-# GEOM GEOM_SWIG : binding of C++ omplementaion with Python
-#
-# Copyright (C) 2003 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.
+# -*- coding: iso-8859-1 -*-
+# Copyright (C) 2007-2011 CEA/DEN, EDF R&D, OPEN CASCADE
#
-# 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.
+# Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
+# CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS
#
-# 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
+# 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.
#
-# See http://www.opencascade.org/SALOME/ or email : webmaster.salome@opencascade.org
+# 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
#
+
+# GEOM GEOM_SWIG : binding of C++ omplementaion with Python
# File : geompy.py
# Author : Paul RASCLE, EDF
# Module : GEOM
# $Header$
-
-from salome import *
-import GEOM
-
-g = lcc.FindOrLoadComponent("FactoryServer", "GEOM")
-geom = g._narrow( GEOM.GEOM_Gen )
-myBuilder = myStudy.NewBuilder()
-
-father = myStudy.FindComponent("GEOM")
-if father is None:
- father = myBuilder.NewComponent("GEOM")
- A1 = myBuilder.FindOrCreateAttribute(father, "AttributeName")
- FName = A1._narrow(SALOMEDS.AttributeName)
- FName.SetValue("Geometry")
- A2 = myBuilder.FindOrCreateAttribute(father, "AttributePixMap")
- aPixmap = A2._narrow(SALOMEDS.AttributePixMap)
- aPixmap.SetPixMap("ICON_OBJBROWSER_Geometry")
- myBuilder.DefineComponentInstance(father,geom)
-
-gg = ImportComponentGUI("GEOM")
-
-# * Get name for sub-shape aSubObj of shape aMainObj
-#
-# * Example: see GEOM_TestAll.py
-#
-def SubShapeName(aSubObj, aMainObj):
- aSubId = orb.object_to_string(aSubObj)
- aMainId = orb.object_to_string(aMainObj)
- index = gg.getIndexTopology(aSubId, aMainId)
- name = gg.getShapeTypeString(aSubId) + "_%d"%(index)
- return name
-
-# * Publish in study aShape with name aName
-#
-# * Example: see GEOM_TestAll.py
-#
-def addToStudy(aShape, aName):
- try:
- aSObject = geom.AddInStudy(myStudy, aShape, aName, None)
- except:
- print "addToStudy() failed"
- return ""
- return aShape.GetStudyEntry()
-
-# * Publish in study aShape with name aName as sub-object of previously published aFather
-#
-# * Example: see GEOM_TestAll.py
-#
-def addToStudyInFather(aFather, aShape, aName):
- try:
- aSObject = geom.AddInStudy(myStudy, aShape, aName, aFather)
- except:
- print "addToStudyInFather() failed"
- return ""
- return aShape.GetStudyEntry()
-
-# -----------------------------------------------------------------------------
-# enumeration ShapeType as a dictionary
-# -----------------------------------------------------------------------------
-
-ShapeType = {"COMPOUND":0, "COMPSOLID":1, "SOLID":2, "SHELL":3, "FACE":4, "WIRE":5, "EDGE":6, "VERTEX":7, "SHAPE":8}
-
-# -----------------------------------------------------------------------------
-# Get Operations Interfaces
-# -----------------------------------------------------------------------------
-
-BasicOp = geom.GetIBasicOperations (myStudyId)
-CurvesOp = geom.GetICurvesOperations (myStudyId)
-PrimOp = geom.GetI3DPrimOperations (myStudyId)
-ShapesOp = geom.GetIShapesOperations (myStudyId)
-HealOp = geom.GetIHealingOperations (myStudyId)
-InsertOp = geom.GetIInsertOperations (myStudyId)
-BoolOp = geom.GetIBooleanOperations (myStudyId)
-TrsfOp = geom.GetITransformOperations(myStudyId)
-LocalOp = geom.GetILocalOperations (myStudyId)
-MeasuOp = geom.GetIMeasureOperations (myStudyId)
-BlocksOp = geom.GetIBlocksOperations (myStudyId)
-GroupOp = geom.GetIGroupOperations (myStudyId)
-
-# -----------------------------------------------------------------------------
-# Basic primitives
-# -----------------------------------------------------------------------------
-
-# * Create point by three coordinates.
-# * \param theX The X coordinate of the point.
-# * \param theY The Y coordinate of the point.
-# * \param theZ The Z coordinate of the point.
-# * \return New GEOM_Object, containing the created point.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeVertex(theX, theY, theZ):
- anObj = BasicOp.MakePointXYZ(theX, theY, theZ)
- if BasicOp.IsDone() == 0:
- print "MakePointXYZ : ", BasicOp.GetErrorCode()
- return anObj
-
-# * Create a point, distant from the referenced point
-# * on the given distances along the coordinate axes.
-# * \param theReference The referenced point.
-# * \param theX Displacement from the referenced point along OX axis.
-# * \param theY Displacement from the referenced point along OY axis.
-# * \param theZ Displacement from the referenced point along OZ axis.
-# * \return New GEOM_Object, containing the created point.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeVertexWithRef(theReference, theX, theY, theZ):
- anObj = BasicOp.MakePointWithReference(theReference, theX, theY, theZ)
- if BasicOp.IsDone() == 0:
- print "MakePointWithReference : ", BasicOp.GetErrorCode()
- return anObj
-
-# * Create a point, corresponding to the given parameter on the given curve.
-# * \param theRefCurve The referenced curve.
-# * \param theParameter Value of parameter on the referenced curve.
-# * \return New GEOM_Object, containing the created point.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeVertexOnCurve(theRefCurve, theParameter):
- anObj = BasicOp.MakePointOnCurve(theRefCurve, theParameter)
- if BasicOp.IsDone() == 0:
- print "MakePointOnCurve : ", BasicOp.GetErrorCode()
- return anObj
-
-# * Create a vector with the given components.
-# * \param theDX X component of the vector.
-# * \param theDY Y component of the vector.
-# * \param theDZ Z component of the vector.
-# * \return New GEOM_Object, containing the created vector.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeVectorDXDYDZ(theDX, theDY, theDZ):
- anObj = BasicOp.MakeVectorDXDYDZ(theDX, theDY, theDZ)
- if BasicOp.IsDone() == 0:
- print "MakeVectorDXDYDZ : ", BasicOp.GetErrorCode()
- return anObj
-
-# * Create a vector between two points.
-# * \param thePnt1 Start point for the vector.
-# * \param thePnt2 End point for the vector.
-# * \return New GEOM_Object, containing the created vector.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeVector(thePnt1, thePnt2):
- anObj = BasicOp.MakeVectorTwoPnt(thePnt1, thePnt2)
- if BasicOp.IsDone() == 0:
- print "MakeVectorTwoPnt : ", BasicOp.GetErrorCode()
- return anObj
-
-# * Create a line, passing through the given point
-# * and parrallel to the given direction
-# * \param thePnt Point. The resulting line will pass through it.
-# * \param theDir Direction. The resulting line will be parallel to it.
-# * \return New GEOM_Object, containing the created line.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeLine(thePnt, theDir):
- anObj = BasicOp.MakeLine(thePnt, theDir)
- if BasicOp.IsDone() == 0:
- print "MakeLine : ", BasicOp.GetErrorCode()
- return anObj
-
-# * Create a line, passing through the given points
-# * \param thePnt1 First of two points, defining the line.
-# * \param thePnt2 Second of two points, defining the line.
-# * \return New GEOM_Object, containing the created line.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeLineTwoPnt(thePnt1, thePnt2):
- anObj = BasicOp.MakeLineTwoPnt(thePnt1, thePnt2)
- if BasicOp.IsDone() == 0:
- print "MakeLineTwoPnt : ", BasicOp.GetErrorCode()
- return anObj
-
-# * Create a plane, passing through the given point
-# * and normal to the given vector.
-# * \param thePnt Point, the plane has to pass through.
-# * \param theVec Vector, defining the plane normal direction.
-# * \param theTrimSize Half size of a side of quadrangle face, representing the plane.
-# * \return New GEOM_Object, containing the created plane.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakePlane(thePnt, theVec, theTrimSize):
- anObj = BasicOp.MakePlanePntVec(thePnt, theVec, theTrimSize)
- if BasicOp.IsDone() == 0:
- print "MakePlanePntVec : ", BasicOp.GetErrorCode()
- return anObj
-
-# * Create a plane, passing through the three given points
-# * \param thePnt1 First of three points, defining the plane.
-# * \param thePnt2 Second of three points, defining the plane.
-# * \param thePnt3 Fird of three points, defining the plane.
-# * \param theTrimSize Half size of a side of quadrangle face, representing the plane.
-# * \return New GEOM_Object, containing the created plane.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakePlaneThreePnt(thePnt1, thePnt2, thePnt3, theTrimSize):
- anObj = BasicOp.MakePlaneThreePnt(thePnt1, thePnt2, thePnt3, theTrimSize)
- if BasicOp.IsDone() == 0:
- print "MakePlaneThreePnt : ", BasicOp.GetErrorCode()
- return anObj
-
-# * Create a plane, similar to the existing one, but with another size of representing face.
