// Copyright (C) 2005 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN, // CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS // // This library is free software; you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public // License as published by the Free Software Foundation; either // version 2.1 of the License. // // 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 GNU // Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public // License along with this library; if not, write to the Free Software // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA // // See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com // #include #include #include "utilities.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // CAREFUL ! position of this file is critic : see Lucien PIGNOLONI / OCC //============================================================================= /*! * constructor: */ //============================================================================= GEOMImpl_I3DPrimOperations::GEOMImpl_I3DPrimOperations (GEOM_Engine* theEngine, int theDocID) : GEOM_IOperations(theEngine, theDocID) { MESSAGE("GEOMImpl_I3DPrimOperations::GEOMImpl_I3DPrimOperations"); } //============================================================================= /*! * destructor */ //============================================================================= GEOMImpl_I3DPrimOperations::~GEOMImpl_I3DPrimOperations() { MESSAGE("GEOMImpl_I3DPrimOperations::~GEOMImpl_I3DPrimOperations"); } //============================================================================= /*! * MakeBoxDXDYDZ */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeBoxDXDYDZ (double theDX, double theDY, double theDZ) { SetErrorCode(KO); //Add a new Box object Handle(GEOM_Object) aBox = GetEngine()->AddObject(GetDocID(), GEOM_BOX); //Add a new Box function with DX_DY_DZ parameters Handle(GEOM_Function) aFunction = aBox->AddFunction(GEOMImpl_BoxDriver::GetID(), BOX_DX_DY_DZ); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_BoxDriver::GetID()) return NULL; GEOMImpl_IBox aBI (aFunction); aBI.SetDX(theDX); aBI.SetDY(theDY); aBI.SetDZ(theDZ); //Compute the box value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Box driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aBox << " = geompy.MakeBoxDXDYDZ(" << theDX << ", " << theDY << ", " << theDZ << ")"; SetErrorCode(OK); return aBox; } //============================================================================= /*! * MakeBoxTwoPnt */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeBoxTwoPnt (Handle(GEOM_Object) thePnt1, Handle(GEOM_Object) thePnt2) { SetErrorCode(KO); if (thePnt1.IsNull() || thePnt2.IsNull()) return NULL; //Add a new Box object Handle(GEOM_Object) aBox = GetEngine()->AddObject(GetDocID(), GEOM_BOX); //Add a new Box function for creation a box relatively to two points Handle(GEOM_Function) aFunction = aBox->AddFunction(GEOMImpl_BoxDriver::GetID(), BOX_TWO_PNT); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_BoxDriver::GetID()) return aBox; GEOMImpl_IBox aBI (aFunction); Handle(GEOM_Function) aRefFunction1 = thePnt1->GetLastFunction(); Handle(GEOM_Function) aRefFunction2 = thePnt2->GetLastFunction(); if (aRefFunction1.IsNull() || aRefFunction2.IsNull()) return aBox; aBI.SetRef1(aRefFunction1); aBI.SetRef2(aRefFunction2); //Compute the Box value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Box driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aBox << " = geompy.MakeBoxTwoPnt(" << thePnt1 << ", " << thePnt2 << ")"; SetErrorCode(OK); return aBox; } //============================================================================= /*! * MakeCylinderRH */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeCylinderRH (double theR, double theH) { SetErrorCode(KO); //Add a new Cylinder object Handle(GEOM_Object) aCylinder = GetEngine()->AddObject(GetDocID(), GEOM_CYLINDER); //Add a new Cylinder function with R and H parameters Handle(GEOM_Function) aFunction = aCylinder->AddFunction(GEOMImpl_CylinderDriver::GetID(), CYLINDER_R_H); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_CylinderDriver::GetID()) return NULL; GEOMImpl_ICylinder aCI (aFunction); aCI.SetR(theR); aCI.SetH(theH); //Compute the Cylinder value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Cylinder driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aCylinder << " = geompy.MakeCylinderRH(" << theR << ", " << theH << ")"; SetErrorCode(OK); return aCylinder; } //============================================================================= /*! * MakeCylinderPntVecRH */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeCylinderPntVecRH (Handle(GEOM_Object) thePnt, Handle(GEOM_Object) theVec, double theR, double theH) { SetErrorCode(KO); if (thePnt.IsNull() || theVec.IsNull()) return NULL; //Add a new Cylinder object Handle(GEOM_Object) aCylinder = GetEngine()->AddObject(GetDocID(), GEOM_CYLINDER); //Add a new Cylinder function for creation a cylinder relatively to point and vector Handle(GEOM_Function) aFunction = aCylinder->AddFunction(GEOMImpl_CylinderDriver::GetID(), CYLINDER_PNT_VEC_R_H); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_CylinderDriver::GetID()) return NULL; GEOMImpl_ICylinder aCI (aFunction); Handle(GEOM_Function) aRefPnt = thePnt->GetLastFunction(); Handle(GEOM_Function) aRefVec = theVec->GetLastFunction(); if (aRefPnt.IsNull() || aRefVec.IsNull()) return NULL; aCI.SetPoint(aRefPnt); aCI.SetVector(aRefVec); aCI.SetR(theR); aCI.SetH(theH); //Compute the Cylinder value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Cylinder driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aCylinder << " = geompy.MakeCylinder(" << thePnt << ", " << theVec << ", " << theR << ", " << theH << ")"; SetErrorCode(OK); return aCylinder; } //============================================================================= /*! * MakeConeR1R2H */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeConeR1R2H (double theR1, double theR2, double theH) { SetErrorCode(KO); //Add a new Cone object Handle(GEOM_Object) aCone = GetEngine()->AddObject(GetDocID(), GEOM_CONE); //Add a new Cone function with R and H parameters Handle(GEOM_Function) aFunction = aCone->AddFunction(GEOMImpl_ConeDriver::GetID(), CONE_R1_R2_H); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_ConeDriver::GetID()) return NULL; GEOMImpl_ICone aCI (aFunction); aCI.SetR1(theR1); aCI.SetR2(theR2); aCI.SetH(theH); //Compute the Cone value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Cone driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aCone << " = geompy.MakeConeR1R2H(" << theR1 << ", " << theR2 << ", " << theH << ")"; SetErrorCode(OK); return aCone; } //============================================================================= /*! * MakeConePntVecR1R2H */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeConePntVecR1R2H (Handle(GEOM_Object) thePnt, Handle(GEOM_Object) theVec, double theR1, double theR2, double theH) { SetErrorCode(KO); if (thePnt.IsNull() || theVec.IsNull()) return NULL; //Add a new Cone object Handle(GEOM_Object) aCone = GetEngine()->AddObject(GetDocID(), GEOM_CONE); //Add a new Cone function for creation a cone relatively to point and vector Handle(GEOM_Function) aFunction = aCone->AddFunction(GEOMImpl_ConeDriver::GetID(), CONE_PNT_VEC_R1_R2_H); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_ConeDriver::GetID()) return NULL; GEOMImpl_ICone aCI (aFunction); Handle(GEOM_Function) aRefPnt = thePnt->GetLastFunction(); Handle(GEOM_Function) aRefVec = theVec->GetLastFunction(); if (aRefPnt.IsNull() || aRefVec.IsNull()) return NULL; aCI.SetPoint(aRefPnt); aCI.SetVector(aRefVec); aCI.SetR1(theR1); aCI.SetR2(theR2); aCI.SetH(theH); //Compute the Cone value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Cone driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aCone << " = geompy.MakeCone(" << thePnt << ", " << theVec << ", " << theR1 << ", " << theR2 << ", " << theH << ")"; SetErrorCode(OK); return aCone; } //============================================================================= /*! * MakeSphereR */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeSphereR (double theR) { SetErrorCode(KO); //Add a new Sphere object Handle(GEOM_Object) aSphere = GetEngine()->AddObject(GetDocID(), GEOM_SPHERE); //Add a new Sphere function with R parameter Handle(GEOM_Function) aFunction = aSphere->AddFunction(GEOMImpl_SphereDriver::GetID(), SPHERE_R); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_SphereDriver::GetID()) return NULL; GEOMImpl_ISphere aCI (aFunction); aCI.SetR(theR); //Compute the Sphere value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Sphere driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aSphere << " = geompy.MakeSphereR(" << theR << ")"; SetErrorCode(OK); return aSphere; } //============================================================================= /*! * MakeSpherePntR */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeSpherePntR (Handle(GEOM_Object) thePnt, double theR) { SetErrorCode(KO); if (thePnt.IsNull()) return NULL; //Add a new Point object Handle(GEOM_Object) aSphere = GetEngine()->AddObject(GetDocID(), GEOM_SPHERE); //Add a new Sphere function for creation a sphere relatively to point Handle(GEOM_Function) aFunction = aSphere->AddFunction(GEOMImpl_SphereDriver::GetID(), SPHERE_PNT_R); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_SphereDriver::GetID()) return NULL; GEOMImpl_ISphere aCI (aFunction); Handle(GEOM_Function) aRefPnt = thePnt->GetLastFunction(); if (aRefPnt.IsNull()) return NULL; aCI.SetPoint(aRefPnt); aCI.SetR(theR); //Compute the Sphere value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Sphere driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aSphere << " = geompy.MakeSpherePntR(" << thePnt << ", " << theR << ")"; SetErrorCode(OK); return aSphere; } //============================================================================= /*! * MakeTorusRR */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeTorusRR (double theRMajor, double theRMinor) { SetErrorCode(KO); //Add a new Torus object Handle(GEOM_Object) anEll = GetEngine()->AddObject(GetDocID(), GEOM_TORUS); //Add a new Torus function Handle(GEOM_Function) aFunction = anEll->AddFunction(GEOMImpl_TorusDriver::GetID(), TORUS_RR); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_TorusDriver::GetID()) return NULL; GEOMImpl_ITorus aCI (aFunction); aCI.SetRMajor(theRMajor); aCI.SetRMinor(theRMinor); //Compute the Torus value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Torus driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << anEll << " = geompy.MakeTorusRR(" << theRMajor << ", " << theRMinor << ")"; SetErrorCode(OK); return anEll; } //============================================================================= /*! * MakeTorusPntVecRR */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeTorusPntVecRR (Handle(GEOM_Object) thePnt, Handle(GEOM_Object) theVec, double theRMajor, double theRMinor) { SetErrorCode(KO); if (thePnt.IsNull() || theVec.IsNull()) return NULL; //Add a new Torus object Handle(GEOM_Object) anEll = GetEngine()->AddObject(GetDocID(), GEOM_TORUS); //Add a new Torus function Handle(GEOM_Function) aFunction = anEll->AddFunction(GEOMImpl_TorusDriver::GetID(), TORUS_PNT_VEC_RR); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_TorusDriver::GetID()) return NULL; GEOMImpl_ITorus aCI (aFunction); Handle(GEOM_Function) aRefPnt = thePnt->GetLastFunction(); Handle(GEOM_Function) aRefVec = theVec->GetLastFunction(); if (aRefPnt.IsNull() || aRefVec.IsNull()) return NULL; aCI.SetCenter(aRefPnt); aCI.SetVector(aRefVec); aCI.SetRMajor(theRMajor); aCI.SetRMinor(theRMinor); //Compute the Torus value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Torus driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << anEll << " = geompy.MakeTorus(" << thePnt << ", " << theVec << ", " << theRMajor << ", " << theRMinor << ")"; SetErrorCode(OK); return anEll; } //============================================================================= /*! * MakePrismVecH */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePrismVecH (Handle(GEOM_Object) theBase, Handle(GEOM_Object) theVec, double theH) { SetErrorCode(KO); if (theBase.IsNull() || theVec.IsNull()) return NULL; //Add a new Prism object Handle(GEOM_Object) aPrism = GetEngine()->AddObject(GetDocID(), GEOM_PRISM); //Add a new Prism function for creation a Prism relatively to vector Handle(GEOM_Function) aFunction = aPrism->AddFunction(GEOMImpl_PrismDriver::GetID(), PRISM_BASE_VEC_H); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_PrismDriver::GetID()) return NULL; GEOMImpl_IPrism aCI (aFunction); Handle(GEOM_Function) aRefBase = theBase->GetLastFunction(); Handle(GEOM_Function) aRefVec = theVec->GetLastFunction(); if (aRefBase.IsNull() || aRefVec.IsNull()) return NULL; aCI.SetBase(aRefBase); aCI.SetVector(aRefVec); aCI.SetH(theH); //Compute the Prism value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { //SetErrorCode("Prism driver failed"); SetErrorCode("Extrusion