1 # Copyright (C) 2007-2008 CEA/DEN, EDF R&D, OPEN CASCADE
3 # Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
4 # CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS
6 # This library is free software; you can redistribute it and/or
7 # modify it under the terms of the GNU Lesser General Public
8 # License as published by the Free Software Foundation; either
9 # version 2.1 of the License.
11 # This library is distributed in the hope that it will be useful,
12 # but WITHOUT ANY WARRANTY; without even the implied warranty of
13 # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
14 # Lesser General Public License for more details.
16 # You should have received a copy of the GNU Lesser General Public
17 # License along with this library; if not, write to the Free Software
18 # Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
20 # See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
22 # GEOM GEOM_SWIG : binding of C++ omplementaion with Python
24 # Author : Paul RASCLE, EDF
32 ## @defgroup l1_geompy_auxiliary Auxiliary data structures and methods
34 ## @defgroup l1_geompy_purpose All package methods, grouped by their purpose
36 ## @defgroup l2_import_export Importing/exporting geometrical objects
37 ## @defgroup l2_creating Creating geometrical objects
39 ## @defgroup l3_basic_go Creating Basic Geometric Objects
41 ## @defgroup l4_curves Creating Curves
44 ## @defgroup l3_3d_primitives Creating 3D Primitives
45 ## @defgroup l3_complex Creating Complex Objects
46 ## @defgroup l3_groups Working with groups
47 ## @defgroup l3_blocks Building by blocks
49 ## @defgroup l4_blocks_measure Check and Improve
52 ## @defgroup l3_sketcher Sketcher
53 ## @defgroup l3_advanced Creating Advanced Geometrical Objects
55 ## @defgroup l4_decompose Decompose objects
56 ## @defgroup l4_access Access to sub-shapes by their unique IDs inside the main shape
57 ## @defgroup l4_obtain Access to subshapes by a criteria
62 ## @defgroup l2_transforming Transforming geometrical objects
64 ## @defgroup l3_basic_op Basic Operations
65 ## @defgroup l3_boolean Boolean Operations
66 ## @defgroup l3_transform Transformation Operations
67 ## @defgroup l3_local Local Operations (Fillet and Chamfer)
68 ## @defgroup l3_blocks_op Blocks Operations
69 ## @defgroup l3_healing Repairing Operations
70 ## @defgroup l3_restore_ss Restore presentation parameters and a tree of subshapes
73 ## @defgroup l2_measure Using measurement tools
81 from salome_notebook import *
86 ## Enumeration ShapeType as a dictionary
87 # @ingroup l1_geompy_auxiliary
88 ShapeType = {"COMPOUND":0, "COMPSOLID":1, "SOLID":2, "SHELL":3, "FACE":4, "WIRE":5, "EDGE":6, "VERTEX":7, "SHAPE":8}
90 ## Raise an Error, containing the Method_name, if Operation is Failed
91 ## @ingroup l1_geompy_auxiliary
92 def RaiseIfFailed (Method_name, Operation):
93 if Operation.IsDone() == 0 and Operation.GetErrorCode() != "NOT_FOUND_ANY":
94 raise RuntimeError, Method_name + " : " + Operation.GetErrorCode()
96 ## Return list of variables value from salome notebook
97 ## @ingroup l1_geompy_auxiliary
98 def ParseParameters(*parameters):
101 for parameter in parameters:
102 if isinstance(parameter,str):
103 if notebook.isVariable(parameter):
104 Result.append(notebook.get(parameter))
106 raise RuntimeError, "Variable with name '" + parameter + "' doesn't exist!!!"
108 Result.append(parameter)
111 StringResult = StringResult + str(parameter)
112 StringResult = StringResult + ":"
114 StringResult = StringResult[:len(StringResult)-1]
115 Result.append(StringResult)
118 ## Return list of variables value from salome notebook
119 ## @ingroup l1_geompy_auxiliary
123 for parameter in list:
124 if isinstance(parameter,str) and notebook.isVariable(parameter):
125 Result.append(str(notebook.get(parameter)))
128 Result.append(str(parameter))
131 StringResult = StringResult + str(parameter)
132 StringResult = StringResult + ":"
134 StringResult = StringResult[:len(StringResult)-1]
135 return Result, StringResult
137 ## Return list of variables value from salome notebook
138 ## @ingroup l1_geompy_auxiliary
139 def ParseSketcherCommand(command):
142 sections = command.split(":")
143 for section in sections:
144 parameters = section.split(" ")
146 for parameter in parameters:
147 if paramIndex > 1 and parameter.find("'") != -1:
148 parameter = parameter.replace("'","")
149 if notebook.isVariable(parameter):
150 Result = Result + str(notebook.get(parameter)) + " "
153 raise RuntimeError, "Variable with name '" + parameter + "' doesn't exist!!!"
157 Result = Result + str(parameter) + " "
160 StringResult = StringResult + parameter
161 StringResult = StringResult + ":"
163 paramIndex = paramIndex + 1
165 Result = Result[:len(Result)-1] + ":"
167 Result = Result[:len(Result)-1]
168 return Result, StringResult
170 ## Kinds of shape enumeration
171 # @ingroup l1_geompy_auxiliary
172 kind = GEOM.GEOM_IKindOfShape
174 ## Information about closed/unclosed state of shell or wire
175 # @ingroup l1_geompy_auxiliary
182 class geompyDC(GEOM._objref_GEOM_Gen):
185 GEOM._objref_GEOM_Gen.__init__(self)
186 self.myBuilder = None
204 ## @addtogroup l1_geompy_auxiliary
206 def init_geom(self,theStudy):
207 self.myStudy = theStudy
208 self.myStudyId = self.myStudy._get_StudyId()
209 self.myBuilder = self.myStudy.NewBuilder()
210 self.father = self.myStudy.FindComponent("GEOM")
211 if self.father is None:
212 self.father = self.myBuilder.NewComponent("GEOM")
213 A1 = self.myBuilder.FindOrCreateAttribute(self.father, "AttributeName")
214 FName = A1._narrow(SALOMEDS.AttributeName)
215 FName.SetValue("Geometry")
216 A2 = self.myBuilder.FindOrCreateAttribute(self.father, "AttributePixMap")
217 aPixmap = A2._narrow(SALOMEDS.AttributePixMap)
218 aPixmap.SetPixMap("ICON_OBJBROWSER_Geometry")
219 self.myBuilder.DefineComponentInstance(self.father,self)
221 self.BasicOp = self.GetIBasicOperations (self.myStudyId)
222 self.CurvesOp = self.GetICurvesOperations (self.myStudyId)
223 self.PrimOp = self.GetI3DPrimOperations (self.myStudyId)
224 self.ShapesOp = self.GetIShapesOperations (self.myStudyId)
225 self.HealOp = self.GetIHealingOperations (self.myStudyId)
226 self.InsertOp = self.GetIInsertOperations (self.myStudyId)
227 self.BoolOp = self.GetIBooleanOperations (self.myStudyId)
228 self.TrsfOp = self.GetITransformOperations(self.myStudyId)
229 self.LocalOp = self.GetILocalOperations (self.myStudyId)
230 self.MeasuOp = self.GetIMeasureOperations (self.myStudyId)
231 self.BlocksOp = self.GetIBlocksOperations (self.myStudyId)
232 self.GroupOp = self.GetIGroupOperations (self.myStudyId)
235 ## Get name for sub-shape aSubObj of shape aMainObj
237 # @ref swig_SubShapeAllSorted "Example"
238 def SubShapeName(self,aSubObj, aMainObj):
239 # Example: see GEOM_TestAll.py
241 #aSubId = orb.object_to_string(aSubObj)
242 #aMainId = orb.object_to_string(aMainObj)
243 #index = gg.getIndexTopology(aSubId, aMainId)
244 #name = gg.getShapeTypeString(aSubId) + "_%d"%(index)
245 index = self.ShapesOp.GetTopologyIndex(aMainObj, aSubObj)
246 name = self.ShapesOp.GetShapeTypeString(aSubObj) + "_%d"%(index)
249 ## Publish in study aShape with name aName
251 # \param aShape the shape to be published
252 # \param aName the name for the shape
253 # \param doRestoreSubShapes if True, finds and publishes also
254 # sub-shapes of <VAR>aShape</VAR>, corresponding to its arguments
255 # and published sub-shapes of arguments
256 # \param theArgs,theFindMethod,theInheritFirstArg see geompy.RestoreSubShapes for
257 # these arguments description
258 # \return study entry of the published shape in form of string
260 # @ref swig_MakeQuad4Vertices "Example"
261 def addToStudy(self, aShape, aName, doRestoreSubShapes=False,
262 theArgs=[], theFindMethod=GEOM.FSM_GetInPlace, theInheritFirstArg=False):
263 # Example: see GEOM_TestAll.py
265 aSObject = self.AddInStudy(self.myStudy, aShape, aName, None)
266 if doRestoreSubShapes:
267 self.RestoreSubShapesSO(self.myStudy, aSObject, theArgs,
268 theFindMethod, theInheritFirstArg)
270 print "addToStudy() failed"
272 return aShape.GetStudyEntry()
274 ## Publish in study aShape with name aName as sub-object of previously published aFather
276 # @ref swig_SubShapeAllSorted "Example"
277 def addToStudyInFather(self, aFather, aShape, aName):
278 # Example: see GEOM_TestAll.py
280 aSObject = self.AddInStudy(self.myStudy, aShape, aName, aFather)
282 print "addToStudyInFather() failed"
284 return aShape.GetStudyEntry()
286 # end of l1_geompy_auxiliary
289 ## @addtogroup l3_restore_ss
292 ## Publish sub-shapes, standing for arguments and sub-shapes of arguments
293 # To be used from python scripts out of geompy.addToStudy (non-default usage)
294 # \param theObject published GEOM object, arguments of which will be published
295 # \param theArgs list of GEOM_Object, operation arguments to be published.
296 # If this list is empty, all operation arguments will be published
297 # \param theFindMethod method to search subshapes, corresponding to arguments and
298 # their subshapes. Value from enumeration GEOM::find_shape_method.
299 # \param theInheritFirstArg set properties of the first argument for <VAR>theObject</VAR>.
300 # Do not publish subshapes in place of arguments, but only
301 # in place of subshapes of the first argument,
302 # because the whole shape corresponds to the first argument.
303 # Mainly to be used after transformations, but it also can be
304 # usefull after partition with one object shape, and some other
305 # operations, where only the first argument has to be considered.
306 # If theObject has only one argument shape, this flag is automatically
307 # considered as True, not regarding really passed value.
308 # \return True in case of success, False otherwise.
310 # @ref tui_restore_prs_params "Example"
311 def RestoreSubShapes (self, theObject, theArgs=[],
312 theFindMethod=GEOM.FSM_GetInPlace, theInheritFirstArg=False):
313 # Example: see GEOM_TestAll.py
314 return self.RestoreSubShapesO(self.myStudy, theObject, theArgs,
315 theFindMethod, theInheritFirstArg)
317 # end of l3_restore_ss
320 ## @addtogroup l3_basic_go
323 ## Create point by three coordinates.
324 # @param theX The X coordinate of the point.
325 # @param theY The Y coordinate of the point.
326 # @param theZ The Z coordinate of the point.
327 # @return New GEOM_Object, containing the created point.
329 # @ref tui_creation_point "Example"
330 def MakeVertex(self,theX, theY, theZ):
331 # Example: see GEOM_TestAll.py
332 theX,theY,theZ,Parameters = ParseParameters(theX, theY, theZ)
333 anObj = self.BasicOp.MakePointXYZ(theX, theY, theZ)
334 RaiseIfFailed("MakePointXYZ", self.BasicOp)
335 anObj.SetParameters(Parameters)
338 ## Create a point, distant from the referenced point
339 # on the given distances along the coordinate axes.
340 # @param theReference The referenced point.
341 # @param theX Displacement from the referenced point along OX axis.
342 # @param theY Displacement from the referenced point along OY axis.
343 # @param theZ Displacement from the referenced point along OZ axis.
344 # @return New GEOM_Object, containing the created point.
346 # @ref tui_creation_point "Example"
347 def MakeVertexWithRef(self,theReference, theX, theY, theZ):
348 # Example: see GEOM_TestAll.py
349 theX,theY,theZ,Parameters = ParseParameters(theX, theY, theZ)
350 anObj = self.BasicOp.MakePointWithReference(theReference, theX, theY, theZ)
351 RaiseIfFailed("MakePointWithReference", self.BasicOp)
352 anObj.SetParameters(Parameters)
355 ## Create a point, corresponding to the given parameter on the given curve.
356 # @param theRefCurve The referenced curve.
357 # @param theParameter Value of parameter on the referenced curve.
358 # @return New GEOM_Object, containing the created point.
360 # @ref tui_creation_point "Example"
361 def MakeVertexOnCurve(self,theRefCurve, theParameter):
362 # Example: see GEOM_TestAll.py
363 theParameter, Parameters = ParseParameters(theParameter)
364 anObj = self.BasicOp.MakePointOnCurve(theRefCurve, theParameter)
365 RaiseIfFailed("MakePointOnCurve", self.BasicOp)
366 anObj.SetParameters(Parameters)
369 ## Create a point, corresponding to the given parameters on the
371 # @param theRefSurf The referenced surface.
372 # @param theUParameter Value of U-parameter on the referenced surface.
373 # @param theVParameter Value of V-parameter on the referenced surface.
374 # @return New GEOM_Object, containing the created point.
376 # @ref swig_MakeVertexOnSurface "Example"
377 def MakeVertexOnSurface(self, theRefSurf, theUParameter, theVParameter):
378 theUParameter, theVParameter, Parameters = ParseParameters(theUParameter, theVParameter)
379 # Example: see GEOM_TestAll.py
380 anObj = self.BasicOp.MakePointOnSurface(theRefSurf, theUParameter, theVParameter)
381 RaiseIfFailed("MakePointOnSurface", self.BasicOp)
382 anObj.SetParameters(Parameters);
385 ## Create a point on intersection of two lines.
386 # @param theRefLine1, theRefLine2 The referenced lines.
387 # @return New GEOM_Object, containing the created point.
389 # @ref swig_MakeVertexOnLinesIntersection "Example"
390 def MakeVertexOnLinesIntersection(self, theRefLine1, theRefLine2):
391 # Example: see GEOM_TestAll.py
392 anObj = self.BasicOp.MakePointOnLinesIntersection(theRefLine1, theRefLine2)
393 RaiseIfFailed("MakePointOnLinesIntersection", self.BasicOp)
396 ## Create a tangent, corresponding to the given parameter on the given curve.
397 # @param theRefCurve The referenced curve.
398 # @param theParameter Value of parameter on the referenced curve.
399 # @return New GEOM_Object, containing the created tangent.
401 # @ref swig_MakeTangentOnCurve "Example"
402 def MakeTangentOnCurve(self, theRefCurve, theParameter):
403 anObj = self.BasicOp.MakeTangentOnCurve(theRefCurve, theParameter)
404 RaiseIfFailed("MakeTangentOnCurve", self.BasicOp)
407 ## Create a tangent plane, corresponding to the given parameter on the given face.
408 # @param theFace The face for which tangent plane should be built.
409 # @param theParameterV vertical value of the center point (0.0 - 1.0).
410 # @param theParameterU horisontal value of the center point (0.0 - 1.0).
411 # @param theTrimSize the size of plane.
412 # @return New GEOM_Object, containing the created tangent.
414 # @ref swig_MakeTangentPlaneOnFace "Example"
415 def MakeTangentPlaneOnFace(self, theFace, theParameterU, theParameterV, theTrimSize):
416 anObj = self.BasicOp.MakeTangentPlaneOnFace(theFace, theParameterU, theParameterV, theTrimSize)
417 RaiseIfFailed("MakeTangentPlaneOnFace", self.BasicOp)
420 ## Create a vector with the given components.
421 # @param theDX X component of the vector.
422 # @param theDY Y component of the vector.
423 # @param theDZ Z component of the vector.
424 # @return New GEOM_Object, containing the created vector.
426 # @ref tui_creation_vector "Example"
427 def MakeVectorDXDYDZ(self,theDX, theDY, theDZ):
428 # Example: see GEOM_TestAll.py
429 theDX,theDY,theDZ,Parameters = ParseParameters(theDX, theDY, theDZ)
430 anObj = self.BasicOp.MakeVectorDXDYDZ(theDX, theDY, theDZ)
431 RaiseIfFailed("MakeVectorDXDYDZ", self.BasicOp)
432 anObj.SetParameters(Parameters)
435 ## Create a vector between two points.
436 # @param thePnt1 Start point for the vector.
437 # @param thePnt2 End point for the vector.
438 # @return New GEOM_Object, containing the created vector.
440 # @ref tui_creation_vector "Example"
441 def MakeVector(self,thePnt1, thePnt2):
442 # Example: see GEOM_TestAll.py
443 anObj = self.BasicOp.MakeVectorTwoPnt(thePnt1, thePnt2)
444 RaiseIfFailed("MakeVectorTwoPnt", self.BasicOp)
447 ## Create a line, passing through the given point
448 # and parrallel to the given direction
449 # @param thePnt Point. The resulting line will pass through it.
450 # @param theDir Direction. The resulting line will be parallel to it.
451 # @return New GEOM_Object, containing the created line.
453 # @ref tui_creation_line "Example"
454 def MakeLine(self,thePnt, theDir):
455 # Example: see GEOM_TestAll.py
456 anObj = self.BasicOp.MakeLine(thePnt, theDir)
457 RaiseIfFailed("MakeLine", self.BasicOp)
460 ## Create a line, passing through the given points
461 # @param thePnt1 First of two points, defining the line.
462 # @param thePnt2 Second of two points, defining the line.
463 # @return New GEOM_Object, containing the created line.
465 # @ref tui_creation_line "Example"
466 def MakeLineTwoPnt(self,thePnt1, thePnt2):
467 # Example: see GEOM_TestAll.py
468 anObj = self.BasicOp.MakeLineTwoPnt(thePnt1, thePnt2)
469 RaiseIfFailed("MakeLineTwoPnt", self.BasicOp)
472 ## Create a line on two faces intersection.
473 # @param theFace1 First of two faces, defining the line.
474 # @param theFace2 Second of two faces, defining the line.
475 # @return New GEOM_Object, containing the created line.
477 # @ref swig_MakeLineTwoFaces "Example"
478 def MakeLineTwoFaces(self, theFace1, theFace2):
479 # Example: see GEOM_TestAll.py
480 anObj = self.BasicOp.MakeLineTwoFaces(theFace1, theFace2)
481 RaiseIfFailed("MakeLineTwoFaces", self.BasicOp)
484 ## Create a plane, passing through the given point
485 # and normal to the given vector.
486 # @param thePnt Point, the plane has to pass through.
487 # @param theVec Vector, defining the plane normal direction.
488 # @param theTrimSize Half size of a side of quadrangle face, representing the plane.
489 # @return New GEOM_Object, containing the created plane.
491 # @ref tui_creation_plane "Example"
492 def MakePlane(self,thePnt, theVec, theTrimSize):
493 # Example: see GEOM_TestAll.py
494 theTrimSize, Parameters = ParseParameters(theTrimSize);
495 anObj = self.BasicOp.MakePlanePntVec(thePnt, theVec, theTrimSize)
496 RaiseIfFailed("MakePlanePntVec", self.BasicOp)
497 anObj.SetParameters(Parameters)
500 ## Create a plane, passing through the three given points
501 # @param thePnt1 First of three points, defining the plane.
502 # @param thePnt2 Second of three points, defining the plane.
503 # @param thePnt3 Fird of three points, defining the plane.
504 # @param theTrimSize Half size of a side of quadrangle face, representing the plane.
505 # @return New GEOM_Object, containing the created plane.
507 # @ref tui_creation_plane "Example"
508 def MakePlaneThreePnt(self,thePnt1, thePnt2, thePnt3, theTrimSize):
509 # Example: see GEOM_TestAll.py
510 theTrimSize, Parameters = ParseParameters(theTrimSize);
511 anObj = self.BasicOp.MakePlaneThreePnt(thePnt1, thePnt2, thePnt3, theTrimSize)
512 RaiseIfFailed("MakePlaneThreePnt", self.BasicOp)
513 anObj.SetParameters(Parameters)
516 ## Create a plane, similar to the existing one, but with another size of representing face.
517 # @param theFace Referenced plane or LCS(Marker).
518 # @param theTrimSize New half size of a side of quadrangle face, representing the plane.
519 # @return New GEOM_Object, containing the created plane.
521 # @ref tui_creation_plane "Example"
522 def MakePlaneFace(self,theFace, theTrimSize):
523 # Example: see GEOM_TestAll.py
524 theTrimSize, Parameters = ParseParameters(theTrimSize);
525 anObj = self.BasicOp.MakePlaneFace(theFace, theTrimSize)
526 RaiseIfFailed("MakePlaneFace", self.BasicOp)
527 anObj.SetParameters(Parameters)
530 ## Create a plane, passing through the 2 vectors
531 # with center in a start point of the first vector.
532 # @param theVec1 Vector, defining center point and plane direction.
533 # @param theVec2 Vector, defining the plane normal direction.
534 # @param theTrimSize Half size of a side of quadrangle face, representing the plane.
535 # @return New GEOM_Object, containing the created plane.
537 # @ref tui_creation_plane "Example"
538 def MakePlane2Vec(self,theVec1, theVec2, theTrimSize):
539 # Example: see GEOM_TestAll.py
540 theTrimSize, Parameters = ParseParameters(theTrimSize);
541 anObj = self.BasicOp.MakePlane2Vec(theVec1, theVec2, theTrimSize)
542 RaiseIfFailed("MakePlane2Vec", self.BasicOp)
543 anObj.SetParameters(Parameters)
546 ## Create a plane, based on a Local coordinate system.
547 # @param theLCS coordinate system, defining plane.
548 # @param theTrimSize Half size of a side of quadrangle face, representing the plane.
549 # @param theOrientation OXY, OYZ or OZX orientation - (1, 2 or 3)
550 # @return New GEOM_Object, containing the created plane.
