-// Copyright (C) 2005 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
+// Copyright (C) 2007-2014 CEA/DEN, EDF R&D, OPEN CASCADE
+//
+// Copyright (C) 2003-2007 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
+// License as published by the Free Software Foundation; either
+// version 2.1 of the License, or (at your option) any later version.
+//
+// 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
+// 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 <Standard_Stream.hxx>
+#include <Basics_OCCTVersion.hxx>
+
#include <GEOMImpl_I3DPrimOperations.hxx>
#include "utilities.h"
#include <GEOMImpl_Types.hxx>
#include <GEOMImpl_BoxDriver.hxx>
+#include <GEOMImpl_FaceDriver.hxx>
+#include <GEOMImpl_DiskDriver.hxx>
#include <GEOMImpl_CylinderDriver.hxx>
#include <GEOMImpl_ConeDriver.hxx>
#include <GEOMImpl_SphereDriver.hxx>
#include <GEOMImpl_TorusDriver.hxx>
#include <GEOMImpl_PrismDriver.hxx>
#include <GEOMImpl_PipeDriver.hxx>
+#include <GEOMImpl_PipePathDriver.hxx>
#include <GEOMImpl_RevolutionDriver.hxx>
#include <GEOMImpl_ShapeDriver.hxx>
#include <GEOMImpl_FillingDriver.hxx>
#include <GEOMImpl_ThruSectionsDriver.hxx>
+#include <GEOMImpl_OffsetDriver.hxx>
#include <GEOMImpl_IBox.hxx>
+#include <GEOMImpl_IFace.hxx>
+#include <GEOMImpl_IDisk.hxx>
#include <GEOMImpl_ICylinder.hxx>
#include <GEOMImpl_ICone.hxx>
#include <GEOMImpl_ISphere.hxx>
#include <GEOMImpl_IPrism.hxx>
#include <GEOMImpl_IPipe.hxx>
#include <GEOMImpl_IRevolution.hxx>
-#include <GEOMImpl_IShapes.hxx>
#include <GEOMImpl_IFilling.hxx>
#include <GEOMImpl_IThruSections.hxx>
#include <GEOMImpl_IPipeDiffSect.hxx>
#include <GEOMImpl_IPipeShellSect.hxx>
+#include <GEOMImpl_IPipeBiNormal.hxx>
+#include <GEOMImpl_IOffset.hxx>
+#include <GEOMImpl_IPipePath.hxx>
+
+#include <Precision.hxx>
#include <Standard_Failure.hxx>
#include <Standard_ErrorHandler.hxx> // CAREFUL ! position of this file is critic : see Lucien PIGNOLONI / OCC
//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;
//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;
return aBox;
}
+//=============================================================================
+/*!
+ * MakeFaceHW
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeFaceHW (double theH, double theW, int theOrientation)
+{
+ SetErrorCode(KO);
+
+ if (theH == 0 || theW == 0) return NULL;
+
+ //Add a new Face object
+ Handle(GEOM_Object) aFace = GetEngine()->AddObject(GetDocID(), GEOM_FACE);
+
+ //Add a new Box function for creation a box relatively to two points
+ Handle(GEOM_Function) aFunction = aFace->AddFunction(GEOMImpl_FaceDriver::GetID(), FACE_H_W);
+ if (aFunction.IsNull()) return NULL;
+
+ //Check if the function is set correctly
+ if (aFunction->GetDriverGUID() != GEOMImpl_FaceDriver::GetID()) return aFace;
+
+ GEOMImpl_IFace aFI (aFunction);
+
+ aFI.SetH(theH);
+ aFI.SetW(theW);
+ aFI.SetOrientation(theOrientation);
+
+ //Compute the Face
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ SetErrorCode("Face 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) << aFace << " = geompy.MakeFaceHW("
+ << theH << ", " << theW << ", " << theOrientation << ")";
+
+ SetErrorCode(OK);
+ return aFace;
+}
+
+//=============================================================================
+/*!
