):
{
const DrawArrays* drawArray = static_cast<const DrawArrays*>(primitiveset);
functor.begin(mode);
unsigned int indexEnd = drawArray->getFirst()+drawArray->getCount();
for(unsigned int vindex=drawArray->getFirst();
vindex<indexEnd;
++vindex)
{
functor.vertex(_vertexData.indices->index(vindex));
}
functor.end();
break;
}
case(PrimitiveSet::DrawArrayLengthsPrimitiveType):
{
const DrawArrayLengths* drawArrayLengths = static_cast<const DrawArrayLengths*>(primitiveset);
unsigned int vindex=drawArrayLengths->getFirst();
for(DrawArrayLengths::const_iterator primItr=drawArrayLengths->begin();
primItr!=drawArrayLengths->end();
++primItr)
{
functor.begin(mode);
for(GLsizei primCount=0;primCount<*primItr;++primCount)
{
functor.vertex(_vertexData.indices->index(vindex));
++vindex;
}
functor.end();
}
break;
}
case(PrimitiveSet::DrawElementsUBytePrimitiveType):
{
const DrawElementsUByte* drawElements = static_cast<const DrawElementsUByte*>(primitiveset);
functor.begin(mode);
unsigned int primCount=0;
for(DrawElementsUByte::const_iterator primItr=drawElements->begin();
primItr!=drawElements->end();
++primCount,++primItr)
{
unsigned int vindex=*primItr;
functor.vertex(_vertexData.indices->index(vindex));
}
functor.end();
break;
}
case(PrimitiveSet::DrawElementsUShortPrimitiveType):
{
const DrawElementsUShort* drawElements = static_cast<const DrawElementsUShort*>(primitiveset);
functor.begin(mode);
for(DrawElementsUShort::const_iterator primItr=drawElements->begin();
primItr!=drawElements->end();
++primItr)
{
unsigned int vindex=*primItr;
functor.vertex(_vertexData.indices->index(vindex));
}
functor.end();
break;
}
case(PrimitiveSet::DrawElementsUIntPrimitiveType):
{
const DrawElementsUInt* drawElements = static_cast<const DrawElementsUInt*>(primitiveset);
functor.begin(mode);
for(DrawElementsUInt::const_iterator primItr=drawElements->begin();
primItr!=drawElements->end();
++primItr)
{
unsigned int vindex=*primItr;
functor.vertex(_vertexData.indices->index(vindex));
}
functor.end();
break;
}
default:
{
break;
}
}
}
}
return;
}
unsigned int _computeNumberOfPrimtives(const osg::Geometry& geom)
{
unsigned int totalNumberOfPrimitives = 0;
for(Geometry::PrimitiveSetList::const_iterator itr=geom.getPrimitiveSetList().begin();
itr!=geom.getPrimitiveSetList().end();
++itr)
{
const PrimitiveSet* primitiveset = itr->get();
GLenum mode=primitiveset->getMode();
unsigned int primLength;
switch(mode)
{
case(GL_POINTS): primLength=1; osg::notify(osg::INFO)<<"prim=GL_POINTS"<<std::endl; break;
case(GL_LINES): primLength=2; osg::notify(osg::INFO)<<"prim=GL_LINES"<<std::endl; break;
case(GL_TRIANGLES): primLength=3; osg::notify(osg::INFO)<<"prim=GL_TRIANGLES"<<std::endl; break;
case(GL_QUADS): primLength=4; osg::notify(osg::INFO)<<"prim=GL_QUADS"<<std::endl; break;
default: primLength=0; osg::notify(osg::INFO)<<"prim="<<std::hex<<mode<<std::dec<<std::endl; break; // compute later when =0.
}
// draw primtives by the more flexible "slow" path,
// sending OpenGL glBegin/glVertex.../glEnd().
switch(primitiveset->getType())
{
case(PrimitiveSet::DrawArrayLengthsPrimitiveType):
{
const DrawArrayLengths* drawArrayLengths = static_cast<const DrawArrayLengths*>(primitiveset);
for(DrawArrayLengths::const_iterator primItr=drawArrayLengths->begin();
primItr!=drawArrayLengths->end();
++primItr)
{
if (primLength==0) totalNumberOfPrimitives += 1;
else totalNumberOfPrimitives += *primItr/primLength;
}
break;
}
default:
{
if (primLength==0) { totalNumberOfPrimitives += 1; osg::notify(osg::INFO)<<" totalNumberOfPrimitives="<<totalNumberOfPrimitives<<std::endl;}
else { totalNumberOfPrimitives += primitiveset->getNumIndices()/primLength; osg::notify(osg::INFO)<<" primitiveset->getNumIndices()="<<primitiveset->getNumIndices()<<" totalNumberOfPrimitives="<<totalNumberOfPrimitives<<std::endl; }
}
}
}
return totalNumberOfPrimitives;
}
template<class A>
bool _verifyBindings(const osg::Geometry& geom, const A& arrayData)
{
unsigned int numElements = arrayData.indices.valid()?arrayData.indices->getNumElements():
arrayData.array.valid()?arrayData.array->getNumElements():0;
switch(arrayData.binding)
{
case(osg::Geometry::BIND_OFF):
if (numElements>0) return false;
break;
case(osg::Geometry::BIND_OVERALL):
if (numElements!=1) return false;
break;
case(osg::Geometry::BIND_PER_PRIMITIVE_SET):
if (numElements!=geom.getPrimitiveSetList().size()) return false;
break;
case(osg::Geometry::BIND_PER_PRIMITIVE):
if (numElements!=_computeNumberOfPrimtives(geom)) return false;
break;
case(osg::Geometry::BIND_PER_VERTEX):
{
unsigned int numVertices = geom.getVertexIndices()?geom.getVertexIndices()->getNumElements():
geom.getVertexArray()?geom.getVertexArray()->getNumElements():0;
if (numElements!=numVertices) return false;
break;
}
}
return true;
}
template<class A>
void _computeCorrectBindingsAndArraySizes(std::ostream& out, const osg::Geometry& geom, A& arrayData, const char* arrayName)
{
unsigned int numElements = arrayData.indices.valid()?arrayData.indices->getNumElements():
arrayData.array.valid()?arrayData.array->getNumElements():0;
// check to see if binding matches 0 elements required.