552 # @ref tui_creation_plane "Example"
553 def MakePlaneLCS(self,theLCS, theTrimSize, theOrientation):
554 # Example: see GEOM_TestAll.py
555 theTrimSize, Parameters = ParseParameters(theTrimSize);
556 anObj = self.BasicOp.MakePlaneLCS(theLCS, theTrimSize, theOrientation)
557 RaiseIfFailed("MakePlaneLCS", self.BasicOp)
558 anObj.SetParameters(Parameters)
561 ## Create a local coordinate system.
562 # @param OX,OY,OZ Three coordinates of coordinate system origin.
563 # @param XDX,XDY,XDZ Three components of OX direction
564 # @param YDX,YDY,YDZ Three components of OY direction
565 # @return New GEOM_Object, containing the created coordinate system.
567 # @ref swig_MakeMarker "Example"
568 def MakeMarker(self, OX,OY,OZ, XDX,XDY,XDZ, YDX,YDY,YDZ):
569 # Example: see GEOM_TestAll.py
570 OX,OY,OZ, XDX,XDY,XDZ, YDX,YDY,YDZ, Parameters = ParseParameters(OX,OY,OZ, XDX,XDY,XDZ, YDX,YDY,YDZ);
571 anObj = self.BasicOp.MakeMarker(OX,OY,OZ, XDX,XDY,XDZ, YDX,YDY,YDZ)
572 RaiseIfFailed("MakeMarker", self.BasicOp)
573 anObj.SetParameters(Parameters)
576 ## Create a local coordinate system.
577 # @param theOrigin Point of coordinate system origin.
578 # @param theXVec Vector of X direction
579 # @param theYVec Vector of Y direction
580 # @return New GEOM_Object, containing the created coordinate system.
582 # @ref swig_MakeMarker "Example"
583 def MakeMarkerPntTwoVec(self, theOrigin, theXVec, theYVec):
584 O = self.PointCoordinates( theOrigin )
586 for vec in [ theXVec, theYVec ]:
587 v1, v2 = self.SubShapeAll( vec, ShapeType["VERTEX"] )
588 p1 = self.PointCoordinates( v1 )
589 p2 = self.PointCoordinates( v2 )
590 for i in range( 0, 3 ):
591 OXOY.append( p2[i] - p1[i] )
593 anObj = self.BasicOp.MakeMarker( O[0], O[1], O[2],
594 OXOY[0], OXOY[1], OXOY[2],
595 OXOY[3], OXOY[4], OXOY[5], )
596 RaiseIfFailed("MakeMarker", self.BasicOp)
602 ## @addtogroup l4_curves
605 ## Create an arc of circle, passing through three given points.
606 # @param thePnt1 Start point of the arc.
607 # @param thePnt2 Middle point of the arc.
608 # @param thePnt3 End point of the arc.
609 # @return New GEOM_Object, containing the created arc.
611 # @ref swig_MakeArc "Example"
612 def MakeArc(self,thePnt1, thePnt2, thePnt3):
613 # Example: see GEOM_TestAll.py
614 anObj = self.CurvesOp.MakeArc(thePnt1, thePnt2, thePnt3)
615 RaiseIfFailed("MakeArc", self.CurvesOp)
618 ## Create an arc of circle from a center and 2 points.
619 # @param thePnt1 Center of the arc
620 # @param thePnt2 Start point of the arc. (Gives also the radius of the arc)
621 # @param thePnt3 End point of the arc (Gives also a direction)
622 # @param theSense Orientation of the arc
623 # @return New GEOM_Object, containing the created arc.
625 # @ref swig_MakeArc "Example"
626 def MakeArcCenter(self, thePnt1, thePnt2, thePnt3, theSense=False):
627 # Example: see GEOM_TestAll.py
628 anObj = self.CurvesOp.MakeArcCenter(thePnt1, thePnt2, thePnt3, theSense)
629 RaiseIfFailed("MakeArcCenter", self.CurvesOp)
632 ## Create an arc of ellipse, of center and two points.
633 # @param theCenter Center of the arc.
634 # @param thePnt1 defines major radius of the arc by distance from Pnt1 to Pnt2.
635 # @param thePnt2 defines plane of ellipse and minor radius as distance from Pnt3 to line from Pnt1 to Pnt2.
636 # @return New GEOM_Object, containing the created arc.
638 # @ref swig_MakeArc "Example"
639 def MakeArcOfEllipse(self,theCenter, thePnt1, thePnt2):
640 # Example: see GEOM_TestAll.py
641 anObj = self.CurvesOp.MakeArcOfEllipse(theCenter, thePnt1, thePnt2)
642 RaiseIfFailed("MakeArcOfEllipse", self.CurvesOp)
645 ## Create a circle with given center, normal vector and radius.
646 # @param thePnt Circle center.
647 # @param theVec Vector, normal to the plane of the circle.
648 # @param theR Circle radius.
649 # @return New GEOM_Object, containing the created circle.
651 # @ref tui_creation_circle "Example"
652 def MakeCircle(self, thePnt, theVec, theR):
653 # Example: see GEOM_TestAll.py
654 theR, Parameters = ParseParameters(theR)
655 anObj = self.CurvesOp.MakeCirclePntVecR(thePnt, theVec, theR)
656 RaiseIfFailed("MakeCirclePntVecR", self.CurvesOp)
657 anObj.SetParameters(Parameters)
660 ## Create a circle with given radius.
661 # Center of the circle will be in the origin of global
662 # coordinate system and normal vector will be codirected with Z axis
663 # @param theR Circle radius.
664 # @return New GEOM_Object, containing the created circle.
665 def MakeCircleR(self, theR):
666 anObj = self.CurvesOp.MakeCirclePntVecR(None, None, theR)
667 RaiseIfFailed("MakeCirclePntVecR", self.CurvesOp)
670 ## Create a circle, passing through three given points
671 # @param thePnt1,thePnt2,thePnt3 Points, defining the circle.
672 # @return New GEOM_Object, containing the created circle.
674 # @ref tui_creation_circle "Example"
675 def MakeCircleThreePnt(self,thePnt1, thePnt2, thePnt3):
676 # Example: see GEOM_TestAll.py
677 anObj = self.CurvesOp.MakeCircleThreePnt(thePnt1, thePnt2, thePnt3)
678 RaiseIfFailed("MakeCircleThreePnt", self.CurvesOp)
681 ## Create a circle, with given point1 as center,
682 # passing through the point2 as radius and laying in the plane,
683 # defined by all three given points.
684 # @param thePnt1,thePnt2,thePnt3 Points, defining the circle.
685 # @return New GEOM_Object, containing the created circle.
687 # @ref swig_MakeCircle "Example"
688 def MakeCircleCenter2Pnt(self,thePnt1, thePnt2, thePnt3):
689 # Example: see GEOM_example6.py
690 anObj = self.CurvesOp.MakeCircleCenter2Pnt(thePnt1, thePnt2, thePnt3)
691 RaiseIfFailed("MakeCircleCenter2Pnt", self.CurvesOp)
694 ## Create an ellipse with given center, normal vector and radiuses.
695 # @param thePnt Ellipse center.
696 # @param theVec Vector, normal to the plane of the ellipse.
697 # @param theRMajor Major ellipse radius.
698 # @param theRMinor Minor ellipse radius.
699 # @param theVecMaj Vector, direction of the ellipse's main axis.
700 # @return New GEOM_Object, containing the created ellipse.
702 # @ref tui_creation_ellipse "Example"
703 def MakeEllipse(self, thePnt, theVec, theRMajor, theRMinor, theVecMaj=None):
704 # Example: see GEOM_TestAll.py
705 theRMajor, theRMinor, Parameters = ParseParameters(theRMajor, theRMinor)
706 if theVecMaj is not None:
707 anObj = self.CurvesOp.MakeEllipseVec(thePnt, theVec, theRMajor, theRMinor, theVecMaj)
709 anObj = self.CurvesOp.MakeEllipse(thePnt, theVec, theRMajor, theRMinor)
711 RaiseIfFailed("MakeEllipse", self.CurvesOp)
712 anObj.SetParameters(Parameters)
715 ## Create an ellipse with given radiuses.
716 # Center of the ellipse will be in the origin of global
717 # coordinate system and normal vector will be codirected with Z axis
718 # @param theRMajor Major ellipse radius.
719 # @param theRMinor Minor ellipse radius.
720 # @return New GEOM_Object, containing the created ellipse.
721 def MakeEllipseRR(self, theRMajor, theRMinor):
722 anObj = self.CurvesOp.MakeEllipse(None, None, theRMajor, theRMinor)
723 RaiseIfFailed("MakeEllipse", self.CurvesOp)
726 ## Create a polyline on the set of points.
727 # @param thePoints Sequence of points for the polyline.
728 # @return New GEOM_Object, containing the created polyline.
730 # @ref tui_creation_curve "Example"
731 def MakePolyline(self,thePoints):
732 # Example: see GEOM_TestAll.py
733 anObj = self.CurvesOp.MakePolyline(thePoints)
734 RaiseIfFailed("MakePolyline", self.CurvesOp)
737 ## Create bezier curve on the set of points.
738 # @param thePoints Sequence of points for the bezier curve.
739 # @return New GEOM_Object, containing the created bezier curve.
741 # @ref tui_creation_curve "Example"
742 def MakeBezier(self,thePoints):
743 # Example: see GEOM_TestAll.py
744 anObj = self.CurvesOp.MakeSplineBezier(thePoints)
745 RaiseIfFailed("MakeSplineBezier", self.CurvesOp)
748 ## Create B-Spline curve on the set of points.
749 # @param thePoints Sequence of points for the B-Spline curve.
750 # @return New GEOM_Object, containing the created B-Spline curve.
752 # @ref tui_creation_curve "Example"
753 def MakeInterpol(self,thePoints):
754 # Example: see GEOM_TestAll.py
755 anObj = self.CurvesOp.MakeSplineInterpolation(thePoints)
756 RaiseIfFailed("MakeSplineInterpolation", self.CurvesOp)
762 ## @addtogroup l3_sketcher
765 ## Create a sketcher (wire or face), following the textual description,
766 # passed through <VAR>theCommand</VAR> argument. \n
767 # Edges of the resulting wire or face will be arcs of circles and/or linear segments. \n
768 # Format of the description string have to be the following:
770 # "Sketcher[:F x1 y1]:CMD[:CMD[:CMD...]]"
773 # - x1, y1 are coordinates of the first sketcher point (zero by default),
775 # - "R angle" : Set the direction by angle
776 # - "D dx dy" : Set the direction by DX & DY
779 # - "TT x y" : Create segment by point at X & Y
780 # - "T dx dy" : Create segment by point with DX & DY
781 # - "L length" : Create segment by direction & Length
782 # - "IX x" : Create segment by direction & Intersect. X
783 # - "IY y" : Create segment by direction & Intersect. Y
786 # - "C radius length" : Create arc by direction, radius and length(in degree)
789 # - "WW" : Close Wire (to finish)
790 # - "WF" : Close Wire and build face (to finish)
792 # @param theCommand String, defining the sketcher in local
793 # coordinates of the working plane.
794 # @param theWorkingPlane Nine double values, defining origin,
795 # OZ and OX directions of the working plane.
796 # @return New GEOM_Object, containing the created wire.
798 # @ref tui_sketcher_page "Example"
799 def MakeSketcher(self, theCommand, theWorkingPlane = [0,0,0, 0,0,1, 1,0,0]):
800 # Example: see GEOM_TestAll.py
801 theCommand,Parameters = ParseSketcherCommand(theCommand)
802 anObj = self.CurvesOp.MakeSketcher(theCommand, theWorkingPlane)
803 RaiseIfFailed("MakeSketcher", self.CurvesOp)
804 anObj.SetParameters(Parameters)
807 ## Create a sketcher (wire or face), following the textual description,
808 # passed through <VAR>theCommand</VAR> argument. \n
809 # For format of the description string see the previous method.\n
810 # @param theCommand String, defining the sketcher in local
811 # coordinates of the working plane.
812 # @param theWorkingPlane Planar Face or LCS(Marker) of the working plane.
813 # @return New GEOM_Object, containing the created wire.
815 # @ref tui_sketcher_page "Example"
816 def MakeSketcherOnPlane(self, theCommand, theWorkingPlane):
817 anObj = self.CurvesOp.MakeSketcherOnPlane(theCommand, theWorkingPlane)
818 RaiseIfFailed("MakeSketcherOnPlane", self.CurvesOp)
821 ## Create a sketcher wire, following the numerical description,
822 # passed through <VAR>theCoordinates</VAR> argument. \n
823 # @param theCoordinates double values, defining points to create a wire,
825 # @return New GEOM_Object, containing the created wire.
827 # @ref tui_sketcher_page "Example"
828 def Make3DSketcher(self, theCoordinates):
829 anObj = self.CurvesOp.Make3DSketcher(theCoordinates)
830 RaiseIfFailed("Make3DSketcher", self.CurvesOp)
836 ## @addtogroup l3_3d_primitives
839 ## Create a box by coordinates of two opposite vertices.
841 # @ref tui_creation_box "Example"
842 def MakeBox(self,x1,y1,z1,x2,y2,z2):
843 # Example: see GEOM_TestAll.py
844 pnt1 = self.MakeVertex(x1,y1,z1)
845 pnt2 = self.MakeVertex(x2,y2,z2)
846 return self.MakeBoxTwoPnt(pnt1,pnt2)
848 ## Create a box with specified dimensions along the coordinate axes
849 # and with edges, parallel to the coordinate axes.
850 # Center of the box will be at point (DX/2, DY/2, DZ/2).
851 # @param theDX Length of Box edges, parallel to OX axis.
852 # @param theDY Length of Box edges, parallel to OY axis.
853 # @param theDZ Length of Box edges, parallel to OZ axis.
854 # @return New GEOM_Object, containing the created box.
856 # @ref tui_creation_box "Example"
857 def MakeBoxDXDYDZ(self,theDX, theDY, theDZ):
858 # Example: see GEOM_TestAll.py
859 theDX,theDY,theDZ,Parameters = ParseParameters(theDX, theDY, theDZ)
860 anObj = self.PrimOp.MakeBoxDXDYDZ(theDX, theDY, theDZ)
861 RaiseIfFailed("MakeBoxDXDYDZ", self.PrimOp)
862 anObj.SetParameters(Parameters)
865 ## Create a box with two specified opposite vertices,
866 # and with edges, parallel to the coordinate axes
867 # @param thePnt1 First of two opposite vertices.
868 # @param thePnt2 Second of two opposite vertices.
869 # @return New GEOM_Object, containing the created box.
871 # @ref tui_creation_box "Example"
872 def MakeBoxTwoPnt(self,thePnt1, thePnt2):
873 # Example: see GEOM_TestAll.py
874 anObj = self.PrimOp.MakeBoxTwoPnt(thePnt1, thePnt2)
875 RaiseIfFailed("MakeBoxTwoPnt", self.PrimOp)
878 ## Create a face with specified dimensions along OX-OY coordinate axes,
879 # with edges, parallel to this coordinate axes.
880 # @param theH height of Face.
881 # @param theW width of Face.
882 # @param theOrientation orientation belong axis OXY OYZ OZX
883 # @return New GEOM_Object, containing the created face.
885 # @ref tui_creation_face "Example"
886 def MakeFaceHW(self,theH, theW, theOrientation):
887 # Example: see GEOM_TestAll.py
888 theH,theW,Parameters = ParseParameters(theH, theW)
889 anObj = self.PrimOp.MakeFaceHW(theH, theW, theOrientation)
890 RaiseIfFailed("MakeFaceHW", self.PrimOp)
891 anObj.SetParameters(Parameters)
894 ## Create a face from another plane and two sizes,
895 # vertical size and horisontal size.
896 # @param theObj Normale vector to the creating face or
898 # @param theH Height (vertical size).
899 # @param theW Width (horisontal size).
900 # @return New GEOM_Object, containing the created face.
902 # @ref tui_creation_face "Example"
903 def MakeFaceObjHW(self, theObj, theH, theW):
904 # Example: see GEOM_TestAll.py
905 theH,theW,Parameters = ParseParameters(theH, theW)
906 anObj = self.PrimOp.MakeFaceObjHW(theObj, theH, theW)
907 RaiseIfFailed("MakeFaceObjHW", self.PrimOp)
908 anObj.SetParameters(Parameters)
911 ## Create a disk with given center, normal vector and radius.
912 # @param thePnt Disk center.
913 # @param theVec Vector, normal to the plane of the disk.
914 # @param theR Disk radius.
915 # @return New GEOM_Object, containing the created disk.
917 # @ref tui_creation_disk "Example"
918 def MakeDiskPntVecR(self,thePnt, theVec, theR):
919 # Example: see GEOM_TestAll.py
920 theR,Parameters = ParseParameters(theR)
921 anObj = self.PrimOp.MakeDiskPntVecR(thePnt, theVec, theR)
922 RaiseIfFailed("MakeDiskPntVecR", self.PrimOp)
923 anObj.SetParameters(Parameters)
926 ## Create a disk, passing through three given points
927 # @param thePnt1,thePnt2,thePnt3 Points, defining the disk.
928 # @return New GEOM_Object, containing the created disk.
930 # @ref tui_creation_disk "Example"
931 def MakeDiskThreePnt(self,thePnt1, thePnt2, thePnt3):
932 # Example: see GEOM_TestAll.py
933 anObj = self.PrimOp.MakeDiskThreePnt(thePnt1, thePnt2, thePnt3)
934 RaiseIfFailed("MakeDiskThreePnt", self.PrimOp)
937 ## Create a disk with specified dimensions along OX-OY coordinate axes.
938 # @param theR Radius of Face.
939 # @param theOrientation set the orientation belong axis OXY or OYZ or OZX
940 # @return New GEOM_Object, containing the created disk.
942 # @ref tui_creation_face "Example"
943 def MakeDiskR(self,theR, theOrientation):
944 # Example: see GEOM_TestAll.py
945 theR,Parameters = ParseParameters(theR)
946 anObj = self.PrimOp.MakeDiskR(theR, theOrientation)
947 RaiseIfFailed("MakeDiskR", self.PrimOp)
948 anObj.SetParameters(Parameters)
951 ## Create a cylinder with given base point, axis, radius and height.
952 # @param thePnt Central point of cylinder base.
953 # @param theAxis Cylinder axis.
954 # @param theR Cylinder radius.
955 # @param theH Cylinder height.
956 # @return New GEOM_Object, containing the created cylinder.
958 # @ref tui_creation_cylinder "Example"
959 def MakeCylinder(self,thePnt, theAxis, theR, theH):
960 # Example: see GEOM_TestAll.py
961 theR,theH,Parameters = ParseParameters(theR, theH)
962 anObj = self.PrimOp.MakeCylinderPntVecRH(thePnt, theAxis, theR, theH)
963 RaiseIfFailed("MakeCylinderPntVecRH", self.PrimOp)
964 anObj.SetParameters(Parameters)
967 ## Create a cylinder with given radius and height at
968 # the origin of coordinate system. Axis of the cylinder
969 # will be collinear to the OZ axis of the coordinate system.
970 # @param theR Cylinder radius.
971 # @param theH Cylinder height.
972 # @return New GEOM_Object, containing the created cylinder.
974 # @ref tui_creation_cylinder "Example"
975 def MakeCylinderRH(self,theR, theH):
976 # Example: see GEOM_TestAll.py
977 theR,theH,Parameters = ParseParameters(theR, theH)
978 anObj = self.PrimOp.MakeCylinderRH(theR, theH)
979 RaiseIfFailed("MakeCylinderRH", self.PrimOp)
980 anObj.SetParameters(Parameters)
983 ## Create a sphere with given center and radius.
984 # @param thePnt Sphere center.
985 # @param theR Sphere radius.
986 # @return New GEOM_Object, containing the created sphere.
988 # @ref tui_creation_sphere "Example"
989 def MakeSpherePntR(self, thePnt, theR):
990 # Example: see GEOM_TestAll.py
991 theR,Parameters = ParseParameters(theR)
992 anObj = self.PrimOp.MakeSpherePntR(thePnt, theR)
993 RaiseIfFailed("MakeSpherePntR", self.PrimOp)
994 anObj.SetParameters(Parameters)
997 ## Create a sphere with given center and radius.
998 # @param x,y,z Coordinates of sphere center.
999 # @param theR Sphere radius.
1000 # @return New GEOM_Object, containing the created sphere.
1002 # @ref tui_creation_sphere "Example"
1003 def MakeSphere(self, x, y, z, theR):
1004 # Example: see GEOM_TestAll.py
1005 point = self.MakeVertex(x, y, z)
1006 anObj = self.MakeSpherePntR(point, theR)
1009 ## Create a sphere with given radius at the origin of coordinate system.
1010 # @param theR Sphere radius.
1011 # @return New GEOM_Object, containing the created sphere.
1013 # @ref tui_creation_sphere "Example"
1014 def MakeSphereR(self, theR):
1015 # Example: see GEOM_TestAll.py
1016 theR,Parameters = ParseParameters(theR)
1017 anObj = self.PrimOp.MakeSphereR(theR)
1018 RaiseIfFailed("MakeSphereR", self.PrimOp)
1019 anObj.SetParameters(Parameters)
1022 ## Create a cone with given base point, axis, height and radiuses.
1023 # @param thePnt Central point of the first cone base.
1024 # @param theAxis Cone axis.
1025 # @param theR1 Radius of the first cone base.
1026 # @param theR2 Radius of the second cone base.
1027 # \note If both radiuses are non-zero, the cone will be truncated.
1028 # \note If the radiuses are equal, a cylinder will be created instead.
1029 # @param theH Cone height.
1030 # @return New GEOM_Object, containing the created cone.