+ * MakeFaceObjHW
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeFaceObjHW (Handle(GEOM_Object) theObj,
+ double theH, double theW)
+{
+ SetErrorCode(KO);
+
+ if (theObj.IsNull()) return NULL;
+
+ //Add a new Face object
+ Handle(GEOM_Object) aFace = GetEngine()->AddObject(GetDocID(), GEOM_FACE);
+
+ //Add a new Box function for creation a box relatively to two points
+ Handle(GEOM_Function) aFunction = aFace->AddFunction(GEOMImpl_FaceDriver::GetID(), FACE_OBJ_H_W);
+ if (aFunction.IsNull()) return NULL;
+
+ //Check if the function is set correctly
+ if (aFunction->GetDriverGUID() != GEOMImpl_FaceDriver::GetID()) return aFace;
+
+ GEOMImpl_IFace aFI (aFunction);
+
+ Handle(GEOM_Function) aRefFunction1 = theObj->GetLastFunction();
+
+ if (aRefFunction1.IsNull())
+ return aFace;
+
+ aFI.SetRef1(aRefFunction1);
+ aFI.SetH(theH);
+ aFI.SetW(theW);
+
+ //Compute the Face
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ SetErrorCode("Face 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) << aFace << " = geompy.MakeFaceObjHW("
+ << theObj << ", " << theH << ", " << theW << ")";
+
+ SetErrorCode(OK);
+ return aFace;
+}
+
+//=============================================================================
+/*!
+ * MakeDiskPntVecR
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeDiskPntVecR
+ (Handle(GEOM_Object) thePnt, Handle(GEOM_Object) theVec, double theR)
+{
+ SetErrorCode(KO);
+
+ if (thePnt.IsNull() || theVec.IsNull()) return NULL;
+
+ //Add a new Disk object
+ Handle(GEOM_Object) aDisk = GetEngine()->AddObject(GetDocID(), GEOM_FACE);
+
+ //Add a new Disk function for creation a disk relatively to point and vector
+ Handle(GEOM_Function) aFunction =
+ aDisk->AddFunction(GEOMImpl_DiskDriver::GetID(), DISK_PNT_VEC_R);
+ if (aFunction.IsNull()) return NULL;
+
+ //Check if the function is set correctly
+ if (aFunction->GetDriverGUID() != GEOMImpl_DiskDriver::GetID()) return NULL;
+
+ GEOMImpl_IDisk 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.SetRadius(theR);
+
+ //Compute the Disk value
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ SetErrorCode("Disk 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) << aDisk << " = geompy.MakeDiskPntVecR("
+ << thePnt << ", " << theVec << ", " << theR << ")";
+
+ SetErrorCode(OK);
+ return aDisk;
+}
+
+//=============================================================================
+/*!
+ * MakeDiskThreePnt
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeDiskThreePnt (Handle(GEOM_Object) thePnt1,
+ Handle(GEOM_Object) thePnt2,
+ Handle(GEOM_Object) thePnt3)
+{
+ SetErrorCode(KO);
+
+ if (thePnt1.IsNull() || thePnt2.IsNull() || thePnt3.IsNull()) return NULL;
+
+ //Add a new Disk object
+ Handle(GEOM_Object) aDisk = GetEngine()->AddObject(GetDocID(), GEOM_FACE);
+
+ //Add a new Disk function for creation a disk relatively to three points
+ Handle(GEOM_Function) aFunction =
+ aDisk->AddFunction(GEOMImpl_DiskDriver::GetID(), DISK_THREE_PNT);
+ if (aFunction.IsNull()) return NULL;
+
+ //Check if the function is set correctly
+ if (aFunction->GetDriverGUID() != GEOMImpl_DiskDriver::GetID()) return NULL;
+
+ GEOMImpl_IDisk aCI (aFunction);
+
+ Handle(GEOM_Function) aRefPnt1 = thePnt1->GetLastFunction();
+ Handle(GEOM_Function) aRefPnt2 = thePnt2->GetLastFunction();
+ Handle(GEOM_Function) aRefPnt3 = thePnt3->GetLastFunction();
+
+ if (aRefPnt1.IsNull() || aRefPnt2.IsNull() || aRefPnt3.IsNull()) return NULL;
+
+ aCI.SetPoint1(aRefPnt1);
+ aCI.SetPoint2(aRefPnt2);
+ aCI.SetPoint3(aRefPnt3);
+
+ //Compute the Disk value
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ SetErrorCode("Disk 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) << aDisk << " = geompy.MakeDiskThreePnt("
+ << thePnt1 << ", " << thePnt2 << ", " << thePnt3 << ")";
+
+ SetErrorCode(OK);
+ return aDisk;
+}
+
+//=============================================================================
+/*!
