Another TUI command is <em>geompy.GetAngleRadians(shape1,shape2),</em>
which returns the value of angle in radians.
+See also a \ref tui_angle_page "TUI example".
+
\image html angle.png
*/
\ No newline at end of file
\n<b>TUI Command:</b> <em>geompy.BasicProperties(Shape),</em> where
\em Shape is a shape whose properties are inquired.
+See also a \ref tui_basic_properties_page "TUI example".
+
\image html neo-basicprop.png
*/
\ No newline at end of file
boundaries, \em ClosedWires is a list of closed free boundary wires,
\em OpenWires is a list of open free boundary wires.
+See also a \ref tui_free_boundaries_page "TUI example".
+
\image html repair9.png
*/
\ No newline at end of file
\n <b>TUI Command:</b> <em>geompy.BoundingBox(Shape),</em> where \em Shape
is a shape for which a bounding box is computed.
+See also a \ref tui_bounding_box_page "TUI example".
+
\image html measures5.png
*/
\ No newline at end of file
\n <b>TUI Command:</b> <em> geompy.MakeCDG(Shape),</em> where \em Shape is
the shape for which a center of gravity is computed.
+See also a \ref tui_center_of_mass_page "TUI example".
+
\image html measures3.png
*/
\ No newline at end of file
+++ /dev/null
-/*!
-
-\page check_compound_page Check Compound of Blocks
-
-Checks whether a shape is a compound of glued blocks. To be
-considered as a compound of blocks, the given shape must satisfy the
-following conditions:
-<ul>
-<li>Each element of the compound should be a Block (6 faces and 12 edges);</li>
-<li>A connection between two Blocks should be an entire quadrangle face or an entire edge;</li>
-<li>The compound should be connected;</li>
-<li>Two quadrangle faces should be glued.</li>
-</ul>
-
-\n Informs of the following possible errors:
-<ul>
-<li>not a block;</li>
-<li>not glued;</li>
-<li>not connected;</li>
-<li>extra or degenerated edge.</li>
-</ul>
-
-\n <b>Result:</b> Boolean; highlight in the viewer.
-\n <b>TUI Command:</b>
-<em>geompy.CheckCompoundOfBlocks(Compound).</em> Checks if the shape
-is a valid compound of blocks. If it is true, then the validity flag
-is returned, and encountered errors are printed in the python console.
-
-\image html measures10.png
-
-*/
\ No newline at end of file
--- /dev/null
+/*!
+
+\page check_compound_of_blocks_page Check Compound of Blocks
+
+Checks whether a shape is a compound of glued blocks. To be
+considered as a compound of blocks, the given shape must satisfy the
+following conditions:
+<ul>
+<li>Each element of the compound should be a Block (6 faces and 12 edges);</li>
+<li>A connection between two Blocks should be an entire quadrangle face or an entire edge;</li>
+<li>The compound should be connected;</li>
+<li>Two quadrangle faces should be glued.</li>
+</ul>
+
+\n Informs of the following possible errors:
+<ul>
+<li>not a block;</li>
+<li>not glued;</li>
+<li>not connected;</li>
+<li>extra or degenerated edge.</li>
+</ul>
+
+\n <b>Result:</b> Boolean; highlight in the viewer.
+\n <b>TUI Command:</b>
+<em>geompy.CheckCompoundOfBlocks(Compound).</em> Checks if the shape
+is a valid compound of blocks. If it is true, then the validity flag
+is returned, and encountered errors are printed in the python console.
+
+See also a \ref tui_check_compound_of_blocks_page "TUI example".
+
+\image html measures10.png
+
+*/
\ No newline at end of file
--- /dev/null
+/*!
+
+\page check_self_intersections_page Detect Self-intersections
+
+\n Checks the topology of the selected shape to detect self-intersections.
+ Returns True if there are no self-intersections. Reports pairs of
+ intersected sub-shapes, if there are any.
+
+\note This tool is useful for detection of shapes, not suitable for
+arguments of Boolean operations and Partition algorithm.
+For more information about Partition and Boolean Operations Algorithms
+and their limitations refer to <a href="SALOME_BOA_PA.pdf">this document</a>.
+
+\n <b>Result:</b> Boolean.
+\n <b>TUI Command:</b> <em>geompy.CheckSelfIntersections(theShape),</em>
+where \em theShape is the shape checked for validity.
+
+See also a \ref tui_check_self_intersections_page "TUI example".
+
+\image html measures11.png
+
+*/
\ No newline at end of file
/*!
-\page check_page Check Shape
+\page check_shape_page Check Shape
\n Checks the topology of the selected geometrical object and returns
True if it is valid. Check also geometry checkbox allows to test the
\n <b>TUI Command:</b> <em>geompy.CheckShape(theShape, theIsCheckGeom = 0),</em>
where \em theShape is the shape checked for validity.
+See also a \ref tui_check_shape_page "TUI example".
+
\image html measures9.png
/*!
-\page faces_page Check Free Faces
+\page free_faces_page Check Free Faces
Highlights all free faces of a given shape. A free
face is a face which is not shared between two objects of the shape.
<b>TUI Command:</b> <em>GetFreeFacesIDs(Shape),</em> where \em Shape is
a shape to be checked.