1032 # @ref tui_creation_cone "Example"
1033 def MakeCone(self,thePnt, theAxis, theR1, theR2, theH):
1034 # Example: see GEOM_TestAll.py
1035 theR1,theR2,theH,Parameters = ParseParameters(theR1,theR2,theH)
1036 anObj = self.PrimOp.MakeConePntVecR1R2H(thePnt, theAxis, theR1, theR2, theH)
1037 RaiseIfFailed("MakeConePntVecR1R2H", self.PrimOp)
1038 anObj.SetParameters(Parameters)
1041 ## Create a cone with given height and radiuses at
1042 # the origin of coordinate system. Axis of the cone will
1043 # be collinear to the OZ axis of the coordinate system.
1044 # @param theR1 Radius of the first cone base.
1045 # @param theR2 Radius of the second cone base.
1046 # \note If both radiuses are non-zero, the cone will be truncated.
1047 # \note If the radiuses are equal, a cylinder will be created instead.
1048 # @param theH Cone height.
1049 # @return New GEOM_Object, containing the created cone.
1051 # @ref tui_creation_cone "Example"
1052 def MakeConeR1R2H(self,theR1, theR2, theH):
1053 # Example: see GEOM_TestAll.py
1054 theR1,theR2,theH,Parameters = ParseParameters(theR1,theR2,theH)
1055 anObj = self.PrimOp.MakeConeR1R2H(theR1, theR2, theH)
1056 RaiseIfFailed("MakeConeR1R2H", self.PrimOp)
1057 anObj.SetParameters(Parameters)
1060 ## Create a torus with given center, normal vector and radiuses.
1061 # @param thePnt Torus central point.
1062 # @param theVec Torus axis of symmetry.
1063 # @param theRMajor Torus major radius.
1064 # @param theRMinor Torus minor radius.
1065 # @return New GEOM_Object, containing the created torus.
1067 # @ref tui_creation_torus "Example"
1068 def MakeTorus(self, thePnt, theVec, theRMajor, theRMinor):
1069 # Example: see GEOM_TestAll.py
1070 theRMajor,theRMinor,Parameters = ParseParameters(theRMajor,theRMinor)
1071 anObj = self.PrimOp.MakeTorusPntVecRR(thePnt, theVec, theRMajor, theRMinor)
1072 RaiseIfFailed("MakeTorusPntVecRR", self.PrimOp)
1073 anObj.SetParameters(Parameters)
1076 ## Create a torus with given radiuses at the origin of coordinate system.
1077 # @param theRMajor Torus major radius.
1078 # @param theRMinor Torus minor radius.
1079 # @return New GEOM_Object, containing the created torus.
1081 # @ref tui_creation_torus "Example"
1082 def MakeTorusRR(self, theRMajor, theRMinor):
1083 # Example: see GEOM_TestAll.py
1084 theRMajor,theRMinor,Parameters = ParseParameters(theRMajor,theRMinor)
1085 anObj = self.PrimOp.MakeTorusRR(theRMajor, theRMinor)
1086 RaiseIfFailed("MakeTorusRR", self.PrimOp)
1087 anObj.SetParameters(Parameters)
1090 # end of l3_3d_primitives
1093 ## @addtogroup l3_complex
1096 ## Create a shape by extrusion of the base shape along a vector, defined by two points.
1097 # @param theBase Base shape to be extruded.
1098 # @param thePoint1 First end of extrusion vector.
1099 # @param thePoint2 Second end of extrusion vector.
1100 # @return New GEOM_Object, containing the created prism.
1102 # @ref tui_creation_prism "Example"
1103 def MakePrism(self, theBase, thePoint1, thePoint2):
1104 # Example: see GEOM_TestAll.py
1105 anObj = self.PrimOp.MakePrismTwoPnt(theBase, thePoint1, thePoint2)
1106 RaiseIfFailed("MakePrismTwoPnt", self.PrimOp)
1109 ## Create a shape by extrusion of the base shape along the vector,
1110 # i.e. all the space, transfixed by the base shape during its translation
1111 # along the vector on the given distance.
1112 # @param theBase Base shape to be extruded.
1113 # @param theVec Direction of extrusion.
1114 # @param theH Prism dimension along theVec.
1115 # @return New GEOM_Object, containing the created prism.
1117 # @ref tui_creation_prism "Example"
1118 def MakePrismVecH(self, theBase, theVec, theH):
1119 # Example: see GEOM_TestAll.py
1120 theH,Parameters = ParseParameters(theH)
1121 anObj = self.PrimOp.MakePrismVecH(theBase, theVec, theH)
1122 RaiseIfFailed("MakePrismVecH", self.PrimOp)
1123 anObj.SetParameters(Parameters)
1126 ## Create a shape by extrusion of the base shape along the vector,
1127 # i.e. all the space, transfixed by the base shape during its translation
1128 # along the vector on the given distance in 2 Ways (forward/backward) .
1129 # @param theBase Base shape to be extruded.
1130 # @param theVec Direction of extrusion.
1131 # @param theH Prism dimension along theVec in forward direction.
1132 # @return New GEOM_Object, containing the created prism.
1134 # @ref tui_creation_prism "Example"
1135 def MakePrismVecH2Ways(self, theBase, theVec, theH):
1136 # Example: see GEOM_TestAll.py
1137 theH,Parameters = ParseParameters(theH)
1138 anObj = self.PrimOp.MakePrismVecH2Ways(theBase, theVec, theH)
1139 RaiseIfFailed("MakePrismVecH2Ways", self.PrimOp)
1140 anObj.SetParameters(Parameters)
1143 ## Create a shape by extrusion of the base shape along the dx, dy, dz direction
1144 # @param theBase Base shape to be extruded.
1145 # @param theDX, theDY, theDZ Directions of extrusion.
1146 # @return New GEOM_Object, containing the created prism.
1148 # @ref tui_creation_prism "Example"
1149 def MakePrismDXDYDZ(self, theBase, theDX, theDY, theDZ):
1150 # Example: see GEOM_TestAll.py
1151 theDX,theDY,theDZ,Parameters = ParseParameters(theDX, theDY, theDZ)
1152 anObj = self.PrimOp.MakePrismDXDYDZ(theBase, theDX, theDY, theDZ)
1153 RaiseIfFailed("MakePrismDXDYDZ", self.PrimOp)
1154 anObj.SetParameters(Parameters)
1157 ## Create a shape by extrusion of the base shape along the dx, dy, dz direction
1158 # i.e. all the space, transfixed by the base shape during its translation
1159 # along the vector on the given distance in 2 Ways (forward/backward) .
1160 # @param theBase Base shape to be extruded.
1161 # @param theDX, theDY, theDZ Directions of extrusion.
1162 # @return New GEOM_Object, containing the created prism.
1164 # @ref tui_creation_prism "Example"
1165 def MakePrismDXDYDZ2Ways(self, theBase, theDX, theDY, theDZ):
1166 # Example: see GEOM_TestAll.py
1167 theDX,theDY,theDZ,Parameters = ParseParameters(theDX, theDY, theDZ)
1168 anObj = self.PrimOp.MakePrismDXDYDZ2Ways(theBase, theDX, theDY, theDZ)
1169 RaiseIfFailed("MakePrismDXDYDZ2Ways", self.PrimOp)
1170 anObj.SetParameters(Parameters)
1173 ## Create a shape by revolution of the base shape around the axis
1174 # on the given angle, i.e. all the space, transfixed by the base
1175 # shape during its rotation around the axis on the given angle.
1176 # @param theBase Base shape to be rotated.
1177 # @param theAxis Rotation axis.
1178 # @param theAngle Rotation angle in radians.
1179 # @return New GEOM_Object, containing the created revolution.
1181 # @ref tui_creation_revolution "Example"
1182 def MakeRevolution(self, theBase, theAxis, theAngle):
1183 # Example: see GEOM_TestAll.py
1184 theAngle,Parameters = ParseParameters(theAngle)
1185 anObj = self.PrimOp.MakeRevolutionAxisAngle(theBase, theAxis, theAngle)
1186 RaiseIfFailed("MakeRevolutionAxisAngle", self.PrimOp)
1187 anObj.SetParameters(Parameters)
1190 ## The Same Revolution but in both ways forward&backward.
1191 def MakeRevolution2Ways(self, theBase, theAxis, theAngle):
1192 theAngle,Parameters = ParseParameters(theAngle)
1193 anObj = self.PrimOp.MakeRevolutionAxisAngle2Ways(theBase, theAxis, theAngle)
1194 RaiseIfFailed("MakeRevolutionAxisAngle2Ways", self.PrimOp)
1195 anObj.SetParameters(Parameters)
1198 ## Create a filling from the given compound of contours.
1199 # @param theShape the compound of contours
1200 # @param theMinDeg a minimal degree of BSpline surface to create
1201 # @param theMaxDeg a maximal degree of BSpline surface to create
1202 # @param theTol2D a 2d tolerance to be reached
1203 # @param theTol3D a 3d tolerance to be reached
1204 # @param theNbIter a number of iteration of approximation algorithm
1205 # @param isApprox if True, BSpline curves are generated in the process
1206 # of surface construction. By default it is False, that means
1207 # the surface is created using Besier curves. The usage of
1208 # Approximation makes the algorithm work slower, but allows
1209 # building the surface for rather complex cases
1210 # @return New GEOM_Object, containing the created filling surface.
1212 # @ref tui_creation_filling "Example"
1213 def MakeFilling(self, theShape, theMinDeg, theMaxDeg, theTol2D, theTol3D, theNbIter, isApprox=0):
1214 # Example: see GEOM_TestAll.py
1215 theMinDeg,theMaxDeg,theTol2D,theTol3D,theNbIter,Parameters = ParseParameters(theMinDeg, theMaxDeg,
1216 theTol2D, theTol3D, theNbIter)
1217 anObj = self.PrimOp.MakeFilling(theShape, theMinDeg, theMaxDeg,
1218 theTol2D, theTol3D, theNbIter, isApprox)
1219 RaiseIfFailed("MakeFilling", self.PrimOp)
1220 anObj.SetParameters(Parameters)
1223 ## Create a shell or solid passing through set of sections.Sections should be wires,edges or vertices.
1224 # @param theSeqSections - set of specified sections.
1225 # @param theModeSolid - mode defining building solid or shell
1226 # @param thePreci - precision 3D used for smoothing by default 1.e-6
1227 # @param theRuled - mode defining type of the result surfaces (ruled or smoothed).
1228 # @return New GEOM_Object, containing the created shell or solid.
1230 # @ref swig_todo "Example"
1231 def MakeThruSections(self,theSeqSections,theModeSolid,thePreci,theRuled):
1232 # Example: see GEOM_TestAll.py
1233 anObj = self.PrimOp.MakeThruSections(theSeqSections,theModeSolid,thePreci,theRuled)
1234 RaiseIfFailed("MakeThruSections", self.PrimOp)
1237 ## Create a shape by extrusion of the base shape along
1238 # the path shape. The path shape can be a wire or an edge.
1239 # @param theBase Base shape to be extruded.
1240 # @param thePath Path shape to extrude the base shape along it.
1241 # @return New GEOM_Object, containing the created pipe.
1243 # @ref tui_creation_pipe "Example"
1244 def MakePipe(self,theBase, thePath):
1245 # Example: see GEOM_TestAll.py
1246 anObj = self.PrimOp.MakePipe(theBase, thePath)
1247 RaiseIfFailed("MakePipe", self.PrimOp)
1250 ## Create a shape by extrusion of the profile shape along
1251 # the path shape. The path shape can be a wire or an edge.
1252 # the several profiles can be specified in the several locations of path.
1253 # @param theSeqBases - list of Bases shape to be extruded.
1254 # @param theLocations - list of locations on the path corresponding
1255 # specified list of the Bases shapes. Number of locations
1256 # should be equal to number of bases or list of locations can be empty.
1257 # @param thePath - Path shape to extrude the base shape along it.
1258 # @param theWithContact - the mode defining that the section is translated to be in
1259 # contact with the spine.
1260 # @param theWithCorrection - defining that the section is rotated to be
1261 # orthogonal to the spine tangent in the correspondent point
1262 # @return New GEOM_Object, containing the created pipe.
1264 # @ref tui_creation_pipe_with_diff_sec "Example"
1265 def MakePipeWithDifferentSections(self, theSeqBases,
1266 theLocations, thePath,
1267 theWithContact, theWithCorrection):
1268 anObj = self.PrimOp.MakePipeWithDifferentSections(theSeqBases,
1269 theLocations, thePath,
1270 theWithContact, theWithCorrection)
1271 RaiseIfFailed("MakePipeWithDifferentSections", self.PrimOp)
1274 ## Create a shape by extrusion of the profile shape along
1275 # the path shape. The path shape can be a wire or a edge.
1276 # the several profiles can be specified in the several locations of path.
1277 # @param theSeqBases - list of Bases shape to be extruded. Base shape must be
1278 # shell or face. If number of faces in neighbour sections
1279 # aren't coincided result solid between such sections will
1280 # be created using external boundaries of this shells.
1281 # @param theSeqSubBases - list of corresponding subshapes of section shapes.
1282 # This list is used for searching correspondences between
1283 # faces in the sections. Size of this list must be equal
1284 # to size of list of base shapes.
1285 # @param theLocations - list of locations on the path corresponding
1286 # specified list of the Bases shapes. Number of locations
1287 # should be equal to number of bases. First and last
1288 # locations must be coincided with first and last vertexes
1289 # of path correspondingly.
1290 # @param thePath - Path shape to extrude the base shape along it.
1291 # @param theWithContact - the mode defining that the section is translated to be in
1292 # contact with the spine.
1293 # @param theWithCorrection - defining that the section is rotated to be
1294 # orthogonal to the spine tangent in the correspondent point
1295 # @return New GEOM_Object, containing the created solids.
1297 # @ref tui_creation_pipe_with_shell_sec "Example"
1298 def MakePipeWithShellSections(self,theSeqBases, theSeqSubBases,
1299 theLocations, thePath,
1300 theWithContact, theWithCorrection):
1301 anObj = self.PrimOp.MakePipeWithShellSections(theSeqBases, theSeqSubBases,
1302 theLocations, thePath,
1303 theWithContact, theWithCorrection)
1304 RaiseIfFailed("MakePipeWithShellSections", self.PrimOp)
1307 ## Create a shape by extrusion of the profile shape along
1308 # the path shape. This function is used only for debug pipe
1309 # functionality - it is a version of previous function
1310 # (MakePipeWithShellSections(...)) which give a possibility to
1311 # recieve information about creating pipe between each pair of
1312 # sections step by step.
1313 def MakePipeWithShellSectionsBySteps(self, theSeqBases, theSeqSubBases,
1314 theLocations, thePath,
1315 theWithContact, theWithCorrection):
1317 nbsect = len(theSeqBases)
1318 nbsubsect = len(theSeqSubBases)
1319 #print "nbsect = ",nbsect
1320 for i in range(1,nbsect):
1322 tmpSeqBases = [ theSeqBases[i-1], theSeqBases[i] ]
1323 tmpLocations = [ theLocations[i-1], theLocations[i] ]
1325 if nbsubsect>0: tmpSeqSubBases = [ theSeqSubBases[i-1], theSeqSubBases[i] ]
1326 anObj = self.PrimOp.MakePipeWithShellSections(tmpSeqBases, tmpSeqSubBases,
1327 tmpLocations, thePath,
1328 theWithContact, theWithCorrection)
1329 if self.PrimOp.IsDone() == 0:
1330 print "Problems with pipe creation between ",i," and ",i+1," sections"
1331 RaiseIfFailed("MakePipeWithShellSections", self.PrimOp)
1334 print "Pipe between ",i," and ",i+1," sections is OK"
1339 resc = self.MakeCompound(res)
1340 #resc = self.MakeSewing(res, 0.001)
1341 #print "resc: ",resc
1344 ## Create solids between given sections
1345 # @param theSeqBases - list of sections (shell or face).
1346 # @param theLocations - list of corresponding vertexes
1347 # @return New GEOM_Object, containing the created solids.
1349 # @ref tui_creation_pipe_without_path "Example"
1350 def MakePipeShellsWithoutPath(self, theSeqBases, theLocations):
1351 anObj = self.PrimOp.MakePipeShellsWithoutPath(theSeqBases, theLocations)
1352 RaiseIfFailed("MakePipeShellsWithoutPath", self.PrimOp)
1355 ## Create a shape by extrusion of the base shape along
1356 # the path shape with constant bi-normal direction along the given vector.
1357 # The path shape can be a wire or an edge.
1358 # @param theBase Base shape to be extruded.
1359 # @param thePath Path shape to extrude the base shape along it.
1360 # @param theVec Vector defines a constant binormal direction to keep the
1361 # same angle beetween the direction and the sections
1362 # along the sweep surface.
1363 # @return New GEOM_Object, containing the created pipe.
1365 # @ref tui_creation_pipe "Example"
1366 def MakePipeBiNormalAlongVector(self,theBase, thePath, theVec):
1367 # Example: see GEOM_TestAll.py
1368 anObj = self.PrimOp.MakePipeBiNormalAlongVector(theBase, thePath, theVec)
1369 RaiseIfFailed("MakePipeBiNormalAlongVector", self.PrimOp)
1375 ## @addtogroup l3_advanced
1378 ## Create a linear edge with specified ends.
1379 # @param thePnt1 Point for the first end of edge.
1380 # @param thePnt2 Point for the second end of edge.
1381 # @return New GEOM_Object, containing the created edge.
1383 # @ref tui_creation_edge "Example"
1384 def MakeEdge(self,thePnt1, thePnt2):
1385 # Example: see GEOM_TestAll.py
1386 anObj = self.ShapesOp.MakeEdge(thePnt1, thePnt2)
1387 RaiseIfFailed("MakeEdge", self.ShapesOp)
1390 ## Create a wire from the set of edges and wires.
1391 # @param theEdgesAndWires List of edges and/or wires.
1392 # @param theTolerance Maximum distance between vertices, that will be merged.
1393 # Values less than 1e-07 are equivalent to 1e-07 (Precision::Confusion()).
1394 # @return New GEOM_Object, containing the created wire.
1396 # @ref tui_creation_wire "Example"
1397 def MakeWire(self, theEdgesAndWires, theTolerance = 1e-07):
1398 # Example: see GEOM_TestAll.py
1399 anObj = self.ShapesOp.MakeWire(theEdgesAndWires, theTolerance)
1400 RaiseIfFailed("MakeWire", self.ShapesOp)
1403 ## Create a face on the given wire.
1404 # @param theWire closed Wire or Edge to build the face on.
1405 # @param isPlanarWanted If TRUE, only planar face will be built.
1406 # If impossible, NULL object will be returned.
1407 # @return New GEOM_Object, containing the created face.
1409 # @ref tui_creation_face "Example"
1410 def MakeFace(self,theWire, isPlanarWanted):
1411 # Example: see GEOM_TestAll.py
1412 anObj = self.ShapesOp.MakeFace(theWire, isPlanarWanted)
1413 RaiseIfFailed("MakeFace", self.ShapesOp)
1416 ## Create a face on the given wires set.
1417 # @param theWires List of closed wires or edges to build the face on.
1418 # @param isPlanarWanted If TRUE, only planar face will be built.
1419 # If impossible, NULL object will be returned.
1420 # @return New GEOM_Object, containing the created face.
1422 # @ref tui_creation_face "Example"
1423 def MakeFaceWires(self,theWires, isPlanarWanted):
1424 # Example: see GEOM_TestAll.py
1425 anObj = self.ShapesOp.MakeFaceWires(theWires, isPlanarWanted)
1426 RaiseIfFailed("MakeFaceWires", self.ShapesOp)
1429 ## Shortcut to MakeFaceWires()
1431 # @ref tui_creation_face "Example 1"
1432 # \n @ref swig_MakeFaces "Example 2"
1433 def MakeFaces(self,theWires, isPlanarWanted):
1434 # Example: see GEOM_TestOthers.py
1435 anObj = self.MakeFaceWires(theWires, isPlanarWanted)
1438 ## Create a shell from the set of faces and shells.
1439 # @param theFacesAndShells List of faces and/or shells.
1440 # @return New GEOM_Object, containing the created shell.
1442 # @ref tui_creation_shell "Example"
1443 def MakeShell(self,theFacesAndShells):
1444 # Example: see GEOM_TestAll.py
1445 anObj = self.ShapesOp.MakeShell(theFacesAndShells)
1446 RaiseIfFailed("MakeShell", self.ShapesOp)
1449 ## Create a solid, bounded by the given shells.
1450 # @param theShells Sequence of bounding shells.
1451 # @return New GEOM_Object, containing the created solid.
1453 # @ref tui_creation_solid "Example"
1454 def MakeSolid(self,theShells):
1455 # Example: see GEOM_TestAll.py
1456 anObj = self.ShapesOp.MakeSolidShells(theShells)
1457 RaiseIfFailed("MakeSolidShells", self.ShapesOp)
1460 ## Create a compound of the given shapes.
1461 # @param theShapes List of shapes to put in compound.
1462 # @return New GEOM_Object, containing the created compound.
1464 # @ref tui_creation_compound "Example"
1465 def MakeCompound(self,theShapes):
1466 # Example: see GEOM_TestAll.py
1467 anObj = self.ShapesOp.MakeCompound(theShapes)
1468 RaiseIfFailed("MakeCompound", self.ShapesOp)
1471 # end of l3_advanced
1474 ## @addtogroup l2_measure
1477 ## Gives quantity of faces in the given shape.
1478 # @param theShape Shape to count faces of.
1479 # @return Quantity of faces.
1481 # @ref swig_NumberOf "Example"
1482 def NumberOfFaces(self, theShape):
1483 # Example: see GEOM_TestOthers.py
1484 nb_faces = self.ShapesOp.NumberOfFaces(theShape)
1485 RaiseIfFailed("NumberOfFaces", self.ShapesOp)
1488 ## Gives quantity of edges in the given shape.
1489 # @param theShape Shape to count edges of.
1490 # @return Quantity of edges.
1492 # @ref swig_NumberOf "Example"
1493 def NumberOfEdges(self, theShape):
1494 # Example: see GEOM_TestOthers.py
1495 nb_edges = self.ShapesOp.NumberOfEdges(theShape)
1496 RaiseIfFailed("NumberOfEdges", self.ShapesOp)
1499 ## Gives quantity of subshapes of type theShapeType in the given shape.