if (numElements==0)
{
// correct binding if not correct.
if (arrayData.binding!=osg::Geometry::BIND_OFF)
{
out<<"Warning: in osg::Geometry::computeCorrectBindingsAndArraySizes() "<<std::endl
<<" "<<arrayName<<" binding has been reset to BIND_OFF"<<std::endl;
arrayData.binding=osg::Geometry::BIND_OFF;
}
return;
}
// check to see if binding matches 1 elements required.
if (numElements==1)
{
// correct binding if not correct.
if (arrayData.binding!=osg::Geometry::BIND_OVERALL)
{
out<<"Warning: in osg::Geometry::computeCorrectBindingsAndArraySizes() "<<std::endl
<<" "<<arrayName<<" binding has been reset to BIND_OVERALL"<<std::endl;
arrayData.binding=osg::Geometry::BIND_OVERALL;
}
return;
}
unsigned int numVertices = geom.getVertexIndices()?geom.getVertexIndices()->getNumElements():
geom.getVertexArray()?geom.getVertexArray()->getNumElements():0;
if ( numVertices==0 )
{
if (arrayData.binding!=osg::Geometry::BIND_OFF)
{
arrayData.array = 0;
arrayData.indices = 0;
arrayData.binding = osg::Geometry::BIND_OFF;
out<<"Warning: in osg::Geometry::computeCorrectBindingsAndArraySizes() vertex array is empty but "<<std::endl
<<" vertex array is empty but"<<arrayName<<" is set"<<std::endl
<<" reseting "<<arrayName<< " binding to BIND_OFF and array & indices to 0."<<std::endl;
}
}
if (numElements==numVertices)
{
// correct the binding to per vertex.
if (arrayData.binding!=osg::Geometry::BIND_PER_VERTEX)
{
out<<"Warning: in osg::Geometry::computeCorrectBindingsAndArraySizes() "<<std::endl
<<" "<<arrayName<<" binding has been reset to BIND_PER_VERTEX"<<std::endl;
arrayData.binding = osg::Geometry::BIND_PER_VERTEX;
}
return;
}
// check to see if binding might be per primitive set
unsigned int numPrimitiveSets = geom.getPrimitiveSetList().size();
if (numElements==numPrimitiveSets)
{
if (arrayData.binding != osg::Geometry::BIND_PER_PRIMITIVE_SET)
{
out<<"Warning: in osg::Geometry::computeCorrectBindingsAndArraySizes() "<<std::endl
<<" "<<arrayName<<" binding has been reset to BIND_PER_PRIMITIVE_SET"<<std::endl;
arrayData.binding = osg::Geometry::BIND_PER_PRIMITIVE_SET;
}
return;
}
// check to see if binding might be per primitive
unsigned int numPrimitives = _computeNumberOfPrimtives(geom);
if (numElements==numPrimitives)
{
if (arrayData.binding != osg::Geometry::BIND_PER_PRIMITIVE)
{
out<<"Warning: in osg::Geometry::computeCorrectBindingsAndArraySizes() "<<std::endl
<<" "<<arrayName<<" binding has been reset to BIND_PER_PRIMITIVE"<<std::endl;
arrayData.binding = osg::Geometry::BIND_PER_PRIMITIVE;
}
return;
}
if (numElements>numVertices)
{
arrayData.binding = osg::Geometry::BIND_PER_VERTEX;
return;
}
if (numElements>numPrimitives)
{
arrayData.binding = osg::Geometry::BIND_PER_PRIMITIVE;
return;
}
if (numElements>numPrimitiveSets)
{
arrayData.binding = osg::Geometry::BIND_PER_PRIMITIVE_SET;
return;
}
if (numElements>=1)
{
arrayData.binding = osg::Geometry::BIND_OVERALL;
return;
}
arrayData.binding = osg::Geometry::BIND_OFF;
}
bool Geometry::verifyBindings(const ArrayData& arrayData) const
{
return _verifyBindings(*this,arrayData);
}
bool Geometry::verifyBindings(const Vec3ArrayData& arrayData) const
{
return _verifyBindings(*this,arrayData);
}
void Geometry::computeCorrectBindingsAndArraySizes(ArrayData& arrayData, const char* arrayName)
{
_computeCorrectBindingsAndArraySizes(osg::notify(osg::INFO),*this,arrayData,arrayName);
}
void Geometry::computeCorrectBindingsAndArraySizes(Vec3ArrayData& arrayData, const char* arrayName)
{
_computeCorrectBindingsAndArraySizes(osg::notify(osg::INFO),*this,arrayData,arrayName);
}
bool Geometry::verifyBindings() const
{
if (!verifyBindings(_normalData)) return false;
if (!verifyBindings(_colorData)) return false;
if (!verifyBindings(_secondaryColorData)) return false;
if (!verifyBindings(_fogCoordData)) return false;
for(ArrayList::const_iterator titr=_texCoordList.begin();
titr!=_texCoordList.end();
++titr)
{
if (!verifyBindings(*titr)) return false;
}
for(ArrayList::const_iterator vitr=_vertexAttribList.begin();