-# * \param theFace Referenced plane.
-# * \param theTrimSize New half size of a side of quadrangle face, representing the plane.
-# * \return New GEOM_Object, containing the created plane.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakePlaneFace(theFace, theTrimSize):
- anObj = BasicOp.MakePlaneFace(theFace, theTrimSize)
- if BasicOp.IsDone() == 0:
- print "MakePlaneFace : ", BasicOp.GetErrorCode()
- return anObj
-
-# * Create a local coordinate system.
-# * \param OX,OY,OZ Three coordinates of coordinate system origin.
-# * \param XDX,XDY,XDZ Three components of OX direction
-# * \param YDX,YDY,YDZ Three components of OY direction
-# * \return New GEOM_Object, containing the created coordinate system.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeMarker(OX,OY,OZ, XDX,XDY,XDZ, YDX,YDY,YDZ):
- anObj = BasicOp.MakeMarker(OX,OY,OZ, XDX,XDY,XDZ, YDX,YDY,YDZ)
- if BasicOp.IsDone() == 0:
- print "MakeMarker : ", BasicOp.GetErrorCode()
- return anObj
-
-# -----------------------------------------------------------------------------
-# Curves
-# -----------------------------------------------------------------------------
-
-# * Create an arc of circle, passing through three given points.
-# * \param thePnt1 Start point of the arc.
-# * \param thePnt2 Middle point of the arc.
-# * \param thePnt3 End point of the arc.
-# * \return New GEOM_Object, containing the created arc.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeArc(thePnt1, thePnt2, thePnt3):
- anObj = CurvesOp.MakeArc(thePnt1, thePnt2, thePnt3)
- if CurvesOp.IsDone() == 0:
- print "MakeArc : ", CurvesOp.GetErrorCode()
- return anObj
-
-# * Create a circle with given center, normal vector and radius.
-# * \param thePnt Circle center.
-# * \param theVec Vector, normal to the plane of the circle.
-# * \param theR Circle radius.
-# * \return New GEOM_Object, containing the created circle.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeCircle(thePnt, theVec, theR):
- anObj = CurvesOp.MakeCirclePntVecR(thePnt, theVec, theR)
- if CurvesOp.IsDone() == 0:
- print "MakeCirclePntVecR : ", CurvesOp.GetErrorCode()
- return anObj
-
-# * Create a circle, passing through three given points
-# * \param thePnt1,thePnt2,thePnt3 Points, defining the circle.
-# * \return New GEOM_Object, containing the created circle.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeCircleThreePnt(thePnt1, thePnt2, thePnt3):
- anObj = CurvesOp.MakeCircleThreePnt(thePnt1, thePnt2, thePnt3)
- if CurvesOp.IsDone() == 0:
- print "MakeCircleThreePnt : ", CurvesOp.GetErrorCode()
- return anObj
-
-# * Create an ellipse with given center, normal vector and radiuses.
-# * \param thePnt Ellipse center.
-# * \param theVec Vector, normal to the plane of the ellipse.
-# * \param theRMajor Major ellipse radius.
-# * \param theRMinor Minor ellipse radius.
-# * \return New GEOM_Object, containing the created ellipse.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeEllipse(thePnt, theVec, theRMajor, theRMinor):
- anObj = CurvesOp.MakeEllipse(thePnt, theVec, theRMajor, theRMinor)
- if CurvesOp.IsDone() == 0:
- print "MakeEllipse : ", CurvesOp.GetErrorCode()
- return anObj
-
-# * Create a polyline on the set of points.
-# * \param thePoints Sequence of points for the polyline.
-# * \return New GEOM_Object, containing the created polyline.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakePolyline(thePoints):
- anObj = CurvesOp.MakePolyline(thePoints)
- if CurvesOp.IsDone() == 0:
- print "MakePolyline : ", CurvesOp.GetErrorCode()
- return anObj
-
-# * Create bezier curve on the set of points.
-# * \param thePoints Sequence of points for the bezier curve.
-# * \return New GEOM_Object, containing the created bezier curve.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeBezier(thePoints):
- anObj = CurvesOp.MakeSplineBezier(thePoints)
- if CurvesOp.IsDone() == 0:
- print "MakeSplineBezier : ", CurvesOp.GetErrorCode()
- return anObj
-
-# * Create B-Spline curve on the set of points.
-# * \param thePoints Sequence of points for the B-Spline curve.
-# * \return New GEOM_Object, containing the created B-Spline curve.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeInterpol(thePoints):
- anObj = CurvesOp.MakeSplineInterpolation(thePoints)
- if CurvesOp.IsDone() == 0:
- print "MakeSplineInterpolation : ", CurvesOp.GetErrorCode()
- return anObj
-
-# * Create a sketcher (wire or face), following the textual description,
-# * passed through \a theCommand argument. \n
-# * Edges of the resulting wire or face will be arcs of circles and/or linear segments. \n
-# * Format of the description string have to be the following:
-# *
-# * "Sketcher[:F x1 y1]:CMD[:CMD[:CMD...]]"
-# *
-# * Where:
-# * - x1, y1 are coordinates of the first sketcher point (zero by default),
-# * - CMD is one of
-# * - "R angle" : Set the direction by angle
-# * - "D dx dy" : Set the direction by DX & DY
-# * .
-# * \n
-# * - "TT x y" : Create segment by point at X & Y
-# * - "T dx dy" : Create segment by point with DX & DY
-# * - "L length" : Create segment by direction & Length
-# * - "IX x" : Create segment by direction & Intersect. X
-# * - "IY y" : Create segment by direction & Intersect. Y
-# * .
-# * \n
-# * - "C radius length" : Create arc by direction, radius and length(in degree)
-# * .
-# * \n
-# * - "WW" : Close Wire (to finish)
-# * - "WF" : Close Wire and build face (to finish)
-# *
-# * \param theCommand String, defining the sketcher in local
-# * coordinates of the working plane.
-# * \param theWorkingPlane Nine double values, defining origin,
-# * OZ and OX directions of the working plane.
-# * \return New GEOM_Object, containing the created wire.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeSketcher(theCommand, theWorkingPlane = [0,0,0, 0,0,1, 1,0,0]):
- anObj = CurvesOp.MakeSketcher(theCommand, theWorkingPlane)
- if CurvesOp.IsDone() == 0:
- print "MakeSketcher : ", CurvesOp.GetErrorCode()
- return anObj
-
-# -----------------------------------------------------------------------------
-# Create 3D Primitives
-# -----------------------------------------------------------------------------
-
-# * Create a box by coordinates of two opposite vertices.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeBox(x1,y1,z1,x2,y2,z2):
- pnt1 = MakeVertex(x1,y1,z1)
- pnt2 = MakeVertex(x2,y2,z2)
- return MakeBoxTwoPnt(pnt1,pnt2)
-
-# * Create a box with specified dimensions along the coordinate axes
-# * and with edges, parallel to the coordinate axes.
-# * Center of the box will be at point (DX/2, DY/2, DZ/2).
-# * \param theDX Length of Box edges, parallel to OX axis.
-# * \param theDY Length of Box edges, parallel to OY axis.
-# * \param theDZ Length of Box edges, parallel to OZ axis.
-# * \return New GEOM_Object, containing the created box.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeBoxDXDYDZ(theDX, theDY, theDZ):
- anObj = PrimOp.MakeBoxDXDYDZ(theDX, theDY, theDZ)
- if PrimOp.IsDone() == 0:
- print "MakeBoxDXDYDZ : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a box with two specified opposite vertices,
-# * and with edges, parallel to the coordinate axes
-# * \param thePnt1 First of two opposite vertices.
-# * \param thePnt2 Second of two opposite vertices.
-# * \return New GEOM_Object, containing the created box.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeBoxTwoPnt(thePnt1, thePnt2):
- anObj = PrimOp.MakeBoxTwoPnt(thePnt1, thePnt2)
- if PrimOp.IsDone() == 0:
- print "MakeBoxTwoPnt : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a cylinder with given base point, axis, radius and height.
-# * \param thePnt Central point of cylinder base.
-# * \param theAxis Cylinder axis.
-# * \param theR Cylinder radius.
-# * \param theH Cylinder height.
-# * \return New GEOM_Object, containing the created cylinder.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeCylinder(thePnt, theAxis, theR, theH):
- anObj = PrimOp.MakeCylinderPntVecRH(thePnt, theAxis, theR, theH)
- if PrimOp.IsDone() == 0:
- print "MakeCylinderPntVecRH : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a cylinder with given radius and height at
-# * the origin of coordinate system. Axis of the cylinder
-# * will be collinear to the OZ axis of the coordinate system.
-# * \param theR Cylinder radius.
-# * \param theH Cylinder height.