+ * MakeDiskR
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeDiskR (double theR, int theOrientation)
+{
+ SetErrorCode(KO);
+
+ if (theR == 0 ) return NULL;
+
+ //Add a new Disk object
+ Handle(GEOM_Object) aDisk = GetEngine()->AddObject(GetDocID(), GEOM_FACE);
+
+ //Add a new Box function for creation a box relatively to two points
+ Handle(GEOM_Function) aFunction = aDisk->AddFunction(GEOMImpl_DiskDriver::GetID(), DISK_R);
+ if (aFunction.IsNull()) return NULL;
+
+ //Check if the function is set correctly
+ if (aFunction->GetDriverGUID() != GEOMImpl_DiskDriver::GetID()) return aDisk;
+
+ GEOMImpl_IDisk aDI (aFunction);
+
+ aDI.SetRadius(theR);
+ aDI.SetOrientation(theOrientation);
+
+ //Compute the Disk
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ SetErrorCode("Disk 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) << aDisk << " = geompy.MakeDiskR("
+ << theR << ", " << theOrientation << ")";
+
+ SetErrorCode(OK);
+ return aDisk;
+}
//=============================================================================
/*!
//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;
return aCylinder;
}
+//=============================================================================
+/*!
+ * MakeCylinderRHA
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeCylinderRHA (double theR, double theH, double theA)
+{
+ 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_A);
+ 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);
+ aCI.SetA(theA);
+
+ //Compute the Cylinder value
+ try {
+ OCC_CATCH_SIGNALS;
+ 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.MakeCylinderRHA(" << theR << ", " << theH << ", " << theA*180./M_PI << "*math.pi/180.)";
+
+ SetErrorCode(OK);
+ return aCylinder;
+}
//=============================================================================
/*!
//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;
return aCylinder;
}
+//=============================================================================
+/*!
+ * MakeCylinderPntVecRHA
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeCylinderPntVecRHA (Handle(GEOM_Object) thePnt,
+ Handle(GEOM_Object) theVec,
+ double theR, double theH, double theA)
+{
+ 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_A);
+ 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);
+ aCI.SetA(theA);
+
+ //Compute the Cylinder value
+ try {
+ OCC_CATCH_SIGNALS;
+ 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.MakeCylinderA("
+ << thePnt << ", " << theVec << ", " << theR << ", " << theH << ", " << theA*180./M_PI << "*math.pi/180.)";
+
+ SetErrorCode(OK);
+ return aCylinder;
+}
+
//=============================================================================
/*!
//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;
//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;
//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;
//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;
//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;
//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;
//=============================================================================
Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePrismVecH (Handle(GEOM_Object) theBase,
Handle(GEOM_Object) theVec,
- double theH)
+ double theH, double theScaleFactor)
{
SetErrorCode(KO);
aCI.SetBase(aRefBase);
aCI.SetVector(aRefVec);
aCI.SetH(theH);
+ aCI.SetScale(theScaleFactor);
//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");
}
//Make a Python command
- GEOM::TPythonDump(aFunction) << aPrism << " = geompy.MakePrismVecH("
- << theBase << ", " << theVec << ", " << theH << ")";
+ GEOM::TPythonDump pd (aFunction);
+ pd << aPrism << " = geompy.MakePrismVecH(" << theBase << ", " << theVec << ", " << theH;
+ if (theScaleFactor > Precision::Confusion())
+ pd << ", " << theScaleFactor << ")";
+ else
+ pd << ")";
SetErrorCode(OK);
return aPrism;
*/
//=============================================================================
Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePrismVecH2Ways (Handle(GEOM_Object) theBase,
- Handle(GEOM_Object) theVec,
- double theH)
+ Handle(GEOM_Object) theVec,
+ double theH)
{
SetErrorCode(KO);
//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");
//=============================================================================
Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePrismTwoPnt
(Handle(GEOM_Object) theBase,
- Handle(GEOM_Object) thePoint1, Handle(GEOM_Object) thePoint2)
+ Handle(GEOM_Object) thePoint1, Handle(GEOM_Object) thePoint2,
+ double theScaleFactor)
{
SetErrorCode(KO);
aCI.SetBase(aRefBase);
aCI.SetFirstPoint(aRefPnt1);
aCI.SetLastPoint(aRefPnt2);
+ aCI.SetScale(theScaleFactor);
//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");
}
//Make a Python command
- GEOM::TPythonDump(aFunction) << aPrism << " = geompy.MakePrism("
- << theBase << ", " << thePoint1 << ", " << thePoint2 << ")";
+ GEOM::TPythonDump pd (aFunction);
+ pd << aPrism << " = geompy.MakePrism(" << theBase << ", " << thePoint1 << ", " << thePoint2;
+ if (theScaleFactor > Precision::Confusion())
+ pd << ", " << theScaleFactor << ")";
+ else
+ pd << ")";
SetErrorCode(OK);
return aPrism;
//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 aPrism;
}
-
+//=============================================================================
+/*!
