// // ******************************************************************** // * License and Disclaimer * // * * // * The Geant4 software is copyright of the Copyright Holders of * // * the Geant4 Collaboration. It is provided under the terms and * // * conditions of the Geant4 Software License, included in the file * // * LICENSE and available at http://cern.ch/geant4/license . These * // * include a list of copyright holders. * // * * // * Neither the authors of this software system, nor their employing * // * institutes,nor the agencies providing financial support for this * // * work make any representation or warranty, express or implied, * // * regarding this software system or assume any liability for its * // * use. Please see the license in the file LICENSE and URL above * // * for the full disclaimer and the limitation of liability. * // * * // * This code implementation is the result of the scientific and * // * technical work of the GEANT4 collaboration. * // * By using, copying, modifying or distributing the software (or * // * any work based on the software) you agree to acknowledge its * // * use in resulting scientific publications, and indicate your * // * acceptance of all terms of the Geant4 Software license. * // ******************************************************************** // // // $Id: G4GDMLWriteStructure.cc,v 1.83 2010/10/14 16:19:40 gcosmo Exp $ // GEANT4 tag $Name: gdml-V09-03-09 $ // // class G4GDMLWriteStructure Implementation // // Original author: Zoltan Torzsok, November 2007 // // -------------------------------------------------------------------- #include "G4GDMLWriteStructure.hh" #include "G4Material.hh" #include "G4ReflectedSolid.hh" #include "G4DisplacedSolid.hh" #include "G4LogicalVolumeStore.hh" #include "G4PhysicalVolumeStore.hh" #include "G4PVDivision.hh" #include "G4PVReplica.hh" #include "G4OpticalSurface.hh" #include "G4LogicalSkinSurface.hh" #include "G4LogicalBorderSurface.hh" G4GDMLWriteStructure::G4GDMLWriteStructure() : G4GDMLWriteParamvol() { } G4GDMLWriteStructure::~G4GDMLWriteStructure() { } void G4GDMLWriteStructure::DivisionvolWrite(xercesc::DOMElement* volumeElement, const G4PVDivision* const divisionvol) { EAxis axis = kUndefined; G4int number = 0; G4double width = 0.0; G4double offset = 0.0; G4bool consuming = false; divisionvol->GetReplicationData(axis,number,width,offset,consuming); axis = divisionvol->GetDivisionAxis(); G4String unitString("mm"); G4String axisString("kUndefined"); if (axis==kXAxis) { axisString = "kXAxis"; } else if (axis==kYAxis) { axisString = "kYAxis"; } else if (axis==kZAxis) { axisString = "kZAxis"; } else if (axis==kRho) { axisString = "kRho"; } else if (axis==kPhi) { axisString = "kPhi"; unitString = "rad"; } const G4String name = GenerateName(divisionvol->GetName(),divisionvol); const G4String volumeref = GenerateName(divisionvol->GetLogicalVolume()->GetName(), divisionvol->GetLogicalVolume()); xercesc::DOMElement* divisionvolElement = NewElement("divisionvol"); divisionvolElement->setAttributeNode(NewAttribute("axis",axisString)); divisionvolElement->setAttributeNode(NewAttribute("number",number)); divisionvolElement->setAttributeNode(NewAttribute("width",width)); divisionvolElement->setAttributeNode(NewAttribute("offset",offset)); divisionvolElement->setAttributeNode(NewAttribute("unit",unitString)); xercesc::DOMElement* volumerefElement = NewElement("volumeref"); volumerefElement->setAttributeNode(NewAttribute("ref",volumeref)); divisionvolElement->appendChild(volumerefElement); volumeElement->appendChild(divisionvolElement); } void G4GDMLWriteStructure::PhysvolWrite(xercesc::DOMElement* volumeElement, const G4VPhysicalVolume* const physvol, const G4Transform3D& T, const G4String& ModuleName) { HepGeom::Scale3D scale; HepGeom::Rotate3D rotate; HepGeom::Translate3D translate; T.getDecomposition(scale,rotate,translate); const G4ThreeVector scl(scale(0,0),scale(1,1),scale(2,2)); const