-# * \return New GEOM_Object, containing the created cylinder.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeCylinderRH(theR, theH):
- anObj = PrimOp.MakeCylinderRH(theR, theH)
- if PrimOp.IsDone() == 0:
- print "MakeCylinderRH : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a sphere with given center and radius.
-# * \param thePnt Sphere center.
-# * \param theR Sphere radius.
-# * \return New GEOM_Object, containing the created sphere.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeSpherePntR(thePnt, theR):
- anObj = PrimOp.MakeSpherePntR(thePnt, theR)
- if PrimOp.IsDone() == 0:
- print "MakeSpherePntR : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a sphere with given center and radius.
-# * \param x,y,z Coordinates of sphere center.
-# * \param theR Sphere radius.
-# * \return New GEOM_Object, containing the created sphere.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeSphere(x, y, z, theR):
- point = MakeVertex(x, y, z)
- anObj = MakeSpherePntR(point, theR)
- return anObj
-
-# * Create a sphere with given radius at the origin of coordinate system.
-# * \param theR Sphere radius.
-# * \return New GEOM_Object, containing the created sphere.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeSphereR(theR):
- anObj = PrimOp.MakeSphereR(theR)
- if PrimOp.IsDone() == 0:
- print "MakeSphereR : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a cone with given base point, axis, height and radiuses.
-# * \param thePnt Central point of the first cone base.
-# * \param theAxis Cone axis.
-# * \param theR1 Radius of the first cone base.
-# * \param theR2 Radius of the second cone base.
-# * \note If both radiuses are non-zero, the cone will be truncated.
-# * \note If the radiuses are equal, a cylinder will be created instead.
-# * \param theH Cone height.
-# * \return New GEOM_Object, containing the created cone.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeCone(thePnt, theAxis, theR1, theR2, theH):
- anObj = PrimOp.MakeConePntVecR1R2H(thePnt, theAxis, theR1, theR2, theH)
- if PrimOp.IsDone() == 0:
- print "MakeConePntVecR1R2H : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a cone with given height and radiuses at
-# * the origin of coordinate system. Axis of the cone will
-# * be collinear to the OZ axis of the coordinate system.
-# * \param theR1 Radius of the first cone base.
-# * \param theR2 Radius of the second cone base.
-# * \note If both radiuses are non-zero, the cone will be truncated.
-# * \note If the radiuses are equal, a cylinder will be created instead.
-# * \param theH Cone height.
-# * \return New GEOM_Object, containing the created cone.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeConeR1R2H(theR1, theR2, theH):
- anObj = PrimOp.MakeConeR1R2H(theR1, theR2, theH)
- if PrimOp.IsDone() == 0:
- print "MakeConeR1R2H : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a torus with given center, normal vector and radiuses.
-# * \param thePnt Torus central point.
-# * \param theVec Torus axis of symmetry.
-# * \param theRMajor Torus major radius.
-# * \param theRMinor Torus minor radius.
-# * \return New GEOM_Object, containing the created torus.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeTorus(thePnt, theVec, theRMajor, theRMinor):
- anObj = PrimOp.MakeTorusPntVecRR(thePnt, theVec, theRMajor, theRMinor)
- if PrimOp.IsDone() == 0:
- print "MakeTorusPntVecRR : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a torus with given radiuses at the origin of coordinate system.
-# * \param theRMajor Torus major radius.
-# * \param theRMinor Torus minor radius.
-# * \return New GEOM_Object, containing the created torus.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeTorusRR(theRMajor, theRMinor):
- anObj = PrimOp.MakeTorusRR(theRMajor, theRMinor)
- if PrimOp.IsDone() == 0:
- print "MakeTorusRR : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a shape by extrusion of the base shape along a vector, defined by two points.
-# * \param theBase Base shape to be extruded.
-# * \param thePoint1 First end of extrusion vector.
-# * \param thePoint2 Second end of extrusion vector.
-# * \return New GEOM_Object, containing the created prism.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakePrism(theBase, thePoint1, thePoint2):
- anObj = PrimOp.MakePrismTwoPnt(theBase, thePoint1, thePoint2)
- if PrimOp.IsDone() == 0:
- print "MakePrismTwoPnt : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a shape by extrusion of the base shape along the vector,
-# * i.e. all the space, transfixed by the base shape during its translation
-# * along the vector on the given distance.
-# * \param theBase Base shape to be extruded.
-# * \param theVec Direction of extrusion.
-# * \param theH Prism dimension along theVec.
-# * \return New GEOM_Object, containing the created prism.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakePrismVecH(theBase, theVec, theH):
- anObj = PrimOp.MakePrismVecH(theBase, theVec, theH)
- if PrimOp.IsDone() == 0:
- print "MakePrismVecH : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a shape by extrusion of the base shape along
-# * the path shape. The path shape can be a wire or an edge.
-# * \param theBase Base shape to be extruded.
-# * \param thePath Path shape to extrude the base shape along it.
-# * \return New GEOM_Object, containing the created pipe.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakePipe(theBase, thePath):
- anObj = PrimOp.MakePipe(theBase, thePath)
- if PrimOp.IsDone() == 0:
- print "MakePipe : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Create a shape by revolution of the base shape around the axis
-# * on the given angle, i.e. all the space, transfixed by the base
-# * shape during its rotation around the axis on the given angle.
-# * \param theBase Base shape to be rotated.
-# * \param theAxis Rotation axis.
-# * \param theAngle Rotation angle in radians.
-# * \return New GEOM_Object, containing the created revolution.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeRevolution(theBase, theAxis, theAngle):
- anObj = PrimOp.MakeRevolutionAxisAngle(theBase, theAxis, theAngle)
- if PrimOp.IsDone() == 0:
- print "MakeRevolutionAxisAngle : ", PrimOp.GetErrorCode()
- return anObj
-
-# -----------------------------------------------------------------------------
-# Create base shapes
-# -----------------------------------------------------------------------------
-
-# * Create a linear edge with specified ends.
-# * \param thePnt1 Point for the first end of edge.
-# * \param thePnt2 Point for the second end of edge.
-# * \return New GEOM_Object, containing the created edge.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeEdge(thePnt1, thePnt2):
- anObj = ShapesOp.MakeEdge(thePnt1, thePnt2)
- if ShapesOp.IsDone() == 0:
- print "MakeEdge : ", ShapesOp.GetErrorCode()
- return anObj
-
-# * Create a wire from the set of edges and wires.
-# * \param theEdgesAndWires List of edges and/or wires.
-# * \return New GEOM_Object, containing the created wire.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeWire(theEdgesAndWires):
- anObj = ShapesOp.MakeWire(theEdgesAndWires)
- if ShapesOp.IsDone() == 0:
- print "MakeWire : ", ShapesOp.GetErrorCode()
- return anObj
-
-# * Create a face on the given wire.
-# * \param theWire Wire to build the face on.
-# * \param isPlanarWanted If TRUE, only planar face will be built.
-# * If impossible, NULL object will be returned.
-# * \return New GEOM_Object, containing the created face.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeFace(theWire, isPlanarWanted):
- anObj = ShapesOp.MakeFace(theWire, isPlanarWanted)
- if ShapesOp.IsDone() == 0:
- print "MakeFace : ", ShapesOp.GetErrorCode()
- return anObj
-
-# * Create a face on the given wires set.
-# * \param theWires List of wires to build the face on.
-# * \param isPlanarWanted If TRUE, only planar face will be built.
-# * If impossible, NULL object will be returned.
-# * \return New GEOM_Object, containing the created face.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeFaceWires(theWires, isPlanarWanted):
- anObj = ShapesOp.MakeFaceWires(theWires, isPlanarWanted)
- if ShapesOp.IsDone() == 0:
- print "MakeFaceWires : ", ShapesOp.GetErrorCode()
- return anObj
-
-# * Shortcut to MakeFaceWires()
-#
-# * Example: see GEOM_TestOthers.py
-#
-def MakeFaces(theWires, isPlanarWanted):
- anObj = MakeFaceWires(theWires, isPlanarWanted)
- return anObj
-
-# * Create a shell from the set of faces and shells.
-# * \param theFacesAndShells List of faces and/or shells.
-# * \return New GEOM_Object, containing the created shell.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeShell(theFacesAndShells):
- anObj = ShapesOp.MakeShell(theFacesAndShells)
- if ShapesOp.IsDone() == 0:
- print "MakeShell : ", ShapesOp.GetErrorCode()
- return anObj
-
-# * Create a solid, bounded by the given shells.
-# * \param theShells Sequence of bounding shells.
-# * \return New GEOM_Object, containing the created solid.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeSolid(theShells):
- anObj = ShapesOp.MakeSolidShells(theShells)
- if ShapesOp.IsDone() == 0:
- print "MakeSolid : ", ShapesOp.GetErrorCode()
- return anObj
-
-# * Create a compound of the given shapes.
-# * \param theShapes List of shapes to put in compound.