can not be created, check input data"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aPrism << " = geompy.MakePrismVecH(" << theBase << ", " << theVec << ", " << theH << ")"; SetErrorCode(OK); return aPrism; } //============================================================================= /*! * MakePrismVecH2Ways */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePrismVecH2Ways (Handle(GEOM_Object) theBase, Handle(GEOM_Object) theVec, double theH) { SetErrorCode(KO); if (theBase.IsNull() || theVec.IsNull()) return NULL; //Add a new Prism object Handle(GEOM_Object) aPrism = GetEngine()->AddObject(GetDocID(), GEOM_PRISM); //Add a new Prism function for creation a Prism relatively to vector Handle(GEOM_Function) aFunction = aPrism->AddFunction(GEOMImpl_PrismDriver::GetID(), PRISM_BASE_VEC_H_2WAYS); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_PrismDriver::GetID()) return NULL; GEOMImpl_IPrism aCI (aFunction); Handle(GEOM_Function) aRefBase = theBase->GetLastFunction(); Handle(GEOM_Function) aRefVec = theVec->GetLastFunction(); if (aRefBase.IsNull() || aRefVec.IsNull()) return NULL; aCI.SetBase(aRefBase); aCI.SetVector(aRefVec); aCI.SetH(theH); //Compute the Prism value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { //SetErrorCode("Prism driver failed"); SetErrorCode("Extrusion can not be created, check input data"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aPrism << " = geompy.MakePrismVecH2Ways(" << theBase << ", " << theVec << ", " << theH << ")"; SetErrorCode(OK); return aPrism; } //============================================================================= /*! * MakePrismTwoPnt */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePrismTwoPnt (Handle(GEOM_Object) theBase, Handle(GEOM_Object) thePoint1, Handle(GEOM_Object) thePoint2) { SetErrorCode(KO); if (theBase.IsNull() || thePoint1.IsNull() || thePoint2.IsNull()) return NULL; //Add a new Prism object Handle(GEOM_Object) aPrism = GetEngine()->AddObject(GetDocID(), GEOM_PRISM); //Add a new Prism function for creation a Prism relatively to two points Handle(GEOM_Function) aFunction = aPrism->AddFunction(GEOMImpl_PrismDriver::GetID(), PRISM_BASE_TWO_PNT); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_PrismDriver::GetID()) return NULL; GEOMImpl_IPrism aCI (aFunction); Handle(GEOM_Function) aRefBase = theBase->GetLastFunction(); Handle(GEOM_Function) aRefPnt1 = thePoint1->GetLastFunction(); Handle(GEOM_Function) aRefPnt2 = thePoint2->GetLastFunction(); if (aRefBase.IsNull() || aRefPnt1.IsNull() || aRefPnt2.IsNull()) return NULL; aCI.SetBase(aRefBase); aCI.SetFirstPoint(aRefPnt1); aCI.SetLastPoint(aRefPnt2); //Compute the Prism value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { //SetErrorCode("Prism driver failed"); SetErrorCode("Extrusion can not be created, check input data"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aPrism << " = geompy.MakePrism(" << theBase << ", " << thePoint1 << ", " << thePoint2 << ")"; SetErrorCode(OK); return aPrism; } //============================================================================= /*! * MakePrismTwoPnt2Ways */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePrismTwoPnt2Ways (Handle(GEOM_Object) theBase, Handle(GEOM_Object) thePoint1, Handle(GEOM_Object) thePoint2) { SetErrorCode(KO); if (theBase.IsNull() || thePoint1.IsNull() || thePoint2.IsNull()) return NULL; //Add a new Prism object Handle(GEOM_Object) aPrism = GetEngine()->AddObject(GetDocID(), GEOM_PRISM); //Add a new Prism function for creation a Prism relatively to two points Handle(GEOM_Function) aFunction = aPrism->AddFunction(GEOMImpl_PrismDriver::GetID(), PRISM_BASE_TWO_PNT_2WAYS); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_PrismDriver::GetID()) return NULL; GEOMImpl_IPrism aCI (aFunction); Handle(GEOM_Function) aRefBase = theBase->GetLastFunction(); Handle(GEOM_Function) aRefPnt1 = thePoint1->GetLastFunction(); Handle(GEOM_Function) aRefPnt2 = thePoint2->GetLastFunction(); if (aRefBase.IsNull() || aRefPnt1.IsNull() || aRefPnt2.IsNull()) return NULL; aCI.SetBase(aRefBase); aCI.SetFirstPoint(aRefPnt1); aCI.SetLastPoint(aRefPnt2); //Compute the Prism value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { //SetErrorCode("Prism driver failed"); SetErrorCode("Extrusion can not be created, check input data"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aPrism << " = geompy.MakePrism2Ways(" << theBase << ", " << thePoint1 << ", " << thePoint2 << ")"; SetErrorCode(OK); return aPrism; } //============================================================================= /*! * MakePipe */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePipe (Handle(GEOM_Object) theBase, Handle(GEOM_Object) thePath) { SetErrorCode(KO); if (theBase.IsNull() || thePath.IsNull()) return NULL; //Add a new Pipe object Handle(GEOM_Object) aPipe = GetEngine()->AddObject(GetDocID(), GEOM_PIPE); //Add a new Pipe function Handle(GEOM_Function) aFunction = aPipe->AddFunction(GEOMImpl_PipeDriver::GetID(), PIPE_BASE_PATH); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_PipeDriver::GetID()) return NULL; GEOMImpl_IPipe aCI (aFunction); Handle(GEOM_Function) aRefBase = theBase->GetLastFunction(); Handle(GEOM_Function) aRefPath = thePath->GetLastFunction(); if (aRefBase.IsNull() || aRefPath.IsNull()) return NULL; aCI.SetBase(aRefBase); aCI.SetPath(aRefPath); //Compute the Pipe value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Pipe driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aPipe << " = geompy.MakePipe(" << theBase << ", " << thePath << ")"; SetErrorCode(OK); return aPipe; } //============================================================================= /*! * MakeRevolutionAxisAngle */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeRevolutionAxisAngle (Handle(GEOM_Object) theBase, Handle(GEOM_Object) theAxis, double theAngle) { SetErrorCode(KO); if (theBase.IsNull() || theAxis.IsNull()) return NULL; //Add a new Revolution object Handle(GEOM_Object) aRevolution = GetEngine()->AddObject(GetDocID(), GEOM_REVOLUTION); //Add a new Revolution function for creation a revolution relatively to axis Handle(GEOM_Function) aFunction = aRevolution->AddFunction(GEOMImpl_RevolutionDriver::GetID(), REVOLUTION_BASE_AXIS_ANGLE); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_RevolutionDriver::GetID()) return NULL; GEOMImpl_IRevolution aCI (aFunction); Handle(GEOM_Function) aRefBase = theBase->GetLastFunction(); Handle(GEOM_Function) aRefAxis = theAxis->GetLastFunction(); if (aRefBase.IsNull() || aRefAxis.IsNull()) return NULL; aCI.SetBase(aRefBase); aCI.SetAxis(aRefAxis); aCI.SetAngle(theAngle); //Compute the Revolution value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Revolution driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aRevolution << " = geompy.MakeRevolution(" << theBase << ", " << theAxis << ", " << theAngle * 180.0 / PI << "*math.pi/180.0)"; SetErrorCode(OK); return aRevolution; } //============================================================================= /*! * MakeRevolutionAxisAngle2Ways */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeRevolutionAxisAngle2Ways (Handle(GEOM_Object) theBase, Handle(GEOM_Object) theAxis, double theAngle) { SetErrorCode(KO); if (theBase.IsNull() || theAxis.IsNull()) return NULL; //Add a new Revolution object Handle(GEOM_Object) aRevolution = GetEngine()->AddObject(GetDocID(), GEOM_REVOLUTION); //Add a new Revolution function for creation a revolution relatively to axis Handle(GEOM_Function) aFunction = aRevolution->AddFunction(GEOMImpl_RevolutionDriver::GetID(), REVOLUTION_BASE_AXIS_ANGLE_2WAYS); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_RevolutionDriver::GetID()) return NULL; GEOMImpl_IRevolution aCI (aFunction); Handle(GEOM_Function) aRefBase = theBase->GetLastFunction(); Handle(GEOM_Function) aRefAxis = theAxis->GetLastFunction(); if (aRefBase.IsNull() || aRefAxis.IsNull()) return NULL; aCI.SetBase(aRefBase); aCI.SetAxis(aRefAxis); aCI.SetAngle(theAngle); //Compute the Revolution value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Revolution driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aRevolution << " = geompy.MakeRevolution2Ways(" << theBase << ", " << theAxis << ", " << theAngle * 180.0 / PI << "*math.pi/180.0)"; SetErrorCode(OK); return aRevolution; } //============================================================================= /*! * MakeSolidShell */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeSolidShell (Handle(GEOM_Object) theShell) { SetErrorCode(KO); if (theShell.IsNull()) return NULL; //Add a new Solid object Handle(GEOM_Object) aSolid = GetEngine()->AddObject(GetDocID(), GEOM_SOLID); //Add a new Solid function