// *********************************************************************************************************
void CDisplayerVisualEntity::drawBBox(const NLMISC::CMatrix &modelMatrix, const NLMISC::CAABBox &bbox, NLMISC::CRGBA colOverZ, NLMISC::CRGBA colUnderZ)
{
	//H_AUTO(R2_CDisplayerVisualEntity_drawBBox)
	//nlwarning("bbox = (%f, %f, %f) - (%f, %f, %f), color = (%d, %d, %d, %d)", bbox.getMin().x, bbox.getMin().y, bbox.getMin().z,
	//												bbox.getMax().x, bbox.getMax().y, bbox.getMax().z, (int) colOverZ.R, (int) colOverZ.G, (int) colOverZ.B, (int) colOverZ.A);
	// for z-precision, work with camera at (0, 0, 0)
	static volatile bool fixMatrixPos = false;
	CMatrix oldViewMatrix = Driver->getViewMatrix();
	Driver->setModelMatrix(modelMatrix);
	CMatrix viewMat = oldViewMatrix;
	if (fixMatrixPos)
	{
		viewMat.setPos(CVector::Null);
	}
	Driver->setViewMatrix(viewMat);
	// draw below zbuffer
	UMaterial::ZFunc oldZfunc = GenericMat.getZFunc();
	bool oldZWrite = GenericMat.getZWrite();
	GenericMat.setZFunc(UMaterial::greater);
	GenericMat.setZWrite(false);
	::drawBox(bbox.getMin(),   bbox.getMax(), colUnderZ );
	GenericMat.setZFunc(oldZfunc);
	GenericMat.setZWrite(oldZWrite);
	::drawBox(bbox.getMin(),   bbox.getMax(), colOverZ);
	Driver->setViewMatrix(oldViewMatrix);
}
// ***************************************************************************
void	CVisualCollisionMesh::CStaticGrid::create(uint nbQuads, uint nbElts, const NLMISC::CAABBox &gridBBox)
{
	/* ***********************************************
	 *	WARNING: This Class/Method must be thread-safe (ctor/dtor/serial): no static access for instance
	 *	It can be loaded/called through CAsyncFileManager for instance
	 * ***********************************************/

	nlassert(nbQuads>0 && isPowerOf2(nbQuads));

	// init the grid
	_GridSize= nbQuads;
	_GridSizePower= getPowerOf2(nbQuads);
	_Grid.resize(_GridSize*_GridSize);
	// start with 0 elt in each case
	memset(_Grid.getPtr(), 0, _Grid.size() * sizeof(CCase));

	// init the Elt Build
	_EltBuild.resize(nbElts);

	// total size is 0
	_GridDataSize= 0;

	// bbox init
	_GridPos= gridBBox.getMin();
	_GridScale= gridBBox.getSize();
	_GridScale.x= _GridSize / _GridScale.x;
	_GridScale.y= _GridSize / _GridScale.y;

	// reset intersection data
	_ItSession= 0;
}
// ***************************************************************************
void		CQuadGridClipClusterQTreeNode::insertModel(const NLMISC::CAABBox &worldBBox, uint distSetup, CTransformShape *model)
{
	// if leaf node, insert the model in the list
	if( LeafNode )
	{
		if(Empty)
		{
			Empty= false;
			BBox= worldBBox;
		}
		else
		{
			// extend the bbox with 2 corners of the incoming bbox (sufficient for an AABBox).
			BBox.extend( worldBBox.getCenter() + worldBBox.getHalfSize() );
			BBox.extend( worldBBox.getCenter() - worldBBox.getHalfSize() );
		}

		// insert in list
		ListNode.insertModel(distSetup, model);
	}
	// else, recurs insert in branch
	else
	{
		// choose what son according to pivot.
		CQuadGridClipClusterQTreeNode	*selectSon;
		if( worldBBox.getCenter().y<PivotBBox.getCenter().y )
		{
			if( worldBBox.getCenter().x<PivotBBox.getCenter().x )
				selectSon= Sons[NL3D_QCC_LEFT_DOWN];
			else
				selectSon= Sons[NL3D_QCC_RIGHT_DOWN];
		}
		else
		{
			if( worldBBox.getCenter().x<PivotBBox.getCenter().x )
				selectSon= Sons[NL3D_QCC_LEFT_UP];
			else
				selectSon= Sons[NL3D_QCC_RIGHT_UP];
		}

		// insert in this cluster
		selectSon->insertModel(worldBBox, distSetup, model);

		// extend my boox according to this son cluster.
		if(Empty)
		{
			Empty= false;
			BBox= selectSon->BBox;
		}
		else
		{
			// extend the bbox with 2 corners of the son bbox (sufficient for an AABBox).
			BBox.extend( selectSon->BBox.getCenter() + selectSon->BBox.getHalfSize() );
			BBox.extend( selectSon->BBox.getCenter() - selectSon->BBox.getHalfSize() );
		}
	}