-# * \return New GEOM_Object, containing the created compound.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeCompound(theShapes):
- anObj = ShapesOp.MakeCompound(theShapes)
- if ShapesOp.IsDone() == 0:
- print "MakeCompound : ", ShapesOp.GetErrorCode()
- return anObj
-
-# * Reverses an orientation the given shape.
-# * \param theShape Shape to be reversed.
-# * \return The reversed copy of theShape.
-#
-# * Example: see GEOM_TestAll.py
-#
-def ChangeOrientation(theShape):
- anObj = ShapesOp.ChangeOrientation(theShape)
- if ShapesOp.IsDone() == 0:
- print "ChangeOrientation : ", ShapesOp.GetErrorCode()
- return anObj
-
-# * Shortcut to ChangeOrientation()
-#
-# * Example: see GEOM_TestOthers.py
-#
-def OrientationChange(theShape):
- anObj = ChangeOrientation(theShape)
- return anObj
-
-# -----------------------------------------------------------------------------
-# Access to sub-shapes by their unique IDs inside the main shape.
-# -----------------------------------------------------------------------------
-
-# * Obtain a composite sub-shape of <aShape>, composed from sub-shapes
-# * of <aShape>, selected by their unique IDs inside <aShape>
-#
-# * Example: see GEOM_TestAll.py
-#
-def GetSubShape(aShape, ListOfID):
- anObj = geom.AddSubShape(aShape,ListOfID)
- return anObj
-
-# * Obtain unique ID of sub-shape <aSubShape> inside <aShape>
-#
-# * Example: see GEOM_TestAll.py
-#
-def GetSubShapeID(aShape, aSubShape):
- anID = LocalOp.GetSubShapeIndex(aShape, aSubShape)
- if LocalOp.IsDone() == 0:
- print "GetSubShapeIndex : ", LocalOp.GetErrorCode()
- return anID
-
-# -----------------------------------------------------------------------------
-# Decompose objects
-# -----------------------------------------------------------------------------
-
-# * Explode a shape on subshapes of a given type.
-# * \param theShape Shape to be exploded.
-# * \param theShapeType Type of sub-shapes to be retrieved.
-# * \return List of sub-shapes of type theShapeType, contained in theShape.
-#
-# * Example: see GEOM_TestAll.py
-#
-def SubShapeAll(aShape, aType):
- ListObj = ShapesOp.MakeExplode(aShape,aType,0)
- if ShapesOp.IsDone() == 0:
- print "MakeExplode : ", ShapesOp.GetErrorCode()
- return ListObj
-
-# * Explode a shape on subshapes of a given type.
-# * Sub-shapes will be sorted by coordinates of their gravity centers.
-# * \param theShape Shape to be exploded.
-# * \param theShapeType Type of sub-shapes to be retrieved.
-# * \return List of sub-shapes of type theShapeType, contained in theShape.
-#
-# * Example: see GEOM_TestAll.py
-#
-def SubShapeAllSorted(aShape, aType):
- ListObj = ShapesOp.MakeExplode(aShape,aType,1)
- if ShapesOp.IsDone() == 0:
- print "MakeExplode : ", ShapesOp.GetErrorCode()
- return ListObj
-
-# * Obtain a compound of sub-shapes of <aShape>,
-# * selected by they indices in list of all sub-shapes of type <aType>.
-# * Each index is in range [1, Nb_Sub-Shapes_Of_Given_Type]
-#
-# * Example: see GEOM_TestAll.py
-#
-def SubShape(aShape, aType, ListOfInd):
- ListOfIDs = []
- AllShapeList = SubShapeAll(aShape, aType)
- for ind in ListOfInd:
- ListOfIDs.append(GetSubShapeID(aShape, AllShapeList[ind - 1]))
- anObj = GetSubShape(aShape, ListOfIDs)
- return anObj
-
-# * Obtain a compound of sub-shapes of <aShape>,
-# * selected by they indices in sorted list of all sub-shapes of type <aType>.
-# * Each index is in range [1, Nb_Sub-Shapes_Of_Given_Type]
-#
-# * Example: see GEOM_TestAll.py
-#
-def SubShapeSorted(aShape, aType, ListOfInd):
- ListOfIDs = []
- AllShapeList = SubShapeAllSorted(aShape, aType)
- for ind in ListOfInd:
- ListOfIDs.append(GetSubShapeID(aShape, AllShapeList[ind - 1]))
- anObj = GetSubShape(aShape, ListOfIDs)
- return anObj
-
-# -----------------------------------------------------------------------------
-# Healing operations
-# -----------------------------------------------------------------------------
-
-# * Apply a sequence of Shape Healing operators to the given object.
-# * \param theShape Shape to be processed.
-# * \param theOperators List of names of operators ("FixShape", "SplitClosedFaces", etc.).
-# * \param theParameters List of names of parameters
-# * ("FixShape.Tolerance3d", "SplitClosedFaces.NbSplitPoints", etc.).
-# * \param theValues List of values of parameters, in the same order
-# * as parameters are listed in \a theParameters list.
-# * \return New GEOM_Object, containing processed shape.
-#
-# * Example: see GEOM_TestHealing.py
-#
-def ProcessShape(theShape, theOperators, theParameters, theValues):
- anObj = HealOp.ProcessShape(theShape, theOperators, theParameters, theValues)
- if HealOp.IsDone() == 0:
- print "ProcessShape : ", HealOp.GetErrorCode()
- return anObj
-
-# * Remove faces from the given object (shape).
-# * \param theObject Shape to be processed.
-# * \param theFaces Indices of faces to be removed, if EMPTY then the method
-# * removes ALL faces of the given object.
-# * \return New GEOM_Object, containing processed shape.
-#
-# * Example: see GEOM_TestHealing.py
-#
-def SuppressFaces(theObject, theFaces):
- anObj = HealOp.SuppressFaces(theObject, theFaces)
- if HealOp.IsDone() == 0:
- print "SuppressFaces : ", HealOp.GetErrorCode()
- return anObj
-
-# * Sewing of some shapes into single shape.
-#
-# * Example: see GEOM_TestHealing.py
-#
-def MakeSewing(ListShape, theTolerance):
- comp = MakeCompound(ListShape)
- anObj = Sew(comp, theTolerance)
- return anObj
-
-# * Sewing of the given object.
-# * \param theObject Shape to be processed.
-# * \param theTolerance Required tolerance value.
-# * \return New GEOM_Object, containing processed shape.
-#
-# * Example: see MakeSewing() above
-#
-def Sew(theObject, theTolerance):
- anObj = HealOp.Sew(theObject, theTolerance)
- if HealOp.IsDone() == 0:
- print "Sew : ", HealOp.GetErrorCode()
- return anObj
-
-# * Remove internal wires and edges from the given object (face).
-# * \param theObject Shape to be processed.
-# * \param theWires Indices of wires to be removed, if EMPTY then the method
-# * removes ALL internal wires of the given object.
-# * \return New GEOM_Object, containing processed shape.
-#
-# * Example: see GEOM_TestHealing.py
-#
-def SuppressInternalWires(theObject, theWires):
- anObj = HealOp.RemoveIntWires(theObject, theWires)
- if HealOp.IsDone() == 0:
- print "SuppressInternalWires : ", HealOp.GetErrorCode()
- return anObj
-
-# * Remove internal closed contours (holes) from the given object.
-# * \param theObject Shape to be processed.
-# * \param theWires Indices of wires to be removed, if EMPTY then the method
-# * removes ALL internal holes of the given object
-# * \return New GEOM_Object, containing processed shape.
-#
-# * Example: see GEOM_TestHealing.py
-#
-def SuppressHoles(theObject, theWires):
- anObj = HealOp.FillHoles(theObject, theWires)
- if HealOp.IsDone() == 0:
- print "SuppressHoles : ", HealOp.GetErrorCode()
- return anObj
-
-# * Close an open wire.
-# * \param theObject Shape to be processed.
-# * \param theWires Indexes of edge(s) and wire(s) to be closed within <VAR>theObject</VAR>'s shape,
-# * if -1, then theObject itself is a wire.
-# * \param isCommonVertex If TRUE : closure by creation of a common vertex,
-# * If FALS : closure by creation of an edge between ends.
-# * \return New GEOM_Object, containing processed shape.
-#
-# * Example: see GEOM_TestHealing.py
-#
-def CloseContour(theObject, theWires, isCommonVertex):
- anObj = HealOp.CloseContour(theObject, theWires, isCommonVertex)
- if HealOp.IsDone() == 0:
- print "CloseContour : ", HealOp.GetErrorCode()
- return anObj
-
-# * Addition of a point to a given edge object.
-# * \param theObject Shape to be processed.
-# * \param theEdgeIndex Index of edge to be divided within theObject's shape,
-# * if -1, then theObject itself is the edge.
-# * \param theValue Value of parameter on edge or length parameter,
-# * depending on \a isByParameter.
-# * \param isByParameter If TRUE : \a theValue is treated as a curve parameter [0..1],
-# * if FALSE : \a theValue is treated as a length parameter [0..1]
-# * \return New GEOM_Object, containing processed shape.