+ * MakePrismDXDYDZ
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePrismDXDYDZ
+ (Handle(GEOM_Object) theBase, double theDX, double theDY, double theDZ,
+ double theScaleFactor)
+{
+ SetErrorCode(KO);
+
+ if (theBase.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 by DXDYDZ
+ Handle(GEOM_Function) aFunction =
+ aPrism->AddFunction(GEOMImpl_PrismDriver::GetID(), PRISM_BASE_DXDYDZ);
+ 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();
+
+ if (aRefBase.IsNull()) return NULL;
+
+ aCI.SetBase(aRefBase);
+ aCI.SetDX(theDX);
+ aCI.SetDY(theDY);
+ aCI.SetDZ(theDZ);
+ aCI.SetScale(theScaleFactor);
+
+ //Compute the Prism value
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ 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 pd (aFunction);
+ pd << aPrism << " = geompy.MakePrismDXDYDZ("
+ << theBase << ", " << theDX << ", " << theDY << ", " << theDZ;
+ if (theScaleFactor > Precision::Confusion())
+ pd << ", " << theScaleFactor << ")";
+ else
+ pd << ")";
+
+ SetErrorCode(OK);
+ return aPrism;
+}
+
+//=============================================================================
+/*!
+ * MakePrismDXDYDZ_2WAYS
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePrismDXDYDZ2Ways
+ (Handle(GEOM_Object) theBase, double theDX, double theDY, double theDZ)
+{
+ SetErrorCode(KO);
+
+ if (theBase.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 by DXDYDZ
+ Handle(GEOM_Function) aFunction =
+ aPrism->AddFunction(GEOMImpl_PrismDriver::GetID(), PRISM_BASE_DXDYDZ_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();
+
+ if (aRefBase.IsNull()) return NULL;
+
+ aCI.SetBase(aRefBase);
+ aCI.SetDX(theDX);
+ aCI.SetDY(theDY);
+ aCI.SetDZ(theDZ);
+
+ //Compute the Prism value
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ 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.MakePrismDXDYDZ2Ways("
+ << theBase << ", " << theDX << ", " << theDY << ", " << theDZ << ")";
+
+ SetErrorCode(OK);
+ return aPrism;
+}
+
+//=============================================================================
+/*!
+ * MakeDraftPrism
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeDraftPrism
+ (Handle(GEOM_Object) theInitShape ,Handle(GEOM_Object) theBase, double theHeight, double theAngle, bool theFuse)
+{
+ SetErrorCode(KO);
+
+ if (theBase.IsNull() || theInitShape.IsNull()) return NULL;
+
+ Handle(GEOM_Object) aPrism = NULL;
+
+ if ( theFuse )
+ {
+ //Add a new Extruded Boss object
+ aPrism = GetEngine()->AddObject(GetDocID(), GEOM_EXTRUDED_BOSS);
+ }
+ else
+ {
+ //Add a new Extruded Cut object
+ aPrism = GetEngine()->AddObject(GetDocID(), GEOM_EXTRUDED_CUT);
+ }
+
+ //Add a new Prism function for the creation of a Draft Prism feature
+ Handle(GEOM_Function) aFunction =
+ aPrism->AddFunction(GEOMImpl_PrismDriver::GetID(), DRAFT_PRISM_FEATURE);
+ 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) aRefInit = theInitShape->GetLastFunction();
+ Handle(GEOM_Function) aRefBase = theBase->GetLastFunction();
+
+ if (aRefBase.IsNull() || aRefInit.IsNull()) return NULL;
+
+ // Set parameters
+ aCI.SetBase(aRefBase);
+ aCI.SetInitShape(aRefInit);
+ aCI.SetH(theHeight);
+ aCI.SetDraftAngle(theAngle);
+ if ( theFuse )
+ aCI.SetFuseFlag(1);
+ else
+ aCI.SetFuseFlag(0);
+
+ //Compute the Draft Prism Feature value
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ 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
+ if(theFuse)
+ {
+ GEOM::TPythonDump(aFunction) << aPrism << " = geompy.MakeExtrudedBoss("
+ << theInitShape << ", " << theBase << ", " << theHeight << ", " << theAngle << ")";
+ }
+ else
+ {
+ GEOM::TPythonDump(aFunction) << aPrism << " = geompy.MakeExtrudedCut("
+ << theInitShape << ", " << theBase << ", " << theHeight << ", " << theAngle << ")";
+ }
+
+ SetErrorCode(OK);
+ return aPrism;
+}
+
//=============================================================================
/*!