	// update bboxExt
	BBoxExt= BBox;
}
// *********************************************************************************************************
NLMISC::CAABBox CDisplayerVisualEntity::getSelectBox() const
{
	//H_AUTO(R2_NLMISC_CAABBox )
	if (!_Entity)
	{
		if (_PlaceHolder)
		{
			return _PlaceHolder->getSelectBox();
		}
		return CDisplayerVisual::getSelectBox();
	}
	if (getSelectionType() == ISelectableObject::LocalSelectBox ||
		getSelectionType() == ISelectableObject::GroundProjected
	   )
	{
		if (_Entity->isAsyncLoading())
		{
			NLMISC::CAABBox result;
			result.setCenter(CVector::Null);
			result.setHalfSize(CVector::Null);
			return result;
		}
		return getEditor().getLocalSelectBox(*_Entity);
	}
	else
	{
		return getEditor().getSelectBox(*_Entity);
	}
}
void CParticleSystemPage::updatePrecomputedBBoxParams()
{
    NLMISC::CAABBox b;
    _Node->getPSPointer()->computeBBox(b);
    _ui.xDoubleSpinBox->setValue(b.getHalfSize().x);
    _ui.yDoubleSpinBox->setValue(b.getHalfSize().y);
    _ui.zDoubleSpinBox->setValue(b.getHalfSize().z);
}
void CParticleSystemPage::decBbox()
{
    NLMISC::CAABBox b;
    _Node->getPSPointer()->computeBBox(b);
    b.setHalfSize(0.9f * b.getHalfSize());
    _Node->getPSPointer()->setPrecomputedBBox(b);
    updatePrecomputedBBoxParams();
}
// *********************************************************************************************************
void CDisplayerVisualShape::drawBBox(NLMISC::CRGBA color) const
{
	//H_AUTO(R2_CDisplayerVisualShape_drawBBox)
	if (getRotateInProgress()) return; // no drawn while drawing (bbox moved one frame too late, must solve this)
	NLMISC::CAABBox bbox;
	_Instance.getShapeAABBox(bbox);
	Driver->setModelMatrix(_BBoxMatrix);
	::drawBox(bbox.getMin(),     bbox.getMax(), color);
}
// *********************************************************************************************************
NLMISC::CAABBox CDisplayerVisualShape::getSelectBox() const
{
	//H_AUTO(R2_CDisplayerVisualShape_getSelectBox)
	if (_Instance.empty()) return CDisplayerVisual::getSelectBox();
	// TODO nico : cache the bbox
	NLMISC::CAABBox bbox;
	_Instance.getShapeAABBox(bbox);
	bbox.setMinMax(_Scale * bbox.getMin(), _Scale * bbox.getMax());
	return bbox;
}
void CParticleSystemPage::setZBbox(double value)
{
    NLMISC::CAABBox b;
    _Node->getPSPointer()->computeBBox(b);
    NLMISC::CVector h;
    h.x = b.getHalfSize().x;
    h.y = b.getHalfSize().y;
    h.z = value;
    b.setHalfSize(h);
    _Node->getPSPointer()->setPrecomputedBBox(b);
}
Beispiel #10
0
// ***************************************************************************
void		CTransformShape::getAABBox(NLMISC::CAABBox &bbox) const
{
	if(Shape)
	{
		Shape->getAABBox(bbox);
	}
	else
	{
		bbox.setCenter(CVector::Null);
		bbox.setHalfSize(CVector::Null);
	}
}
// ***************************************************************************
uint	CVisualCollisionMesh::CStaticGrid::select(const NLMISC::CAABBox &bbox, std::vector<uint16> &res)
{
	/* ***********************************************
	 *	WARNING: This Class/Method must be thread-safe (ctor/dtor/serial): no static access for instance
	 *	It can be loaded/called through CAsyncFileManager for instance
	 * ***********************************************/

	// increment the intersection session
	_ItSession++;
	// enlarge the result array as needed
	if(res.size()<_Sessions.size())
		res.resize(_Sessions.size());
	// the number of selected element
	uint	numSel= 0;

	// compute the 2D bbox
	CVector	minp= bbox.getMin() - _GridPos;
	CVector	maxp= bbox.getMax() - _GridPos;
	sint	xmin= (sint)floorf(minp.x*_GridScale.x);
	sint	ymin= (sint)floorf(minp.y*_GridScale.y);
	sint	xmax= (sint)ceilf(maxp.x*_GridScale.x);
	sint	ymax= (sint)ceilf(maxp.y*_GridScale.y);
	clamp(xmin, 0, (sint)_GridSize-1);
	clamp(ymin, 0, (sint)_GridSize-1);
	clamp(xmax, xmin+1, (sint)_GridSize);
	clamp(ymax, ymin+1, (sint)_GridSize);

	// for each case touched, increment NumElts
	for(uint y=ymin;y<(uint)ymax;y++)
	{
		for(uint x=xmin;x<(uint)xmax;x++)
		{
			CCase	&gcase= _Grid[(y<<_GridSizePower)+x];
			// for each element in this case
			for(uint i= gcase.Start;i<gcase.Start + gcase.NumElts;i++)
			{
				uint	elt= _GridData[i];

				// if not alread inserted in the dest
				if(_Sessions[elt]!=_ItSession)
				{
					// mark as intersected
					_Sessions[elt]= _ItSession;
					// append
					res[numSel++]= elt;
				}
			}
		}
	}

	// return the number of selected elements
	return numSel;
}
///===========================================================================
void	CParticleSystemShape::getAABBox(NLMISC::CAABBox &bbox) const
{
	if (!_UsePrecomputedBBox)
	{
		bbox.setCenter(NLMISC::CVector::Null);
		bbox.setHalfSize(NLMISC::CVector(1, 1, 1));
	}
	else
	{
		bbox = _PrecomputedBBox;
	}
}
// *********************************************************************************************************
bool CDisplayerVisualEntity::isInProjection(const NLMISC::CVector2f &pos) const
{
	//H_AUTO(R2_CDisplayerVisualEntity_isInProjection)
	if (getActualSelectionDisplayMode() == CircleSelection) return false;
	nlassert(getSelectionType() == LocalSelectBox || getSelectionType() == GroundProjected);
	CVector localPos = getInvertedMatrix() * pos;
	NLMISC::CAABBox selectBox = getSelectBox();
	CVector pmin = selectBox.getMin();
	CVector pmax = selectBox.getMax();
	if (localPos.x < pmin.x || localPos.x > pmax.x ||
		localPos.y < pmin.y || localPos.y > pmax.y) return false;
	return true;
}
Beispiel #14
0
// *********************************************************************************************************
void CDisplayerVisual::evalIconInScenePos(NLMISC::CVector &dest) const
{
	//H_AUTO(R2_CDisplayerVisual_evalIconInScenePos)
	NLMISC::CAABBox selectBox = getSelectBox();
	float radius = std::max(selectBox.getHalfSize().x, selectBox.getHalfSize().y);
	// use middle front of bbox for icon pos
	NLMISC::CVector result = getWorldPos().asVector() - radius * MainCam.getMatrix().getJ() + selectBox.getHalfSize().z * CVector::K;
	static volatile bool wantAssert = true;
	if (!isValidDouble(result.x) || !isValidDouble(result.y) ||!isValidDouble(result.z))
	{
		nlassert(!wantAssert);
		return;
	}
	dest = result;
}
// ***************************************************************************
void	CVisualCollisionMesh::CStaticGrid::add(uint16 id, const NLMISC::CAABBox &bbox)
{
	/* ***********************************************
	 *	WARNING: This Class/Method must be thread-safe (ctor/dtor/serial): no static access for instance
	 *	It can be loaded/called through CAsyncFileManager for instance
	 * ***********************************************/