1500 # @param theShape Shape to count subshapes of.
1501 # @param theShapeType Type of subshapes to count.
1502 # @return Quantity of subshapes of given type.
1504 # @ref swig_NumberOf "Example"
1505 def NumberOfSubShapes(self, theShape, theShapeType):
1506 # Example: see GEOM_TestOthers.py
1507 nb_ss = self.ShapesOp.NumberOfSubShapes(theShape, theShapeType)
1508 RaiseIfFailed("NumberOfSubShapes", self.ShapesOp)
1511 ## Gives quantity of solids in the given shape.
1512 # @param theShape Shape to count solids in.
1513 # @return Quantity of solids.
1515 # @ref swig_NumberOf "Example"
1516 def NumberOfSolids(self, theShape):
1517 # Example: see GEOM_TestOthers.py
1518 nb_solids = self.ShapesOp.NumberOfSubShapes(theShape, ShapeType["SOLID"])
1519 RaiseIfFailed("NumberOfSolids", self.ShapesOp)
1525 ## @addtogroup l3_healing
1528 ## Reverses an orientation the given shape.
1529 # @param theShape Shape to be reversed.
1530 # @return The reversed copy of theShape.
1532 # @ref swig_ChangeOrientation "Example"
1533 def ChangeOrientation(self,theShape):
1534 # Example: see GEOM_TestAll.py
1535 anObj = self.ShapesOp.ChangeOrientation(theShape)
1536 RaiseIfFailed("ChangeOrientation", self.ShapesOp)
1539 ## Shortcut to ChangeOrientation()
1541 # @ref swig_OrientationChange "Example"
1542 def OrientationChange(self,theShape):
1543 # Example: see GEOM_TestOthers.py
1544 anObj = self.ChangeOrientation(theShape)
1550 ## @addtogroup l4_obtain
1553 ## Retrieve all free faces from the given shape.
1554 # Free face is a face, which is not shared between two shells of the shape.
1555 # @param theShape Shape to find free faces in.
1556 # @return List of IDs of all free faces, contained in theShape.
1558 # @ref tui_measurement_tools_page "Example"
1559 def GetFreeFacesIDs(self,theShape):
1560 # Example: see GEOM_TestOthers.py
1561 anIDs = self.ShapesOp.GetFreeFacesIDs(theShape)
1562 RaiseIfFailed("GetFreeFacesIDs", self.ShapesOp)
1565 ## Get all sub-shapes of theShape1 of the given type, shared with theShape2.
1566 # @param theShape1 Shape to find sub-shapes in.
1567 # @param theShape2 Shape to find shared sub-shapes with.
1568 # @param theShapeType Type of sub-shapes to be retrieved.
1569 # @return List of sub-shapes of theShape1, shared with theShape2.
1571 # @ref swig_GetSharedShapes "Example"
1572 def GetSharedShapes(self,theShape1, theShape2, theShapeType):
1573 # Example: see GEOM_TestOthers.py
1574 aList = self.ShapesOp.GetSharedShapes(theShape1, theShape2, theShapeType)
1575 RaiseIfFailed("GetSharedShapes", self.ShapesOp)
1578 ## Find in <VAR>theShape</VAR> all sub-shapes of type <VAR>theShapeType</VAR>,
1579 # situated relatively the specified plane by the certain way,
1580 # defined through <VAR>theState</VAR> parameter.
1581 # @param theShape Shape to find sub-shapes of.
1582 # @param theShapeType Type of sub-shapes to be retrieved.
1583 # @param theAx1 Vector (or line, or linear edge), specifying normal
1584 # direction and location of the plane to find shapes on.
1585 # @param theState The state of the subshapes to find. It can be one of
1586 # ST_ON, ST_OUT, ST_ONOUT, ST_IN, ST_ONIN.
1587 # @return List of all found sub-shapes.
1589 # @ref swig_GetShapesOnPlane "Example"
1590 def GetShapesOnPlane(self,theShape, theShapeType, theAx1, theState):
1591 # Example: see GEOM_TestOthers.py
1592 aList = self.ShapesOp.GetShapesOnPlane(theShape, theShapeType, theAx1, theState)
1593 RaiseIfFailed("GetShapesOnPlane", self.ShapesOp)
1596 ## Works like the above method, but returns list of sub-shapes indices
1598 # @ref swig_GetShapesOnPlaneIDs "Example"
1599 def GetShapesOnPlaneIDs(self,theShape, theShapeType, theAx1, theState):
1600 # Example: see GEOM_TestOthers.py
1601 aList = self.ShapesOp.GetShapesOnPlaneIDs(theShape, theShapeType, theAx1, theState)
1602 RaiseIfFailed("GetShapesOnPlaneIDs", self.ShapesOp)
1605 ## Find in <VAR>theShape</VAR> all sub-shapes of type <VAR>theShapeType</VAR>,
1606 # situated relatively the specified plane by the certain way,
1607 # defined through <VAR>theState</VAR> parameter.
1608 # @param theShape Shape to find sub-shapes of.
1609 # @param theShapeType Type of sub-shapes to be retrieved.
1610 # @param theAx1 Vector (or line, or linear edge), specifying normal
1611 # direction of the plane to find shapes on.
1612 # @param thePnt Point specifying location of the plane to find shapes on.
1613 # @param theState The state of the subshapes to find. It can be one of
1614 # ST_ON, ST_OUT, ST_ONOUT, ST_IN, ST_ONIN.
1615 # @return List of all found sub-shapes.
1617 # @ref swig_GetShapesOnPlaneWithLocation "Example"
1618 def GetShapesOnPlaneWithLocation(self, theShape, theShapeType, theAx1, thePnt, theState):
1619 # Example: see GEOM_TestOthers.py
1620 aList = self.ShapesOp.GetShapesOnPlaneWithLocation(theShape, theShapeType,
1621 theAx1, thePnt, theState)
1622 RaiseIfFailed("GetShapesOnPlaneWithLocation", self.ShapesOp)
1625 ## Works like the above method, but returns list of sub-shapes indices
1627 # @ref swig_GetShapesOnPlaneWithLocationIDs "Example"
1628 def GetShapesOnPlaneWithLocationIDs(self, theShape, theShapeType, theAx1, thePnt, theState):
1629 # Example: see GEOM_TestOthers.py
1630 aList = self.ShapesOp.GetShapesOnPlaneWithLocationIDs(theShape, theShapeType,
1631 theAx1, thePnt, theState)
1632 RaiseIfFailed("GetShapesOnPlaneWithLocationIDs", self.ShapesOp)
1635 ## Find in \a theShape all sub-shapes of type \a theShapeType, situated relatively
1636 # the specified cylinder by the certain way, defined through \a theState parameter.
1637 # @param theShape Shape to find sub-shapes of.
1638 # @param theShapeType Type of sub-shapes to be retrieved.
1639 # @param theAxis Vector (or line, or linear edge), specifying
1640 # axis of the cylinder to find shapes on.
1641 # @param theRadius Radius of the cylinder to find shapes on.
1642 # @param theState The state of the subshapes to find. It can be one of
1643 # ST_ON, ST_OUT, ST_ONOUT, ST_IN, ST_ONIN.
1644 # @return List of all found sub-shapes.
1646 # @ref swig_GetShapesOnCylinder "Example"
1647 def GetShapesOnCylinder(self, theShape, theShapeType, theAxis, theRadius, theState):
1648 # Example: see GEOM_TestOthers.py
1649 aList = self.ShapesOp.GetShapesOnCylinder(theShape, theShapeType, theAxis, theRadius, theState)
1650 RaiseIfFailed("GetShapesOnCylinder", self.ShapesOp)
1653 ## Works like the above method, but returns list of sub-shapes indices
1655 # @ref swig_GetShapesOnCylinderIDs "Example"
1656 def GetShapesOnCylinderIDs(self, theShape, theShapeType, theAxis, theRadius, theState):
1657 # Example: see GEOM_TestOthers.py
1658 aList = self.ShapesOp.GetShapesOnCylinderIDs(theShape, theShapeType, theAxis, theRadius, theState)
1659 RaiseIfFailed("GetShapesOnCylinderIDs", self.ShapesOp)
1662 ## Find in \a theShape all sub-shapes of type \a theShapeType, situated relatively
1663 # the specified sphere by the certain way, defined through \a theState parameter.
1664 # @param theShape Shape to find sub-shapes of.
1665 # @param theShapeType Type of sub-shapes to be retrieved.
1666 # @param theCenter Point, specifying center of the sphere to find shapes on.
1667 # @param theRadius Radius of the sphere to find shapes on.
1668 # @param theState The state of the subshapes to find. It can be one of
1669 # ST_ON, ST_OUT, ST_ONOUT, ST_IN, ST_ONIN.
1670 # @return List of all found sub-shapes.
1672 # @ref swig_GetShapesOnSphere "Example"
1673 def GetShapesOnSphere(self,theShape, theShapeType, theCenter, theRadius, theState):
1674 # Example: see GEOM_TestOthers.py
1675 aList = self.ShapesOp.GetShapesOnSphere(theShape, theShapeType, theCenter, theRadius, theState)
1676 RaiseIfFailed("GetShapesOnSphere", self.ShapesOp)
1679 ## Works like the above method, but returns list of sub-shapes indices
1681 # @ref swig_GetShapesOnSphereIDs "Example"
1682 def GetShapesOnSphereIDs(self,theShape, theShapeType, theCenter, theRadius, theState):
1683 # Example: see GEOM_TestOthers.py
1684 aList = self.ShapesOp.GetShapesOnSphereIDs(theShape, theShapeType, theCenter, theRadius, theState)
1685 RaiseIfFailed("GetShapesOnSphereIDs", self.ShapesOp)
1688 ## Find in \a theShape all sub-shapes of type \a theShapeType, situated relatively
1689 # the specified quadrangle by the certain way, defined through \a theState parameter.
1690 # @param theShape Shape to find sub-shapes of.
1691 # @param theShapeType Type of sub-shapes to be retrieved.
1692 # @param theTopLeftPoint Point, specifying top left corner of a quadrangle
1693 # @param theTopRigthPoint Point, specifying top right corner of a quadrangle
1694 # @param theBottomLeftPoint Point, specifying bottom left corner of a quadrangle
1695 # @param theBottomRigthPoint Point, specifying bottom right corner of a quadrangle
1696 # @param theState The state of the subshapes to find. It can be one of
1697 # ST_ON, ST_OUT, ST_ONOUT, ST_IN, ST_ONIN.
1698 # @return List of all found sub-shapes.
1700 # @ref swig_GetShapesOnQuadrangle "Example"
1701 def GetShapesOnQuadrangle(self, theShape, theShapeType,
1702 theTopLeftPoint, theTopRigthPoint,
1703 theBottomLeftPoint, theBottomRigthPoint, theState):
1704 # Example: see GEOM_TestOthers.py
1705 aList = self.ShapesOp.GetShapesOnQuadrangle(theShape, theShapeType,
1706 theTopLeftPoint, theTopRigthPoint,
1707 theBottomLeftPoint, theBottomRigthPoint, theState)
1708 RaiseIfFailed("GetShapesOnQuadrangle", self.ShapesOp)
1711 ## Works like the above method, but returns list of sub-shapes indices
1713 # @ref swig_GetShapesOnQuadrangleIDs "Example"
1714 def GetShapesOnQuadrangleIDs(self, theShape, theShapeType,
1715 theTopLeftPoint, theTopRigthPoint,
1716 theBottomLeftPoint, theBottomRigthPoint, theState):
1717 # Example: see GEOM_TestOthers.py
1718 aList = self.ShapesOp.GetShapesOnQuadrangleIDs(theShape, theShapeType,
1719 theTopLeftPoint, theTopRigthPoint,
1720 theBottomLeftPoint, theBottomRigthPoint, theState)
1721 RaiseIfFailed("GetShapesOnQuadrangleIDs", self.ShapesOp)
1724 ## Find in \a theShape all sub-shapes of type \a theShapeType, situated relatively
1725 # the specified \a theBox by the certain way, defined through \a theState parameter.
1726 # @param theBox Shape for relative comparing.
1727 # @param theShape Shape to find sub-shapes of.
1728 # @param theShapeType Type of sub-shapes to be retrieved.
1729 # @param theState The state of the subshapes to find. It can be one of
1730 # ST_ON, ST_OUT, ST_ONOUT, ST_IN, ST_ONIN.
1731 # @return List of all found sub-shapes.
1733 # @ref swig_GetShapesOnBox "Example"
1734 def GetShapesOnBox(self, theBox, theShape, theShapeType, theState):
1735 # Example: see GEOM_TestOthers.py
1736 aList = self.ShapesOp.GetShapesOnBox(theBox, theShape, theShapeType, theState)
1737 RaiseIfFailed("GetShapesOnBox", self.ShapesOp)
1740 ## Works like the above method, but returns list of sub-shapes indices
1742 # @ref swig_GetShapesOnBoxIDs "Example"
1743 def GetShapesOnBoxIDs(self, theBox, theShape, theShapeType, theState):
1744 # Example: see GEOM_TestOthers.py
1745 aList = self.ShapesOp.GetShapesOnBoxIDs(theBox, theShape, theShapeType, theState)
1746 RaiseIfFailed("GetShapesOnBoxIDs", self.ShapesOp)
1749 ## Find in \a theShape all sub-shapes of type \a theShapeType,
1750 # situated relatively the specified \a theCheckShape by the
1751 # certain way, defined through \a theState parameter.
1752 # @param theCheckShape Shape for relative comparing.
1753 # @param theShape Shape to find sub-shapes of.
1754 # @param theShapeType Type of sub-shapes to be retrieved.
1755 # @param theState The state of the subshapes to find. It can be one of
1756 # ST_ON, ST_OUT, ST_ONOUT, ST_IN, ST_ONIN.
1757 # @return List of all found sub-shapes.
1759 # @ref swig_GetShapesOnShape "Example"
1760 def GetShapesOnShape(self, theCheckShape, theShape, theShapeType, theState):
1761 # Example: see GEOM_TestOthers.py
1762 aList = self.ShapesOp.GetShapesOnShape(theCheckShape, theShape,
1763 theShapeType, theState)
1764 RaiseIfFailed("GetShapesOnShape", self.ShapesOp)
1767 ## Works like the above method, but returns result as compound
1769 # @ref swig_GetShapesOnShapeAsCompound "Example"
1770 def GetShapesOnShapeAsCompound(self, theCheckShape, theShape, theShapeType, theState):
1771 # Example: see GEOM_TestOthers.py
1772 anObj = self.ShapesOp.GetShapesOnShapeAsCompound(theCheckShape, theShape,
1773 theShapeType, theState)
1774 RaiseIfFailed("GetShapesOnShapeAsCompound", self.ShapesOp)
1777 ## Works like the above method, but returns list of sub-shapes indices
1779 # @ref swig_GetShapesOnShapeIDs "Example"
1780 def GetShapesOnShapeIDs(self, theCheckShape, theShape, theShapeType, theState):
1781 # Example: see GEOM_TestOthers.py
1782 aList = self.ShapesOp.GetShapesOnShapeIDs(theCheckShape, theShape,
1783 theShapeType, theState)
1784 RaiseIfFailed("GetShapesOnShapeIDs", self.ShapesOp)
1787 ## Get sub-shape(s) of theShapeWhere, which are
1788 # coincident with \a theShapeWhat or could be a part of it.
1789 # @param theShapeWhere Shape to find sub-shapes of.
1790 # @param theShapeWhat Shape, specifying what to find.
1791 # @return Group of all found sub-shapes or a single found sub-shape.
1793 # @ref swig_GetInPlace "Example"
1794 def GetInPlace(self,theShapeWhere, theShapeWhat):
1795 # Example: see GEOM_TestOthers.py
1796 anObj = self.ShapesOp.GetInPlace(theShapeWhere, theShapeWhat)
1797 RaiseIfFailed("GetInPlace", self.ShapesOp)
1800 ## Get sub-shape(s) of \a theShapeWhere, which are
1801 # coincident with \a theShapeWhat or could be a part of it.
1803 # Implementation of this method is based on a saved history of an operation,
1804 # produced \a theShapeWhere. The \a theShapeWhat must be among this operation's
1805 # arguments (an argument shape or a sub-shape of an argument shape).
1806 # The operation could be the Partition or one of boolean operations,
1807 # performed on simple shapes (not on compounds).
1809 # @param theShapeWhere Shape to find sub-shapes of.
1810 # @param theShapeWhat Shape, specifying what to find (must be in the
1811 # building history of the ShapeWhere).
1812 # @return Group of all found sub-shapes or a single found sub-shape.
1814 # @ref swig_GetInPlace "Example"
1815 def GetInPlaceByHistory(self, theShapeWhere, theShapeWhat):
1816 # Example: see GEOM_TestOthers.py
1817 anObj = self.ShapesOp.GetInPlaceByHistory(theShapeWhere, theShapeWhat)
1818 RaiseIfFailed("GetInPlaceByHistory", self.ShapesOp)
1821 ## Get sub-shape of theShapeWhere, which is
1822 # equal to \a theShapeWhat.
1823 # @param theShapeWhere Shape to find sub-shape of.
1824 # @param theShapeWhat Shape, specifying what to find.
1825 # @return New GEOM_Object for found sub-shape.
1827 # @ref swig_GetSame "Example"
1828 def GetSame(self,theShapeWhere, theShapeWhat):
1829 anObj = self.ShapesOp.GetSame(theShapeWhere, theShapeWhat)
1830 RaiseIfFailed("GetSame", self.ShapesOp)
1836 ## @addtogroup l4_access
1839 ## Obtain a composite sub-shape of <VAR>aShape</VAR>, composed from sub-shapes
1840 # of aShape, selected by their unique IDs inside <VAR>aShape</VAR>
1842 # @ref swig_all_decompose "Example"
1843 def GetSubShape(self, aShape, ListOfID):
1844 # Example: see GEOM_TestAll.py
1845 anObj = self.AddSubShape(aShape,ListOfID)
1848 ## Obtain unique ID of sub-shape <VAR>aSubShape</VAR> inside <VAR>aShape</VAR>
1850 # @ref swig_all_decompose "Example"
1851 def GetSubShapeID(self, aShape, aSubShape):
1852 # Example: see GEOM_TestAll.py
1853 anID = self.LocalOp.GetSubShapeIndex(aShape, aSubShape)
1854 RaiseIfFailed("GetSubShapeIndex", self.LocalOp)
1860 ## @addtogroup l4_decompose
1863 ## Explode a shape on subshapes of a given type.
1864 # @param aShape Shape to be exploded.
1865 # @param aType Type of sub-shapes to be retrieved.
1866 # @return List of sub-shapes of type theShapeType, contained in theShape.
1868 # @ref swig_all_decompose "Example"
1869 def SubShapeAll(self, aShape, aType):
1870 # Example: see GEOM_TestAll.py
1871 ListObj = self.ShapesOp.MakeExplode(aShape,aType,0)
1872 RaiseIfFailed("MakeExplode", self.ShapesOp)
1875 ## Explode a shape on subshapes of a given type.
1876 # @param aShape Shape to be exploded.
1877 # @param aType Type of sub-shapes to be retrieved.
1878 # @return List of IDs of sub-shapes.
1880 # @ref swig_all_decompose "Example"
1881 def SubShapeAllIDs(self, aShape, aType):
1882 ListObj = self.ShapesOp.SubShapeAllIDs(aShape,aType,0)
1883 RaiseIfFailed("SubShapeAllIDs", self.ShapesOp)
1886 ## Explode a shape on subshapes of a given type.
1887 # Sub-shapes will be sorted by coordinates of their gravity centers.
1888 # @param aShape Shape to be exploded.
1889 # @param aType Type of sub-shapes to be retrieved.
1890 # @return List of sub-shapes of type theShapeType, contained in theShape.
1892 # @ref swig_SubShapeAllSorted "Example"
1893 def SubShapeAllSorted(self, aShape, aType):
1894 # Example: see GEOM_TestAll.py
1895 ListObj = self.ShapesOp.MakeExplode(aShape,aType,1)
1896 RaiseIfFailed("MakeExplode", self.ShapesOp)
1899 ## Explode a shape on subshapes of a given type.
1900 # Sub-shapes will be sorted by coordinates of their gravity centers.
1901 # @param aShape Shape to be exploded.
1902 # @param aType Type of sub-shapes to be retrieved.
1903 # @return List of IDs of sub-shapes.
1905 # @ref swig_all_decompose "Example"
1906 def SubShapeAllSortedIDs(self, aShape, aType):
1907 ListIDs = self.ShapesOp.SubShapeAllIDs(aShape,aType,1)
1908 RaiseIfFailed("SubShapeAllIDs", self.ShapesOp)
1911 ## Obtain a compound of sub-shapes of <VAR>aShape</VAR>,
1912 # selected by they indices in list of all sub-shapes of type <VAR>aType</VAR>.
1913 # Each index is in range [1, Nb_Sub-Shapes_Of_Given_Type]
1915 # @ref swig_all_decompose "Example"
1916 def SubShape(self, aShape, aType, ListOfInd):
1917 # Example: see GEOM_TestAll.py
1919 AllShapeList = self.SubShapeAll(aShape, aType)
1920 for ind in ListOfInd:
1921 ListOfIDs.append(self.GetSubShapeID(aShape, AllShapeList[ind - 1]))
1922 anObj = self.GetSubShape(aShape, ListOfIDs)
1925 ## Obtain a compound of sub-shapes of <VAR>aShape</VAR>,
1926 # selected by they indices in sorted list of all sub-shapes of type <VAR>aType</VAR>.
1927 # Each index is in range [1, Nb_Sub-Shapes_Of_Given_Type]
1929 # @ref swig_all_decompose "Example"
1930 def SubShapeSorted(self,aShape, aType, ListOfInd):
1931 # Example: see GEOM_TestAll.py
1933 AllShapeList = self.SubShapeAllSorted(aShape, aType)
1934 for ind in ListOfInd:
1935 ListOfIDs.append(self.GetSubShapeID(aShape, AllShapeList[ind - 1]))
1936 anObj = self.GetSubShape(aShape, ListOfIDs)
1939 # end of l4_decompose
1942 ## @addtogroup l3_healing
1945 ## Apply a sequence of Shape Healing operators to the given object.