* MakePipe
//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;
//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;
//Make a Python command
GEOM::TPythonDump(aFunction) << aRevolution << " = geompy.MakeRevolution("
- << theBase << ", " << theAxis << ", " << theAngle * 180.0 / PI << "*math.pi/180.0)";
-
+ << theBase << ", " << theAxis << ", " << theAngle * 180.0 / M_PI << "*math.pi/180.0)";
+
SetErrorCode(OK);
return aRevolution;
}
//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;
//Make a Python command
GEOM::TPythonDump(aFunction) << aRevolution << " = geompy.MakeRevolution2Ways("
- << theBase << ", " << theAxis << ", " << theAngle * 180.0 / PI << "*math.pi/180.0)";
+ << theBase << ", " << theAxis << ", " << theAngle * 180.0 / M_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)
+ double theTol2D, double theTol3D, int theNbIter,
+ int theMethod, bool isApprox)
{
SetErrorCode(KO);
aFI.SetTol3D(theTol3D);
aFI.SetNbIter(theNbIter);
aFI.SetApprox(isApprox);
+ aFI.SetMethod(theMethod);
//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;
//Make a Python command
GEOM::TPythonDump pd (aFunction);
- pd << aFilling << " = geompy.MakeFilling("
- << theShape << ", " << theMinDeg << ", " << theMaxDeg << ", "
- << theTol2D << ", " << theTol3D << ", " << theNbIter;
- if(isApprox)
- pd << ", " << isApprox;
+ pd << aFilling << " = geompy.MakeFilling(" << theShape ;
+ if ( theMinDeg != 2 ) pd << ", theMinDeg=" << theMinDeg ;
+ if ( theMaxDeg != 5 ) pd << ", theMaxDeg=" << theMaxDeg ;
+ if ( fabs(theTol2D-0.0001) > Precision::Confusion() )
+ pd << ", theTol2D=" << theTol2D ;
+ if ( fabs(theTol3D-0.0001) > Precision::Confusion() )
+ pd << ", theTol3D=" << theTol3D ;
+ if ( theNbIter != 0 ) pd << ", theNbIter=" << theNbIter ;
+ if ( theMethod==1 ) pd << ", theMethod=GEOM.FOM_UseOri";
+ else if( theMethod==2 ) pd << ", theMethod=GEOM.FOM_AutoCorrect";
+ if(isApprox) pd << ", isApprox=" << isApprox ;
pd << ")";
SetErrorCode(OK);
*/
//=============================================================================
Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeThruSections(
- const Handle(TColStd_HSequenceOfTransient)& theSeqSections,
- bool theModeSolid,
- double thePreci,
- bool theRuled)
+ const Handle(TColStd_HSequenceOfTransient)& theSeqSections,
+ bool theModeSolid,
+ double thePreci,
+ bool theRuled)
{
Handle(GEOM_Object) anObj;
SetErrorCode(KO);
return anObj;
Standard_Integer nbObj = theSeqSections->Length();
- if (!nbObj)
+ 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(Standard_Transient) anItem = theSeqSections->Value(i);
if(anItem.IsNull())
continue;
-
+
Handle(GEOM_Object) aSectObj = Handle(GEOM_Object)::DownCast(anItem);
if(!aSectObj.IsNull())
{
//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;
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<<", ";
}
}
-
+
pyDump<< "],"<<theModeSolid << "," << thePreci <<","<< theRuled <<")";
SetErrorCode(OK);
return aThruSect;
-
-
}
*/
//=============================================================================
Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePipeWithDifferentSections(
- const Handle(TColStd_HSequenceOfTransient)& theBases,
- const Handle(TColStd_HSequenceOfTransient)& theLocations,
- const Handle(GEOM_Object)& thePath,
- bool theWithContact,
- bool theWithCorrections)
+ const Handle(TColStd_HSequenceOfTransient)& theBases,
+ const Handle(TColStd_HSequenceOfTransient)& theLocations,
+ const Handle(GEOM_Object)& thePath,
+ bool theWithContact,
+ bool theWithCorrections)
{
Handle(GEOM_Object) anObj;
SetErrorCode(KO);
return anObj;
Standard_Integer nbBases = theBases->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 =
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(Standard_Transient) anItemLoc = theLocations->Value(i);
if(anItemLoc.IsNull())
- continue;
-
+ continue;
+
Handle(GEOM_Object) aLoc = Handle(GEOM_Object)::DownCast(anItemLoc);
if(aLoc.IsNull())
- continue;
+ continue;
Handle(GEOM_Function) aRefLoc = aLoc->GetLastFunction();
if(aRefLoc.IsNull())
- continue;
+ continue;
aSeqLocs->Append(aRefLoc);
}
aSeqBases->Append(aRefBase);
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;
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<<", ";
}
-
}
-
+
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<<", ";
}
- }
+ }
pyDump<< "], "<<thePath<<","<<theWithContact << "," << theWithCorrections<<")";
SetErrorCode(OK);
return aPipeDS;