	CVector	minp= bbox.getMin() - _GridPos;
	CVector	maxp= bbox.getMax() - _GridPos;

	// compute the 2D bbox
	sint	xmin= (sint)floorf(minp.x*_GridScale.x);
	sint	ymin= (sint)floorf(minp.y*_GridScale.y);
	sint	xmax= (sint)ceilf(maxp.x*_GridScale.x);
	sint	ymax= (sint)ceilf(maxp.y*_GridScale.y);
	clamp(xmin, 0, (sint)_GridSize-1);
	clamp(ymin, 0, (sint)_GridSize-1);
	clamp(xmax, xmin+1, (sint)_GridSize);
	clamp(ymax, ymin+1, (sint)_GridSize);

	// set in the elt build
	_EltBuild[id].X0= xmin;
	_EltBuild[id].Y0= ymin;
	_EltBuild[id].X1= xmax;
	_EltBuild[id].Y1= ymax;

	// for each case touched, increment NumElts
	for(uint y=ymin;y<(uint)ymax;y++)
	{
		for(uint x=xmin;x<(uint)xmax;x++)
		{
			_Grid[(y<<_GridSizePower)+x].NumElts++;
			_GridDataSize++;
		}
	}
}
Beispiel #16
0
//============================================
void	CWaveMakerShape::getAABBox(NLMISC::CAABBox &bbox) const
{
	// its just a point
	bbox.setCenter(NLMISC::CVector::Null);
	bbox.setHalfSize(NLMISC::CVector::Null);
}
///=========================================================
int main (int argc, char* argv[])
{
	// Filter addSearchPath
	NLMISC::createDebug();
	InfoLog->addNegativeFilter ("adding the path");

	TShapeMap shapeMap;

	// Check number of args
	if (argc<5)
	{
		// Help message
		printf ("zone_dependencies [properties.cfg] [firstZone.zone] [lastzone.zone] [output_dependencies.cfg]\n");
	}
	else
	{
		NL3D::registerSerial3d();
		// Light direction
		CVector lightDirection;

		// Config file handler
		try
		{
			// Read the properties file
			CConfigFile properties;
			
			// Load and parse the properties file
			properties.load (argv[1]);

			// Get the light direction
			CConfigFile::CVar &sun_direction = properties.getVar ("sun_direction");
			lightDirection.set (sun_direction.asFloat(0), sun_direction.asFloat(1), sun_direction.asFloat(2));
			lightDirection.normalize();


			// Get the search pathes
			CConfigFile::CVar &search_pathes = properties.getVar ("search_pathes");
			uint path;
			for (path = 0; path < (uint)search_pathes.size(); path++)
			{
				// Add to search path
				CPath::addSearchPath (search_pathes.asString(path));
			}
/*
			CConfigFile::CVar &ig_path = properties.getVar ("ig_path");
			NLMISC::CPath::addSearchPath(ig_path.asString(), true, true);

			CConfigFile::CVar &shapes_path = properties.getVar ("shapes_path");
			NLMISC::CPath::addSearchPath(shapes_path.asString(), true, true);
*/
			CConfigFile::CVar &compute_dependencies_with_igs = properties.getVar ("compute_dependencies_with_igs");
			bool computeDependenciesWithIgs = compute_dependencies_with_igs.asInt() != 0;								


			// Get the file extension
			string ext=getExt (argv[2]);

			// Get the file directory
			string dir=getDir (argv[2]);

			// Get output extension
			string outExt=getExt (argv[4]);

			// Get output directory
			string outDir=getDir (argv[4]);

			// Get the first and last name
			string firstName=getName (argv[2]);
			string lastName=getName (argv[3]);

			// Get the coordinates
			uint16 firstX, firstY;
			uint16 lastX, lastY;
			if (getZoneCoordByName (firstName.c_str(), firstX, firstY))
			{
				// Last zone
				if (getZoneCoordByName (lastName.c_str(), lastX, lastY))
				{
					// Take care
					if (lastX<firstX)
					{
						uint16 tmp=firstX;
						firstX=lastX;
						lastX=firstX;
					}
					if (lastY<firstY)
					{
						uint16 tmp=firstY;
						firstY=lastY;
						lastY=firstY;
					}

					// Min z
					float minZ=FLT_MAX;

					// Make a quad grid
					CQuadGrid<CZoneDescriptorBB>	quadGrid;
					quadGrid.create (256, 100);

					// The dependencies list
					vector< CZoneDependencies > dependencies;
					dependencies.resize ((lastX-firstX+1)*(lastY-firstY+1));

					// Ryzom specific: build bbox for villages
					TString2LightingBBox villagesBBox;					
					computeIGBBoxFromContinent(properties, shapeMap, villagesBBox);		


					// Insert each zone in the quad tree
					sint y, x;
					for (y=firstY; y<=lastY; y++)
					for (x=firstX; x<=lastX; x++)
					{
						

						// Progress
						progress ("Build bounding boxes", (float)(x+y*lastX)/(float)(lastX*lastY));

						// Make a zone file name
						string zoneName;
						getZoneNameByCoord (x, y, zoneName);