for creation a solid from a shell Handle(GEOM_Function) aFunction = aSolid->AddFunction(GEOMImpl_ShapeDriver::GetID(), SOLID_SHELL); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_ShapeDriver::GetID()) return NULL; GEOMImpl_IShapes aCI (aFunction); Handle(GEOM_Function) aRefShell = theShell->GetLastFunction(); if (aRefShell.IsNull()) return NULL; aCI.SetBase(aRefShell); //Compute the Solid value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Solid driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump(aFunction) << aSolid << " = geompy.MakeSolid(" << theShell << ")"; SetErrorCode(OK); return aSolid; } //============================================================================= /*! * MakeFilling */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeFilling (Handle(GEOM_Object) theShape, int theMinDeg, int theMaxDeg, double theTol2D, double theTol3D, int theNbIter, bool isApprox) { SetErrorCode(KO); if (theShape.IsNull()) return NULL; //Add a new Filling object Handle(GEOM_Object) aFilling = GetEngine()->AddObject(GetDocID(), GEOM_FILLING); //Add a new Filling function for creation a filling from a compound Handle(GEOM_Function) aFunction = aFilling->AddFunction(GEOMImpl_FillingDriver::GetID(), BASIC_FILLING); if (aFunction.IsNull()) return NULL; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_FillingDriver::GetID()) return NULL; GEOMImpl_IFilling aFI (aFunction); Handle(GEOM_Function) aRefShape = theShape->GetLastFunction(); if (aRefShape.IsNull()) return NULL; aFI.SetShape(aRefShape); aFI.SetMinDeg(theMinDeg); aFI.SetMaxDeg(theMaxDeg); aFI.SetTol2D(theTol2D); aFI.SetTol3D(theTol3D); aFI.SetNbIter(theNbIter); aFI.SetApprox(isApprox); //Compute the Solid value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Filling driver failed"); return NULL; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); if (strcmp(aFail->GetMessageString(), "Geom_BSplineSurface") == 0) SetErrorCode("B-Spline surface construction failed"); else SetErrorCode(aFail->GetMessageString()); return NULL; } //Make a Python command GEOM::TPythonDump pd (aFunction); pd << aFilling << " = geompy.MakeFilling(" << theShape << ", " << theMinDeg << ", " << theMaxDeg << ", " << theTol2D << ", " << theTol3D << ", " << theNbIter; if(isApprox) pd << ", " << isApprox; pd << ")"; SetErrorCode(OK); return aFilling; } //============================================================================= /*! * MakeThruSections */ //============================================================================= Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeThruSections( const Handle(TColStd_HSequenceOfTransient)& theSeqSections, bool theModeSolid, double thePreci, bool theRuled) { Handle(GEOM_Object) anObj; SetErrorCode(KO); if(theSeqSections.IsNull()) return anObj; Standard_Integer nbObj = theSeqSections->Length(); if (!nbObj) return anObj; //Add a new ThruSections object Handle(GEOM_Object) aThruSect = GetEngine()->AddObject(GetDocID(), GEOM_THRUSECTIONS); //Add a new ThruSections function int aTypeFunc = (theRuled ? THRUSECTIONS_RULED : THRUSECTIONS_SMOOTHED); Handle(GEOM_Function) aFunction = aThruSect->AddFunction(GEOMImpl_ThruSectionsDriver::GetID(), aTypeFunc); if (aFunction.IsNull()) return anObj; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_ThruSectionsDriver::GetID()) return NULL; GEOMImpl_IThruSections aCI (aFunction); Handle(TColStd_HSequenceOfTransient) aSeqSections = new TColStd_HSequenceOfTransient; Standard_Integer i =1; for( ; i <= nbObj; i++) { Handle(Standard_Transient) anItem = theSeqSections->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) aSectObj = Handle(GEOM_Object)::DownCast(anItem); if(!aSectObj.IsNull()) { Handle(GEOM_Function) aRefSect = aSectObj->GetLastFunction(); if(!aRefSect.IsNull()) aSeqSections->Append(aRefSect); } } if(!aSeqSections->Length()) return anObj; aCI.SetSections(aSeqSections); aCI.SetSolidMode(theModeSolid); aCI.SetPrecision(thePreci); //Compute the ThruSections value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("ThruSections driver failed"); return anObj; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return anObj; } //Make a Python command GEOM::TPythonDump pyDump(aFunction); pyDump << aThruSect << " = geompy.MakeThruSections(["; for(i =1 ; i <= nbObj; i++) { Handle(Standard_Transient) anItem = theSeqSections->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) aSectObj = Handle(GEOM_Object)::DownCast(anItem); if(!aSectObj.IsNull()) { pyDump<< aSectObj; if(i < nbObj) pyDump<<", "; } } pyDump<< "],"<Length(); if (!nbBases) return anObj; Standard_Integer nbLocs = (theLocations.IsNull() ? 