1946 # @param theShape Shape to be processed.
1947 # @param theOperators List of names of operators ("FixShape", "SplitClosedFaces", etc.).
1948 # @param theParameters List of names of parameters
1949 # ("FixShape.Tolerance3d", "SplitClosedFaces.NbSplitPoints", etc.).
1950 # @param theValues List of values of parameters, in the same order
1951 # as parameters are listed in <VAR>theParameters</VAR> list.
1952 # @return New GEOM_Object, containing processed shape.
1954 # @ref tui_shape_processing "Example"
1955 def ProcessShape(self,theShape, theOperators, theParameters, theValues):
1956 # Example: see GEOM_TestHealing.py
1957 theValues,Parameters = ParseList(theValues)
1958 anObj = self.HealOp.ProcessShape(theShape, theOperators, theParameters, theValues)
1959 RaiseIfFailed("ProcessShape", self.HealOp)
1960 for string in (theOperators + theParameters):
1961 Parameters = ":" + Parameters
1963 anObj.SetParameters(Parameters)
1966 ## Remove faces from the given object (shape).
1967 # @param theObject Shape to be processed.
1968 # @param theFaces Indices of faces to be removed, if EMPTY then the method
1969 # removes ALL faces of the given object.
1970 # @return New GEOM_Object, containing processed shape.
1972 # @ref tui_suppress_faces "Example"
1973 def SuppressFaces(self,theObject, theFaces):
1974 # Example: see GEOM_TestHealing.py
1975 anObj = self.HealOp.SuppressFaces(theObject, theFaces)
1976 RaiseIfFailed("SuppressFaces", self.HealOp)
1979 ## Sewing of some shapes into single shape.
1981 # @ref tui_sewing "Example"
1982 def MakeSewing(self, ListShape, theTolerance):
1983 # Example: see GEOM_TestHealing.py
1984 comp = self.MakeCompound(ListShape)
1985 anObj = self.Sew(comp, theTolerance)
1988 ## Sewing of the given object.
1989 # @param theObject Shape to be processed.
1990 # @param theTolerance Required tolerance value.
1991 # @return New GEOM_Object, containing processed shape.
1992 def Sew(self, theObject, theTolerance):
1993 # Example: see MakeSewing() above
1994 theTolerance,Parameters = ParseParameters(theTolerance)
1995 anObj = self.HealOp.Sew(theObject, theTolerance)
1996 RaiseIfFailed("Sew", self.HealOp)
1997 anObj.SetParameters(Parameters)
2000 ## Remove internal wires and edges from the given object (face).
2001 # @param theObject Shape to be processed.
2002 # @param theWires Indices of wires to be removed, if EMPTY then the method
2003 # removes ALL internal wires of the given object.
2004 # @return New GEOM_Object, containing processed shape.
2006 # @ref tui_suppress_internal_wires "Example"
2007 def SuppressInternalWires(self,theObject, theWires):
2008 # Example: see GEOM_TestHealing.py
2009 anObj = self.HealOp.RemoveIntWires(theObject, theWires)
2010 RaiseIfFailed("RemoveIntWires", self.HealOp)
2013 ## Remove internal closed contours (holes) from the given object.
2014 # @param theObject Shape to be processed.
2015 # @param theWires Indices of wires to be removed, if EMPTY then the method
2016 # removes ALL internal holes of the given object
2017 # @return New GEOM_Object, containing processed shape.
2019 # @ref tui_suppress_holes "Example"
2020 def SuppressHoles(self,theObject, theWires):
2021 # Example: see GEOM_TestHealing.py
2022 anObj = self.HealOp.FillHoles(theObject, theWires)
2023 RaiseIfFailed("FillHoles", self.HealOp)
2026 ## Close an open wire.
2027 # @param theObject Shape to be processed.
2028 # @param theWires Indexes of edge(s) and wire(s) to be closed within <VAR>theObject</VAR>'s shape,
2029 # if -1, then <VAR>theObject</VAR> itself is a wire.
2030 # @param isCommonVertex If TRUE : closure by creation of a common vertex,
2031 # If FALS : closure by creation of an edge between ends.
2032 # @return New GEOM_Object, containing processed shape.
2034 # @ref tui_close_contour "Example"
2035 def CloseContour(self,theObject, theWires, isCommonVertex):
2036 # Example: see GEOM_TestHealing.py
2037 anObj = self.HealOp.CloseContour(theObject, theWires, isCommonVertex)
2038 RaiseIfFailed("CloseContour", self.HealOp)
2041 ## Addition of a point to a given edge object.
2042 # @param theObject Shape to be processed.
2043 # @param theEdgeIndex Index of edge to be divided within theObject's shape,
2044 # if -1, then theObject itself is the edge.
2045 # @param theValue Value of parameter on edge or length parameter,
2046 # depending on \a isByParameter.
2047 # @param isByParameter If TRUE : \a theValue is treated as a curve parameter [0..1],
2048 # if FALSE : \a theValue is treated as a length parameter [0..1]
2049 # @return New GEOM_Object, containing processed shape.
2051 # @ref tui_add_point_on_edge "Example"
2052 def DivideEdge(self,theObject, theEdgeIndex, theValue, isByParameter):
2053 # Example: see GEOM_TestHealing.py
2054 theEdgeIndex,theValue,isByParameter,Parameters = ParseParameters(theEdgeIndex,theValue,isByParameter)
2055 anObj = self.HealOp.DivideEdge(theObject, theEdgeIndex, theValue, isByParameter)
2056 RaiseIfFailed("DivideEdge", self.HealOp)
2057 anObj.SetParameters(Parameters)
2060 ## Change orientation of the given object. Updates given shape.
2061 # @param theObject Shape to be processed.
2063 # @ref swig_todo "Example"
2064 def ChangeOrientationShell(self,theObject):
2065 theObject = self.HealOp.ChangeOrientation(theObject)
2066 RaiseIfFailed("ChangeOrientation", self.HealOp)
2069 ## Change orientation of the given object.
2070 # @param theObject Shape to be processed.
2071 # @return New GEOM_Object, containing processed shape.
2073 # @ref swig_todo "Example"
2074 def ChangeOrientationShellCopy(self,theObject):
2075 anObj = self.HealOp.ChangeOrientationCopy(theObject)
2076 RaiseIfFailed("ChangeOrientationCopy", self.HealOp)
2079 ## Get a list of wires (wrapped in GEOM_Object-s),
2080 # that constitute a free boundary of the given shape.
2081 # @param theObject Shape to get free boundary of.
2082 # @return [status, theClosedWires, theOpenWires]
2083 # status: FALSE, if an error(s) occured during the method execution.
2084 # theClosedWires: Closed wires on the free boundary of the given shape.
2085 # theOpenWires: Open wires on the free boundary of the given shape.
2087 # @ref tui_measurement_tools_page "Example"
2088 def GetFreeBoundary(self,theObject):
2089 # Example: see GEOM_TestHealing.py
2090 anObj = self.HealOp.GetFreeBoundary(theObject)
2091 RaiseIfFailed("GetFreeBoundary", self.HealOp)
2094 ## Replace coincident faces in theShape by one face.
2095 # @param theShape Initial shape.
2096 # @param theTolerance Maximum distance between faces, which can be considered as coincident.
2097 # @param doKeepNonSolids If FALSE, only solids will present in the result,
2098 # otherwise all initial shapes.
2099 # @return New GEOM_Object, containing a copy of theShape without coincident faces.
2101 # @ref tui_glue_faces "Example"
2102 def MakeGlueFaces(self, theShape, theTolerance, doKeepNonSolids=True):
2103 # Example: see GEOM_Spanner.py
2104 theTolerance,Parameters = ParseParameters(theTolerance)
2105 anObj = self.ShapesOp.MakeGlueFaces(theShape, theTolerance, doKeepNonSolids)
2107 raise RuntimeError, "MakeGlueFaces : " + self.ShapesOp.GetErrorCode()
2108 anObj.SetParameters(Parameters)
2111 ## Find coincident faces in theShape for possible gluing.
2112 # @param theShape Initial shape.
2113 # @param theTolerance Maximum distance between faces,
2114 # which can be considered as coincident.
2117 # @ref swig_todo "Example"
2118 def GetGlueFaces(self, theShape, theTolerance):
2119 # Example: see GEOM_Spanner.py
2120 anObj = self.ShapesOp.GetGlueFaces(theShape, theTolerance)
2121 RaiseIfFailed("GetGlueFaces", self.ShapesOp)
2124 ## Replace coincident faces in theShape by one face
2125 # in compliance with given list of faces
2126 # @param theShape Initial shape.
2127 # @param theTolerance Maximum distance between faces,
2128 # which can be considered as coincident.
2129 # @param theFaces List of faces for gluing.
2130 # @param doKeepNonSolids If FALSE, only solids will present in the result,
2131 # otherwise all initial shapes.
2132 # @return New GEOM_Object, containing a copy of theShape
2133 # without some faces.
2135 # @ref swig_todo "Example"
2136 def MakeGlueFacesByList(self, theShape, theTolerance, theFaces, doKeepNonSolids=True):
2137 # Example: see GEOM_Spanner.py
2138 anObj = self.ShapesOp.MakeGlueFacesByList(theShape, theTolerance, theFaces, doKeepNonSolids)
2140 raise RuntimeError, "MakeGlueFacesByList : " + self.ShapesOp.GetErrorCode()
2146 ## @addtogroup l3_boolean Boolean Operations
2149 # -----------------------------------------------------------------------------
2150 # Boolean (Common, Cut, Fuse, Section)
2151 # -----------------------------------------------------------------------------
2153 ## Perform one of boolean operations on two given shapes.
2154 # @param theShape1 First argument for boolean operation.
2155 # @param theShape2 Second argument for boolean operation.
2156 # @param theOperation Indicates the operation to be done:
2157 # 1 - Common, 2 - Cut, 3 - Fuse, 4 - Section.
2158 # @return New GEOM_Object, containing the result shape.
2160 # @ref tui_fuse "Example"
2161 def MakeBoolean(self,theShape1, theShape2, theOperation):
2162 # Example: see GEOM_TestAll.py
2163 anObj = self.BoolOp.MakeBoolean(theShape1, theShape2, theOperation)
2164 RaiseIfFailed("MakeBoolean", self.BoolOp)
2167 ## Shortcut to MakeBoolean(s1, s2, 1)
2169 # @ref tui_common "Example 1"
2170 # \n @ref swig_MakeCommon "Example 2"
2171 def MakeCommon(self, s1, s2):
2172 # Example: see GEOM_TestOthers.py
2173 return self.MakeBoolean(s1, s2, 1)
2175 ## Shortcut to MakeBoolean(s1, s2, 2)
2177 # @ref tui_cut "Example 1"
2178 # \n @ref swig_MakeCommon "Example 2"
2179 def MakeCut(self, s1, s2):
2180 # Example: see GEOM_TestOthers.py
2181 return self.MakeBoolean(s1, s2, 2)
2183 ## Shortcut to MakeBoolean(s1, s2, 3)
2185 # @ref tui_fuse "Example 1"
2186 # \n @ref swig_MakeCommon "Example 2"
2187 def MakeFuse(self, s1, s2):
2188 # Example: see GEOM_TestOthers.py
2189 return self.MakeBoolean(s1, s2, 3)
2191 ## Shortcut to MakeBoolean(s1, s2, 4)
2193 # @ref tui_section "Example 1"
2194 # \n @ref swig_MakeCommon "Example 2"
2195 def MakeSection(self, s1, s2):
2196 # Example: see GEOM_TestOthers.py
2197 return self.MakeBoolean(s1, s2, 4)
2202 ## @addtogroup l3_basic_op
2205 ## Perform partition operation.
2206 # @param ListShapes Shapes to be intersected.
2207 # @param ListTools Shapes to intersect theShapes.
2208 # !!!NOTE: Each compound from ListShapes and ListTools will be exploded
2209 # in order to avoid possible intersection between shapes from
2211 # @param Limit Type of resulting shapes (corresponding to TopAbs_ShapeEnum).
2212 # @param KeepNonlimitShapes: if this parameter == 0 - only shapes with
2213 # type <= Limit are kept in the result,
2214 # else - shapes with type > Limit are kept
2215 # also (if they exist)
2217 # After implementation new version of PartitionAlgo (October 2006)
2218 # other parameters are ignored by current functionality. They are kept
2219 # in this function only for support old versions.
2220 # Ignored parameters:
2221 # @param ListKeepInside Shapes, outside which the results will be deleted.
2222 # Each shape from theKeepInside must belong to theShapes also.
2223 # @param ListRemoveInside Shapes, inside which the results will be deleted.
2224 # Each shape from theRemoveInside must belong to theShapes also.
2225 # @param RemoveWebs If TRUE, perform Glue 3D algorithm.
2226 # @param ListMaterials Material indices for each shape. Make sence,
2227 # only if theRemoveWebs is TRUE.
2229 # @return New GEOM_Object, containing the result shapes.
2231 # @ref tui_partition "Example"
2232 def MakePartition(self, ListShapes, ListTools=[], ListKeepInside=[], ListRemoveInside=[],
2233 Limit=ShapeType["SHAPE"], RemoveWebs=0, ListMaterials=[],
2234 KeepNonlimitShapes=0):
2235 # Example: see GEOM_TestAll.py
2236 anObj = self.BoolOp.MakePartition(ListShapes, ListTools,
2237 ListKeepInside, ListRemoveInside,
2238 Limit, RemoveWebs, ListMaterials,
2239 KeepNonlimitShapes);
2240 RaiseIfFailed("MakePartition", self.BoolOp)
2243 ## Perform partition operation.
2244 # This method may be useful if it is needed to make a partition for
2245 # compound contains nonintersected shapes. Performance will be better
2246 # since intersection between shapes from compound is not performed.
2248 # Description of all parameters as in previous method MakePartition()
2250 # !!!NOTE: Passed compounds (via ListShapes or via ListTools)
2251 # have to consist of nonintersecting shapes.
2253 # @return New GEOM_Object, containing the result shapes.
2255 # @ref swig_todo "Example"
2256 def MakePartitionNonSelfIntersectedShape(self, ListShapes, ListTools=[],
2257 ListKeepInside=[], ListRemoveInside=[],
2258 Limit=ShapeType["SHAPE"], RemoveWebs=0,
2259 ListMaterials=[], KeepNonlimitShapes=0):
2260 anObj = self.BoolOp.MakePartitionNonSelfIntersectedShape(ListShapes, ListTools,
2261 ListKeepInside, ListRemoveInside,
2262 Limit, RemoveWebs, ListMaterials,
2263 KeepNonlimitShapes);
2264 RaiseIfFailed("MakePartitionNonSelfIntersectedShape", self.BoolOp)
2267 ## Shortcut to MakePartition()
2269 # @ref tui_partition "Example 1"
2270 # \n @ref swig_Partition "Example 2"
2271 def Partition(self, ListShapes, ListTools=[], ListKeepInside=[], ListRemoveInside=[],
2272 Limit=ShapeType["SHAPE"], RemoveWebs=0, ListMaterials=[],
2273 KeepNonlimitShapes=0):
2274 # Example: see GEOM_TestOthers.py
2275 anObj = self.MakePartition(ListShapes, ListTools,
2276 ListKeepInside, ListRemoveInside,
2277 Limit, RemoveWebs, ListMaterials,
2278 KeepNonlimitShapes);
2281 ## Perform partition of the Shape with the Plane
2282 # @param theShape Shape to be intersected.
2283 # @param thePlane Tool shape, to intersect theShape.
2284 # @return New GEOM_Object, containing the result shape.
2286 # @ref tui_partition "Example"
2287 def MakeHalfPartition(self,theShape, thePlane):
2288 # Example: see GEOM_TestAll.py
2289 anObj = self.BoolOp.MakeHalfPartition(theShape, thePlane)
2290 RaiseIfFailed("MakeHalfPartition", self.BoolOp)
2293 # end of l3_basic_op
2296 ## @addtogroup l3_transform
2299 ## Translate the given object along the vector, specified
2300 # by its end points, creating its copy before the translation.
2301 # @param theObject The object to be translated.
2302 # @param thePoint1 Start point of translation vector.
2303 # @param thePoint2 End point of translation vector.
2304 # @return New GEOM_Object, containing the translated object.
2306 # @ref tui_translation "Example 1"
2307 # \n @ref swig_MakeTranslationTwoPoints "Example 2"
2308 def MakeTranslationTwoPoints(self,theObject, thePoint1, thePoint2):
2309 # Example: see GEOM_TestAll.py
2310 anObj = self.TrsfOp.TranslateTwoPointsCopy(theObject, thePoint1, thePoint2)
2311 RaiseIfFailed("TranslateTwoPointsCopy", self.TrsfOp)
2314 ## Translate the given object along the vector, specified by its components.
2315 # @param theObject The object to be translated.
2316 # @param theDX,theDY,theDZ Components of translation vector.
2317 # @return Translated GEOM_Object.
2319 # @ref tui_translation "Example"
2320 def TranslateDXDYDZ(self,theObject, theDX, theDY, theDZ):
2321 # Example: see GEOM_TestAll.py
2322 theDX, theDY, theDZ, Parameters = ParseParameters(theDX, theDY, theDZ)
2323 anObj = self.TrsfOp.TranslateDXDYDZ(theObject, theDX, theDY, theDZ)
2324 anObj.SetParameters(Parameters)
2325 RaiseIfFailed("TranslateDXDYDZ", self.TrsfOp)
2328 ## Translate the given object along the vector, specified
2329 # by its components, creating its copy before the translation.
2330 # @param theObject The object to be translated.
2331 # @param theDX,theDY,theDZ Components of translation vector.
2332 # @return New GEOM_Object, containing the translated object.
2334 # @ref tui_translation "Example"
2335 def MakeTranslation(self,theObject, theDX, theDY, theDZ):
2336 # Example: see GEOM_TestAll.py
2337 theDX, theDY, theDZ, Parameters = ParseParameters(theDX, theDY, theDZ)
2338 anObj = self.TrsfOp.TranslateDXDYDZCopy(theObject, theDX, theDY, theDZ)
2339 anObj.SetParameters(Parameters)
2340 RaiseIfFailed("TranslateDXDYDZ", self.TrsfOp)
2343 ## Translate the given object along the given vector,
2344 # creating its copy before the translation.
2345 # @param theObject The object to be translated.
2346 # @param theVector The translation vector.
2347 # @return New GEOM_Object, containing the translated object.
2349 # @ref tui_translation "Example"
2350 def MakeTranslationVector(self,theObject, theVector):
2351 # Example: see GEOM_TestAll.py
2352 anObj = self.TrsfOp.TranslateVectorCopy(theObject, theVector)
2353 RaiseIfFailed("TranslateVectorCopy", self.TrsfOp)
2356 ## Translate the given object along the given vector on given distance.
2357 # @param theObject The object to be translated.
2358 # @param theVector The translation vector.
2359 # @param theDistance The translation distance.
2360 # @param theCopy Flag used to translate object itself or create a copy.
2361 # @return Translated GEOM_Object.
2363 # @ref tui_translation "Example"
2364 def TranslateVectorDistance(self, theObject, theVector, theDistance, theCopy):
2365 # Example: see GEOM_TestAll.py
2366 theDistance,Parameters = ParseParameters(theDistance)
2367 anObj = self.TrsfOp.TranslateVectorDistance(theObject, theVector, theDistance, theCopy)
2368 RaiseIfFailed("TranslateVectorDistance", self.TrsfOp)
2369 anObj.SetParameters(Parameters)
2372 ## Translate the given object along the given vector on given distance,
2373 # creating its copy before the translation.
2374 # @param theObject The object to be translated.
2375 # @param theVector The translation vector.
2376 # @param theDistance The translation distance.
2377 # @return New GEOM_Object, containing the translated object.
2379 # @ref tui_translation "Example"
2380 def MakeTranslationVectorDistance(self, theObject, theVector, theDistance):
2381 # Example: see GEOM_TestAll.py
2382 theDistance,Parameters = ParseParameters(theDistance)
2383 anObj = self.TrsfOp.TranslateVectorDistance(theObject, theVector, theDistance, 1)
2384 RaiseIfFailed("TranslateVectorDistance", self.TrsfOp)
2385 anObj.SetParameters(Parameters)
2388 ## Rotate the given object around the given axis on the given angle.
2389 # @param theObject The object to be rotated.
2390 # @param theAxis Rotation axis.
2391 # @param theAngle Rotation angle in radians.
2392 # @return Rotated GEOM_Object.
2394 # @ref tui_rotation "Example"
2395 def Rotate(self,theObject, theAxis, theAngle):
2396 # Example: see GEOM_TestAll.py
2398 if isinstance(theAngle,str):
2400 theAngle, Parameters = ParseParameters(theAngle)
2402 theAngle = theAngle*math.pi/180.0
2403 anObj = self.TrsfOp.Rotate(theObject, theAxis, theAngle)
2404 RaiseIfFailed("RotateCopy", self.TrsfOp)
2405 anObj.SetParameters(Parameters)
2408 ## Rotate the given object around the given axis
2409 # on the given angle, creating its copy before the rotatation.
2410 # @param theObject The object to be rotated.
2411 # @param theAxis Rotation axis.
2412 # @param theAngle Rotation angle in radians.
2413 # @return New GEOM_Object, containing the rotated object.
2415 # @ref tui_rotation "Example"
2416 def MakeRotation(self,theObject, theAxis, theAngle):
2417 # Example: see GEOM_TestAll.py
2419 if isinstance(theAngle,str):
2421 theAngle, Parameters = ParseParameters(theAngle)
2423 theAngle = theAngle*math.pi/180.0
2424 anObj = self.TrsfOp.RotateCopy(theObject, theAxis, theAngle)
2425 RaiseIfFailed("RotateCopy", self.TrsfOp)
2426 anObj.SetParameters(Parameters)
2429 ## Rotate given object around vector perpendicular to plane
2430 # containing three points, creating its copy before the rotatation.