						// Open the file
						CIFile file;
						if (file.open (dir+zoneName+ext))
						{							
							// The zone
							CZone zone;

							try
							{
								// Serial the zone
								file.serial (zone);

								/// get bbox from the ig of this zone
								CLightingBBox igBBox;								
								if (computeDependenciesWithIgs)
								{
									computeZoneIGBBox(zoneName.c_str(), igBBox, shapeMap, villagesBBox);
								}								
								// Create a zone descriptor
								

								
								NLMISC::CAABBox zoneBox;
								zoneBox.setCenter(zone.getZoneBB().getCenter());
								zoneBox.setHalfSize(zone.getZoneBB().getHalfSize());

								CLightingBBox zoneLBox;
								zoneLBox.OccludingBox = zoneLBox.ReceivingBox = zoneBox; // can't be void
								zoneLBox.makeUnion(igBBox);								
								nlassert(!zoneLBox.ReceivingBox.IsVoid);
								//
								CZoneDescriptorBB zoneDesc;
								zoneDesc.X=x;
								zoneDesc.Y=y;
								zoneDesc.BBox=zoneLBox.ReceivingBox.Box;
								//
								if (!zoneLBox.OccludingBox.IsVoid)
								{
									quadGrid.insert (zoneLBox.ReceivingBox.Box.getMin(), zoneLBox.ReceivingBox.Box.getMax(), zoneDesc);
								}
																								
								// Insert in the dependencies
								// Index 
								uint index=(x-firstX)+(y-firstY)*(lastX-firstX+1);
								

								// Loaded
								dependencies[index].Loaded=true;
								dependencies[index].X=x;
								dependencies[index].Y=y;
								dependencies[index].BBox=zoneLBox.OccludingBox.Box;

								// ZMin
								float newZ=zoneLBox.ReceivingBox.Box.getMin().z;
								if (newZ<minZ)
									minZ=newZ;
							}
							catch (Exception& e)
							{
								// Error handling
								nlwarning ("ERROR in file %s, %s", (dir+zoneName+ext).c_str(), e.what ());
							}
						}
					}

					// Now select each zone in others and make a depencies list
					for (y=firstY; y<=lastY; y++)
					for (x=firstX; x<=lastX; x++)
					{
						// Progress
						progress ("Compute dependencies", (float)(x+y*lastX)/(float)(lastX*lastY));

						// Index 
						uint index=(x-firstX)+(y-firstY)*(lastX-firstX+1);

						// Loaded ?
						if (dependencies[index].Loaded)
						{
							// Min max vectors
							CVector vMin (dependencies[index].BBox.getMin());
							CVector vMax (dependencies[index].BBox.getMax());

							// Make a corner array 
							CVector corners[4] = 
							{
								CVector (vMin.x, vMin.y, vMax.z), CVector (vMax.x, vMin.y, vMax.z), 
								CVector (vMax.x, vMax.y, vMax.z), CVector (vMin.x, vMax.y, vMax.z)
							};

							// Extended bbox
							CAABBox	bBox=dependencies[index].BBox.getAABBox();

							// For each corner
							uint corner;
							for (corner=0; corner<4; corner++)
							{
								// Target position
								CVector target;
								if (lightDirection.z!=0)
								{
									// Not horizontal target
									target=corners[corner]+(lightDirection*((minZ-corners[corner].z)/lightDirection.z));
								}
								else
								{
									// Horizontal target, select 500 meters around.
									target=(500*lightDirection)+corners[corner];
								}

								// Extend the bbox
								bBox.extend (target);
							}

							// Clear quad tree selection
							quadGrid.clearSelection ();

							// Select
							quadGrid.select (bBox.getMin(), bBox.getMax());

							// Check selection
							CQuadGrid<CZoneDescriptorBB>::CIterator it=quadGrid.begin();
							while (it!=quadGrid.end())
							{
								// Index 
								uint targetIndex=((*it).X-firstX)+((*it).Y-firstY)*(lastX-firstX+1);

								// Not the same
								if (targetIndex!=index)
								{
									// Target min z
									float targetMinZ=dependencies[targetIndex].BBox.getMin().z;
									if (targetMinZ<vMax.z)
									{
										// Min z inf to max z ?
										// Target optimized bbox
										CAABBox	bBoxOptimized=dependencies[index].BBox.getAABBox();

										// For each corner
										for (corner=0; corner<4; corner++)
										{
											// Target position
											CVector target;
											if (lightDirection.z!=0)
											{
												// Not horizontal target
												target=corners[corner]+(lightDirection*((targetMinZ-corners[corner].z)
													/lightDirection.z));
											}
											else
											{
												// Horizontal target, select 500 meters around.
												target=(500*lightDirection)+corners[corner];
											}

											// Extend the bbox
											bBoxOptimized.extend (target);
										}

										// Check it more presisly
										//if ((*it).BBox.intersect (bBoxOptimized))
										if ((*it).BBox.intersect (bBox))
										{
											// Insert in the set
											dependencies[targetIndex].Dependences.insert (CZoneDependenciesValue (x, y));
										}
									}
								}

								// Next selected
								it++;
							}
						}
					}

					// For each zone
					for (y=firstY; y<=lastY; y++)
					for (x=firstX; x<=lastX; x++)
					{
						// Progress
						progress ("Save depend files", (float)(x+y*lastX)/(float)(lastX*lastY));

						// Index 
						uint index=(x-firstX)+(y-firstY)*(lastX-firstX+1);

						// Loaded ?
						if (dependencies[index].Loaded)
						{
							// Make a file name
							string outputFileName;
							getZoneNameByCoord(x, y, outputFileName);
							outputFileName=outDir+outputFileName+outExt;

							// Write the dependencies file
							FILE *outputFile;
							if ((outputFile=fopen (toLower (outputFileName).c_str(), "w")))
							{
								// Add a dependency entry
								fprintf (outputFile, "dependencies =\n{\n");