vitr!=_vertexAttribList.end();
++vitr)
{
if (!verifyBindings(*vitr)) return false;
}
return true;
}
void Geometry::computeCorrectBindingsAndArraySizes()
{
// if (verifyBindings()) return;
computeCorrectBindingsAndArraySizes(_normalData,"_normalData");
computeCorrectBindingsAndArraySizes(_colorData,"_colorData");
computeCorrectBindingsAndArraySizes(_secondaryColorData,"_secondaryColorData");
computeCorrectBindingsAndArraySizes(_fogCoordData,"_fogCoordData");
for(ArrayList::iterator titr=_texCoordList.begin();
titr!=_texCoordList.end();
++titr)
{
computeCorrectBindingsAndArraySizes(*titr,"_texCoordList[]");
}
for(ArrayList::iterator vitr=_vertexAttribList.begin();
vitr!=_vertexAttribList.end();
++vitr)
{
computeCorrectBindingsAndArraySizes(*vitr,"_vertAttribList[]");
}
}
class ExpandIndexedArray : public osg::ConstArrayVisitor
{
public:
ExpandIndexedArray(const osg::IndexArray& indices,Array* targetArray):
_indices(indices),
_targetArray(targetArray) {}
virtual ~ExpandIndexedArray() {}
template <class T,class I>
T* create(const T& array,const I& indices)
{
T* newArray = 0;
// if source array type and target array type are equal but arrays arn't equal
if (_targetArray && _targetArray->getType()==array.getType() && _targetArray!=(osg::Array*)(&array))
{
// reuse exisiting target array
newArray = static_cast<T*>(_targetArray);
if (newArray->size()!=indices.size())
{
// make sure its the right size
newArray->resize(indices.size());
}
}
else
{
// else create a new array.
newArray = new T(indices.size());
}
for(unsigned int i=0;i<indices.size();++i)
{
(*newArray)[i]= array[indices[i]];
}
return newArray;
}
template <class T>
T* create(const T& array)
{
switch(_indices.getType())
{
case(osg::Array::ByteArrayType): return create(array,static_cast<const osg::ByteArray&>(_indices));
case(osg::Array::ShortArrayType): return create(array,static_cast<const osg::ShortArray&>(_indices));
case(osg::Array::IntArrayType): return create(array,static_cast<const osg::IntArray&>(_indices));
case(osg::Array::UByteArrayType): return create(array,static_cast<const osg::UByteArray&>(_indices));
case(osg::Array::UShortArrayType): return create(array,static_cast<const osg::UShortArray&>(_indices));
case(osg::Array::UIntArrayType): return create(array,static_cast<const osg::UIntArray&>(_indices));
default: return 0;
}
}
virtual void apply(const osg::ByteArray& array) { _targetArray = create(array); }
virtual void apply(const osg::ShortArray& array) { _targetArray = create(array); }
virtual void apply(const osg::IntArray& array) { _targetArray = create(array); }
virtual void apply(const osg::UByteArray& array) { _targetArray = create(array); }
virtual void apply(const osg::UShortArray& array) { _targetArray = create(array); }
virtual void apply(const osg::UIntArray& array) { _targetArray = create(array); }
virtual void apply(const osg::Vec4ubArray& array) { _targetArray = create(array); }
virtual void apply(const osg::FloatArray& array) { _targetArray = create(array); }
virtual void apply(const osg::Vec2Array& array) { _targetArray = create(array); }
virtual void apply(const osg::Vec3Array& array) { _targetArray = create(array); }
virtual void apply(const osg::Vec4Array& array) { _targetArray = create(array); }
const osg::IndexArray& _indices;
osg::Array* _targetArray;
};
bool Geometry::suitableForOptimization() const
{
bool hasIndices = false;
if (getVertexIndices()) hasIndices = true;
if (getNormalIndices()) hasIndices = true;
if (getColorIndices()) hasIndices = true;
if (getSecondaryColorIndices()) hasIndices = true;
if (getFogCoordIndices()) hasIndices = true;
for(unsigned int ti=0;ti<getNumTexCoordArrays();++ti)
{
if (getTexCoordIndices(ti)) hasIndices = true;
}
for(unsigned int vi=0;vi<getNumVertexAttribArrays();++vi)
{
if (getVertexAttribIndices(vi)) hasIndices = true;
}
return hasIndices;
}
void Geometry::copyToAndOptimize(Geometry& target)
{
bool copyToSelf = (this==&target);
// copy over primitive sets.