-#
-# * Example: see GEOM_TestHealing.py
-#
-def DivideEdge(theObject, theEdgeIndex, theValue, isByParameter):
- anObj = HealOp.DivideEdge(theObject, theEdgeIndex, theValue, isByParameter)
- if HealOp.IsDone() == 0:
- print "DivideEdge : ", HealOp.GetErrorCode()
- return anObj
-
-# * Get a list of wires (wrapped in GEOM_Object-s),
-# * that constitute a free boundary of the given shape.
-# * \param theObject Shape to get free boundary of.
-# * \return [status, theClosedWires, theOpenWires]
-# * status: FALSE, if an error(s) occured during the method execution.
-# * theClosedWires: Closed wires on the free boundary of the given shape.
-# * theOpenWires: Open wires on the free boundary of the given shape.
-#
-# * Example: see GEOM_TestHealing.py
-#
-def GetFreeBoundary(theObject):
- anObj = HealOp.GetFreeBoundary(theObject)
- if HealOp.IsDone() == 0:
- print "GetFreeBoundaries : ", HealOp.GetErrorCode()
- return anObj
-
-# -----------------------------------------------------------------------------
-# Create advanced objects
-# -----------------------------------------------------------------------------
-
-# * Create a copy of the given object
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeCopy(theOriginal):
- anObj = InsertOp.MakeCopy(theOriginal)
- if InsertOp.IsDone() == 0:
- print "MakeCopy : ", InsertOp.GetErrorCode()
- return anObj
-
-# * Create a filling from the given compound of contours.
-# * \param theShape the compound of contours
-# * \param theMinDeg a minimal degree
-# * \param theMaxDeg a maximal degree
-# * \param theTol2D a 2d tolerance
-# * \param theTol3D a 3d tolerance
-# * \param theNbIter a number of iteration
-# * \return New GEOM_Object, containing the created filling surface.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeFilling(theShape, theMinDeg, theMaxDeg, theTol2D, theTol3D, theNbIter):
- anObj = PrimOp.MakeFilling(theShape, theMinDeg, theMaxDeg, theTol2D, theTol3D, theNbIter)
- if PrimOp.IsDone() == 0:
- print "MakeFilling : ", PrimOp.GetErrorCode()
- return anObj
-
-# * Replace coincident faces in theShape by one face.
-# * \param theShape Initial shape.
-# * \param theTolerance Maximum distance between faces, which can be considered as coincident.
-# * \return New GEOM_Object, containing a copy of theShape without coincident faces.
-#
-# * Example: see GEOM_Spanner.py
-#
-def MakeGlueFaces(theShape, theTolerance):
- anObj = ShapesOp.MakeGlueFaces(theShape, theTolerance)
- if ShapesOp.IsDone() == 0:
- print "MakeGlueFaces : ", ShapesOp.GetErrorCode()
- return anObj
-
-# -----------------------------------------------------------------------------
-# Boolean (Common, Cut, Fuse, Section)
-# -----------------------------------------------------------------------------
-
-# * Perform one of boolean operations on two given shapes.
-# * \param theShape1 First argument for boolean operation.
-# * \param theShape2 Second argument for boolean operation.
-# * \param theOperation Indicates the operation to be done:
-# * 1 - Common, 2 - Cut, 3 - Fuse, 4 - Section.
-# * \return New GEOM_Object, containing the result shape.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeBoolean(theShape1, theShape2, theOperation):
- anObj = BoolOp.MakeBoolean(theShape1, theShape2, theOperation)
- if BoolOp.IsDone() == 0:
- print "MakeBoolean : ", BoolOp.GetErrorCode()
- return anObj
-
-# * Shortcuts to MakeBoolean() for certain operations
-#
-# * Example: see GEOM_TestOthers.py
-#
-def MakeCommon(s1, s2):
- return MakeBoolean(s1, s2, 1)
-#
-def MakeCut(s1, s2):
- return MakeBoolean(s1, s2, 2)
-#
-def MakeFuse(s1, s2):
- return MakeBoolean(s1, s2, 3)
-#
-def MakeSection(s1, s2):
- return MakeBoolean(s1, s2, 4)
-
-# * Perform partition operation.
-# * \param ListShapes Shapes to be intersected.
-# * \param ListTools Shapes to intersect theShapes.
-# * \param ListKeepInside Shapes, outside which the results will be deleted.
-# * Each shape from theKeepInside must belong to theShapes also.
-# * \param ListRemoveInside Shapes, inside which the results will be deleted.
-# * Each shape from theRemoveInside must belong to theShapes also.
-# * \param Limit Type of resulting shapes (corresponding to TopAbs_ShapeEnum).
-# * \param RemoveWebs If TRUE, perform Glue 3D algorithm.
-# * \param ListMaterials Material indices for each shape. Make sence, only if theRemoveWebs is TRUE.
-# * \return New GEOM_Object, containing the result shapes.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakePartition(ListShapes, ListTools=[], ListKeepInside=[], ListRemoveInside=[],
- Limit=ShapeType["SHAPE"], RemoveWebs=0, ListMaterials=[]):
- anObj = BoolOp.MakePartition(ListShapes, ListTools,
- ListKeepInside, ListRemoveInside,
- Limit, RemoveWebs, ListMaterials);
- if BoolOp.IsDone() == 0:
- print "MakePartition : ", BoolOp.GetErrorCode()
- return anObj
-
-# * Shortcut to MakePartition()
-#
-# * Example: see GEOM_TestOthers.py
-#
-def Partition(ListShapes, ListTools=[], ListKeepInside=[], ListRemoveInside=[],
- Limit=ShapeType["SHAPE"], RemoveWebs=0, ListMaterials=[]):
- anObj = MakePartition(ListShapes, ListTools,
- ListKeepInside, ListRemoveInside,
- Limit, RemoveWebs, ListMaterials);
- return anObj
-
-# -----------------------------------------------------------------------------
-# Transform objects
-# -----------------------------------------------------------------------------
-
-# * Translate the given object along the vector, specified
-# * by its end points, creating its copy before the translation.
-# * \param theObject The object to be translated.
-# * \param thePoint1 Start point of translation vector.
-# * \param thePoint2 End point of translation vector.
-# * \return New GEOM_Object, containing the translated object.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeTranslationTwoPoints(theObject, thePoint1, thePoint2):
- anObj = TrsfOp.TranslateTwoPointsCopy(theObject, thePoint1, thePoint2)
- if TrsfOp.IsDone() == 0:
- print "TranslateTwoPointsCopy : ", TrsfOp.GetErrorCode()
- return anObj
-
-# * Translate the given object along the vector, specified
-# * by its components, creating its copy before the translation.
-# * \param theObject The object to be translated.
-# * \param theDX,theDY,theDZ Components of translation vector.
-# * \return New GEOM_Object, containing the translated object.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeTranslation(theObject, theDX, theDY, theDZ):
- anObj = TrsfOp.TranslateDXDYDZCopy(theObject, theDX, theDY, theDZ)
- if TrsfOp.IsDone() == 0:
- print "TranslateDXDYDZCopy : ", TrsfOp.GetErrorCode()
- return anObj
-
-# * Rotate the given object around the given axis
-# * on the given angle, creating its copy before the rotatation.
-# * \param theObject The object to be rotated.
-# * \param theAxis Rotation axis.
-# * \param theAngle Rotation angle in radians.
-# * \return New GEOM_Object, containing the rotated object.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeRotation(theObject, theAxis, theAngle):
- anObj = TrsfOp.RotateCopy(theObject, theAxis, theAngle)
- if TrsfOp.IsDone() == 0:
- print "RotateCopy : ", TrsfOp.GetErrorCode()
- return anObj
-
-# * Scale the given object by the factor, creating its copy before the scaling.
-# * \param theObject The object to be scaled.
-# * \param thePoint Center point for scaling.
-# * \param theFactor Scaling factor value.
-# * \return New GEOM_Object, containing the scaled shape.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeScaleTransform(theObject, thePoint, theFactor):
- anObj = TrsfOp.ScaleShapeCopy(theObject, thePoint, theFactor)
- if TrsfOp.IsDone() == 0:
- print "ScaleShapeCopy : ", TrsfOp.GetErrorCode()
- return anObj
-
-# * Create an object, symmetrical
-# * to the given one relatively the given plane.
-# * \param theObject The object to be mirrored.
-# * \param thePlane Plane of symmetry.
-# * \return New GEOM_Object, containing the mirrored shape.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeMirrorByPlane(theObject, thePlane):
- anObj = TrsfOp.MirrorPlaneCopy(theObject, thePlane)
- if TrsfOp.IsDone() == 0:
- print "MirrorPlaneCopy : ", TrsfOp.GetErrorCode()
- return anObj
-
-# * Modify the Location of the given object by LCS
-# * creating its copy before the setting
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakePosition(theObject, theStartLCS, theEndLCS):
- anObj = TrsfOp.PositionShapeCopy(theObject, theStartLCS, theEndLCS)
- if TrsfOp.IsDone() == 0:
- print "PositionShapeCopy : ", TrsfOp.GetErrorCode()
- return anObj
-
-# * Create new object as offset of the given one.