								// Add dependent zones
								set<CZoneDependenciesValue>::iterator ite=dependencies[index].Dependences.begin();
								while (ite!=dependencies[index].Dependences.end())
								{
									// Name of the dependent zone
									std::string zoneName;
									getZoneNameByCoord(ite->first, ite->second, zoneName);

									// Write it
									string message="\t\""+zoneName+"\"";
									fprintf (outputFile, "%s", toLower (message).c_str());

									// Next ite;
									ite++;
									if (ite!=dependencies[index].Dependences.end())
										fprintf (outputFile, ",\n");
								}

								// Close the variable
								fprintf (outputFile, "\n};\n\n");
							}
							else
							{
								nlwarning ("ERROR can't open %s for writing.\n", outputFileName.c_str());
							}

							// Close the file
							fclose (outputFile);
						}
					}

				}
				else
				{
					// Not valid
					nlwarning ("ERROR %s is not a valid zone name.\n", lastName.c_str());
				}
			}
			else
			{
				// Not valid
				nlwarning ("ERROR %s is not a valid zone name.\n", firstName.c_str());
			}
		}
		catch (Exception &ee)
		{
			nlwarning ("ERROR %s\n", ee.what());
		}
	}

	return 0;
}
Beispiel #18
0
//***************************************************************************************************************
void				CFlareShape::getAABBox(NLMISC::CAABBox &bbox) const
{
	// the flare himself is a point
	bbox.setCenter(CVector::Null);
	bbox.setHalfSize(CVector::Null);
}
Beispiel #19
0
CInstanceGroup*	CExportNel::buildInstanceGroup(const vector<INode*>& vectNode, vector<INode*>& resultInstanceNode, TimeValue tvTime)
{
	// Extract from the node the name, the transformations and the parent

	CInstanceGroup::TInstanceArray aIGArray;
	uint32 i, nNumIG;
	uint32 j,k,m;

	aIGArray.empty ();
	resultInstanceNode.empty ();
	aIGArray.resize (vectNode.size());
	resultInstanceNode.resize (vectNode.size());

	int nNbInstance = 0;
	for (i = 0; i < vectNode.size(); ++i)
	{
		INode *pNode = vectNode[i];

		int nAccelType = CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_ACCEL, 32);

		if ((nAccelType&3) == 0) // If not an accelerator
		if (!RPO::isZone (*pNode, tvTime))
		if (CExportNel::isMesh (*pNode, tvTime) || CExportNel::isDummy(*pNode, tvTime))
		{
			++nNbInstance;
		}
	}

	// Check integrity of the hierarchy and set the parents
	std::vector<INode*>::const_iterator it = vectNode.begin();
	nNumIG = 0;
	for (i = 0; i < (sint)vectNode.size(); ++i, ++it)
	{
		INode *pNode = *it;

		int nAccelType = CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_ACCEL, 32);

		if ((nAccelType&3) == 0) // If not an accelerator
		if (!RPO::isZone( *pNode, tvTime ))
		if (CExportNel::isMesh( *pNode, tvTime ) || CExportNel::isDummy(*pNode, tvTime))
		{
			aIGArray[nNumIG].DontAddToScene = CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_DONT_ADD_TO_SCENE, 0)?true:false;
			aIGArray[nNumIG].InstanceName = CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_INSTANCE_NAME, "");
			resultInstanceNode[nNumIG] = pNode;
			if (aIGArray[nNumIG].InstanceName == "") // no instance name was set, takes the node name instead
			{
				aIGArray[nNumIG].InstanceName = pNode->GetName();
			}

			// Visible? always true, but if special flag for camera collision
			sint	appDataCameraCol= CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_CAMERA_COLLISION_MESH_GENERATION, 0);
			aIGArray[nNumIG].Visible= appDataCameraCol!=3;


			INode *pParent = pNode->GetParentNode();

			// Set the DontCastShadow flag.
			aIGArray[nNumIG].DontCastShadow= pNode->CastShadows()==0;

			// Set the Special DontCastShadow flag.
			aIGArray[nNumIG].DontCastShadowForInterior= CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_LIGHT_DONT_CAST_SHADOW_INTERIOR, BST_UNCHECKED)?true:false;
			aIGArray[nNumIG].DontCastShadowForExterior= CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_LIGHT_DONT_CAST_SHADOW_EXTERIOR, BST_UNCHECKED)?true:false;

			// Is the pNode has the root node for parent ?
			if( pParent->IsRootNode() == 0 )
			{
				// Look if the parent is in the selection
				int nNumIG2 = 0;
				for (j = 0; j < vectNode.size(); ++j)
				{
					INode *pNode2 = vectNode[j];

					int nAccelType2 = CExportNel::getScriptAppData (pNode2, NEL3D_APPDATA_ACCEL, 32);
					if ((nAccelType2&3) == 0) // If not an accelerator
					if (!RPO::isZone( *pNode2, tvTime ))
					if (CExportNel::isMesh( *pNode2, tvTime ))
					{
						if (pNode2 == pParent)
							break;
						++nNumIG2;
					}
				}
				if (nNumIG2 == nNbInstance)
				{
					// The parent is not selected ! link to root
					aIGArray[nNumIG].nParent = -1;
				}
				else
				{
					aIGArray[nNumIG].nParent = nNumIG2;
				}
			}
			else
			{
				aIGArray[nNumIG].nParent = -1;
			}
			++nNumIG;
		}
	}
	aIGArray.resize( nNumIG );
	resultInstanceNode.resize( nNumIG );

	// Build the array of node
	vGlobalPos = CVector(0,0,0);
	nNumIG = 0;
	it = vectNode.begin();
	for (i = 0; i < (sint)vectNode.size(); ++i, ++it)
	{
		INode *pNode = *it;

		int nAccelType = CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_ACCEL, 32);

		if ((nAccelType&3) == 0) // If not an accelerator
		if (!RPO::isZone (*pNode, tvTime))
		if (CExportNel::isMesh (*pNode, tvTime) || CExportNel::isDummy(*pNode, tvTime))
		{
			CVector vScaleTemp;
			CQuat qRotTemp;
			CVector vPosTemp;