-
-
}
*/
//=============================================================================
Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePipeWithShellSections(
- const Handle(TColStd_HSequenceOfTransient)& theBases,
- const Handle(TColStd_HSequenceOfTransient)& theSubBases,
- const Handle(TColStd_HSequenceOfTransient)& theLocations,
- const Handle(GEOM_Object)& thePath,
- bool theWithContact,
- bool theWithCorrections)
+ const Handle(TColStd_HSequenceOfTransient)& theBases,
+ const Handle(TColStd_HSequenceOfTransient)& theSubBases,
+ const Handle(TColStd_HSequenceOfTransient)& theLocations,
+ const Handle(GEOM_Object)& thePath,
+ bool theWithContact,
+ bool theWithCorrections)
{
Handle(GEOM_Object) anObj;
SetErrorCode(KO);
return anObj;
Standard_Integer nbBases = theBases->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 =
if( nbSubBases >= nbBases ) {
Handle(Standard_Transient) aSubItem = theSubBases->Value(i);
if(aSubItem.IsNull())
- continue;
+ continue;
Handle(GEOM_Object) aSubBase = Handle(GEOM_Object)::DownCast(aSubItem);
if(aSubBase.IsNull())
- continue;
+ continue;
Handle(GEOM_Function) aRefSubBase = aSubBase->GetLastFunction();
if(aRefSubBase.IsNull())
- continue;
+ continue;
aSeqSubBases->Append(aRefSubBase);
}
if(nbLocs) {
Handle(Standard_Transient) anItemLoc = theLocations->Value(i);
if(anItemLoc.IsNull())
- continue;
+ continue;
Handle(GEOM_Object) aLoc = Handle(GEOM_Object)::DownCast(anItemLoc);
if(aLoc.IsNull())
- continue;
+ continue;
Handle(GEOM_Function) aRefLoc = aLoc->GetLastFunction();
if(aRefLoc.IsNull())
- continue;
+ continue;
aSeqLocs->Append(aRefLoc);
}
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;
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<<", ";
}
-
}
-
+
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<<", ";
}
-
}
-
+
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<<", ";
}
- }
+ }
pyDump<< "], "<<thePath<<","<<theWithContact << "," << theWithCorrections<<")";
*/
//=============================================================================
Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePipeShellsWithoutPath(
- const Handle(TColStd_HSequenceOfTransient)& theBases,
- const Handle(TColStd_HSequenceOfTransient)& theLocations)
+ const Handle(TColStd_HSequenceOfTransient)& theBases,
+ const Handle(TColStd_HSequenceOfTransient)& theLocations)
{
Handle(GEOM_Object) anObj;
SetErrorCode(KO);
return anObj;
Standard_Integer nbBases = theBases->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 =
if(nbLocs) {
Handle(Standard_Transient) anItemLoc = theLocations->Value(i);
if(anItemLoc.IsNull())
- continue;
+ continue;
Handle(GEOM_Object) aLoc = Handle(GEOM_Object)::DownCast(anItemLoc);
if(aLoc.IsNull())
- continue;
+ continue;
Handle(GEOM_Function) aRefLoc = aLoc->GetLastFunction();
if(aRefLoc.IsNull())
- continue;
+ continue;
aSeqLocs->Append(aRefLoc);
}
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;
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<<", ";
}
-
}
-
+
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<<", ";
}
- }
+ }
pyDump<< "])";
}
+//=============================================================================
+/*!
+ * MakePipeBiNormalAlongVector
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakePipeBiNormalAlongVector (Handle(GEOM_Object) theBase,
+ Handle(GEOM_Object) thePath,
+ Handle(GEOM_Object) theVec)
+{
+ SetErrorCode(KO);
+
+ if (theBase.IsNull() || thePath.IsNull() || theVec.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_BI_NORMAL_ALONG_VECTOR);
+ if (aFunction.IsNull()) return NULL;
+
+ //Check if the function is set correctly
+ if (aFunction->GetDriverGUID() != GEOMImpl_PipeDriver::GetID()) return NULL;
+
+ GEOMImpl_IPipeBiNormal aCI (aFunction);
+
+ Handle(GEOM_Function) aRefBase = theBase->GetLastFunction();
+ Handle(GEOM_Function) aRefPath = thePath->GetLastFunction();
+ Handle(GEOM_Function) aRefVec = theVec->GetLastFunction();
+
+ if (aRefBase.IsNull() || aRefPath.IsNull() || aRefVec.IsNull()) return NULL;
+
+ aCI.SetBase(aRefBase);
+ aCI.SetPath(aRefPath);
+ aCI.SetVector(aRefVec);
+
+ //Compute the Pipe value
+ try {
+ OCC_CATCH_SIGNALS;
+ 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.MakePipeBiNormalAlongVector("
+ << theBase << ", " << thePath << ", " << theVec << ")";
+
+ SetErrorCode(OK);
+ return aPipe;
+}
+
+//=============================================================================
+/*!