if (!copyToSelf) target.getPrimitiveSetList() = getPrimitiveSetList();
// copy over attribute arrays.
if (getVertexIndices())
{
ExpandIndexedArray eia(*(getVertexIndices()),target.getVertexArray());
getVertexArray()->accept(eia);
target.setVertexArray(eia._targetArray);
target.setVertexIndices(0);
}
else if (getVertexArray())
{
if (!copyToSelf) target.setVertexArray(getVertexArray());
}
target.setNormalBinding(getNormalBinding());
if (getNormalIndices())
{
ExpandIndexedArray eia(*(getNormalIndices()),target.getNormalArray());
getNormalArray()->accept(eia);
target.setNormalArray(dynamic_cast<osg::Vec3Array*>(eia._targetArray));
target.setNormalIndices(0);
}
else if (getNormalArray())
{
if (!copyToSelf) target.setNormalArray(getNormalArray());
}
target.setColorBinding(getColorBinding());
if (getColorIndices())
{
ExpandIndexedArray eia(*(getColorIndices()),target.getColorArray());
getColorArray()->accept(eia);
target.setColorArray(eia._targetArray);
target.setColorIndices(0);
}
else if (getColorArray())
{
if (!copyToSelf) target.setColorArray(getColorArray());
}
target.setSecondaryColorBinding(getSecondaryColorBinding());
if (getSecondaryColorIndices())
{
ExpandIndexedArray eia(*(getSecondaryColorIndices()),target.getSecondaryColorArray());
getSecondaryColorArray()->accept(eia);
target.setSecondaryColorArray(eia._targetArray);
target.setSecondaryColorIndices(0);
}
else if (getSecondaryColorArray())
{
if (!copyToSelf) target.setSecondaryColorArray(getSecondaryColorArray());
}
target.setFogCoordBinding(getFogCoordBinding());
if (getFogCoordIndices())
{
ExpandIndexedArray eia(*(getFogCoordIndices()),target.getFogCoordArray());
getFogCoordArray()->accept(eia);
target.setFogCoordArray(eia._targetArray);
target.setFogCoordIndices(0);
}
else if (getFogCoordArray())
{
if (!copyToSelf) target.setFogCoordArray(getFogCoordArray());
}
for(unsigned int ti=0;ti<getNumTexCoordArrays();++ti)
{
if (getTexCoordIndices(ti))
{
ExpandIndexedArray eia(*(getTexCoordIndices(ti)),target.getTexCoordArray(ti));
getTexCoordArray(ti)->accept(eia);
target.setTexCoordArray(ti,eia._targetArray);
target.setTexCoordIndices(ti,0);
}
else if (getTexCoordArray(ti))
{
if (!copyToSelf) target.setTexCoordArray(ti,getTexCoordArray(ti));
}
}
for(unsigned int vi=0;vi<_vertexAttribList.size();++vi)
{
ArrayData& arrayData = _vertexAttribList[vi];
if (arrayData.indices.valid())
{
ExpandIndexedArray eia(*arrayData.indices,target.getVertexAttribArray(vi));
arrayData.array->accept(eia);
target.setVertexAttribData(vi,ArrayData(eia._targetArray, 0, arrayData.binding, arrayData.normalize));
}
else if (arrayData.array.valid())
{
if (!copyToSelf) target.setVertexAttribData(vi,arrayData);
}
}
}
void Geometry::computeInternalOptimizedGeometry()
{
if (suitableForOptimization())
{
if (!_internalOptimizedGeometry) _internalOptimizedGeometry = new Geometry;
copyToAndOptimize(*_internalOptimizedGeometry);
}
}
Geometry* osg::createTexturedQuadGeometry(const Vec3& corner,const Vec3& widthVec,const Vec3& heightVec, float l, float b, float r, float t)
{
Geometry* geom = new Geometry;
Vec3Array* coords = new Vec3Array(4);
(*coords)[0] = corner+heightVec;
(*coords)[1] = corner;
(*coords)[2] = corner+widthVec;
(*coords)[3] = corner+widthVec+heightVec;
geom->setVertexArray(coords);
Vec2Array* tcoords = new Vec2Array(4);
(*tcoords)[0].set(l,t);
(*tcoords)[1].set(l,b);
(*tcoords)[2].set(r,b);
(*tcoords)[3].set(r,t);
geom->setTexCoordArray(0,tcoords);
osg::Vec4Array* colours = new osg::Vec4Array(1);
(*colours)[0].set(1.0f,1.0f,1.0,1.0f);
geom->setColorArray(colours);
geom->setColorBinding(Geometry::BIND_OVERALL);
osg::Vec3Array* normals = new osg::Vec3Array(1);
(*normals)[0] = widthVec^heightVec;
(*normals)[0].normalize();
geom->setNormalArray(normals);
geom->setNormalBinding(Geometry::BIND_OVERALL);
geom->addPrimitiveSet(new DrawArrays(PrimitiveSet::QUADS,0,4));
return geom;
}
///////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////
// experimental templated rendering code, please ignore...