2431 # @param theObject The object to be rotated.
2432 # @param theCentPoint central point - the axis is the vector perpendicular to the plane
2433 # containing the three points.
2434 # @param thePoint1,thePoint2 - in a perpendicular plane of the axis.
2435 # @return New GEOM_Object, containing the rotated object.
2437 # @ref tui_rotation "Example"
2438 def MakeRotationThreePoints(self,theObject, theCentPoint, thePoint1, thePoint2):
2439 # Example: see GEOM_TestAll.py
2440 anObj = self.TrsfOp.RotateThreePointsCopy(theObject, theCentPoint, thePoint1, thePoint2)
2441 RaiseIfFailed("RotateThreePointsCopy", self.TrsfOp)
2444 ## Scale the given object by the factor, creating its copy before the scaling.
2445 # @param theObject The object to be scaled.
2446 # @param thePoint Center point for scaling.
2447 # Passing None for it means scaling relatively the origin of global CS.
2448 # @param theFactor Scaling factor value.
2449 # @return New GEOM_Object, containing the scaled shape.
2451 # @ref tui_scale "Example"
2452 def MakeScaleTransform(self, theObject, thePoint, theFactor):
2453 # Example: see GEOM_TestAll.py
2454 theFactor, Parameters = ParseParameters(theFactor)
2455 anObj = self.TrsfOp.ScaleShapeCopy(theObject, thePoint, theFactor)
2456 RaiseIfFailed("ScaleShapeCopy", self.TrsfOp)
2457 anObj.SetParameters(Parameters)
2460 ## Scale the given object by different factors along coordinate axes,
2461 # creating its copy before the scaling.
2462 # @param theObject The object to be scaled.
2463 # @param thePoint Center point for scaling.
2464 # Passing None for it means scaling relatively the origin of global CS.
2465 # @param theFactorX,theFactorY,theFactorZ Scaling factors along each axis.
2466 # @return New GEOM_Object, containing the scaled shape.
2468 # @ref swig_scale "Example"
2469 def MakeScaleAlongAxes(self, theObject, thePoint, theFactorX, theFactorY, theFactorZ):
2470 # Example: see GEOM_TestAll.py
2471 theFactorX, theFactorY, theFactorZ, Parameters = ParseParameters(theFactorX, theFactorY, theFactorZ)
2472 anObj = self.TrsfOp.ScaleShapeAlongAxesCopy(theObject, thePoint,
2473 theFactorX, theFactorY, theFactorZ)
2474 RaiseIfFailed("MakeScaleAlongAxes", self.TrsfOp)
2475 anObj.SetParameters(Parameters)
2478 ## Create an object, symmetrical
2479 # to the given one relatively the given plane.
2480 # @param theObject The object to be mirrored.
2481 # @param thePlane Plane of symmetry.
2482 # @return New GEOM_Object, containing the mirrored shape.
2484 # @ref tui_mirror "Example"
2485 def MakeMirrorByPlane(self,theObject, thePlane):
2486 # Example: see GEOM_TestAll.py
2487 anObj = self.TrsfOp.MirrorPlaneCopy(theObject, thePlane)
2488 RaiseIfFailed("MirrorPlaneCopy", self.TrsfOp)
2491 ## Create an object, symmetrical
2492 # to the given one relatively the given axis.
2493 # @param theObject The object to be mirrored.
2494 # @param theAxis Axis of symmetry.
2495 # @return New GEOM_Object, containing the mirrored shape.
2497 # @ref tui_mirror "Example"
2498 def MakeMirrorByAxis(self,theObject, theAxis):
2499 # Example: see GEOM_TestAll.py
2500 anObj = self.TrsfOp.MirrorAxisCopy(theObject, theAxis)
2501 RaiseIfFailed("MirrorAxisCopy", self.TrsfOp)
2504 ## Create an object, symmetrical
2505 # to the given one relatively the given point.
2506 # @param theObject The object to be mirrored.
2507 # @param thePoint Point of symmetry.
2508 # @return New GEOM_Object, containing the mirrored shape.
2510 # @ref tui_mirror "Example"
2511 def MakeMirrorByPoint(self,theObject, thePoint):
2512 # Example: see GEOM_TestAll.py
2513 anObj = self.TrsfOp.MirrorPointCopy(theObject, thePoint)
2514 RaiseIfFailed("MirrorPointCopy", self.TrsfOp)
2517 ## Modify the Location of the given object by LCS,
2518 # creating its copy before the setting.
2519 # @param theObject The object to be displaced.
2520 # @param theStartLCS Coordinate system to perform displacement from it.
2521 # If \a theStartLCS is NULL, displacement
2522 # will be performed from global CS.
2523 # If \a theObject itself is used as \a theStartLCS,
2524 # its location will be changed to \a theEndLCS.
2525 # @param theEndLCS Coordinate system to perform displacement to it.
2526 # @return New GEOM_Object, containing the displaced shape.
2528 # @ref tui_modify_location "Example"
2529 def MakePosition(self,theObject, theStartLCS, theEndLCS):
2530 # Example: see GEOM_TestAll.py
2531 anObj = self.TrsfOp.PositionShapeCopy(theObject, theStartLCS, theEndLCS)
2532 RaiseIfFailed("PositionShapeCopy", self.TrsfOp)
2535 ## Modify the Location of the given object by Path,
2536 # @param theObject The object to be displaced.
2537 # @param thePath Wire or Edge along that the object will be translated.
2538 # @param theDistance progress of Path (0 = start location, 1 = end of path location).
2539 # @param theCopy is to create a copy objects if true.
2540 # @param theReverse - 0 for usual direction, 1 to reverse path direction.
2541 # @return New GEOM_Object, containing the displaced shape.
2543 # @ref tui_modify_location "Example"
2544 def PositionAlongPath(self,theObject, thePath, theDistance, theCopy, theReverse):
2545 # Example: see GEOM_TestAll.py
2546 anObj = self.TrsfOp.PositionAlongPath(theObject, thePath, theDistance, theCopy, theReverse)
2547 RaiseIfFailed("PositionAlongPath", self.TrsfOp)
2550 ## Create new object as offset of the given one.
2551 # @param theObject The base object for the offset.
2552 # @param theOffset Offset value.
2553 # @return New GEOM_Object, containing the offset object.
2555 # @ref tui_offset "Example"
2556 def MakeOffset(self,theObject, theOffset):
2557 # Example: see GEOM_TestAll.py
2558 theOffset, Parameters = ParseParameters(theOffset)
2559 anObj = self.TrsfOp.OffsetShapeCopy(theObject, theOffset)
2560 RaiseIfFailed("OffsetShapeCopy", self.TrsfOp)
2561 anObj.SetParameters(Parameters)
2564 # -----------------------------------------------------------------------------
2566 # -----------------------------------------------------------------------------
2568 ## Translate the given object along the given vector a given number times
2569 # @param theObject The object to be translated.
2570 # @param theVector Direction of the translation.
2571 # @param theStep Distance to translate on.
2572 # @param theNbTimes Quantity of translations to be done.
2573 # @return New GEOM_Object, containing compound of all
2574 # the shapes, obtained after each translation.
2576 # @ref tui_multi_translation "Example"
2577 def MakeMultiTranslation1D(self,theObject, theVector, theStep, theNbTimes):
2578 # Example: see GEOM_TestAll.py
2579 theStep, theNbTimes, Parameters = ParseParameters(theStep, theNbTimes)
2580 anObj = self.TrsfOp.MultiTranslate1D(theObject, theVector, theStep, theNbTimes)
2581 RaiseIfFailed("MultiTranslate1D", self.TrsfOp)
2582 anObj.SetParameters(Parameters)
2585 ## Conseqently apply two specified translations to theObject specified number of times.
2586 # @param theObject The object to be translated.
2587 # @param theVector1 Direction of the first translation.
2588 # @param theStep1 Step of the first translation.
2589 # @param theNbTimes1 Quantity of translations to be done along theVector1.
2590 # @param theVector2 Direction of the second translation.
2591 # @param theStep2 Step of the second translation.
2592 # @param theNbTimes2 Quantity of translations to be done along theVector2.
2593 # @return New GEOM_Object, containing compound of all
2594 # the shapes, obtained after each translation.
2596 # @ref tui_multi_translation "Example"
2597 def MakeMultiTranslation2D(self,theObject, theVector1, theStep1, theNbTimes1,
2598 theVector2, theStep2, theNbTimes2):
2599 # Example: see GEOM_TestAll.py
2600 theStep1,theNbTimes1,theStep2,theNbTimes2, Parameters = ParseParameters(theStep1,theNbTimes1,theStep2,theNbTimes2)
2601 anObj = self.TrsfOp.MultiTranslate2D(theObject, theVector1, theStep1, theNbTimes1,
2602 theVector2, theStep2, theNbTimes2)
2603 RaiseIfFailed("MultiTranslate2D", self.TrsfOp)
2604 anObj.SetParameters(Parameters)
2607 ## Rotate the given object around the given axis a given number times.
2608 # Rotation angle will be 2*PI/theNbTimes.
2609 # @param theObject The object to be rotated.
2610 # @param theAxis The rotation axis.
2611 # @param theNbTimes Quantity of rotations to be done.
2612 # @return New GEOM_Object, containing compound of all the
2613 # shapes, obtained after each rotation.
2615 # @ref tui_multi_rotation "Example"
2616 def MultiRotate1D(self,theObject, theAxis, theNbTimes):
2617 # Example: see GEOM_TestAll.py
2618 theAxis, theNbTimes, Parameters = ParseParameters(theAxis, theNbTimes)
2619 anObj = self.TrsfOp.MultiRotate1D(theObject, theAxis, theNbTimes)
2620 RaiseIfFailed("MultiRotate1D", self.TrsfOp)
2621 anObj.SetParameters(Parameters)
2624 ## Rotate the given object around the
2625 # given axis on the given angle a given number
2626 # times and multi-translate each rotation result.
2627 # Translation direction passes through center of gravity
2628 # of rotated shape and its projection on the rotation axis.
2629 # @param theObject The object to be rotated.
2630 # @param theAxis Rotation axis.
2631 # @param theAngle Rotation angle in graduces.
2632 # @param theNbTimes1 Quantity of rotations to be done.
2633 # @param theStep Translation distance.
2634 # @param theNbTimes2 Quantity of translations to be done.
2635 # @return New GEOM_Object, containing compound of all the
2636 # shapes, obtained after each transformation.
2638 # @ref tui_multi_rotation "Example"
2639 def MultiRotate2D(self,theObject, theAxis, theAngle, theNbTimes1, theStep, theNbTimes2):
2640 # Example: see GEOM_TestAll.py
2641 theAngle, theNbTimes1, theStep, theNbTimes2, Parameters = ParseParameters(theAngle, theNbTimes1, theStep, theNbTimes2)
2642 anObj = self.TrsfOp.MultiRotate2D(theObject, theAxis, theAngle, theNbTimes1, theStep, theNbTimes2)
2643 RaiseIfFailed("MultiRotate2D", self.TrsfOp)
2644 anObj.SetParameters(Parameters)
2647 ## The same, as MultiRotate1D(), but axis is given by direction and point
2648 # @ref swig_MakeMultiRotation "Example"
2649 def MakeMultiRotation1D(self,aShape,aDir,aPoint,aNbTimes):
2650 # Example: see GEOM_TestOthers.py
2651 aVec = self.MakeLine(aPoint,aDir)
2652 anObj = self.MultiRotate1D(aShape,aVec,aNbTimes)
2655 ## The same, as MultiRotate2D(), but axis is given by direction and point
2656 # @ref swig_MakeMultiRotation "Example"
2657 def MakeMultiRotation2D(self,aShape,aDir,aPoint,anAngle,nbtimes1,aStep,nbtimes2):
2658 # Example: see GEOM_TestOthers.py
2659 aVec = self.MakeLine(aPoint,aDir)
2660 anObj = self.MultiRotate2D(aShape,aVec,anAngle,nbtimes1,aStep,nbtimes2)
2663 # end of l3_transform
2666 ## @addtogroup l3_local
2669 ## Perform a fillet on all edges of the given shape.
2670 # @param theShape Shape, to perform fillet on.
2671 # @param theR Fillet radius.
2672 # @return New GEOM_Object, containing the result shape.
2674 # @ref tui_fillet "Example 1"
2675 # \n @ref swig_MakeFilletAll "Example 2"
2676 def MakeFilletAll(self,theShape, theR):
2677 # Example: see GEOM_TestOthers.py
2678 theR,Parameters = ParseParameters(theR)
2679 anObj = self.LocalOp.MakeFilletAll(theShape, theR)
2680 RaiseIfFailed("MakeFilletAll", self.LocalOp)
2681 anObj.SetParameters(Parameters)
2684 ## Perform a fillet on the specified edges/faces of the given shape
2685 # @param theShape Shape, to perform fillet on.
2686 # @param theR Fillet radius.
2687 # @param theShapeType Type of shapes in <VAR>theListShapes</VAR>.
2688 # @param theListShapes Global indices of edges/faces to perform fillet on.
2689 # \note Global index of sub-shape can be obtained, using method geompy.GetSubShapeID().
2690 # @return New GEOM_Object, containing the result shape.
2692 # @ref tui_fillet "Example"
2693 def MakeFillet(self,theShape, theR, theShapeType, theListShapes):
2694 # Example: see GEOM_TestAll.py
2695 theR,Parameters = ParseParameters(theR)
2697 if theShapeType == ShapeType["EDGE"]:
2698 anObj = self.LocalOp.MakeFilletEdges(theShape, theR, theListShapes)
2699 RaiseIfFailed("MakeFilletEdges", self.LocalOp)
2701 anObj = self.LocalOp.MakeFilletFaces(theShape, theR, theListShapes)
2702 RaiseIfFailed("MakeFilletFaces", self.LocalOp)
2703 anObj.SetParameters(Parameters)
2706 ## The same that MakeFillet but with two Fillet Radius R1 and R2
2707 def MakeFilletR1R2(self, theShape, theR1, theR2, theShapeType, theListShapes):
2708 theR1,theR2,Parameters = ParseParameters(theR1,theR2)
2710 if theShapeType == ShapeType["EDGE"]:
2711 anObj = self.LocalOp.MakeFilletEdgesR1R2(theShape, theR1, theR2, theListShapes)
2712 RaiseIfFailed("MakeFilletEdgesR1R2", self.LocalOp)
2714 anObj = self.LocalOp.MakeFilletFacesR1R2(theShape, theR1, theR2, theListShapes)
2715 RaiseIfFailed("MakeFilletFacesR1R2", self.LocalOp)
2716 anObj.SetParameters(Parameters)
2719 ## Perform a fillet on the specified edges/faces of the given shape
2720 # @param theShape - Face Shape to perform fillet on.
2721 # @param theR - Fillet radius.
2722 # @param theListOfVertexes Global indices of vertexes to perform fillet on.
2723 # \note Global index of sub-shape can be obtained, using method geompy.GetSubShapeID().
2724 # @return New GEOM_Object, containing the result shape.
2726 # @ref tui_fillet2d "Example"
2727 def MakeFillet2D(self,theShape, theR, theListOfVertexes):
2728 # Example: see GEOM_TestAll.py
2729 anObj = self.LocalOp.MakeFillet2D(theShape, theR, theListOfVertexes)
2730 RaiseIfFailed("MakeFillet2D", self.LocalOp)
2733 ## Perform a symmetric chamfer on all edges of the given shape.
2734 # @param theShape Shape, to perform chamfer on.
2735 # @param theD Chamfer size along each face.
2736 # @return New GEOM_Object, containing the result shape.
2738 # @ref tui_chamfer "Example 1"
2739 # \n @ref swig_MakeChamferAll "Example 2"
2740 def MakeChamferAll(self,theShape, theD):
2741 # Example: see GEOM_TestOthers.py
2742 theD,Parameters = ParseParameters(theD)
2743 anObj = self.LocalOp.MakeChamferAll(theShape, theD)
2744 RaiseIfFailed("MakeChamferAll", self.LocalOp)
2745 anObj.SetParameters(Parameters)
2748 ## Perform a chamfer on edges, common to the specified faces,
2749 # with distance D1 on the Face1
2750 # @param theShape Shape, to perform chamfer on.
2751 # @param theD1 Chamfer size along \a theFace1.
2752 # @param theD2 Chamfer size along \a theFace2.
2753 # @param theFace1,theFace2 Global indices of two faces of \a theShape.
2754 # \note Global index of sub-shape can be obtained, using method geompy.GetSubShapeID().
2755 # @return New GEOM_Object, containing the result shape.
2757 # @ref tui_chamfer "Example"
2758 def MakeChamferEdge(self,theShape, theD1, theD2, theFace1, theFace2):
2759 # Example: see GEOM_TestAll.py
2760 theD1,theD2,Parameters = ParseParameters(theD1,theD2)
2761 anObj = self.LocalOp.MakeChamferEdge(theShape, theD1, theD2, theFace1, theFace2)
2762 RaiseIfFailed("MakeChamferEdge", self.LocalOp)
2763 anObj.SetParameters(Parameters)
2766 ## The Same that MakeChamferEdge but with params theD is chamfer length and
2767 # theAngle is Angle of chamfer (angle in radians or a name of variable which defines angle in degrees)
2768 def MakeChamferEdgeAD(self, theShape, theD, theAngle, theFace1, theFace2):
2770 if isinstance(theAngle,str):
2772 theD,theAngle,Parameters = ParseParameters(theD,theAngle)
2774 theAngle = theAngle*math.pi/180.0
2775 anObj = self.LocalOp.MakeChamferEdgeAD(theShape, theD, theAngle, theFace1, theFace2)
2776 RaiseIfFailed("MakeChamferEdgeAD", self.LocalOp)
2777 anObj.SetParameters(Parameters)
2780 ## Perform a chamfer on all edges of the specified faces,
2781 # with distance D1 on the first specified face (if several for one edge)
2782 # @param theShape Shape, to perform chamfer on.
2783 # @param theD1 Chamfer size along face from \a theFaces. If both faces,
2784 # connected to the edge, are in \a theFaces, \a theD1
2785 # will be get along face, which is nearer to \a theFaces beginning.
2786 # @param theD2 Chamfer size along another of two faces, connected to the edge.
2787 # @param theFaces Sequence of global indices of faces of \a theShape.
2788 # \note Global index of sub-shape can be obtained, using method geompy.GetSubShapeID().
2789 # @return New GEOM_Object, containing the result shape.
2791 # @ref tui_chamfer "Example"
2792 def MakeChamferFaces(self,theShape, theD1, theD2, theFaces):
2793 # Example: see GEOM_TestAll.py
2794 theD1,theD2,Parameters = ParseParameters(theD1,theD2)
2795 anObj = self.LocalOp.MakeChamferFaces(theShape, theD1, theD2, theFaces)
2796 RaiseIfFailed("MakeChamferFaces", self.LocalOp)
2797 anObj.SetParameters(Parameters)
2800 ## The Same that MakeChamferFaces but with params theD is chamfer lenght and
2801 # theAngle is Angle of chamfer (angle in radians or a name of variable which defines angle in degrees)
2803 # @ref swig_FilletChamfer "Example"
2804 def MakeChamferFacesAD(self, theShape, theD, theAngle, theFaces):
2806 if isinstance(theAngle,str):
2808 theD,theAngle,Parameters = ParseParameters(theD,theAngle)
2810 theAngle = theAngle*math.pi/180.0
2811 anObj = self.LocalOp.MakeChamferFacesAD(theShape, theD, theAngle, theFaces)
2812 RaiseIfFailed("MakeChamferFacesAD", self.LocalOp)
2813 anObj.SetParameters(Parameters)
2816 ## Perform a chamfer on edges,
2817 # with distance D1 on the first specified face (if several for one edge)
2818 # @param theShape Shape, to perform chamfer on.
2819 # @param theD1,theD2 Chamfer size
2820 # @param theEdges Sequence of edges of \a theShape.
2821 # @return New GEOM_Object, containing the result shape.
2823 # @ref swig_FilletChamfer "Example"
2824 def MakeChamferEdges(self, theShape, theD1, theD2, theEdges):
2825 theD1,theD2,Parameters = ParseParameters(theD1,theD2)
2826 anObj = self.LocalOp.MakeChamferEdges(theShape, theD1, theD2, theEdges)
2827 RaiseIfFailed("MakeChamferEdges", self.LocalOp)
2828 anObj.SetParameters(Parameters)
2831 ## The Same that MakeChamferEdges but with params theD is chamfer lenght and
2832 # theAngle is Angle of chamfer (angle in radians or a name of variable which defines angle in degrees)
2833 def MakeChamferEdgesAD(self, theShape, theD, theAngle, theEdges):
2835 if isinstance(theAngle,str):
2837 theD,theAngle,Parameters = ParseParameters(theD,theAngle)
2839 theAngle = theAngle*math.pi/180.0
2840 anObj = self.LocalOp.MakeChamferEdgesAD(theShape, theD, theAngle, theEdges)
2841 RaiseIfFailed("MakeChamferEdgesAD", self.LocalOp)
2842 anObj.SetParameters(Parameters)
2845 ## Shortcut to MakeChamferEdge() and MakeChamferFaces()
2847 # @ref swig_MakeChamfer "Example"
2848 def MakeChamfer(self,aShape,d1,d2,aShapeType,ListShape):
2849 # Example: see GEOM_TestOthers.py
2851 if aShapeType == ShapeType["EDGE"]:
2852 anObj = self.MakeChamferEdge(aShape,d1,d2,ListShape[0],ListShape[1])
2854 anObj = self.MakeChamferFaces(aShape,d1,d2,ListShape)
2860 ## @addtogroup l3_basic_op
2863 ## Perform an Archimde operation on the given shape with given parameters.
2864 # The object presenting the resulting face is returned.
2865 # @param theShape Shape to be put in water.