+ * MakeThickening
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::MakeThickening(Handle(GEOM_Object) theObject,
+ double theOffset,
+ bool copy = true)
+{
+ SetErrorCode(KO);
+
+ if (theObject.IsNull()) return NULL;
+
+ Handle(GEOM_Function) anOriginal = theObject->GetLastFunction();
+ if (anOriginal.IsNull()) return NULL; //There is no function which creates an object to be offset
+
+ //Add a new Offset function
+ Handle(GEOM_Function) aFunction;
+ Handle(GEOM_Object) aCopy;
+ if (copy)
+ {
+ //Add a new Copy object
+ aCopy = GetEngine()->AddObject(GetDocID(), theObject->GetType());
+ aFunction = aCopy->AddFunction(GEOMImpl_OffsetDriver::GetID(), OFFSET_THICKENING_COPY);
+ }
+ else
+ aFunction = theObject->AddFunction(GEOMImpl_OffsetDriver::GetID(), OFFSET_THICKENING);
+
+ if (aFunction.IsNull()) return NULL;
+
+ //Check if the function is set correctly
+ if (aFunction->GetDriverGUID() != GEOMImpl_OffsetDriver::GetID()) return NULL;
+
+ GEOMImpl_IOffset aTI (aFunction);
+ aTI.SetShape(anOriginal);
+ aTI.SetValue(theOffset);
+
+ //Compute the offset
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ SetErrorCode("Offset driver failed");
+ return NULL;
+ }
+ }
+ catch (Standard_Failure) {
+ Handle(Standard_Failure) aFail = Standard_Failure::Caught();
+ SetErrorCode(aFail->GetMessageString());
+ return NULL;
+ }
+
+ //Make a Python command
+ if(copy)
+ {
+ GEOM::TPythonDump(aFunction) << aCopy << " = geompy.MakeThickSolid("
+ << theObject << ", " << theOffset << ")";
+ SetErrorCode(OK);
+ return aCopy;
+ }
+ else
+ {
+ GEOM::TPythonDump(aFunction) << "geompy.Thicken("
+ << theObject << ", " << theOffset << ")";
+ SetErrorCode(OK);
+ return theObject;
+ }
+}
+
+//=============================================================================
+/*!
+ * RestorePath
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::RestorePath (Handle(GEOM_Object) theShape,
+ Handle(GEOM_Object) theBase1,
+ Handle(GEOM_Object) theBase2)
+{
+ SetErrorCode(KO);
+
+ if (theShape.IsNull() || theBase1.IsNull() || theBase2.IsNull()) return NULL;
+
+ // Add a new Path object
+ Handle(GEOM_Object) aPath = GetEngine()->AddObject(GetDocID(), GEOM_PIPE_PATH);
+
+ // Add a new Path function
+ Handle(GEOM_Function) aFunction =
+ aPath->AddFunction(GEOMImpl_PipePathDriver::GetID(), PIPE_PATH_TWO_BASES);
+ if (aFunction.IsNull()) return NULL;
+
+ // Check if the function is set correctly
+ if (aFunction->GetDriverGUID() != GEOMImpl_PipePathDriver::GetID()) return NULL;
+
+ GEOMImpl_IPipePath aCI (aFunction);
+
+ Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
+ Handle(GEOM_Function) aRefBase1 = theBase1->GetLastFunction();
+ Handle(GEOM_Function) aRefBase2 = theBase2->GetLastFunction();
+
+ if (aRefShape.IsNull() || aRefBase1.IsNull() || aRefBase2.IsNull()) return NULL;
+
+ aCI.SetShape(aRefShape);
+ aCI.SetBase1(aRefBase1);
+ aCI.SetBase2(aRefBase2);
+
+ // Compute the Path value
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ SetErrorCode("PipePath driver failed");
+ return NULL;
+ }
+ }
+ catch (Standard_Failure) {
+ Handle(Standard_Failure) aFail = Standard_Failure::Caught();
+ SetErrorCode("RestorePath: inappropriate arguments given");
+ return NULL;
+ }
+
+ // Make a Python command
+ GEOM::TPythonDump(aFunction) << aPath << " = geompy.RestorePath("
+ << theShape << ", " << theBase1 << ", " << theBase2 << ")";
+
+ SetErrorCode(OK);
+ return aPath;
+}
+
+//=============================================================================
+/*!