// will move to osg::Geometry once complete.
// Robert Osfield, August 2003.
#if 0
struct DrawAttributeArrays
{
virtual bool valid() const = 0;
virtual void set(osg::Geometry* geometry) = 0;
virtual unsigned int draw(unsigned int index, unsigned int count) const = 0;
};
struct V3
{
V3():_array(0) {}
bool valid() const { return _array!=0; }
void set(osg::Geometry* geometry)
{
_array = 0;
osg::Array* array = geometry->getVertexArray();
if (array && array->getType()==osg::Array::Vec3ArrayType)
{
osg::Vec3Array* vec3array = static_cast<osg::Vec3Array*>(array);
if (!vec3array->empty()) _array = &(vec3array->front());
}
}
inline void draw(unsigned int index) const
{
glVertex3fv(_array[index].ptr());
}
osg::Vec3* _array;
};
struct V3USI
{
V3USI():_array(0),_indices(0) {}
bool valid() const { return _array!=0 && _indices!=0; }
void set(osg::Geometry* geometry)
{
_array = 0;
osg::Array* array = geometry->getVertexArray();
if (array && array->getType()==osg::Array::Vec3ArrayType)
{
osg::Vec3Array* vec3array = static_cast<osg::Vec3Array*>(array);
if (!vec3array->empty()) _array = &(vec3array->front());
}
_indices = 0;
osg::IndexArray* indices = geometry->getVertexIndices();
if (indices && indices->getType()==osg::Array::UShortArrayType)
{
osg::UShortArray* ushort3array = static_cast<osg::UShortArray*>(array);
if (!ushort3array->empty()) _indices = &(ushort3array->front());
}
}
inline void draw(unsigned int index) const
{
glVertex3fv(_array[_indices[index]].ptr());
}
osg::Vec3* _array;
unsigned short* _indices;
};
//////////////////////////////
struct N3
{
N3():_array(0) {}
bool valid() const { return _array!=0; }
void set(osg::Geometry* geometry)
{
_array = 0;
osg::Array* array = geometry->getVertexArray();
if (array && array->getType()==osg::Array::Vec3ArrayType)
{
osg::Vec3Array* vec3array = static_cast<osg::Vec3Array*>(array);
if (!vec3array->empty()) _array = &(vec3array->front());
}
}
inline void draw(unsigned int index) const
{
glNormal3fv(_array[index].ptr());
}
osg::Vec3* _array;
};
struct N3USI
{
N3USI():_array(0),_indices(0) {}
bool valid() const { return _array!=0 && _indices!=0; }
void set(osg::Geometry* geometry)
{
_array = 0;
osg::Array* array = geometry->getVertexArray();
if (array && array->getType()==osg::Array::Vec3ArrayType)
{
osg::Vec3Array* vec3array = static_cast<osg::Vec3Array*>(array);
if (!vec3array->empty()) _array = &(vec3array->front());
}
_indices = 0;
osg::IndexArray* indices = geometry->getVertexIndices();
if (indices && indices->getType()==osg::Array::UShortArrayType)
{
osg::UShortArray* ushortarray = static_cast<osg::UShortArray*>(array);
if (!ushortarray->empty()) _indices = &(ushortarray->front());
}
}
inline void draw(unsigned int index) const
{
glNormal3fv(_array[_indices[index]].ptr());
}
osg::Vec3* _array;
unsigned short* _indices;
};
//////////////////////////////
struct C4
{
C4():_array(0) {}
bool valid() const { return _array!=0; }
void set(osg::Geometry* geometry)
{
_array = 0;
osg::Array* array = geometry->getColorArray();
if (array && array->getType()==osg::Array::Vec4ArrayType)
{
osg::Vec4Array* vec4array = static_cast<osg::Vec4Array*>(array);
if (!vec4array->empty()) _array = &(vec4array->front());
}
}
inline void draw(unsigned int index) const
{
glVertex3fv(_array[index].ptr());
}
osg::Vec4* _array;
};
struct C4USI
{
C4USI():_array(0),_indices(0) {}
bool valid() const { return _array!=0 && _indices!=0; }
void set(osg::Geometry* geometry)
{
_array = 0;
osg::Array* array = geometry->getColorArray();
if (array && array->getType()==osg::Array::Vec4ArrayType)
{
osg::Vec4Array* vec4array = static_cast<osg::Vec4Array*>(array);
if (!vec4array->empty()) _array = &(vec4array->front());
}
_indices = 0;
osg::IndexArray* indices = geometry->getColorIndices();