			// Get Nel Name for the object.
			aIGArray[nNumIG].Name= CExportNel::getNelObjectName(*pNode);

			//Get the local transformation matrix
			Matrix3 nodeTM = pNode->GetNodeTM(0);
			INode *pParent = pNode->GetParentNode();
			Matrix3 parentTM = pParent->GetNodeTM(0);
			Matrix3 localTM	= nodeTM*Inverse(parentTM);

			// Extract transformations
			CExportNel::decompMatrix (vScaleTemp, qRotTemp, vPosTemp, localTM);
			aIGArray[nNumIG].Rot   = qRotTemp;
			aIGArray[nNumIG].Pos   = vPosTemp;
			aIGArray[nNumIG].Scale = vScaleTemp;
			vGlobalPos += vPosTemp;
			++nNumIG;
		}
	}
	// todo Make this work (precision):
	/*
	vGlobalPos = vGlobalPos / nNumIG;
	for (i = 0; i < nNumIG; ++i)
		aIGArray[i].Pos -= vGlobalPos;
	*/

	vGlobalPos = CVector(0,0,0); // Temporary !!!

	// Accelerator Portal/Cluster part
	//=================

	// Creation of all the clusters
	vector<CCluster> vClusters;
	it = vectNode.begin();
	for (i = 0; i < (sint)vectNode.size(); ++i, ++it)
	{
		INode *pNode = *it;

		int nAccelType = CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_ACCEL, NEL3D_APPDATA_ACCEL_DEFAULT);
		bool bFatherVisible = nAccelType&NEL3D_APPDATA_ACCEL_FATHER_VISIBLE?true:false;
		bool bVisibleFromFather = nAccelType&NEL3D_APPDATA_ACCEL_VISIBLE_FROM_FATHER?true:false;
		bool bAudibleLikeVisible = (nAccelType&NEL3D_APPDATA_ACCEL_AUDIBLE_NOT_LIKE_VISIBLE)?false:true;
		bool bFatherAudible = bAudibleLikeVisible ? bFatherVisible : nAccelType&NEL3D_APPDATA_ACCEL_FATHER_AUDIBLE?true:false;
		bool bAudibleFromFather = bAudibleLikeVisible ? bVisibleFromFather : nAccelType&NEL3D_APPDATA_ACCEL_AUDIBLE_FROM_FATHER?true:false;

		if ((nAccelType&NEL3D_APPDATA_ACCEL_TYPE) == NEL3D_APPDATA_ACCEL_CLUSTER) // If cluster
		if (!RPO::isZone (*pNode, tvTime))
		if (CExportNel::isMesh(*pNode, tvTime))
		{
			CCluster clusterTemp;
			std::string temp;

			temp = CExportNel::getScriptAppData(pNode, NEL3D_APPDATA_SOUND_GROUP, "no sound");
			clusterTemp.setSoundGroup(temp != "no sound" ? temp : "");
			temp = CExportNel::getScriptAppData(pNode, NEL3D_APPDATA_ENV_FX, "no fx");
			clusterTemp.setEnvironmentFx(temp != "no fx" ? temp : "");

			CMesh::CMeshBuild *pMB;
			CMeshBase::CMeshBaseBuild *pMBB;
			pMB = createMeshBuild (*pNode, tvTime, pMBB);

			convertToWorldCoordinate( pMB, pMBB );

			for (j = 0; j < pMB->Faces.size(); ++j)
			{
				if (!clusterTemp.makeVolume (pMB->Vertices[pMB->Faces[j].Corner[0].Vertex],
											 pMB->Vertices[pMB->Faces[j].Corner[1].Vertex],
											 pMB->Vertices[pMB->Faces[j].Corner[2].Vertex]) )
				{
					// ERROR : The volume is not convex !!!
					char tam[256];
					sprintf(tam,"ERROR: The cluster %s is not convex.",vectNode[i]->GetName());
					//MessageBox(NULL,tam,"Error",MB_OK|MB_ICONERROR);
					nlwarning(tam);
				}
			}

			clusterTemp.FatherVisible = bFatherVisible;
			clusterTemp.VisibleFromFather = bVisibleFromFather;
			clusterTemp.FatherAudible = bFatherAudible;
			clusterTemp.AudibleFromFather = bAudibleFromFather;
			clusterTemp.Name = pNode->GetName();

			vClusters.push_back (clusterTemp);
			delete pMB;
			delete pMBB;
		}
	}

	// Creation of all the portals
	vector<CPortal> vPortals;
	it = vectNode.begin();
	for (i = 0; i < (sint)vectNode.size(); ++i, ++it)
	{
		INode *pNode = *it;

		int nAccelType = CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_ACCEL, 32);

		if ((nAccelType&3) == 1) // If Portal
		if (!RPO::isZone (*pNode, tvTime))
		if (CExportNel::isMesh(*pNode, tvTime))
		{
			CPortal portalTemp;
			std::string temp;

			temp = CExportNel::getScriptAppData(pNode, NEL3D_APPDATA_OCC_MODEL, "no occlusion");
			portalTemp.setOcclusionModel(temp != "no occlusion" ? temp : "");
			temp = CExportNel::getScriptAppData(pNode, NEL3D_APPDATA_OPEN_OCC_MODEL, "no occlusion");
			portalTemp.setOpenOcclusionModel(temp != "no occlusion" ? temp : "");