-# * \param theObject The base object for the offset.
-# * \param theOffset Offset value.
-# * \return New GEOM_Object, containing the offset object.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeOffset(theObject, theOffset):
- anObj = TrsfOp.OffsetShapeCopy(theObject, theOffset)
- if TrsfOp.IsDone() == 0:
- print "OffsetShapeCopy : ", TrsfOp.GetErrorCode()
- return anObj
-
-# -----------------------------------------------------------------------------
-# Patterns
-# -----------------------------------------------------------------------------
-
-# * Translate the given object along the given vector a given number times
-# * \param theObject The object to be translated.
-# * \param theVector Direction of the translation.
-# * \param theStep Distance to translate on.
-# * \param theNbTimes Quantity of translations to be done.
-# * \return New GEOM_Object, containing compound of all
-# * the shapes, obtained after each translation.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeMultiTranslation1D(theObject, theVector, theStep, theNbTimes):
- anObj = TrsfOp.MultiTranslate1D(theObject, theVector, theStep, theNbTimes)
- if TrsfOp.IsDone() == 0:
- print "MultiTranslate1D : ", TrsfOp.GetErrorCode()
- return anObj
-
-# * Conseqently apply two specified translations to theObject specified number of times.
-# * \param theObject The object to be translated.
-# * \param theVector1 Direction of the first translation.
-# * \param theStep1 Step of the first translation.
-# * \param theNbTimes1 Quantity of translations to be done along theVector1.
-# * \param theVector2 Direction of the second translation.
-# * \param theStep2 Step of the second translation.
-# * \param theNbTimes2 Quantity of translations to be done along theVector2.
-# * \return New GEOM_Object, containing compound of all
-# * the shapes, obtained after each translation.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeMultiTranslation2D(theObject, theVector1, theStep1, theNbTimes1,
- theVector2, theStep2, theNbTimes2):
- anObj = TrsfOp.MultiTranslate2D(theObject, theVector1, theStep1, theNbTimes1,
- theVector2, theStep2, theNbTimes2)
- if TrsfOp.IsDone() == 0:
- print "MultiTranslate2D : ", TrsfOp.GetErrorCode()
- return anObj
-
-# * Rotate the given object around the given axis a given number times.
-# * Rotation angle will be 2*PI/theNbTimes.
-# * \param theObject The object to be rotated.
-# * \param theAxis The rotation axis.
-# * \param theNbTimes Quantity of rotations to be done.
-# * \return New GEOM_Object, containing compound of all the
-# * shapes, obtained after each rotation.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MultiRotate1D(theObject, theAxis, theNbTimes):
- anObj = TrsfOp.MultiRotate1D(theObject, theAxis, theNbTimes)
- if TrsfOp.IsDone() == 0:
- print "MultiRotate1D : ", TrsfOp.GetErrorCode()
- return anObj
-
-# * Rotate the given object around the
-# * given axis on the given angle a given number
-# * times and multi-translate each rotation result.
-# * Translation direction passes through center of gravity
-# * of rotated shape and its projection on the rotation axis.
-# * \param theObject The object to be rotated.
-# * \param theAxis Rotation axis.
-# * \param theAngle Rotation angle in graduces.
-# * \param theNbTimes1 Quantity of rotations to be done.
-# * \param theStep Translation distance.
-# * \param theNbTimes2 Quantity of translations to be done.
-# * \return New GEOM_Object, containing compound of all the
-# * shapes, obtained after each transformation.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MultiRotate2D(theObject, theAxis, theAngle, theNbTimes1, theStep, theNbTimes2):
- anObj = TrsfOp.MultiRotate2D(theObject, theAxis, theAngle, theNbTimes1, theStep, theNbTimes2)
- if TrsfOp.IsDone() == 0:
- print "MultiRotate2D : ", TrsfOp.GetErrorCode()
- return anObj
-
-# * The same, as MultiRotate1D(), but axis is given by direction and point
-#
-# * Example: see GEOM_TestOthers.py
-#
-def MakeMultiRotation1D(aShape,aDir,aPoint,aNbTimes):
- aVec = MakeLine(aPoint,aDir)
- anObj = MultiRotate1D(aShape,aVec,aNbTimes)
- return anObj
-
-# * The same, as MultiRotate2D(), but axis is given by direction and point
-#
-# * Example: see GEOM_TestOthers.py
-#
-def MakeMultiRotation2D(aShape,aDir,aPoint,anAngle,nbtimes1,aStep,nbtimes2):
- aVec = MakeLine(aPoint,aDir)
- anObj = MultiRotate2D(aShape,aVec,anAngle,nbtimes1,aStep,nbtimes2)
- return anObj
-
-# -----------------------------------------------------------------------------
-# Local operations
-# -----------------------------------------------------------------------------
-
-# * Perform a fillet on all edges of the given shape.
-# * \param theShape Shape, to perform fillet on.
-# * \param theR Fillet radius.
-# * \return New GEOM_Object, containing the result shape.
-#
-# * Example: see GEOM_TestOthers.py
-#
-def MakeFilletAll(theShape, theR):
- anObj = LocalOp.MakeFilletAll(theShape, theR)
- if LocalOp.IsDone() == 0:
- print "MakeFilletAll : ", LocalOp.GetErrorCode()
- return anObj
-
-# * Perform a fillet on the specified edges/faces of the given shape
-# * \param theShape Shape, to perform fillet on.
-# * \param theR Fillet radius.
-# * \param theShapeType Type of shapes in <theListShapes>.
-# * \param theListShapes Global indices of edges/faces to perform fillet on.
-# * \note Global index of sub-shape can be obtained, using method geompy.GetSubShapeID().
-# * \return New GEOM_Object, containing the result shape.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeFillet(theShape, theR, theShapeType, theListShapes):
- anObj = None
- if theShapeType == ShapeType["EDGE"]:
- anObj = LocalOp.MakeFilletEdges(theShape, theR, theListShapes)
- else:
- anObj = LocalOp.MakeFilletFaces(theShape, theR, theListShapes)
- if LocalOp.IsDone() == 0:
- print "MakeFillet : ", LocalOp.GetErrorCode()
- return anObj
-
-# * Perform a symmetric chamfer on all edges of the given shape.
-# * \param theShape Shape, to perform chamfer on.
-# * \param theD Chamfer size along each face.
-# * \return New GEOM_Object, containing the result shape.
-#
-# * Example: see GEOM_TestOthers.py
-#
-def MakeChamferAll(theShape, theD):
- anObj = LocalOp.MakeChamferAll(theShape, theD)
- if LocalOp.IsDone() == 0:
- print "MakeChamferAll : ", LocalOp.GetErrorCode()
- return anObj
-
-# * Perform a chamfer on edges, common to the specified faces,
-# * with distance D1 on the Face1
-# * \param theShape Shape, to perform chamfer on.
-# * \param theD1 Chamfer size along \a theFace1.
-# * \param theD2 Chamfer size along \a theFace2.
-# * \param theFace1,theFace2 Global indices of two faces of \a theShape.
-# * \note Global index of sub-shape can be obtained, using method geompy.GetSubShapeID().
-# * \return New GEOM_Object, containing the result shape.
#
-# * Example: see GEOM_TestAll.py
-#
-def MakeChamferEdge(theShape, theD1, theD2, theFace1, theFace2):
- anObj = LocalOp.MakeChamferEdge(theShape, theD1, theD2, theFace1, theFace2)
- if LocalOp.IsDone() == 0:
- print "MakeChamferEdge : ", LocalOp.GetErrorCode()
- return anObj
-
-# * Perform a chamfer on all edges of the specified faces,
-# * with distance D1 on the first specified face (if several for one edge)
-# * \param theShape Shape, to perform chamfer on.
-# * \param theD1 Chamfer size along face from \a theFaces. If both faces,
-# * connected to the edge, are in \a theFaces, \a theD1
-# * will be get along face, which is nearer to \a theFaces beginning.
-# * \param theD2 Chamfer size along another of two faces, connected to the edge.
-# * \param theFaces Sequence of global indices of faces of \a theShape.
-# * \note Global index of sub-shape can be obtained, using method geompy.GetSubShapeIndex().
-# * \return New GEOM_Object, containing the result shape.
-#
-# * Example: see GEOM_TestAll.py
-#
-def MakeChamferFaces(theShape, theD1, theD2, theFaces):
- anObj = LocalOp.MakeChamferFaces(theShape, theD1, theD2, theFaces)
- if LocalOp.IsDone() == 0:
- print "MakeChamferFaces : ", LocalOp.GetErrorCode()
- return anObj
-
-# * Shortcut to MakeChamferEdge() and MakeChamferFaces()
-#
-# * Example: see GEOM_TestOthers.py
-#
-def MakeChamfer(aShape,d1,d2,aShapeType,ListShape):
- anObj = None
- if aShapeType == ShapeType["EDGE"]:
- anObj = MakeChamferEdge(aShape,d1,d2,ListShape[0],ListShape[1])
- else:
- anObj = MakeChamferFaces(aShape,d1,d2,ListShape)
- return anObj
-
-# * Perform an Archimde operation on the given shape with given parameters.