if (indices && indices->getType()==osg::Array::UShortArrayType)
{
osg::UShortArray* ushortarray = static_cast<osg::UShortArray*>(array);
if (!ushortarray->empty()) _indices = &(ushortarray->front());
}
}
inline void draw(unsigned int index) const
{
glColor4fv(_array[_indices[index]].ptr());
}
osg::Vec4* _array;
unsigned short* _indices;
};
//////////////////////////////
struct T2
{
T2():_array(0) {}
bool valid() const { return _array!=0; }
void set(osg::Geometry* geometry)
{
_array = 0;
osg::Array* array = geometry->getTexCoordArray(0);
if (array && array->getType()==osg::Array::Vec2ArrayType)
{
osg::Vec2Array* vec2array = static_cast<osg::Vec2Array*>(array);
if (!vec2array->empty()) _array = &(vec2array->front());
}
}
inline void draw(unsigned int index) const
{
glTexCoord2fv(_array[index].ptr());
}
osg::Vec2* _array;
};
struct T2USI
{
T2USI():_array(0),_indices(0) {}
bool valid() const { return _array!=0 && _indices!=0; }
void set(osg::Geometry* geometry)
{
_array = 0;
osg::Array* array = geometry->getTexCoordArray(0);
if (array && array->getType()==osg::Array::Vec2ArrayType)
{
osg::Vec2Array* vec2array = static_cast<osg::Vec2Array*>(array);
if (!vec2array->empty()) _array = &(vec2array->front());
}
_indices = 0;
osg::IndexArray* indices = geometry->getTexCoordIndices(0);
if (indices && indices->getType()==osg::Array::UShortArrayType)
{
osg::UShortArray* ushortarray = static_cast<osg::UShortArray*>(array);
if (!ushortarray->empty()) _indices = &(ushortarray->front());
}
}
inline void draw(unsigned int index) const
{
glTexCoord2fv(_array[_indices[index]].ptr());
}
osg::Vec2* _array;
unsigned short* _indices;
};
/////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
template < class T1 >
struct DrawAttributeArrays_T : public DrawAttributeArrays
{
DrawAttributeArrays_T(osg::Geometry* geometry)
{
}
virtual bool valid() const { return _t1.valid(); }
virtual void set(osg::Geometry* geometry)
{
_t1.set(geometry);
}
virtual unsigned int draw(unsigned int index, unsigned int count) const
{
for(unsigned int i=0;i<count;++i,++index)
{
_t1.draw(index);
}
return index;
}
T1 _t1;
};
template < class T1, class T2 >
struct DrawAttributeArrays_TT : public DrawAttributeArrays
{
DrawAttributeArrays_TT()
{
}
virtual bool valid() const { return _t1.valid() && _t2.valid(); }
virtual void set(osg::Geometry* geometry)
{
_t1.set(geometry);
_t2.set(geometry);
}
virtual unsigned int draw(unsigned int index, unsigned int count) const
{
for(unsigned int i=0;i<count;++i,++index)
{
_t1.draw(index);
_t2.draw(index);
}
return index;
}
T1 _t1;
T1 _t2;
};
template < class T1, class T2, class T3 >
struct DrawAttributeArrays_TTT : public DrawAttributeArrays
{
DrawAttributeArrays_TTT()
{
}
virtual bool valid() const { return _t1.valid() && _t2.valid() && _t3.valid(); }
virtual void set(osg::Geometry* geometry)
{
_t1.set(geometry);
_t2.set(geometry);
_t3.set(geometry);
}
virtual unsigned int draw(unsigned int index, unsigned int count) const
{
for(unsigned int i=0;i<count;++i,++index)
{
_t1.draw(index);
_t2.draw(index);
_t3.draw(index);
}
return index;
}
T1 _t1;
T2 _t2;
T3 _t3;
};
template < class T1, class T2, class T3, class T4 >
struct DrawAttributeArrays_TTTT : public DrawAttributeArrays
{
DrawAttributeArrays_TTTT()
{
}
virtual bool valid() const { return _t1.valid() && _t2.valid() && _t3.valid() && _t4.valid(); }
virtual void set(osg::Geometry* geometry)
{
_t1.set(geometry);
_t2.set(geometry);
_t3.set(geometry);
_t4.set(geometry);
}
virtual unsigned int draw(unsigned int index, unsigned int count) const
{
for(unsigned int i=0;i<count;++i,++index)
{
_t1.draw(index);
_t2.draw(index);
_t3.draw(index);
_t4.draw(index);
}
return index;
}
T1 _t1;
T2 _t2;
T3 _t3;
T4 _t4;
};