2866 # @param theWeight Weight og the shape.
2867 # @param theWaterDensity Density of the water.
2868 # @param theMeshDeflection Deflection of the mesh, using to compute the section.
2869 # @return New GEOM_Object, containing a section of \a theShape
2870 # by a plane, corresponding to water level.
2872 # @ref tui_archimede "Example"
2873 def Archimede(self,theShape, theWeight, theWaterDensity, theMeshDeflection):
2874 # Example: see GEOM_TestAll.py
2875 theWeight,theWaterDensity,theMeshDeflection,Parameters = ParseParameters(
2876 theWeight,theWaterDensity,theMeshDeflection)
2877 anObj = self.LocalOp.MakeArchimede(theShape, theWeight, theWaterDensity, theMeshDeflection)
2878 RaiseIfFailed("MakeArchimede", self.LocalOp)
2879 anObj.SetParameters(Parameters)
2882 # end of l3_basic_op
2885 ## @addtogroup l2_measure
2888 ## Get point coordinates
2891 # @ref tui_measurement_tools_page "Example"
2892 def PointCoordinates(self,Point):
2893 # Example: see GEOM_TestMeasures.py
2894 aTuple = self.MeasuOp.PointCoordinates(Point)
2895 RaiseIfFailed("PointCoordinates", self.MeasuOp)
2898 ## Get summarized length of all wires,
2899 # area of surface and volume of the given shape.
2900 # @param theShape Shape to define properties of.
2901 # @return [theLength, theSurfArea, theVolume]
2902 # theLength: Summarized length of all wires of the given shape.
2903 # theSurfArea: Area of surface of the given shape.
2904 # theVolume: Volume of the given shape.
2906 # @ref tui_measurement_tools_page "Example"
2907 def BasicProperties(self,theShape):
2908 # Example: see GEOM_TestMeasures.py
2909 aTuple = self.MeasuOp.GetBasicProperties(theShape)
2910 RaiseIfFailed("GetBasicProperties", self.MeasuOp)
2913 ## Get parameters of bounding box of the given shape
2914 # @param theShape Shape to obtain bounding box of.
2915 # @return [Xmin,Xmax, Ymin,Ymax, Zmin,Zmax]
2916 # Xmin,Xmax: Limits of shape along OX axis.
2917 # Ymin,Ymax: Limits of shape along OY axis.
2918 # Zmin,Zmax: Limits of shape along OZ axis.
2920 # @ref tui_measurement_tools_page "Example"
2921 def BoundingBox(self,theShape):
2922 # Example: see GEOM_TestMeasures.py
2923 aTuple = self.MeasuOp.GetBoundingBox(theShape)
2924 RaiseIfFailed("GetBoundingBox", self.MeasuOp)
2927 ## Get inertia matrix and moments of inertia of theShape.
2928 # @param theShape Shape to calculate inertia of.
2929 # @return [I11,I12,I13, I21,I22,I23, I31,I32,I33, Ix,Iy,Iz]
2930 # I(1-3)(1-3): Components of the inertia matrix of the given shape.
2931 # Ix,Iy,Iz: Moments of inertia of the given shape.
2933 # @ref tui_measurement_tools_page "Example"
2934 def Inertia(self,theShape):
2935 # Example: see GEOM_TestMeasures.py
2936 aTuple = self.MeasuOp.GetInertia(theShape)
2937 RaiseIfFailed("GetInertia", self.MeasuOp)
2940 ## Get minimal distance between the given shapes.
2941 # @param theShape1,theShape2 Shapes to find minimal distance between.
2942 # @return Value of the minimal distance between the given shapes.
2944 # @ref tui_measurement_tools_page "Example"
2945 def MinDistance(self, theShape1, theShape2):
2946 # Example: see GEOM_TestMeasures.py
2947 aTuple = self.MeasuOp.GetMinDistance(theShape1, theShape2)
2948 RaiseIfFailed("GetMinDistance", self.MeasuOp)
2951 ## Get minimal distance between the given shapes.
2952 # @param theShape1,theShape2 Shapes to find minimal distance between.
2953 # @return Value of the minimal distance between the given shapes.
2955 # @ref swig_all_measure "Example"
2956 def MinDistanceComponents(self, theShape1, theShape2):
2957 # Example: see GEOM_TestMeasures.py
2958 aTuple = self.MeasuOp.GetMinDistance(theShape1, theShape2)
2959 RaiseIfFailed("GetMinDistance", self.MeasuOp)
2960 aRes = [aTuple[0], aTuple[4] - aTuple[1], aTuple[5] - aTuple[2], aTuple[6] - aTuple[3]]
2963 ## Get angle between the given shapes in degrees.
2964 # @param theShape1,theShape2 Lines or linear edges to find angle between.
2965 # @return Value of the angle between the given shapes in degrees.
2967 # @ref tui_measurement_tools_page "Example"
2968 def GetAngle(self, theShape1, theShape2):
2969 # Example: see GEOM_TestMeasures.py
2970 anAngle = self.MeasuOp.GetAngle(theShape1, theShape2)
2971 RaiseIfFailed("GetAngle", self.MeasuOp)
2973 ## Get angle between the given shapes in radians.
2974 # @param theShape1,theShape2 Lines or linear edges to find angle between.
2975 # @return Value of the angle between the given shapes in radians.
2977 # @ref tui_measurement_tools_page "Example"
2978 def GetAngleRadians(self, theShape1, theShape2):
2979 # Example: see GEOM_TestMeasures.py
2980 anAngle = self.MeasuOp.GetAngle(theShape1, theShape2)*math.pi/180.
2981 RaiseIfFailed("GetAngle", self.MeasuOp)
2984 ## @name Curve Curvature Measurement
2985 # Methods for receiving radius of curvature of curves
2986 # in the given point
2989 ## Measure curvature of a curve at a point, set by parameter.
2990 # @ref swig_todo "Example"
2991 def CurveCurvatureByParam(self, theCurve, theParam):
2992 # Example: see GEOM_TestMeasures.py
2993 aCurv = self.MeasuOp.CurveCurvatureByParam(theCurve,theParam)
2994 RaiseIfFailed("CurveCurvatureByParam", self.MeasuOp)
2998 # @ref swig_todo "Example"
2999 def CurveCurvatureByPoint(self, theCurve, thePoint):
3000 aCurv = self.MeasuOp.CurveCurvatureByPoint(theCurve,thePoint)
3001 RaiseIfFailed("CurveCurvatureByPoint", self.MeasuOp)
3005 ## @name Surface Curvature Measurement
3006 # Methods for receiving max and min radius of curvature of surfaces
3007 # in the given point
3011 ## @ref swig_todo "Example"
3012 def MaxSurfaceCurvatureByParam(self, theSurf, theUParam, theVParam):
3013 # Example: see GEOM_TestMeasures.py
3014 aSurf = self.MeasuOp.MaxSurfaceCurvatureByParam(theSurf,theUParam,theVParam)
3015 RaiseIfFailed("MaxSurfaceCurvatureByParam", self.MeasuOp)
3019 ## @ref swig_todo "Example"
3020 def MaxSurfaceCurvatureByPoint(self, theSurf, thePoint):
3021 aSurf = self.MeasuOp.MaxSurfaceCurvatureByPoint(theSurf,thePoint)
3022 RaiseIfFailed("MaxSurfaceCurvatureByPoint", self.MeasuOp)
3026 ## @ref swig_todo "Example"
3027 def MinSurfaceCurvatureByParam(self, theSurf, theUParam, theVParam):
3028 aSurf = self.MeasuOp.MinSurfaceCurvatureByParam(theSurf,theUParam,theVParam)
3029 RaiseIfFailed("MinSurfaceCurvatureByParam", self.MeasuOp)
3033 ## @ref swig_todo "Example"
3034 def MinSurfaceCurvatureByPoint(self, theSurf, thePoint):
3035 aSurf = self.MeasuOp.MinSurfaceCurvatureByPoint(theSurf,thePoint)
3036 RaiseIfFailed("MinSurfaceCurvatureByPoint", self.MeasuOp)
3040 ## Get min and max tolerances of sub-shapes of theShape
3041 # @param theShape Shape, to get tolerances of.
3042 # @return [FaceMin,FaceMax, EdgeMin,EdgeMax, VertMin,VertMax]
3043 # FaceMin,FaceMax: Min and max tolerances of the faces.
3044 # EdgeMin,EdgeMax: Min and max tolerances of the edges.
3045 # VertMin,VertMax: Min and max tolerances of the vertices.
3047 # @ref tui_measurement_tools_page "Example"
3048 def Tolerance(self,theShape):
3049 # Example: see GEOM_TestMeasures.py
3050 aTuple = self.MeasuOp.GetTolerance(theShape)
3051 RaiseIfFailed("GetTolerance", self.MeasuOp)
3054 ## Obtain description of the given shape (number of sub-shapes of each type)
3055 # @param theShape Shape to be described.
3056 # @return Description of the given shape.
3058 # @ref tui_measurement_tools_page "Example"
3059 def WhatIs(self,theShape):
3060 # Example: see GEOM_TestMeasures.py
3061 aDescr = self.MeasuOp.WhatIs(theShape)
3062 RaiseIfFailed("WhatIs", self.MeasuOp)
3065 ## Get a point, situated at the centre of mass of theShape.
3066 # @param theShape Shape to define centre of mass of.
3067 # @return New GEOM_Object, containing the created point.
3069 # @ref tui_measurement_tools_page "Example"
3070 def MakeCDG(self,theShape):
3071 # Example: see GEOM_TestMeasures.py
3072 anObj = self.MeasuOp.GetCentreOfMass(theShape)
3073 RaiseIfFailed("GetCentreOfMass", self.MeasuOp)
3076 ## Get a normale to the given face. If the point is not given,
3077 # the normale is calculated at the center of mass.
3078 # @param theFace Face to define normale of.
3079 # @param theOptionalPoint Point to compute the normale at.
3080 # @return New GEOM_Object, containing the created vector.
3082 # @ref swig_todo "Example"
3083 def GetNormal(self, theFace, theOptionalPoint = None):
3084 # Example: see GEOM_TestMeasures.py
3085 anObj = self.MeasuOp.GetNormal(theFace, theOptionalPoint)
3086 RaiseIfFailed("GetNormal", self.MeasuOp)
3089 ## Check a topology of the given shape.
3090 # @param theShape Shape to check validity of.
3091 # @param theIsCheckGeom If FALSE, only the shape's topology will be checked,
3092 # if TRUE, the shape's geometry will be checked also.
3093 # @return TRUE, if the shape "seems to be valid".
3094 # If theShape is invalid, prints a description of problem.
3096 # @ref tui_measurement_tools_page "Example"
3097 def CheckShape(self,theShape, theIsCheckGeom = 0):
3098 # Example: see GEOM_TestMeasures.py
3100 (IsValid, Status) = self.MeasuOp.CheckShapeWithGeometry(theShape)
3101 RaiseIfFailed("CheckShapeWithGeometry", self.MeasuOp)
3103 (IsValid, Status) = self.MeasuOp.CheckShape(theShape)
3104 RaiseIfFailed("CheckShape", self.MeasuOp)
3109 ## Get position (LCS) of theShape.
3111 # Origin of the LCS is situated at the shape's center of mass.
3112 # Axes of the LCS are obtained from shape's location or,
3113 # if the shape is a planar face, from position of its plane.
3115 # @param theShape Shape to calculate position of.
3116 # @return [Ox,Oy,Oz, Zx,Zy,Zz, Xx,Xy,Xz].
3117 # Ox,Oy,Oz: Coordinates of shape's LCS origin.
3118 # Zx,Zy,Zz: Coordinates of shape's LCS normal(main) direction.
3119 # Xx,Xy,Xz: Coordinates of shape's LCS X direction.
3121 # @ref swig_todo "Example"
3122 def GetPosition(self,theShape):
3123 # Example: see GEOM_TestMeasures.py
3124 aTuple = self.MeasuOp.GetPosition(theShape)
3125 RaiseIfFailed("GetPosition", self.MeasuOp)
3128 ## Get kind of theShape.
3130 # @param theShape Shape to get a kind of.
3131 # @return Returns a kind of shape in terms of <VAR>GEOM_IKindOfShape.shape_kind</VAR> enumeration
3132 # and a list of parameters, describing the shape.
3133 # @note Concrete meaning of each value, returned via \a theIntegers
3134 # or \a theDoubles list depends on the kind of the shape.
3135 # The full list of possible outputs is:
3137 # - geompy.kind.COMPOUND nb_solids nb_faces nb_edges nb_vertices
3138 # - geompy.kind.COMPSOLID nb_solids nb_faces nb_edges nb_vertices
3140 # - geompy.kind.SHELL geompy.info.CLOSED nb_faces nb_edges nb_vertices
3141 # - geompy.kind.SHELL geompy.info.UNCLOSED nb_faces nb_edges nb_vertices
3143 # - geompy.kind.WIRE geompy.info.CLOSED nb_edges nb_vertices
3144 # - geompy.kind.WIRE geompy.info.UNCLOSED nb_edges nb_vertices
3146 # - geompy.kind.SPHERE xc yc zc R
3147 # - geompy.kind.CYLINDER xb yb zb dx dy dz R H
3148 # - geompy.kind.BOX xc yc zc ax ay az
3149 # - geompy.kind.ROTATED_BOX xc yc zc zx zy zz xx xy xz ax ay az
3150 # - geompy.kind.TORUS xc yc zc dx dy dz R_1 R_2
3151 # - geompy.kind.CONE xb yb zb dx dy dz R_1 R_2 H
3152 # - geompy.kind.POLYHEDRON nb_faces nb_edges nb_vertices
3153 # - geompy.kind.SOLID nb_faces nb_edges nb_vertices
3155 # - geompy.kind.SPHERE2D xc yc zc R
3156 # - geompy.kind.CYLINDER2D xb yb zb dx dy dz R H
3157 # - geompy.kind.TORUS2D xc yc zc dx dy dz R_1 R_2
3158 # - geompy.kind.CONE2D xc yc zc dx dy dz R_1 R_2 H
3159 # - geompy.kind.DISK_CIRCLE xc yc zc dx dy dz R
3160 # - geompy.kind.DISK_ELLIPSE xc yc zc dx dy dz R_1 R_2
3161 # - geompy.kind.POLYGON xo yo zo dx dy dz nb_edges nb_vertices
3162 # - geompy.kind.PLANE xo yo zo dx dy dz
3163 # - geompy.kind.PLANAR xo yo zo dx dy dz nb_edges nb_vertices
3164 # - geompy.kind.FACE nb_edges nb_vertices
3166 # - geompy.kind.CIRCLE xc yc zc dx dy dz R
3167 # - geompy.kind.ARC_CIRCLE xc yc zc dx dy dz R x1 y1 z1 x2 y2 z2
3168 # - geompy.kind.ELLIPSE xc yc zc dx dy dz R_1 R_2
3169 # - geompy.kind.ARC_ELLIPSE xc yc zc dx dy dz R_1 R_2 x1 y1 z1 x2 y2 z2
3170 # - geompy.kind.LINE xo yo zo dx dy dz
3171 # - geompy.kind.SEGMENT x1 y1 z1 x2 y2 z2
3172 # - geompy.kind.EDGE nb_vertices
3174 # - geompy.kind.VERTEX x y z
3176 # @ref swig_todo "Example"
3177 def KindOfShape(self,theShape):
3178 # Example: see GEOM_TestMeasures.py
3179 aRoughTuple = self.MeasuOp.KindOfShape(theShape)
3180 RaiseIfFailed("KindOfShape", self.MeasuOp)
3182 aKind = aRoughTuple[0]
3183 anInts = aRoughTuple[1]
3184 aDbls = aRoughTuple[2]
3186 # Now there is no exception from this rule:
3187 aKindTuple = [aKind] + aDbls + anInts
3189 # If they are we will regroup parameters for such kind of shape.
3191 #if aKind == kind.SOME_KIND:
3192 # # SOME_KIND int int double int double double
3193 # aKindTuple = [aKind, anInts[0], anInts[1], aDbls[0], anInts[2], aDbls[1], aDbls[2]]
3200 ## @addtogroup l2_import_export
3203 ## Import a shape from the BREP or IGES or STEP file
3204 # (depends on given format) with given name.
3205 # @param theFileName The file, containing the shape.
3206 # @param theFormatName Specify format for the file reading.
3207 # Available formats can be obtained with InsertOp.ImportTranslators() method.
3208 # If format 'IGES_SCALE' is used instead 'IGES' length unit will be
3209 # set to 'meter' and result model will be scaled.
3210 # @return New GEOM_Object, containing the imported shape.
3212 # @ref swig_Import_Export "Example"
3213 def Import(self,theFileName, theFormatName):
3214 # Example: see GEOM_TestOthers.py
3215 anObj = self.InsertOp.Import(theFileName, theFormatName)
3216 RaiseIfFailed("Import", self.InsertOp)
3219 ## Shortcut to Import() for BREP format
3221 # @ref swig_Import_Export "Example"
3222 def ImportBREP(self,theFileName):
3223 # Example: see GEOM_TestOthers.py
3224 return self.Import(theFileName, "BREP")
3226 ## Shortcut to Import() for IGES format
3228 # @ref swig_Import_Export "Example"
3229 def ImportIGES(self,theFileName):
3230 # Example: see GEOM_TestOthers.py
3231 return self.Import(theFileName, "IGES")
3233 ## Return length unit from given IGES file
3235 # @ref swig_Import_Export "Example"
3236 def GetIGESUnit(self,theFileName):
3237 # Example: see GEOM_TestOthers.py
3238 anObj = self.InsertOp.Import(theFileName, "IGES_UNIT")
3239 #RaiseIfFailed("Import", self.InsertOp)
3240 # recieve name using returned vertex
3242 vertices = self.SubShapeAll(anObj,ShapeType["VERTEX"])
3244 p = self.PointCoordinates(vertices[0])
3245 if abs(p[0]-0.01) < 1.e-6:
3247 elif abs(p[0]-0.001) < 1.e-6:
3251 ## Shortcut to Import() for STEP format
3253 # @ref swig_Import_Export "Example"
3254 def ImportSTEP(self,theFileName):
3255 # Example: see GEOM_TestOthers.py
3256 return self.Import(theFileName, "STEP")
3258 ## Export the given shape into a file with given name.
3259 # @param theObject Shape to be stored in the file.
3260 # @param theFileName Name of the file to store the given shape in.
3261 # @param theFormatName Specify format for the shape storage.
3262 # Available formats can be obtained with InsertOp.ImportTranslators() method.
3264 # @ref swig_Import_Export "Example"
3265 def Export(self,theObject, theFileName, theFormatName):
3266 # Example: see GEOM_TestOthers.py
3267 self.InsertOp.Export(theObject, theFileName, theFormatName)
3268 if self.InsertOp.IsDone() == 0:
3269 raise RuntimeError, "Export : " + self.InsertOp.GetErrorCode()
3273 ## Shortcut to Export() for BREP format
3275 # @ref swig_Import_Export "Example"
3276 def ExportBREP(self,theObject, theFileName):
3277 # Example: see GEOM_TestOthers.py
3278 return self.Export(theObject, theFileName, "BREP")
3280 ## Shortcut to Export() for IGES format
3282 # @ref swig_Import_Export "Example"
3283 def ExportIGES(self,theObject, theFileName):
3284 # Example: see GEOM_TestOthers.py
3285 return self.Export(theObject, theFileName, "IGES")
3287 ## Shortcut to Export() for STEP format
3289 # @ref swig_Import_Export "Example"
3290 def ExportSTEP(self,theObject, theFileName):
3291 # Example: see GEOM_TestOthers.py
3292 return self.Export(theObject, theFileName, "STEP")
3294 # end of l2_import_export
3297 ## @addtogroup l3_blocks
3300 ## Create a quadrangle face from four edges. Order of Edges is not
3301 # important. It is not necessary that edges share the same vertex.
3302 # @param E1,E2,E3,E4 Edges for the face bound.
3303 # @return New GEOM_Object, containing the created face.
3305 # @ref tui_building_by_blocks_page "Example"
3306 def MakeQuad(self,E1, E2, E3, E4):
3307 # Example: see GEOM_Spanner.py
3308 anObj = self.BlocksOp.MakeQuad(E1, E2, E3, E4)
3309 RaiseIfFailed("MakeQuad", self.BlocksOp)
3312 ## Create a quadrangle face on two edges.
3313 # The missing edges will be built by creating the shortest ones.
3314 # @param E1,E2 Two opposite edges for the face.
3315 # @return New GEOM_Object, containing the created face.
3317 # @ref tui_building_by_blocks_page "Example"
3318 def MakeQuad2Edges(self,E1, E2):
3319 # Example: see GEOM_Spanner.py
3320 anObj = self.BlocksOp.MakeQuad2Edges(E1, E2)
3321 RaiseIfFailed("MakeQuad2Edges", self.BlocksOp)
3324 ## Create a quadrangle face with specified corners.
3325 # The missing edges will be built by creating the shortest ones.
3326 # @param V1,V2,V3,V4 Corner vertices for the face.
3327 # @return New GEOM_Object, containing the created face.
3329 # @ref tui_building_by_blocks_page "Example 1"
3330 # \n @ref swig_MakeQuad4Vertices "Example 2"
3331 def MakeQuad4Vertices(self,V1, V2, V3, V4):
3332 # Example: see GEOM_Spanner.py
3333 anObj = self.BlocksOp.MakeQuad4Vertices(V1, V2, V3, V4)
3334 RaiseIfFailed("MakeQuad4Vertices", self.BlocksOp)
3337 ## Create a hexahedral solid, bounded by the six given faces. Order of
3338 # faces is not important. It is not necessary that Faces share the same edge.
3339 # @param F1,F2,F3,F4,F5,F6 Faces for the hexahedral solid.
3340 # @return New GEOM_Object, containing the created solid.