-# * The object presenting the resulting face is returned
-# * \param theShape Shape to be put in water.
-# * \param theWeight Weight og the shape.
-# * \param theWaterDensity Density of the water.
-# * \param theMeshDeflection Deflection of the mesh, using to compute the section.
-# * \return New GEOM_Object, containing a section of \a theShape
-# * by a plane, corresponding to water level.
-#
-# * Example: see GEOM_TestAll.py
-#
-def Archimede(theShape, theWeight, theWaterDensity, theMeshDeflection):
- anObj = LocalOp.MakeArchimede(theShape, theWeight, theWaterDensity, theMeshDeflection)
- if LocalOp.IsDone() == 0:
- print "MakeArchimede : ", LocalOp.GetErrorCode()
- return anObj
-
-# -----------------------------------------------------------------------------
-# Information objects
-# -----------------------------------------------------------------------------
-
-# * Get point coordinates
-# * \return [x, y, z]
-#
-# * Example: see GEOM_TestMeasures.py
-#
-def PointCoordinates(Point):
- aTuple = MeasuOp.PointCoordinates(Point)
- if MeasuOp.IsDone() == 0:
- print "PointCoordinates : ", MeasuOp.GetErrorCode()
- return aTuple
-
-# * Get summarized length of all wires,
-# * area of surface and volume of the given shape.
-# * \param theShape Shape to define properties of.
-# * \return [theLength, theSurfArea, theVolume]
-# * theLength: Summarized length of all wires of the given shape.
-# * theSurfArea: Area of surface of the given shape.
-# * theVolume: Volume of the given shape.
-#
-# * Example: see GEOM_TestMeasures.py
-#
-def BasicProperties(theShape):
- aTuple = MeasuOp.GetBasicProperties(theShape)
- if MeasuOp.IsDone() == 0:
- print "BasicProperties : ", MeasuOp.GetErrorCode()
- return aTuple
-
-# * Get parameters of bounding box of the given shape
-# * \param theShape Shape to obtain bounding box of.
-# * \return [Xmin,Xmax, Ymin,Ymax, Zmin,Zmax]
-# * Xmin,Xmax: Limits of shape along OX axis.
-# * Ymin,Ymax: Limits of shape along OY axis.
-# * Zmin,Zmax: Limits of shape along OZ axis.
-#
-# * Example: see GEOM_TestMeasures.py
-#
-def BoundingBox(theShape):
- aTuple = MeasuOp.GetBoundingBox(theShape)
- if MeasuOp.IsDone() == 0:
- print "BoundingBox : ", MeasuOp.GetErrorCode()
- return aTuple
-
-# * Get inertia matrix and moments of inertia of theShape.
-# * \param theShape Shape to calculate inertia of.
-# * \return [I11,I12,I13, I21,I22,I23, I31,I32,I33, Ix,Iy,Iz]
-# * I(1-3)(1-3): Components of the inertia matrix of the given shape.
-# * Ix,Iy,Iz: Moments of inertia of the given shape.
-#
-# * Example: see GEOM_TestMeasures.py
-#
-def Inertia(theShape):
- aTuple = MeasuOp.GetInertia(theShape)
- if MeasuOp.IsDone() == 0:
- print "Inertia : ", MeasuOp.GetErrorCode()
- return aTuple
-
-# * Get minimal distance between the given shapes.
-# * \param theShape1,theShape2 Shapes to find minimal distance between.
-# * \return Value of the minimal distance between the given shapes.
-#
-# * Example: see GEOM_TestMeasures.py
-#
-def MinDistance(theShape1, theShape2):
- aTuple = MeasuOp.GetMinDistance(theShape1, theShape2)
- if MeasuOp.IsDone() == 0:
- print "MinDistance : ", MeasuOp.GetErrorCode()
- return aTuple[0]
-
-# * Get min and max tolerances of sub-shapes of theShape
-# * \param theShape Shape, to get tolerances of.
-# * \return [FaceMin,FaceMax, EdgeMin,EdgeMax, VertMin,VertMax]
-# * FaceMin,FaceMax: Min and max tolerances of the faces.
-# * EdgeMin,EdgeMax: Min and max tolerances of the edges.
-# * VertMin,VertMax: Min and max tolerances of the vertices.
-#
-# * Example: see GEOM_TestMeasures.py
-#
-def Tolerance(theShape):
- aTuple = MeasuOp.GetTolerance(theShape)
- if MeasuOp.IsDone() == 0:
- print "Tolerance : ", MeasuOp.GetErrorCode()
- return aTuple
-
-# * Obtain description of the given shape (number of sub-shapes of each type)
-# * \param theShape Shape to be described.
-# * \return Description of the given shape.
-#
-# * Example: see GEOM_TestMeasures.py
-#
-def WhatIs(theShape):
- aDescr = MeasuOp.WhatIs(theShape)
- if MeasuOp.IsDone() == 0:
- print "WhatIs : ", MeasuOp.GetErrorCode()
- return aDescr
-
-# * Get a point, situated at the centre of mass of theShape.
-# * \param theShape Shape to define centre of mass of.
-# * \return New GEOM_Object, containing the created point.
-#
-# * Example: see GEOM_TestMeasures.py
-#
-def MakeCDG(theShape):
- anObj = MeasuOp.GetCentreOfMass(theShape)
- if MeasuOp.IsDone() == 0:
- print "GetCentreOfMass : ", MeasuOp.GetErrorCode()
- return anObj
-
-# * Check a topology of the given shape.
-# * \param theShape Shape to check validity of.
-# * \return TRUE, if the shape "seems to be valid" from the topological point of view.
-# * If theShape is invalid, prints a description of problem.
-#
-# * Example: see GEOM_TestMeasures.py
-#
-def CheckShape(theShape):
- (IsValid, Status) = MeasuOp.CheckShape(theShape)
- if MeasuOp.IsDone() == 0:
- print "CheckShape : ", MeasuOp.GetErrorCode()
- else:
- if IsValid == 0:
- print Status
- return IsValid
-
-# -----------------------------------------------------------------------------
-# Import/Export objects
-# -----------------------------------------------------------------------------
-
-# * Import a shape from the BREP or IGES or STEP file
-# * (depends on given format) with given name.
-# * \param theFileName The file, containing the shape.
-# * \param theFormatName Specify format for the file reading.
-# * Available formats can be obtained with InsertOp.ImportTranslators() method.
-# * \return New GEOM_Object, containing the imported shape.
-#
-# * Example: see GEOM_TestOthers.py
-#
-def Import(theFileName, theFormatName):
- anObj = InsertOp.Import(theFileName, theFormatName)
- if InsertOp.IsDone() == 0:
- print "Import : ", InsertOp.GetErrorCode()
- return anObj
-
-# * Shortcuts to Import() for certain formats
-#
-# * Example: see GEOM_TestOthers.py
-#
-def ImportBREP(theFileName):
- return Import(theFileName, "BREP")
-#
-def ImportIGES(theFileName):
- return Import(theFileName, "IGES")
-#
-def ImportSTEP(theFileName):
- return Import(theFileName, "STEP")
-
-# * Export the given shape into a file with given name.
-# * \param theObject Shape to be stored in the file.
-# * \param theFileName Name of the file to store the given shape in.
-# * \param theFormatName Specify format for the shape storage.
-# * Available formats can be obtained with InsertOp.ImportTranslators() method.
-#
-# * Example: see GEOM_TestOthers.py
-#
-def Export(theObject, theFileName, theFormatName):
- InsertOp.Export(theObject, theFileName, theFormatName)
- if InsertOp.IsDone() == 0:
- print "Export : ", InsertOp.GetErrorCode()
-
-# * Shortcuts to Export() for certain formats
-#
-# * Example: see GEOM_TestOthers.py
-#
-def ExportBREP(theObject, theFileName):
- return Export(theObject, theFileName, "BREP")
-#
-def ExportIGES(theObject, theFileName):
- return Export(theObject, theFileName, "IGES")
-#
-def ExportSTEP(theObject, theFileName):
- return Export(theObject, theFileName, "STEP")
-
-# -----------------------------------------------------------------------------
-# Block operations
-# -----------------------------------------------------------------------------
-
-# * Create a quadrangle face from four edges. Order of Edges is not
-# * important. It is not necessary that edges share the same vertex.
-# * \param E1,E2,E3,E4 Edges for the face bound.
-# * \return New GEOM_Object, containing the created face.
-#
-# * Example: see GEOM_Spanner.py
-#
-def MakeQuad(E1, E2, E3, E4):
- anObj = BlocksOp.MakeQuad(E1, E2, E3, E4)
- if BlocksOp.IsDone() == 0:
- print "MakeQuad : ", BlocksOp.GetErrorCode()
- return anObj
-
-# * Create a quadrangle face on two edges.