template < class T1, class T2 >
struct DrawAttributeArrays_TT_USI : public DrawAttributeArrays
{
DrawAttributeArrays_TT_USI()
{
}
virtual bool valid() const { return _t1.valid() && _t2.valid() && _indices!=0; }
virtual void set(osg::Geometry* geometry)
{
_t1.set(geometry);
_t2.set(geometry);
_indices = 0;
osg::IndexArray* indices = geometry->getVertexIndices();
if (indices && indices->getType()==osg::Array::UShortArrayType)
{
osg::UShortArray* ushort3array = static_cast<osg::UShortArray*>(array);
if (!ushort3array->empty()) _indices = &(ushort3array->front());
}
}
virtual unsigned int draw(unsigned int index, unsigned int count) const
{
for(unsigned int i=0;i<count;++i,++index)
{
unsigned int ivalue = _indices[index];
_t1.draw(ivalue);
_t2.draw(ivalue);
}
return index;
}
T1 _t1;
T2 _t2;
};
template < class T1, class T2, class T3 >
struct DrawAttributeArrays_TTT_USI : public DrawAttributeArrays
{
DrawAttributeArrays_TTT_USI()
{
}
virtual bool valid() const { return _t1.valid() && _t2.valid() && _t3.valid() && _indices!=0; }
virtual void set(osg::Geometry* geometry)
{
_t1.set(geometry);
_t2.set(geometry);
_t3.set(geometry);
_indices = 0;
osg::IndexArray* indices = geometry->getVertexIndices();
if (indices && indices->getType()==osg::Array::UShortArrayType)
{
osg::UShortArray* ushort3array = static_cast<osg::UShortArray*>(array);
if (!ushort3array->empty()) _indices = &(ushort3array->front());
}
}
virtual unsigned int draw(unsigned int index, unsigned int count) const
{
for(unsigned int i=0;i<count;++i,++index)
{
unsigned int ivalue = _indices[index];
_t1.draw(ivalue);
_t2.draw(ivalue);
_t3.draw(ivalue);
}
return index;
}
T1 _t1;
T2 _t2;
T3 _t3;
};
template < class T1, class T2, class T3, class T4 >
struct DrawAttributeArrays_TTTT_USI : public DrawAttributeArrays
{
DrawAttributeArrays_TTTT_USI()
{
}
virtual bool valid() const { return _t1.valid() && _t2.valid() && _t3.valid() && _t4.valid() && _indices!=0; }
virtual void set(osg::Geometry* geometry)
{
_t1.set(geometry);
_t2.set(geometry);
_t3.set(geometry);
_t4.set(geometry);
_indices = 0;
osg::IndexArray* indices = geometry->getVertexIndices();
if (indices && indices->getType()==osg::Array::UShortArrayType)
{
osg::UShortArray* ushort3array = static_cast<osg::UShortArray*>(array);
if (!ushort3array->empty()) _indices = &(ushort3array->front());
}
}
virtual unsigned int draw(unsigned int index, unsigned int count) const
{
for(unsigned int i=0;i<count;++i,++index)
{
unsigned int ivalue = _indices[index];
_t1.draw(ivalue);
_t2.draw(ivalue);
_t3.draw(ivalue);
_t4.draw(ivalue);
}
return index;
}
T1 _t1;
T2 _t2;
T3 _t3;
T4 _t4;
};
/////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// One attribute x 2
typedef DrawAttributeArrays_T<V3> DrawAttributeArrays_V3;
typedef DrawAttributeArrays_T<V3USI> DrawAttributeArrays_V3i;
// Two attributes x 15
typedef DrawAttributeArrays_TT<N3,V3> DrawAttributeArrays_N3V3;
typedef DrawAttributeArrays_TT<N3USI,V3> DrawAttributeArrays_N3iV3;
typedef DrawAttributeArrays_TT<N3,V3USI> DrawAttributeArrays_N3V3i;
typedef DrawAttributeArrays_TT<N3USI,V3USI> DrawAttributeArrays_N3iV3i;
typedef DrawAttributeArrays_TT_USI<N3,V3> DrawAttributeArrays_N3V3_i;
typedef DrawAttributeArrays_TT<C4,V3> DrawAttributeArrays_C4V3;
typedef DrawAttributeArrays_TT<C4USI,V3> DrawAttributeArrays_C4iV3;
typedef DrawAttributeArrays_TT<C4,V3USI> DrawAttributeArrays_C4V3i;
typedef DrawAttributeArrays_TT<C4USI,V3USI> DrawAttributeArrays_C4iV3i;
typedef DrawAttributeArrays_TT_USI<C4,V3> DrawAttributeArrays_C4V3_i;
typedef DrawAttributeArrays_TT<T2,V3> DrawAttributeArrays_T2V3;
typedef DrawAttributeArrays_TT<T2USI,V3> DrawAttributeArrays_T2iV3;
typedef DrawAttributeArrays_TT<T2,V3USI> DrawAttributeArrays_T2V3i;