			CMesh::CMeshBuild *pMB;
			CMeshBase::CMeshBaseBuild *pMBB;
			pMB = createMeshBuild (*pNode, tvTime, pMBB);

			convertToWorldCoordinate( pMB, pMBB );

			vector<sint32> poly;
			vector<bool> facechecked;
			facechecked.resize (pMB->Faces.size());
			for (j = 0; j < pMB->Faces.size(); ++j)
				facechecked[j] = false;

			poly.push_back(pMB->Faces[0].Corner[0].Vertex);
			poly.push_back(pMB->Faces[0].Corner[1].Vertex);
			poly.push_back(pMB->Faces[0].Corner[2].Vertex);
			facechecked[0] = true;
			for (j = 0; j < pMB->Faces.size(); ++j)
			if (!facechecked[j])
			{
				bool found = false;

				for(k = 0; k < 3; ++k)
				{
					for(m = 0; m < poly.size(); ++m)
					{
						if ((pMB->Faces[j].Corner[k].Vertex == poly[m]) &&
							(pMB->Faces[j].Corner[(k+1)%3].Vertex == poly[(m+1)%poly.size()]))
						{
							found = true;
							break;
						}
						if ((pMB->Faces[j].Corner[(k+1)%3].Vertex == poly[m]) &&
							(pMB->Faces[j].Corner[k].Vertex == poly[(m+1)%poly.size()]))
						{
							found = true;
							break;
						}
					}
					if (found)
						break;
				}
				if (found)
				{
					// insert an empty space in poly between m and m+1
					poly.resize (poly.size()+1);
					for (uint32 a = poly.size()-2; a > m; --a)
						poly[a+1] = poly[a];
					poly[m+1] = pMB->Faces[j].Corner[(k+2)%3].Vertex;
					facechecked[j] = true;
					j = 0;
				}
			}
			vector<CVector> polyv;
			polyv.resize (poly.size());
			for (j = 0; j < poly.size(); ++j)
				polyv[j] = pMB->Vertices[poly[j]];
			
			if (!portalTemp.setPoly (polyv))
			{
				// ERROR : Poly not convex, or set of vertices not plane
				char tam[256];
				sprintf(tam,"ERROR: The portal %s is not convex.",vectNode[i]->GetName());
				//MessageBox(NULL,tam,"Error",MB_OK|MB_ICONERROR);
				nlwarning(tam);
			}

			if (nAccelType&16) // is dynamic portal ?
			{
				string InstanceName = CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_INSTANCE_NAME, "");
				if (!InstanceName.empty())
					portalTemp.setName (InstanceName);
				else
					portalTemp.setName (string(pNode->GetName()));
			}

			// Check if portal has 2 cluster
			int nNbCluster = 0;
			for (j = 0; j < vClusters.size(); ++j)
			{
				bool bPortalInCluster = true;
				for (k = 0; k < polyv.size(); ++k)
					if (!vClusters[j].isIn (polyv[k]) )
					{
						bPortalInCluster = false;
						break;
					}
				if (bPortalInCluster)
					++nNbCluster;
			}
			if (nNbCluster != 2)
			{
				// ERROR
				char tam[256];
				sprintf(tam,"ERROR: The portal %s has not 2 clusters but %d",vectNode[i]->GetName(), nNbCluster);
				//MessageBox(NULL,tam,"Error",MB_OK|MB_ICONERROR);
				nlwarning(tam);
			}


			vPortals.push_back (portalTemp);
			delete pMB;
			delete pMBB;
		}
	}

	// Link instance to clusters (an instance has a list of clusters)
	nNumIG = 0;
	it = vectNode.begin();
	for (i = 0; i < (sint)vectNode.size(); ++i, ++it)
	{
		INode *pNode = *it;

		int nAccelType = CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_ACCEL, 32);

		if ((nAccelType&3) == 0) // If not an accelerator
		if (!RPO::isZone (*pNode, tvTime))
		if (CExportNel::isMesh (*pNode, tvTime) || CExportNel::isDummy(*pNode, tvTime))
		{
			if (nAccelType&32) // Is the flag clusterize set ?
			{
				// Test against all clusters

				// The list of vertices used to test against cluster
				std::vector<NLMISC::CVector> *testVertices;
				std::vector<NLMISC::CVector>       FXVertices;  // Used only if the obj is a fx. It contains the corners of the bbox.
				bool  buildMeshBBox = true;

				/** If it is a mesh, we build its bbox and transform in world
				  * If it is a FX, we read its bbox from its shape
				  * If we can't read it, we use the bbox of the fx helper in max
				  */
				Object *obj = pNode->EvalWorldState(tvTime).obj;
				// Check if there is an object
				if (obj)
				{
					Class_ID  clid = obj->ClassID();
					// is the object a particle system ?					
					if (clid.PartA() == NEL_PARTICLE_SYSTEM_CLASS_ID)
					{
						// build the shape from the file name
						std::string objName = CExportNel::getNelObjectName(*pNode); 						
						if (!objName.empty())
						{											
							NL3D::CShapeStream ss;
							NLMISC::CIFile iF;
							if (iF.open(objName.c_str()))
							{
								try
								{								
									iF.serial(ss);
									NL3D::CParticleSystemShape *pss = dynamic_cast<NL3D::CParticleSystemShape *>(ss.getShapePointer());
									if (!pss)
									{
										nlwarning("ERROR: Node %s shape is not a FX", CExportNel::getName(*pNode).c_str());
									}
									else
									{									
										NLMISC::CAABBox bbox;
										pss->getAABBox(bbox);
										// transform in world
										Matrix3 xForm = pNode->GetNodeTM(tvTime);
										NLMISC::CMatrix nelXForm;
										CExportNel::convertMatrix(nelXForm, xForm);									
										bbox = NLMISC::CAABBox::transformAABBox(nelXForm, bbox);
										// store vertices of the bbox in the list
										FXVertices.reserve(8);
										for(uint k = 0; k < 8; ++k)
										{
											FXVertices.push_back(CVector(((k & 1) ? 1 : -1) * bbox.getHalfSize().x + bbox.getCenter().x,
																		 ((k & 2) ? 1 : -1) * bbox.getHalfSize().y + bbox.getCenter().y,
																		 ((k & 4) ? 1 : -1) * bbox.getHalfSize().z + bbox.getCenter().z));
										}
										//
										testVertices = &FXVertices;
										buildMeshBBox = false;
									}
									delete ss.getShapePointer();
								}
								catch (NLMISC::Exception &e)
								{
									nlwarning(e.what());									
								}
							}							
							if (buildMeshBBox)
							{
								nlwarning("ERROR: Can't get bbox of a particle system from its shape, using helper bbox instead");
							}
						}
					}
				}