G4ThreeVector rot = GetAngles(rotate.getRotation()); const G4ThreeVector pos = T.getTranslation(); const G4String name = GenerateName(physvol->GetName(),physvol); xercesc::DOMElement* physvolElement = NewElement("physvol"); physvolElement->setAttributeNode(NewAttribute("name",name)); volumeElement->appendChild(physvolElement); const G4String volumeref = GenerateName(physvol->GetLogicalVolume()->GetName(), physvol->GetLogicalVolume()); if (ModuleName.empty()) { xercesc::DOMElement* volumerefElement = NewElement("volumeref"); volumerefElement->setAttributeNode(NewAttribute("ref",volumeref)); physvolElement->appendChild(volumerefElement); } else { xercesc::DOMElement* fileElement = NewElement("file"); fileElement->setAttributeNode(NewAttribute("name",ModuleName)); fileElement->setAttributeNode(NewAttribute("volname",volumeref)); physvolElement->appendChild(fileElement); } if (std::fabs(pos.x()) > kLinearPrecision || std::fabs(pos.y()) > kLinearPrecision || std::fabs(pos.z()) > kLinearPrecision) { PositionWrite(physvolElement,name+"_pos",pos); } if (std::fabs(rot.x()) > kAngularPrecision || std::fabs(rot.y()) > kAngularPrecision || std::fabs(rot.z()) > kAngularPrecision) { RotationWrite(physvolElement,name+"_rot",rot); } if (std::fabs(scl.x()-1.0) > kRelativePrecision || std::fabs(scl.y()-1.0) > kRelativePrecision || std::fabs(scl.z()-1.0) > kRelativePrecision) { ScaleWrite(physvolElement,name+"_scl",scl); } } void G4GDMLWriteStructure::ReplicavolWrite(xercesc::DOMElement* volumeElement, const G4VPhysicalVolume* const replicavol) { EAxis axis = kUndefined; G4int number = 0; G4double width = 0.0; G4double offset = 0.0; G4bool consuming = false; G4String unitString("mm"); replicavol->GetReplicationData(axis,number,width,offset,consuming); const G4String volumeref = GenerateName(replicavol->GetLogicalVolume()->GetName(), replicavol->GetLogicalVolume()); xercesc::DOMElement* replicavolElement = NewElement("replicavol"); replicavolElement->setAttributeNode(NewAttribute("number",number)); xercesc::DOMElement* volumerefElement = NewElement("volumeref"); volumerefElement->setAttributeNode(NewAttribute("ref",volumeref)); replicavolElement->appendChild(volumerefElement); xercesc::DOMElement* replicateElement = NewElement("replicate_along_axis"); replicavolElement->appendChild(replicateElement); xercesc::DOMElement* dirElement = NewElement("direction"); if(axis==kXAxis) { dirElement->setAttributeNode(NewAttribute("x","1")); } else if(axis==kYAxis) { dirElement->setAttributeNode(NewAttribute("y","1")); } else if(axis==kZAxis) { dirElement->setAttributeNode(NewAttribute("z","1")); } else if(axis==kRho) { dirElement->setAttributeNode(NewAttribute("rho","1")); } else if(axis==kPhi) { dirElement->setAttributeNode(NewAttribute("phi","1")); unitString="rad"; } replicateElement->appendChild(dirElement); xercesc::DOMElement* widthElement = NewElement("width"); widthElement->setAttributeNode(NewAttribute("value",width)); widthElement->setAttributeNode(NewAttribute("unit",unitString)); replicateElement->appendChild(widthElement); xercesc::DOMElement* offsetElement = NewElement("offset"); offsetElement->setAttributeNode(NewAttribute("value",offset)); offsetElement->setAttributeNode(NewAttribute("unit",unitString)); replicateElement->appendChild(offsetElement); volumeElement->appendChild(replicavolElement); } void G4GDMLWriteStructure:: BorderSurfaceCache(const G4LogicalBorderSurface* const bsurf) { if (!bsurf) { return; } const G4SurfaceProperty* psurf = bsurf->GetSurfaceProperty(); // Generate the new element for border-surface // xercesc::DOMElement* borderElement = NewElement("bordersurface"); borderElement->setAttributeNode(NewAttribute("name", bsurf->GetName())); borderElement->setAttributeNode(NewAttribute("surfaceproperty", psurf->GetName())); const G4String volumeref1 = GenerateName(bsurf->GetVolume1()->GetName(), bsurf->GetVolume1()); const G4String volumeref2 = GenerateName(bsurf->GetVolume2()->GetName(), bsurf->GetVolume2()); xercesc::DOMElement* volumerefElement1 = NewElement("physvolref"); xercesc::DOMElement* volumerefElement2 = NewElement("physvolref"); volumerefElement1->setAttributeNode(NewAttribute("ref",volumeref1)); volumerefElement2->setAttributeNode(NewAttribute("ref",volumeref2)); borderElement->appendChild(volumerefElement1); borderElement->appendChild(volumerefElement2); if (FindOpticalSurface(psurf)) { const G4OpticalSurface* opsurf = dynamic_cast(psurf); if (!opsurf) { G4Exception("G4GDMLWriteStructure::BorderSurfaceCache()", "InvalidSetup", FatalException, "No optical surface found!"); return; } OpticalSurfaceWrite(solidsElement, opsurf); } borderElementVec.push_back(borderElement); } void G4GDMLWriteStructure:: SkinSurfaceCache(const G4LogicalSkinSurface* const ssurf) { if (!ssurf) { return; } const G4SurfaceProperty* psurf = ssurf->GetSurfaceProperty(); // Generate the new element for border-surface // xercesc::DOMElement* skinElement = NewElement("skinsurface"); skinElement->setAttributeNode(NewAttribute("name", ssurf->GetName())); skinElement->setAttributeNode(NewAttribute("surfaceproperty", psurf->GetName())); const G4String volumeref = GenerateName(ssurf->GetLogicalVolume()->GetName(), ssurf->GetLogicalVolume()); xercesc::DOMElement* volumerefElement = NewElement("volumeref"); volumerefElement->setAttributeNode(NewAttribute("ref",volumeref)); skinElement->appendChild(volumerefElement); if (FindOpticalSurface(psurf)) { const G4OpticalSurface* opsurf = dynamic_cast(psurf); if (!opsurf) { G4Exception("G4GDMLWriteStructure::SkinSurfaceCache()", "InvalidSetup", FatalException, "No optical surface found!"); return; } OpticalSurfaceWrite(solidsElement, opsurf); } skinElementVec.push_back(skinElement); } G4bool G4GDMLWriteStructure::FindOpticalSurface(const G4SurfaceProperty* psurf) { const G4OpticalSurface* osurf = dynamic_cast(psurf); std::vector::const_iterator pos; pos = std::find(opt_vec.begin(), opt_vec.end(), osurf); if (pos != opt_vec.end()) { return false; } // item already created! opt_vec.push_back(osurf); // cache it for future reference return true; } const G4LogicalSkinSurface* G4GDMLWriteStructure::GetSkinSurface(const G4LogicalVolume* const lvol) { G4LogicalSkinSurface* surf = 0; G4int nsurf = G4LogicalSkinSurface::GetNumberOfSkinSurfaces(); if (nsurf) { const G4LogicalSkinSurfaceTable* stable = G4LogicalSkinSurface::GetSurfaceTable(); std::vector::const_iterator pos; for (pos = stable->begin(); pos != stable->end(); pos++) { if (lvol == (*pos)->GetLogicalVolume()) { surf = *pos; break; } } } return surf; } const G4LogicalBorderSurface* G4GDMLWriteStructure::GetBorderSurface(const G4VPhysicalVolume* const pvol) { G4LogicalBorderSurface* surf = 0; G4int nsurf = G4LogicalBorderSurface::GetNumberOfBorderSurfaces(); if (nsurf) { const G4LogicalBorderSurfaceTable* btable = G4LogicalBorderSurface::GetSurfaceTable(); std::vector::const_iterator pos; for (pos = btable->begin(); pos != btable->end(); pos++) { if (pvol == (*pos)->GetVolume1()) // just the first in the couple { // is enough surf = *pos; break; } } } return surf; } void G4GDMLWriteStructure::SurfacesWrite() { G4cout << "G4GDML: Writing surfaces..." << G4endl; std::vector::const_iterator pos; for (pos = skinElementVec.begin(); pos != skinElementVec.end(); pos++) { structureElement->appendChild(*pos); } for (pos = borderElementVec.begin(); pos != borderElementVec.end(); pos++) { structureElement->appendChild(*pos); } } void G4GDMLWriteStructure::StructureWrite(xercesc::DOMElement* gdmlElement) { G4cout << "G4GDML: Writing structure..." << G4endl; structureElement = NewElement("structure"); gdmlElement->appendChild(structureElement); } G4Transform3D G4GDMLWriteStructure:: TraverseVolumeTree(const G4LogicalVolume* const volumePtr, const G4int depth) { if (VolumeMap().find(volumePtr) != VolumeMap().end()) { return VolumeMap()[volumePtr]; // Volume is already processed } G4VSolid* solidPtr = volumePtr->GetSolid(); G4Transform3D R,invR; G4int trans=0; while (true) // Solve possible displacement/reflection { // of the referenced solid! if (trans>maxTransforms) { G4String ErrorMessage = "Referenced solid in volume '" + volumePtr->GetName() + "' was displaced/reflected too many times!"; G4Exception("G4GDMLWriteStructure::TraverseVolumeTree()", "InvalidSetup", FatalException, ErrorMessage); } if (G4ReflectedSolid* refl = dynamic_cast(solidPtr)) { R = R*refl->GetTransform3D(); solidPtr = refl->GetConstituentMovedSolid(); trans++; continue; } if (G4DisplacedSolid* disp = dynamic_cast(solidPtr)) { R = R*G4Transform3D(disp->GetObjectRotation(), disp->GetObjectTranslation()); solidPtr = disp->GetConstituentMovedSolid(); trans++; continue; } break; } // Only compute the inverse when necessary! // if (trans>0) { invR = R.inverse(); } const G4String name = GenerateName(volumePtr->GetName(),volumePtr); const G4String materialref = GenerateName(volumePtr->GetMaterial()->GetName(), volumePtr->GetMaterial()); const G4String solidref = GenerateName(solidPtr->GetName(),solidPtr); xercesc::DOMElement* volumeElement = NewElement("volume"); volumeElement->setAttributeNode(NewAttribute("name",name)); xercesc::DOMElement* materialrefElement = NewElement("materialref"); materialrefElement->setAttributeNode(NewAttribute("ref",materialref)); volumeElement->appendChild(materialrefElement); xercesc::DOMElement* solidrefElement = NewElement("solidref"); solidrefElement->setAttributeNode(NewAttribute("ref",solidref)); volumeElement->appendChild(solidrefElement); const G4int daughterCount = volumePtr->GetNoDaughters(); for (G4int i=0;iGetDaughter(i); const G4String ModuleName = Modularize(physvol,depth); G4Transform3D daughterR; if (ModuleName.empty()) // Check if subtree requested to be { // a separate module! daughterR = TraverseVolumeTree(physvol->GetLogicalVolume(),depth+1); } else { G4GDMLWriteStructure writer; daughterR = writer.Write(ModuleName,physvol->GetLogicalVolume(), SchemaLocation,depth+1); } if (const G4PVDivision* const divisionvol = dynamic_cast(physvol)) // Is it division? { if (!G4Transform3D::Identity.isNear(invR*daughterR,kRelativePrecision)) { G4String ErrorMessage = "Division volume in '" + name + "' can not be related to reflected solid!"; G4Exception("G4GDMLWriteStructure::TraverseVolumeTree()", "InvalidSetup", FatalException, ErrorMessage); } DivisionvolWrite(volumeElement,divisionvol); } else if (physvol->IsParameterised()) // Is it a paramvol? { if (!G4Transform3D::Identity.isNear(invR*daughterR,kRelativePrecision)) { G4String ErrorMessage = "Parameterised volume in '" + name + "' can not be related to reflected solid!"; G4Exception("G4GDMLWriteStructure::TraverseVolumeTree()", "InvalidSetup", FatalException, ErrorMessage); } ParamvolWrite(volumeElement,physvol); } else if (physvol->IsReplicated()) // Is it a replicavol? { if (!G4Transform3D::Identity.isNear(invR*daughterR,kRelativePrecision)) { G4String ErrorMessage = "Replica volume in '" + name + "' can not be related to reflected solid!"; G4Exception("G4GDMLWriteStructure::TraverseVolumeTree()", "InvalidSetup", FatalException, ErrorMessage); } ReplicavolWrite(volumeElement,physvol); } else // Is it a physvol? { G4RotationMatrix rot; if (physvol->GetFrameRotation() != 0) { rot = *(physvol->GetFrameRotation()); } G4Transform3D P(rot,physvol->GetObjectTranslation()); PhysvolWrite(volumeElement,physvol,invR*P*daughterR,ModuleName); } BorderSurfaceCache(GetBorderSurface(physvol)); } structureElement->appendChild(volumeElement); // Append the volume AFTER traversing the children so that // the order of volumes will be correct! VolumeMap()[volumePtr] = R; AddExtension(volumeElement, volumePtr); // Add any possible user defined extension attached to a volume AddMaterial(volumePtr->GetMaterial()); // Add the involved materials and solids! AddSolid(solidPtr); SkinSurfaceCache(GetSkinSurface(volumePtr)); return R; }