typedef DrawAttributeArrays_TT<T2USI,V3USI> DrawAttributeArrays_T2iV3i;
typedef DrawAttributeArrays_TT_USI<T2,V3> DrawAttributeArrays_T2V3_i;
// Three attributes x 27
typedef DrawAttributeArrays_TTT<C4,N3,V3> DrawAttributeArrays_C4N3V3;
typedef DrawAttributeArrays_TTT<C4USI,N3,V3> DrawAttributeArrays_C4iN3V3;
typedef DrawAttributeArrays_TTT<C4,N3USI,V3> DrawAttributeArrays_C4N3iV3;
typedef DrawAttributeArrays_TTT<C4USI,N3USI,V3> DrawAttributeArrays_C4iN3iV3;
typedef DrawAttributeArrays_TTT<C4,N3,V3USI> DrawAttributeArrays_C4N3V3i;
typedef DrawAttributeArrays_TTT<C4USI,N3,V3USI> DrawAttributeArrays_C4iN3V3i;
typedef DrawAttributeArrays_TTT<C4,N3USI,V3USI> DrawAttributeArrays_C4N3iV3i;
typedef DrawAttributeArrays_TTT<C4USI,N3USI,V3USI> DrawAttributeArrays_C4iN3iV3i;
typedef DrawAttributeArrays_TTT_USI<C4,N3,V3> DrawAttributeArrays_C4N3V3_i;
typedef DrawAttributeArrays_TTT<T2,N3,V3> DrawAttributeArrays_T2N3V3;
typedef DrawAttributeArrays_TTT<T2USI,N3,V3> DrawAttributeArrays_T2iN3V3;
typedef DrawAttributeArrays_TTT<T2,N3USI,V3> DrawAttributeArrays_T2iN3iV3;
typedef DrawAttributeArrays_TTT<T2USI,N3USI,V3> DrawAttributeArrays_T2N3iV3;
typedef DrawAttributeArrays_TTT<T2,N3,V3USI> DrawAttributeArrays_T2N3V3i;
typedef DrawAttributeArrays_TTT<T2USI,N3,V3USI> DrawAttributeArrays_T2iN3V3i;
typedef DrawAttributeArrays_TTT<T2,N3USI,V3USI> DrawAttributeArrays_T2iN3iV3i;
typedef DrawAttributeArrays_TTT<T2USI,N3USI,V3USI> DrawAttributeArrays_T2N3iV3i;
typedef DrawAttributeArrays_TTT_USI<T2,N3,V3> DrawAttributeArrays_T2N3V3_i;
typedef DrawAttributeArrays_TTT<T2,C4,V3> DrawAttributeArrays_T2C4V3;
typedef DrawAttributeArrays_TTT<T2USI,C4,V3> DrawAttributeArrays_T2iC4V3;
typedef DrawAttributeArrays_TTT<T2,C4USI,V3> DrawAttributeArrays_T2C4iV3;
typedef DrawAttributeArrays_TTT<T2USI,C4USI,V3> DrawAttributeArrays_T2iC4iV3;
typedef DrawAttributeArrays_TTT<T2,C4,V3USI> DrawAttributeArrays_T2C4V3i;
typedef DrawAttributeArrays_TTT<T2USI,C4,V3USI> DrawAttributeArrays_T2iC4V3i;
typedef DrawAttributeArrays_TTT<T2,C4USI,V3USI> DrawAttributeArrays_T2C4iV3i;
typedef DrawAttributeArrays_TTT<T2USI,C4USI,V3USI> DrawAttributeArrays_T2iC4iV3i;
typedef DrawAttributeArrays_TTT_USI<T2,C4,V3> DrawAttributeArrays_T2C4V3_t;
// Four attributes x 17
typedef DrawAttributeArrays_TTTT<T2,C4,N3,V3> DrawAttributeArrays_T2C4N3V3;
typedef DrawAttributeArrays_TTTT<T2USI,C4,N3,V3> DrawAttributeArrays_T2iC4N3V3;
typedef DrawAttributeArrays_TTTT<T2,C4USI,N3,V3> DrawAttributeArrays_T2C4iN3V3;
typedef DrawAttributeArrays_TTTT<T2USI,C4USI,N3,V3> DrawAttributeArrays_T2iC4iN3V3;
typedef DrawAttributeArrays_TTTT<T2,C4,N3USI,V3> DrawAttributeArrays_T2C4N3iV3;
typedef DrawAttributeArrays_TTTT<T2USI,C4,N3USI,V3> DrawAttributeArrays_T2iC4N3iV3;
typedef DrawAttributeArrays_TTTT<T2,C4USI,N3USI,V3> DrawAttributeArrays_T2C4iN3iV3;
typedef DrawAttributeArrays_TTTT<T2USI,C4USI,N3USI,V3> DrawAttributeArrays_T2iC4iN3iV3;
typedef DrawAttributeArrays_TTTT<T2,C4,N3,V3USI> DrawAttributeArrays_T2C4N3V3i;
typedef DrawAttributeArrays_TTTT<T2USI,C4,N3,V3USI> DrawAttributeArrays_T2iC4N3V3i;
typedef DrawAttributeArrays_TTTT<T2,C4USI,N3,V3USI> DrawAttributeArrays_T2C4iN3V3i;
typedef DrawAttributeArrays_TTTT<T2USI,C4USI,N3,V3USI> DrawAttributeArrays_T2iC4iN3V3i;
typedef DrawAttributeArrays_TTTT<T2,C4,N3USI,V3USI> DrawAttributeArrays_T2C4N3iV3i;
typedef DrawAttributeArrays_TTTT<T2USI,C4,N3USI,V3USI> DrawAttributeArrays_T2iC4N3iV3i;
typedef DrawAttributeArrays_TTTT<T2,C4USI,N3USI,V3USI> DrawAttributeArrays_T2C4iN3iV3i;
typedef DrawAttributeArrays_TTTT<T2USI,C4USI,N3USI,V3USI> DrawAttributeArrays_T2iC4iN3iV3i;
typedef DrawAttributeArrays_TTTT_USI<T2,C4,N3,V3> DrawAttributeArrays_T2C4N3V3_i;
/////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
#endif