0 :theLocations->Length()); //Add a new Pipe object Handle(GEOM_Object) aPipeDS = GetEngine()->AddObject(GetDocID(), GEOM_PIPE); //Add a new Pipe function Handle(GEOM_Function) aFunction = aPipeDS->AddFunction(GEOMImpl_PipeDriver::GetID(), PIPE_DIFFERENT_SECTIONS); if (aFunction.IsNull()) return anObj; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_PipeDriver::GetID()) return anObj; GEOMImpl_IPipeDiffSect aCI (aFunction); Handle(GEOM_Function) aRefPath = thePath->GetLastFunction(); if(aRefPath.IsNull()) return anObj; Handle(TColStd_HSequenceOfTransient) aSeqBases = new TColStd_HSequenceOfTransient; Handle(TColStd_HSequenceOfTransient) aSeqLocs = new TColStd_HSequenceOfTransient; Standard_Integer i =1; for( ; i <= nbBases; i++) { Handle(Standard_Transient) anItem = theBases->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) aBase = Handle(GEOM_Object)::DownCast(anItem); if(aBase.IsNull()) continue; Handle(GEOM_Function) aRefBase = aBase->GetLastFunction(); if(aRefBase.IsNull()) continue; if(nbLocs) { Handle(Standard_Transient) anItemLoc = theLocations->Value(i); if(anItemLoc.IsNull()) continue; Handle(GEOM_Object) aLoc = Handle(GEOM_Object)::DownCast(anItemLoc); if(aLoc.IsNull()) continue; Handle(GEOM_Function) aRefLoc = aLoc->GetLastFunction(); if(aRefLoc.IsNull()) continue; aSeqLocs->Append(aRefLoc); } aSeqBases->Append(aRefBase); } if(!aSeqBases->Length()) return anObj; aCI.SetBases(aSeqBases); aCI.SetLocations(aSeqLocs); aCI.SetPath(aRefPath); aCI.SetWithContactMode(theWithContact); aCI.SetWithCorrectionMode(theWithCorrections); //Compute the Pipe value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Pipe with defferent section driver failed"); return anObj; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return anObj; } //Make a Python command GEOM::TPythonDump pyDump(aFunction); pyDump << aPipeDS << " = geompy.MakePipeWithDifferentSections(["; for(i =1 ; i <= nbBases; i++) { Handle(Standard_Transient) anItem = theBases->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) anObj = Handle(GEOM_Object)::DownCast(anItem); if(!anObj.IsNull()) { pyDump<< anObj; if(i < nbBases) pyDump<<", "; } } pyDump<< "], ["; for(i =1 ; i <= nbLocs; i++) { Handle(Standard_Transient) anItem = theLocations->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) anObj = Handle(GEOM_Object)::DownCast(anItem); if(!anObj.IsNull()) { pyDump<< anObj; if(i < nbLocs) pyDump<<", "; } } pyDump<< "], "<Length(); if (!nbBases) return anObj; Standard_Integer nbSubBases = (theSubBases.IsNull() ? 0 :theSubBases->Length()); Standard_Integer nbLocs = (theLocations.IsNull() ? 0 :theLocations->Length()); //Add a new Pipe object Handle(GEOM_Object) aPipeDS = GetEngine()->AddObject(GetDocID(), GEOM_PIPE); //Add a new Pipe function Handle(GEOM_Function) aFunction = aPipeDS->AddFunction(GEOMImpl_PipeDriver::GetID(), PIPE_SHELL_SECTIONS); if (aFunction.IsNull()) return anObj; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_PipeDriver::GetID()) return anObj; //GEOMImpl_IPipeDiffSect aCI (aFunction); GEOMImpl_IPipeShellSect aCI (aFunction); Handle(GEOM_Function) aRefPath = thePath->GetLastFunction(); if(aRefPath.IsNull()) return anObj; Handle(TColStd_HSequenceOfTransient) aSeqBases = new TColStd_HSequenceOfTransient; Handle(TColStd_HSequenceOfTransient) aSeqSubBases = new TColStd_HSequenceOfTransient; Handle(TColStd_HSequenceOfTransient) aSeqLocs = new TColStd_HSequenceOfTransient; Standard_Integer i =1; for( ; i <= nbBases; i++) { Handle(Standard_Transient) anItem = theBases->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) aBase = Handle(GEOM_Object)::DownCast(anItem); if(aBase.IsNull()) continue; Handle(GEOM_Function) aRefBase = aBase->GetLastFunction(); if(aRefBase.IsNull()) continue; if( nbSubBases >= nbBases ) { Handle(Standard_Transient) aSubItem = theSubBases->Value(i); if(aSubItem.IsNull()) continue; Handle(GEOM_Object) aSubBase = Handle(GEOM_Object)::DownCast(aSubItem); if(aSubBase.IsNull()) continue; Handle(GEOM_Function) aRefSubBase = aSubBase->GetLastFunction(); if(aRefSubBase.IsNull()) continue; aSeqSubBases->Append(aRefSubBase); } if(nbLocs) { Handle(Standard_Transient) anItemLoc = theLocations->Value(i); if(anItemLoc.IsNull()) continue; Handle(GEOM_Object) aLoc = Handle(GEOM_Object)::DownCast(anItemLoc); if(aLoc.IsNull()) continue; Handle(GEOM_Function) aRefLoc = aLoc->GetLastFunction(); if(aRefLoc.IsNull()) continue; aSeqLocs->Append(aRefLoc); } aSeqBases->Append(aRefBase); } if(!aSeqBases->Length()) return anObj; aCI.SetBases(aSeqBases); aCI.SetSubBases(aSeqSubBases); aCI.SetLocations(aSeqLocs); aCI.SetPath(aRefPath); aCI.SetWithContactMode(theWithContact); aCI.SetWithCorrectionMode(theWithCorrections); //Compute the Pipe value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Pipe with shell sections driver failed"); return anObj; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return anObj; } //Make a Python command GEOM::TPythonDump pyDump(aFunction); pyDump << aPipeDS << " = geompy.MakePipeWithShellSections(["; for(i =1 ; i <= nbBases; i++) { Handle(Standard_Transient) anItem = theBases->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) anObj = Handle(GEOM_Object)::DownCast(anItem); if(!anObj.IsNull()) { pyDump<< anObj; if(i < nbBases) pyDump<<", "; } } pyDump<< "], ["; for(i =1 ; i <= nbSubBases; i++) { Handle(Standard_Transient) anItem = theSubBases->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) anObj = Handle(GEOM_Object)::DownCast(anItem); if(!anObj.IsNull()) { pyDump<< anObj; if(i < nbBases) pyDump<<", "; } } pyDump<< "], ["; for(i =1 ; i <= nbLocs; i++) { Handle(Standard_Transient) anItem = theLocations->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) anObj = Handle(GEOM_Object)::DownCast(anItem); if(!anObj.IsNull()) { pyDump<< anObj; if(i < nbLocs) pyDump<<", "; } } pyDump<< "], "<Length(); if (!nbBases) return anObj; Standard_Integer nbLocs = (theLocations.IsNull() ? 0 :theLocations->Length()); //Add a new Pipe object Handle(GEOM_Object) aPipeDS = GetEngine()->AddObject(GetDocID(), GEOM_PIPE); //Add a new Pipe function Handle(GEOM_Function) aFunction = aPipeDS->AddFunction(GEOMImpl_PipeDriver::GetID(), PIPE_SHELLS_WITHOUT_PATH); if (aFunction.IsNull()) return anObj; //Check if the function is set correctly if (aFunction->GetDriverGUID() != GEOMImpl_PipeDriver::GetID()) return anObj; GEOMImpl_IPipeShellSect aCI (aFunction); Handle(TColStd_HSequenceOfTransient) aSeqBases = new TColStd_HSequenceOfTransient; Handle(TColStd_HSequenceOfTransient) aSeqLocs = new TColStd_HSequenceOfTransient; Standard_Integer i =1; for( ; i <= nbBases; i++) { Handle(Standard_Transient) anItem = theBases->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) aBase = Handle(GEOM_Object)::DownCast(anItem); if(aBase.IsNull()) continue; Handle(GEOM_Function) aRefBase = aBase->GetLastFunction(); if(aRefBase.IsNull()) continue; if(nbLocs) { Handle(Standard_Transient) anItemLoc = theLocations->Value(i); if(anItemLoc.IsNull()) continue; Handle(GEOM_Object) aLoc = Handle(GEOM_Object)::DownCast(anItemLoc); if(aLoc.IsNull()) continue; Handle(GEOM_Function) aRefLoc = aLoc->GetLastFunction(); if(aRefLoc.IsNull()) continue; aSeqLocs->Append(aRefLoc); } aSeqBases->Append(aRefBase); } if(!aSeqBases->Length()) return anObj; aCI.SetBases(aSeqBases); aCI.SetLocations(aSeqLocs); //Compute the Pipe value try { #if (OCC_VERSION_MAJOR << 16 | OCC_VERSION_MINOR << 8 | OCC_VERSION_MAINTENANCE) > 0x060100 OCC_CATCH_SIGNALS; #endif if (!GetSolver()->ComputeFunction(aFunction)) { SetErrorCode("Pipe with shell sections without path driver failed"); return anObj; } } catch (Standard_Failure) { Handle(Standard_Failure) aFail = Standard_Failure::Caught(); SetErrorCode(aFail->GetMessageString()); return anObj; } //Make a Python command GEOM::TPythonDump pyDump(aFunction); pyDump << aPipeDS << " = geompy.MakePipeShellsWithoutPath(["; for(i =1 ; i <= nbBases; i++) { Handle(Standard_Transient) anItem = theBases->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) anObj = Handle(GEOM_Object)::DownCast(anItem); if(!anObj.IsNull()) { pyDump<< anObj; if(i < nbBases) pyDump<<", "; } } pyDump<< "], ["; for(i =1 ; i <= nbLocs; i++) { Handle(Standard_Transient) anItem = theLocations->Value(i); if(anItem.IsNull()) continue; Handle(GEOM_Object) anObj = Handle(GEOM_Object)::DownCast(anItem); if(!anObj.IsNull()) { pyDump<< anObj; if(i < nbLocs) pyDump<<", "; } } pyDump<< "])"; SetErrorCode(OK); return aPipeDS; }