				CMesh::CMeshBuild *pMB = NULL;
				CMeshBase::CMeshBaseBuild *pMBB = NULL;

				if (buildMeshBBox)
				{				
					pMB = createMeshBuild (*pNode, tvTime, pMBB);
					convertToWorldCoordinate( pMB, pMBB );
					testVertices = &pMB->Vertices;
				}

				for(k = 0; k < vClusters.size(); ++k)
				{
					bool bMeshInCluster = false;

					for(j = 0; j < testVertices->size(); ++j)
					{
						if (vClusters[k].isIn ((*testVertices)[j]))
						{
							bMeshInCluster = true;
							break;
						}
					}

					if (bMeshInCluster)
					{
						aIGArray[nNumIG].Clusters.push_back (k);
					}
				}
				
				// debug purpose : to remove
				if (vClusters.size() > 0)
				if (aIGArray[nNumIG].Clusters.size() == 0)
				{
					char tam[256];
					sprintf(tam,"ERROR: Object %s is not attached to any cluster\nbut his flag clusterize is set", pNode->GetName());
					//MessageBox(NULL, tam, "Warning", MB_OK);
					nlwarning(tam);
				}
				// debug purpose : to remove

				delete pMB;
				delete pMBB;
			}
			
			++nNumIG;
		}
		// debug purpose : to remove
		/*
		if ((nAccelType&3) == 0) // If not an accelerator
		if (!(nAccelType&32))
		{
			char tam[256];
			sprintf(tam,"Object %s is not clusterized", pNode->GetName());
			MessageBox(NULL, tam, "Info", MB_OK);
		}
		*/
		// debug purpose : to remove

	}


	// PointLight part
	//=================
	bool	sunLightEnabled= false;
	sint	nNumPointLight = 0;
	vector<CPointLightNamed>	pointLights;
	pointLights.resize(vectNode.size());
	// For all nodes
	for (i = 0; i < (sint)vectNode.size(); ++i)
	{
		INode *pNode = vectNode[i];

		SLightBuild		sLightBuild;

		// If it is a Max Light.
		if ( sLightBuild.canConvertFromMaxLight(pNode, tvTime) )
		{
			// And if this light is checked to realtime export
			int		nRTExport= CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_EXPORT_REALTIME_LIGHT, BST_CHECKED);
			if(nRTExport == BST_CHECKED)
			{
				// get Max Light info.
				sLightBuild.convertFromMaxLight(pNode, tvTime);

				// Skip if LightDir
				if(sLightBuild.Type != SLightBuild::LightDir)
				{
					// Fill PointLight Info.
					NL3D::CPointLightNamed	&plNamed= pointLights[nNumPointLight];

					// Position
					plNamed.setPosition(sLightBuild.Position);
					// Attenuation
					plNamed.setupAttenuation(sLightBuild.rRadiusMin, sLightBuild.rRadiusMax);
					// Colors
					// Ensure A=255 for localAmbient to work.
					NLMISC::CRGBA	ambient= sLightBuild.Ambient;
					ambient.A= 255;
					plNamed.setDefaultAmbient(ambient);
					plNamed.setAmbient(ambient);
					plNamed.setDefaultDiffuse(sLightBuild.Diffuse);
					plNamed.setDiffuse(sLightBuild.Diffuse);
					plNamed.setDefaultSpecular(sLightBuild.Specular);
					plNamed.setSpecular(sLightBuild.Specular);

					// GroupName.
					plNamed.AnimatedLight = sLightBuild.AnimatedLight;
					plNamed.LightGroup = sLightBuild.LightGroup;

					// Which light type??
					if(sLightBuild.bAmbientOnly || sLightBuild.Type== SLightBuild::LightAmbient)
					{
						plNamed.setType(CPointLight::AmbientLight);
						// Special ambient info
						int		nRTAmbAdd= CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_REALTIME_AMBIENT_ADD_SUN, BST_UNCHECKED);
						plNamed.setAddAmbientWithSun(nRTAmbAdd==BST_CHECKED);
					}
					else if(sLightBuild.Type== SLightBuild::LightPoint)
					{
						plNamed.setType(CPointLight::PointLight);
					}
					else if(sLightBuild.Type== SLightBuild::LightSpot)
					{
						plNamed.setType(CPointLight::SpotLight);
						// Export Spot infos.
						plNamed.setupSpotDirection(sLightBuild.Direction);
						plNamed.setupSpotAngle(sLightBuild.rHotspot, sLightBuild.rFallof);
					}
					else
					{
						// What???
						nlstop;
					}


					// inc Size
					++nNumPointLight;
				}
			}

			// if this light is a directionnal and checked to export as Sun Light
			int		nExportSun= CExportNel::getScriptAppData (pNode, NEL3D_APPDATA_EXPORT_AS_SUN_LIGHT, BST_UNCHECKED);
			if(nExportSun== BST_CHECKED)
			{
				// get Max Light info.
				sLightBuild.convertFromMaxLight(pNode, tvTime);

				// Skip if not dirLight.
				if(sLightBuild.Type == SLightBuild::LightDir)
					sunLightEnabled= true;
			}
		}
	}
	// Good size
	pointLights.resize(nNumPointLight);


	// Build the ig
	//=================

	CInstanceGroup* pIG = new CInstanceGroup;

	// Link portals and clusters and create meta cluster if one
	pIG->build (vGlobalPos,  aIGArray, vClusters, vPortals, pointLights);

	// IG touched by sun ??
	pIG->enableRealTimeSunContribution(sunLightEnabled);

	return pIG;
}