-# * The missing edges will be built by creating the shortest ones.
-# * \param E1,E2 Two opposite edges for the face.
-# * \return New GEOM_Object, containing the created face.
-#
-# * Example: see GEOM_Spanner.py
-#
-def MakeQuad2Edges(E1, E2):
- anObj = BlocksOp.MakeQuad2Edges(E1, E2)
- if BlocksOp.IsDone() == 0:
- print "MakeQuad2Edges : ", BlocksOp.GetErrorCode()
- return anObj
-
-# * Create a quadrangle face with specified corners.
-# * The missing edges will be built by creating the shortest ones.
-# * \param V1,V2,V3,V4 Corner vertices for the face.
-# * \return New GEOM_Object, containing the created face.
-#
-# * Example: see GEOM_Spanner.py
-#
-def MakeQuad4Vertices(V1, V2, V3, V4):
- anObj = BlocksOp.MakeQuad4Vertices(V1, V2, V3, V4)
- if BlocksOp.IsDone() == 0:
- print "MakeQuad4Vertices : ", BlocksOp.GetErrorCode()
- return anObj
-
-# * Create a hexahedral solid, bounded by the six given faces. Order of
-# * faces is not important. It is not necessary that Faces share the same edge.
-# * \param F1,F2,F3,F4,F5,F6 Faces for the hexahedral solid.
-# * \return New GEOM_Object, containing the created solid.
-#
-# * Example: see GEOM_Spanner.py
-#
-def MakeHexa(F1, F2, F3, F4, F5, F6):
- anObj = BlocksOp.MakeHexa(F1, F2, F3, F4, F5, F6)
- if BlocksOp.IsDone() == 0:
- print "MakeHexa : ", BlocksOp.GetErrorCode()
- return anObj
-
-# * Create a hexahedral solid between two given faces.
-# * The missing faces will be built by creating the smallest ones.
-# * \param F1,F2 Two opposite faces for the hexahedral solid.
-# * \return New GEOM_Object, containing the created solid.
-#
-# * Example: see GEOM_Spanner.py
-#
-def MakeHexa2Faces(F1, F2):
- anObj = BlocksOp.MakeHexa2Faces(F1, F2)
- if BlocksOp.IsDone() == 0:
- print "MakeHexa2Faces : ", BlocksOp.GetErrorCode()
- return anObj
-
-# * Multi-transformate block and glue the result.
-# * Transformation is defined so, as to superpose direction faces.
-# * \param Block Hexahedral solid to be multi-transformed.
-# * \param DirFace1 ID of First direction face.
-# * \param DirFace2 ID of Second direction face.
-# * \param NbTimes Quantity of transformations to be done.
-# * \note Unique ID of sub-shape can be obtained, using method GetSubShapeID().
-# * \return New GEOM_Object, containing the result shape.
-#
-# * Example: see GEOM_Spanner.py
-#
-def MakeMultiTransformation1D(Block, DirFace1, DirFace2, NbTimes):
- anObj = BlocksOp.MakeMultiTransformation1D(Block, DirFace1, DirFace2, NbTimes)
- if BlocksOp.IsDone() == 0:
- print "MakeMultiTransformation1D : ", BlocksOp.GetErrorCode()
- return anObj
-
-# * Multi-transformate block and glue the result.
-# * \param Block Hexahedral solid to be multi-transformed.
-# * \param DirFace1U,DirFace2U IDs of Direction faces for the first transformation.
-# * \param DirFace1V,DirFace2V IDs of Direction faces for the second transformation.
-# * \param NbTimesU,NbTimesV Quantity of transformations to be done.
-# * \return New GEOM_Object, containing the result shape.
-#
-# * Example: see GEOM_Spanner.py
-#
-def MakeMultiTransformation2D(Block, DirFace1U, DirFace2U, NbTimesU,
- DirFace1V, DirFace2V, NbTimesV):
- anObj = BlocksOp.MakeMultiTransformation2D(Block, DirFace1U, DirFace2U, NbTimesU,
- DirFace1V, DirFace2V, NbTimesV)
- if BlocksOp.IsDone() == 0:
- print "MakeMultiTransformation2D : ", BlocksOp.GetErrorCode()
- return anObj
-
-# * Get all the blocks, contained in the given compound.
-# * \param theCompound The compound to explode.
-# * \param theMinNbFaces If solid has lower number of faces, it is not a block.
-# * \param theMaxNbFaces If solid has higher number of faces, it is not a block.
-# * \note If theMaxNbFaces = 0, the maximum number of faces is not restricted.
-# * \return List of GEOM_Objects, containing the retrieved blocks.
-#
-# * Example: see GEOM_TestOthers.py
-#
-def MakeBlockExplode(theCompound, theMinNbFaces, theMaxNbFaces):
- aList = BlocksOp.ExplodeCompoundOfBlocks(theCompound, theMinNbFaces, theMaxNbFaces)
- if BlocksOp.IsDone() == 0:
- print "MakeBlockExplode : ", BlocksOp.GetErrorCode()
- return aList
-
-# * Check, if the compound of blocks is given.
-# * To be considered as a compound of blocks, the
-# * given shape must satisfy the following conditions:
-# * - Each element of the compound should be a Block (6 faces and 12 edges).
-# * - A connection between two Blocks should be an entire quadrangle face or an entire edge.
-# * - The compound should be connexe.
-# * - The glue between two quadrangle faces should be applied.
-# * \param theCompound The compound to check.
-# * \return TRUE, if the given shape is a compound of blocks.
-# * If theCompound is not valid, prints all discovered errors.
-#
-# * Example: see GEOM_TestOthers.py
-#
-def CheckCompoundOfBlocks(theCompound):
- (IsValid, BCErrors) = BlocksOp.CheckCompoundOfBlocks(theCompound)
- if BlocksOp.IsDone() == 0:
- print "CheckCompoundOfBlocks : ", BlocksOp.GetErrorCode()
- else:
- if IsValid == 0:
- Descr = BlocksOp.PrintBCErrors(theCompound, BCErrors)
- print Descr
- return IsValid
-
-# -----------------------------------------------------------------------------
-# Group operations
-# -----------------------------------------------------------------------------
-
-# * Creates a new group which will store sub shapes of theMainShape
-# * \param theMainShape is a GEOM object on which the group is selected
-# * \param theShapeType defines a shape type of the group
-# * \return a newly created GEOM group
-#
-# * Example: see GEOM_TestOthers.py
-#
-def CreateGroup(theMainShape, theShapeType):
- anObj = GroupOp.CreateGroup(theMainShape, theShapeType)
- if GroupOp.IsDone() == 0:
- print "CreateGroup : ", GroupOp.GetErrorCode()
- return anObj
-
-# * Adds a sub object with ID theSubShapeId to the group
-# * \param theGroup is a GEOM group to which the new sub shape is added
-# * \param theSubShapeID is a sub shape ID in the main object.
-# * \note Use method GetSubShapeID() to get an unique ID of the sub shape
-#
-# * Example: see GEOM_TestOthers.py
-#
-def AddObject(theGroup, theSubShapeID):
- GroupOp.AddObject(theGroup, theSubShapeID)
- if GroupOp.IsDone() == 0:
- print "AddObject : ", GroupOp.GetErrorCode()
+import salome
+import geompyDC
+from salome import *
-# * Removes a sub object with ID \a theSubShapeId from the group
-# * \param theGroup is a GEOM group from which the new sub shape is removed
-# * \param theSubShapeID is a sub shape ID in the main object.
-# * \note Use method GetSubShapeID() to get an unique ID of the sub shape
-#
-# * Example: see GEOM_TestOthers.py
-#
-def RemoveObject(theGroup, theSubShapeID):
- GroupOp.RemoveObject(theGroup, theSubShapeID)
- if GroupOp.IsDone() == 0:
- print "RemoveObject : ", GroupOp.GetErrorCode()
+geom = lcc.FindOrLoadComponent("FactoryServer", "GEOM")
+geom.init_geom(salome.myStudy)
-# * Returns a list of sub objects ID stored in the group
-# * \param theGroup is a GEOM group for which a list of IDs is requested
-#
-# * Example: see GEOM_TestOthers.py
-#
-def GetObjectIDs(theGroup):
- ListIDs = GroupOp.GetObjects(theGroup)
- if GroupOp.IsDone() == 0:
- print "GetObjectIDs : ", GroupOp.GetErrorCode()
- return ListIDs
+# Export the methods of geompyDC
+for k in dir(geom):
+ if k[0] == '_':continue
+ globals()[k]=getattr(geom,k)
+del k
+from geompyDC import ShapeType, GEOM, kind, info, PackData, ReadTexture, EnumToLong
-# Add Path to the system path
-#
-def addPath(Path):
- if (sys.path.count(Path) < 1):
- sys.path.append(Path)