3342 # @ref tui_building_by_blocks_page "Example 1"
3343 # \n @ref swig_MakeHexa "Example 2"
3344 def MakeHexa(self,F1, F2, F3, F4, F5, F6):
3345 # Example: see GEOM_Spanner.py
3346 anObj = self.BlocksOp.MakeHexa(F1, F2, F3, F4, F5, F6)
3347 RaiseIfFailed("MakeHexa", self.BlocksOp)
3350 ## Create a hexahedral solid between two given faces.
3351 # The missing faces will be built by creating the smallest ones.
3352 # @param F1,F2 Two opposite faces for the hexahedral solid.
3353 # @return New GEOM_Object, containing the created solid.
3355 # @ref tui_building_by_blocks_page "Example 1"
3356 # \n @ref swig_MakeHexa2Faces "Example 2"
3357 def MakeHexa2Faces(self,F1, F2):
3358 # Example: see GEOM_Spanner.py
3359 anObj = self.BlocksOp.MakeHexa2Faces(F1, F2)
3360 RaiseIfFailed("MakeHexa2Faces", self.BlocksOp)
3366 ## @addtogroup l3_blocks_op
3369 ## Get a vertex, found in the given shape by its coordinates.
3370 # @param theShape Block or a compound of blocks.
3371 # @param theX,theY,theZ Coordinates of the sought vertex.
3372 # @param theEpsilon Maximum allowed distance between the resulting
3373 # vertex and point with the given coordinates.
3374 # @return New GEOM_Object, containing the found vertex.
3376 # @ref swig_GetPoint "Example"
3377 def GetPoint(self,theShape, theX, theY, theZ, theEpsilon):
3378 # Example: see GEOM_TestOthers.py
3379 anObj = self.BlocksOp.GetPoint(theShape, theX, theY, theZ, theEpsilon)
3380 RaiseIfFailed("GetPoint", self.BlocksOp)
3383 ## Get an edge, found in the given shape by two given vertices.
3384 # @param theShape Block or a compound of blocks.
3385 # @param thePoint1,thePoint2 Points, close to the ends of the desired edge.
3386 # @return New GEOM_Object, containing the found edge.
3388 # @ref swig_todo "Example"
3389 def GetEdge(self,theShape, thePoint1, thePoint2):
3390 # Example: see GEOM_Spanner.py
3391 anObj = self.BlocksOp.GetEdge(theShape, thePoint1, thePoint2)
3392 RaiseIfFailed("GetEdge", self.BlocksOp)
3395 ## Find an edge of the given shape, which has minimal distance to the given point.
3396 # @param theShape Block or a compound of blocks.
3397 # @param thePoint Point, close to the desired edge.
3398 # @return New GEOM_Object, containing the found edge.
3400 # @ref swig_GetEdgeNearPoint "Example"
3401 def GetEdgeNearPoint(self,theShape, thePoint):
3402 # Example: see GEOM_TestOthers.py
3403 anObj = self.BlocksOp.GetEdgeNearPoint(theShape, thePoint)
3404 RaiseIfFailed("GetEdgeNearPoint", self.BlocksOp)
3407 ## Returns a face, found in the given shape by four given corner vertices.
3408 # @param theShape Block or a compound of blocks.
3409 # @param thePoint1,thePoint2,thePoint3,thePoint4 Points, close to the corners of the desired face.
3410 # @return New GEOM_Object, containing the found face.
3412 # @ref swig_todo "Example"
3413 def GetFaceByPoints(self,theShape, thePoint1, thePoint2, thePoint3, thePoint4):
3414 # Example: see GEOM_Spanner.py
3415 anObj = self.BlocksOp.GetFaceByPoints(theShape, thePoint1, thePoint2, thePoint3, thePoint4)
3416 RaiseIfFailed("GetFaceByPoints", self.BlocksOp)
3419 ## Get a face of block, found in the given shape by two given edges.
3420 # @param theShape Block or a compound of blocks.
3421 # @param theEdge1,theEdge2 Edges, close to the edges of the desired face.
3422 # @return New GEOM_Object, containing the found face.
3424 # @ref swig_todo "Example"
3425 def GetFaceByEdges(self,theShape, theEdge1, theEdge2):
3426 # Example: see GEOM_Spanner.py
3427 anObj = self.BlocksOp.GetFaceByEdges(theShape, theEdge1, theEdge2)
3428 RaiseIfFailed("GetFaceByEdges", self.BlocksOp)
3431 ## Find a face, opposite to the given one in the given block.
3432 # @param theBlock Must be a hexahedral solid.
3433 # @param theFace Face of \a theBlock, opposite to the desired face.
3434 # @return New GEOM_Object, containing the found face.
3436 # @ref swig_GetOppositeFace "Example"
3437 def GetOppositeFace(self,theBlock, theFace):
3438 # Example: see GEOM_Spanner.py
3439 anObj = self.BlocksOp.GetOppositeFace(theBlock, theFace)
3440 RaiseIfFailed("GetOppositeFace", self.BlocksOp)
3443 ## Find a face of the given shape, which has minimal distance to the given point.
3444 # @param theShape Block or a compound of blocks.
3445 # @param thePoint Point, close to the desired face.
3446 # @return New GEOM_Object, containing the found face.
3448 # @ref swig_GetFaceNearPoint "Example"
3449 def GetFaceNearPoint(self,theShape, thePoint):
3450 # Example: see GEOM_Spanner.py
3451 anObj = self.BlocksOp.GetFaceNearPoint(theShape, thePoint)
3452 RaiseIfFailed("GetFaceNearPoint", self.BlocksOp)
3455 ## Find a face of block, whose outside normale has minimal angle with the given vector.
3456 # @param theBlock Block or a compound of blocks.
3457 # @param theVector Vector, close to the normale of the desired face.
3458 # @return New GEOM_Object, containing the found face.
3460 # @ref swig_todo "Example"
3461 def GetFaceByNormale(self, theBlock, theVector):
3462 # Example: see GEOM_Spanner.py
3463 anObj = self.BlocksOp.GetFaceByNormale(theBlock, theVector)
3464 RaiseIfFailed("GetFaceByNormale", self.BlocksOp)
3467 # end of l3_blocks_op
3470 ## @addtogroup l4_blocks_measure
3473 ## Check, if the compound of blocks is given.
3474 # To be considered as a compound of blocks, the
3475 # given shape must satisfy the following conditions:
3476 # - Each element of the compound should be a Block (6 faces and 12 edges).
3477 # - A connection between two Blocks should be an entire quadrangle face or an entire edge.
3478 # - The compound should be connexe.
3479 # - The glue between two quadrangle faces should be applied.
3480 # @param theCompound The compound to check.
3481 # @return TRUE, if the given shape is a compound of blocks.
3482 # If theCompound is not valid, prints all discovered errors.
3484 # @ref tui_measurement_tools_page "Example 1"
3485 # \n @ref swig_CheckCompoundOfBlocks "Example 2"
3486 def CheckCompoundOfBlocks(self,theCompound):
3487 # Example: see GEOM_Spanner.py
3488 (IsValid, BCErrors) = self.BlocksOp.CheckCompoundOfBlocks(theCompound)
3489 RaiseIfFailed("CheckCompoundOfBlocks", self.BlocksOp)
3491 Descr = self.BlocksOp.PrintBCErrors(theCompound, BCErrors)
3495 ## Remove all seam and degenerated edges from \a theShape.
3496 # Unite faces and edges, sharing one surface. It means that
3497 # this faces must have references to one C++ surface object (handle).
3498 # @param theShape The compound or single solid to remove irregular edges from.
3499 # @param theOptimumNbFaces If more than zero, unite faces only for those solids,
3500 # that have more than theOptimumNbFaces faces. If zero, unite faces always,
3501 # regardsless their quantity in the solid. If negative (the default value),
3502 # do not unite faces at all. For blocks repairing recommended value is 6.
3503 # @return Improved shape.
3505 # @ref swig_RemoveExtraEdges "Example"
3506 def RemoveExtraEdges(self,theShape,theOptimumNbFaces=-1):
3507 # Example: see GEOM_TestOthers.py
3508 anObj = self.BlocksOp.RemoveExtraEdges(theShape,theOptimumNbFaces)
3509 RaiseIfFailed("RemoveExtraEdges", self.BlocksOp)
3512 ## Check, if the given shape is a blocks compound.
3513 # Fix all detected errors.
3514 # \note Single block can be also fixed by this method.
3515 # @param theShape The compound to check and improve.
3516 # @return Improved compound.
3518 # @ref swig_CheckAndImprove "Example"
3519 def CheckAndImprove(self,theShape):
3520 # Example: see GEOM_TestOthers.py
3521 anObj = self.BlocksOp.CheckAndImprove(theShape)
3522 RaiseIfFailed("CheckAndImprove", self.BlocksOp)
3525 # end of l4_blocks_measure
3528 ## @addtogroup l3_blocks_op
3531 ## Get all the blocks, contained in the given compound.
3532 # @param theCompound The compound to explode.
3533 # @param theMinNbFaces If solid has lower number of faces, it is not a block.
3534 # @param theMaxNbFaces If solid has higher number of faces, it is not a block.
3535 # \note If theMaxNbFaces = 0, the maximum number of faces is not restricted.
3536 # @return List of GEOM_Objects, containing the retrieved blocks.
3538 # @ref tui_explode_on_blocks "Example 1"
3539 # \n @ref swig_MakeBlockExplode "Example 2"
3540 def MakeBlockExplode(self,theCompound, theMinNbFaces, theMaxNbFaces):
3541 # Example: see GEOM_TestOthers.py
3542 theMinNbFaces,theMaxNbFaces,Parameters = ParseParameters(theMinNbFaces,theMaxNbFaces)
3543 aList = self.BlocksOp.ExplodeCompoundOfBlocks(theCompound, theMinNbFaces, theMaxNbFaces)
3544 RaiseIfFailed("ExplodeCompoundOfBlocks", self.BlocksOp)
3546 anObj.SetParameters(Parameters)
3550 ## Find block, containing the given point inside its volume or on boundary.
3551 # @param theCompound Compound, to find block in.
3552 # @param thePoint Point, close to the desired block. If the point lays on
3553 # boundary between some blocks, we return block with nearest center.
3554 # @return New GEOM_Object, containing the found block.
3556 # @ref swig_todo "Example"
3557 def GetBlockNearPoint(self,theCompound, thePoint):
3558 # Example: see GEOM_Spanner.py
3559 anObj = self.BlocksOp.GetBlockNearPoint(theCompound, thePoint)
3560 RaiseIfFailed("GetBlockNearPoint", self.BlocksOp)
3563 ## Find block, containing all the elements, passed as the parts, or maximum quantity of them.
3564 # @param theCompound Compound, to find block in.
3565 # @param theParts List of faces and/or edges and/or vertices to be parts of the found block.
3566 # @return New GEOM_Object, containing the found block.
3568 # @ref swig_GetBlockByParts "Example"
3569 def GetBlockByParts(self,theCompound, theParts):
3570 # Example: see GEOM_TestOthers.py
3571 anObj = self.BlocksOp.GetBlockByParts(theCompound, theParts)
3572 RaiseIfFailed("GetBlockByParts", self.BlocksOp)
3575 ## Return all blocks, containing all the elements, passed as the parts.
3576 # @param theCompound Compound, to find blocks in.
3577 # @param theParts List of faces and/or edges and/or vertices to be parts of the found blocks.
3578 # @return List of GEOM_Objects, containing the found blocks.
3580 # @ref swig_todo "Example"
3581 def GetBlocksByParts(self,theCompound, theParts):
3582 # Example: see GEOM_Spanner.py
3583 aList = self.BlocksOp.GetBlocksByParts(theCompound, theParts)
3584 RaiseIfFailed("GetBlocksByParts", self.BlocksOp)
3587 ## Multi-transformate block and glue the result.
3588 # Transformation is defined so, as to superpose direction faces.
3589 # @param Block Hexahedral solid to be multi-transformed.
3590 # @param DirFace1 ID of First direction face.
3591 # @param DirFace2 ID of Second direction face.
3592 # @param NbTimes Quantity of transformations to be done.
3593 # \note Unique ID of sub-shape can be obtained, using method GetSubShapeID().
3594 # @return New GEOM_Object, containing the result shape.
3596 # @ref tui_multi_transformation "Example"
3597 def MakeMultiTransformation1D(self,Block, DirFace1, DirFace2, NbTimes):
3598 # Example: see GEOM_Spanner.py
3599 DirFace1,DirFace2,NbTimes,Parameters = ParseParameters(DirFace1,DirFace2,NbTimes)
3600 anObj = self.BlocksOp.MakeMultiTransformation1D(Block, DirFace1, DirFace2, NbTimes)
3601 RaiseIfFailed("MakeMultiTransformation1D", self.BlocksOp)
3602 anObj.SetParameters(Parameters)
3605 ## Multi-transformate block and glue the result.
3606 # @param Block Hexahedral solid to be multi-transformed.
3607 # @param DirFace1U,DirFace2U IDs of Direction faces for the first transformation.
3608 # @param DirFace1V,DirFace2V IDs of Direction faces for the second transformation.
3609 # @param NbTimesU,NbTimesV Quantity of transformations to be done.
3610 # @return New GEOM_Object, containing the result shape.
3612 # @ref tui_multi_transformation "Example"
3613 def MakeMultiTransformation2D(self,Block, DirFace1U, DirFace2U, NbTimesU,
3614 DirFace1V, DirFace2V, NbTimesV):
3615 # Example: see GEOM_Spanner.py
3616 DirFace1U,DirFace2U,NbTimesU,DirFace1V,DirFace2V,NbTimesV,Parameters = ParseParameters(
3617 DirFace1U,DirFace2U,NbTimesU,DirFace1V,DirFace2V,NbTimesV)
3618 anObj = self.BlocksOp.MakeMultiTransformation2D(Block, DirFace1U, DirFace2U, NbTimesU,
3619 DirFace1V, DirFace2V, NbTimesV)
3620 RaiseIfFailed("MakeMultiTransformation2D", self.BlocksOp)
3621 anObj.SetParameters(Parameters)
3624 ## Build all possible propagation groups.
3625 # Propagation group is a set of all edges, opposite to one (main)
3626 # edge of this group directly or through other opposite edges.
3627 # Notion of Opposite Edge make sence only on quadrangle face.
3628 # @param theShape Shape to build propagation groups on.
3629 # @return List of GEOM_Objects, each of them is a propagation group.
3631 # @ref swig_Propagate "Example"
3632 def Propagate(self,theShape):
3633 # Example: see GEOM_TestOthers.py
3634 listChains = self.BlocksOp.Propagate(theShape)
3635 RaiseIfFailed("Propagate", self.BlocksOp)
3638 # end of l3_blocks_op
3641 ## @addtogroup l3_groups
3644 ## Creates a new group which will store sub shapes of theMainShape
3645 # @param theMainShape is a GEOM object on which the group is selected
3646 # @param theShapeType defines a shape type of the group
3647 # @return a newly created GEOM group
3649 # @ref tui_working_with_groups_page "Example 1"
3650 # \n @ref swig_CreateGroup "Example 2"
3651 def CreateGroup(self,theMainShape, theShapeType):
3652 # Example: see GEOM_TestOthers.py
3653 anObj = self.GroupOp.CreateGroup(theMainShape, theShapeType)
3654 RaiseIfFailed("CreateGroup", self.GroupOp)
3657 ## Adds a sub object with ID theSubShapeId to the group
3658 # @param theGroup is a GEOM group to which the new sub shape is added
3659 # @param theSubShapeID is a sub shape ID in the main object.
3660 # \note Use method GetSubShapeID() to get an unique ID of the sub shape
3662 # @ref tui_working_with_groups_page "Example"
3663 def AddObject(self,theGroup, theSubShapeID):
3664 # Example: see GEOM_TestOthers.py
3665 self.GroupOp.AddObject(theGroup, theSubShapeID)
3666 RaiseIfFailed("AddObject", self.GroupOp)
3669 ## Removes a sub object with ID \a theSubShapeId from the group
3670 # @param theGroup is a GEOM group from which the new sub shape is removed
3671 # @param theSubShapeID is a sub shape ID in the main object.
3672 # \note Use method GetSubShapeID() to get an unique ID of the sub shape
3674 # @ref tui_working_with_groups_page "Example"
3675 def RemoveObject(self,theGroup, theSubShapeID):
3676 # Example: see GEOM_TestOthers.py
3677 self.GroupOp.RemoveObject(theGroup, theSubShapeID)
3678 RaiseIfFailed("RemoveObject", self.GroupOp)
3681 ## Adds to the group all the given shapes. No errors, if some shapes are alredy included.
3682 # @param theGroup is a GEOM group to which the new sub shapes are added.
3683 # @param theSubShapes is a list of sub shapes to be added.
3685 # @ref tui_working_with_groups_page "Example"
3686 def UnionList (self,theGroup, theSubShapes):
3687 # Example: see GEOM_TestOthers.py
3688 self.GroupOp.UnionList(theGroup, theSubShapes)
3689 RaiseIfFailed("UnionList", self.GroupOp)
3692 ## Works like the above method, but argument
3693 # theSubShapes here is a list of sub-shapes indices
3695 # @ref swig_UnionIDs "Example"
3696 def UnionIDs(self,theGroup, theSubShapes):
3697 # Example: see GEOM_TestOthers.py
3698 self.GroupOp.UnionIDs(theGroup, theSubShapes)
3699 RaiseIfFailed("UnionIDs", self.GroupOp)
3702 ## Removes from the group all the given shapes. No errors, if some shapes are not included.
3703 # @param theGroup is a GEOM group from which the sub-shapes are removed.
3704 # @param theSubShapes is a list of sub-shapes to be removed.
3706 # @ref tui_working_with_groups_page "Example"
3707 def DifferenceList (self,theGroup, theSubShapes):
3708 # Example: see GEOM_TestOthers.py
3709 self.GroupOp.DifferenceList(theGroup, theSubShapes)
3710 RaiseIfFailed("DifferenceList", self.GroupOp)
3713 ## Works like the above method, but argument
3714 # theSubShapes here is a list of sub-shapes indices
3716 # @ref swig_DifferenceIDs "Example"
3717 def DifferenceIDs(self,theGroup, theSubShapes):
3718 # Example: see GEOM_TestOthers.py
3719 self.GroupOp.DifferenceIDs(theGroup, theSubShapes)
3720 RaiseIfFailed("DifferenceIDs", self.GroupOp)
3723 ## Returns a list of sub objects ID stored in the group
3724 # @param theGroup is a GEOM group for which a list of IDs is requested
3726 # @ref swig_GetObjectIDs "Example"
3727 def GetObjectIDs(self,theGroup):
3728 # Example: see GEOM_TestOthers.py
3729 ListIDs = self.GroupOp.GetObjects(theGroup)
3730 RaiseIfFailed("GetObjects", self.GroupOp)
3733 ## Returns a type of sub objects stored in the group
3734 # @param theGroup is a GEOM group which type is returned.
3736 # @ref swig_GetType "Example"
3737 def GetType(self,theGroup):
3738 # Example: see GEOM_TestOthers.py
3739 aType = self.GroupOp.GetType(theGroup)
3740 RaiseIfFailed("GetType", self.GroupOp)
3743 ## Returns a main shape associated with the group
3744 # @param theGroup is a GEOM group for which a main shape object is requested
3745 # @return a GEOM object which is a main shape for theGroup
3747 # @ref swig_GetMainShape "Example"
3748 def GetMainShape(self,theGroup):
3749 # Example: see GEOM_TestOthers.py
3750 anObj = self.GroupOp.GetMainShape(theGroup)
3751 RaiseIfFailed("GetMainShape", self.GroupOp)
3754 ## Create group of edges of theShape, whose length is in range [min_length, max_length].
3755 # If include_min/max == 0, edges with length == min/max_length will not be included in result.
3757 # @ref swig_todo "Example"
3758 def GetEdgesByLength (self, theShape, min_length, max_length, include_min = 1, include_max = 1):
3759 edges = self.SubShapeAll(theShape, ShapeType["EDGE"])
3762 Props = self.BasicProperties(edge)
3763 if min_length <= Props[0] and Props[0] <= max_length:
3764 if (not include_min) and (min_length == Props[0]):
3767 if (not include_max) and (Props[0] == max_length):
3770 edges_in_range.append(edge)
3772 if len(edges_in_range) <= 0:
3773 print "No edges found by given criteria"
3776 group_edges = self.CreateGroup(theShape, ShapeType["EDGE"])
3777 self.UnionList(group_edges, edges_in_range)
3781 ## Create group of edges of selected shape, whose length is in range [min_length, max_length].
3782 # If include_min/max == 0, edges with length == min/max_length will not be included in result.
3784 # @ref swig_todo "Example"
3785 def SelectEdges (self, min_length, max_length, include_min = 1, include_max = 1):
3786 nb_selected = sg.SelectedCount()
3788 print "Select a shape before calling this function, please."
3791 print "Only one shape must be selected"
3794 id_shape = sg.getSelected(0)
3795 shape = IDToObject( id_shape )
3797 group_edges = self.GetEdgesByLength(shape, min_length, max_length, include_min, include_max)
3801 if include_min: left_str = " <= "
3802 if include_max: right_str = " <= "
3804 self.addToStudyInFather(shape, group_edges, "Group of edges with " + `min_length`
3805 + left_str + "length" + right_str + `max_length`)
3807 sg.updateObjBrowser(1)
3814 ## Create a copy of the given object
3815 # @ingroup l1_geompy_auxiliary
3817 # @ref swig_all_advanced "Example"
3818 def MakeCopy(self,theOriginal):
3819 # Example: see GEOM_TestAll.py
3820 anObj = self.InsertOp.MakeCopy(theOriginal)
3821 RaiseIfFailed("MakeCopy", self.InsertOp)
3824 ## Add Path to load python scripts from
3825 # @ingroup l1_geompy_auxiliary
3826 def addPath(self,Path):
3827 if (sys.path.count(Path) < 1):
3828 sys.path.append(Path)
3831 #Register the new proxy for GEOM_Gen
3832 omniORB.registerObjref(GEOM._objref_GEOM_Gen._NP_RepositoryId, geompyDC)