+ * RestorePath
+ */
+//=============================================================================
+Handle(GEOM_Object) GEOMImpl_I3DPrimOperations::RestorePath
+ (Handle(GEOM_Object) theShape,
+ const Handle(TColStd_HSequenceOfTransient)& theBase1,
+ const Handle(TColStd_HSequenceOfTransient)& theBase2)
+{
+ SetErrorCode(KO);
+
+ if (theShape.IsNull() || theBase1.IsNull() || theBase2.IsNull()) return NULL;
+
+ Standard_Integer nbBases1 = theBase1->Length();
+ Standard_Integer nbBases2 = theBase2->Length();
+
+ if (!nbBases1 || !nbBases2)
+ return NULL;
+
+ // Add a new Path object
+ Handle(GEOM_Object) aPath = GetEngine()->AddObject(GetDocID(), GEOM_PIPE_PATH);
+
+ // Add a new Path function
+ Handle(GEOM_Function) aFunction =
+ aPath->AddFunction(GEOMImpl_PipePathDriver::GetID(), PIPE_PATH_TWO_SEQS);
+ if (aFunction.IsNull()) return NULL;
+
+ // Check if the function is set correctly
+ if (aFunction->GetDriverGUID() != GEOMImpl_PipePathDriver::GetID()) return NULL;
+
+ GEOMImpl_IPipePath aCI (aFunction);
+
+ Handle(GEOM_Function) aRefShape = theShape->GetLastFunction();
+ if (aRefShape.IsNull()) return NULL;
+
+ Handle(TColStd_HSequenceOfTransient) aSeqBases1 = new TColStd_HSequenceOfTransient;
+ Handle(TColStd_HSequenceOfTransient) aSeqBases2 = new TColStd_HSequenceOfTransient;
+
+ Standard_Integer i;
+ for (i = 1; i <= nbBases1; i++) {
+ Handle(Standard_Transient) anItem = theBase1->Value(i);
+ if (!anItem.IsNull()) {
+ Handle(GEOM_Object) aBase = Handle(GEOM_Object)::DownCast(anItem);
+ if (!aBase.IsNull()) {
+ Handle(GEOM_Function) aRefBase = aBase->GetLastFunction();
+ if (!aRefBase.IsNull())
+ aSeqBases1->Append(aRefBase);
+ }
+ }
+ }
+ for (i = 1; i <= nbBases2; i++) {
+ Handle(Standard_Transient) anItem = theBase2->Value(i);
+ if (!anItem.IsNull()) {
+ Handle(GEOM_Object) aBase = Handle(GEOM_Object)::DownCast(anItem);
+ if (!aBase.IsNull()) {
+ Handle(GEOM_Function) aRefBase = aBase->GetLastFunction();
+ if (!aRefBase.IsNull())
+ aSeqBases2->Append(aRefBase);
+ }
+ }
+ }
+ if (!aSeqBases1->Length() || !aSeqBases2->Length()) return NULL;
+
+ aCI.SetShape(aRefShape);
+ aCI.SetBaseSeq1(aSeqBases1);
+ aCI.SetBaseSeq2(aSeqBases2);
+
+ // Compute the Path value
+ try {
+ OCC_CATCH_SIGNALS;
+ if (!GetSolver()->ComputeFunction(aFunction)) {
+ SetErrorCode("PipePath driver failed");
+ return NULL;
+ }
+ }
+ catch (Standard_Failure) {
+ Handle(Standard_Failure) aFail = Standard_Failure::Caught();
+ SetErrorCode("RestorePath: inappropriate arguments given");
+ return NULL;
+ }
+
+ // Make a Python command
+ GEOM::TPythonDump pyDump (aFunction);
+ pyDump << aPath << " = geompy.RestorePathEdges(" << theShape << ", [";
+ for (i = 1; i <= nbBases1; i++) {
+ Handle(GEOM_Object) anObj = Handle(GEOM_Object)::DownCast(theBase1->Value(i));
+ if (!anObj.IsNull()) {
+ pyDump << anObj;
+ if (i < nbBases1)
+ pyDump << ", ";
+ }
+ }
+ pyDump<< "], [";
+ for (i = 1; i <= nbBases2; i++) {
+ Handle(GEOM_Object) anObj = Handle(GEOM_Object)::DownCast(theBase2->Value(i));
+ if (!anObj.IsNull()) {
+ pyDump << anObj;
+ if (i < nbBases2)
+ pyDump << ", ";
+ }
+ }
+ pyDump << "])";
+
+ SetErrorCode(OK);
+ return aPath;
+}