+See also a \ref tui_free_faces_page "TUI example".
+
\image html repair10.png
*/
\ No newline at end of file
a shape for which the own matrix of inertia and the relative moments of inertia are
returned.
+See also a \ref tui_inertia_page "TUI example".
+
\image html measures4.png
*/
\ No newline at end of file
where \em Shape1 and \em Shape2 are shapes between which the minimal
distance is computed.
+See also a \ref tui_min_distance_page "TUI example".
+
\image html distance.png
*/
\ No newline at end of file
\n Calculates the normal vector to the selected \b Face. The \b Point
is a point of the \b Face, where the Normal should be calculated.
+\n <b>TUI Command:</b> <em>geompy.GetNormal(Face, OptionalPoint = None),</em> where \em Face is
+the face to define normale of and \em OptionalPoint is the point to compute the normal at.
+If the point is not given, the normale is calculated at the center of mass.
+
+See also a \ref tui_normal_face_page "TUI example".
+
\image html normaletoface.png
*/
\n<b>TUI Command:</b> <em>geompy.PointCoordinates(Point),</em>
where \em Point is a point whose coordinates are inquired.
+See also a \ref tui_point_coordinates_page "TUI example".
+
\image html measures1.png
*/
\ No newline at end of file
+++ /dev/null
-/*!
-
-\page check_self_intersections_page Detect Self-intersections
-
-\n Checks the topology of the selected shape to detect self-intersections.
- Returns True if there are no self-intersections. Reports pairs of
- intersected sub-shapes, if there are any.
-
-\note This tool is useful for detection of shapes, not suitable for
-arguments of Boolean operations and Partition algorithm.
-For more information about Partition and Boolean Operations Algorithms
-and their limitations refer to <a href="SALOME_BOA_PA.pdf">this document</a>.
-
-\n <b>Result:</b> Boolean.
-\n <b>TUI Command:</b> <em>geompy.CheckSelfIntersections(theShape),</em>
-where \em theShape is the shape checked for validity.
-
-\image html measures11.png
-
-*/
\ No newline at end of file
\n <b>TUI Command:</b> <em>geompy.Tolerance(Shape),</em> where \em Shape
is a shape for which minimal and maximal tolerances are returned.
+See also a \ref tui_tolerance_page "TUI example".
+
\image html new-tolerance.png
*/
\ No newline at end of file
--- /dev/null
+/*!
+
+\page tui_angle_page Angle
+
+\code
+import salome
+salome.salome_init()
+
+import math
+import geompy
+geompy.init_geom(salome.myStudy)
+
+OX = geompy.MakeVectorDXDYDZ(10, 0,0)
+OXY = geompy.MakeVectorDXDYDZ(10,10,0)
+
+# in one plane
+Angle = geompy.GetAngle(OX, OXY)
+
+print "\nAngle between OX and OXY = ", Angle
+if math.fabs(Angle - 45.0) > 1e-05:
+ print " Error: returned angle is", Angle, "while must be 45.0"
+ pass
+
+Angle = geompy.GetAngleRadians(OX, OXY)
+
+print "\nAngle between OX and OXY in radians = ", Angle
+if math.fabs(Angle - math.pi/4) > 1e-05:
+ print " Error: returned angle is", Angle, "while must be pi/4"
+ pass
+
+# not in one plane
+OXY_shift = geompy.MakeTranslation(OXY,10,-10,20)
+Angle = geompy.GetAngle(OX, OXY_shift)
+
+print "Angle between OX and OXY_shift = ", Angle
+if math.fabs(Angle - 45.0) > 1e-05:
+ print " Error: returned angle is", Angle, "while must be 45.0"
+ pass
+
+# not linear
+pnt1 = geompy.MakeVertex(0, 0, 0)
+pnt2 = geompy.MakeVertex(10, 0, 0)
+pnt3 = geompy.MakeVertex(20, 10, 0)
+arc = geompy.MakeArc(pnt1, pnt2, pnt3)
+Angle = geompy.GetAngle(OX, arc)
+
+if (math.fabs(Angle + 1.0) > 1e-6 or geompy.MeasuOp.IsDone()):
+ print "Error. Angle must not be computed on curvilinear edges"
+ pass
+
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_basic_properties_page Basic Properties
+
+\code
+import geompy
+import math
+
+# create a box
+box = geompy.MakeBoxDXDYDZ(100,30,100)
+props = geompy.BasicProperties(box)
+print "\nBox 100x30x100 Basic Properties:"
+print " Wires length: ", props[0]
+print " Surface area: ", props[1]
+print " Volume : ", props[2]
+length = math.sqrt((props[0] - 1840)*(props[0] - 1840))
+area = math.sqrt((props[1] - 32000)*(props[1] - 32000))
+volume = math.sqrt((props[2] - 300000)*(props[2] - 300000))
+if length > 1e-7 or area > 1e-7 or volume > 1e-7:
+ print "While must be:"
+ print " Wires length: ", 1840
+ print " Surface area: ", 32000
+ print " Volume : ", 300000.
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_bounding_box_page Bounding Box
+
+\code
+import geompy
+
+# create a box
+box = geompy.MakeBoxDXDYDZ(100,30,100)
+bb = geompy.BoundingBox(box)
+print "\nBounding Box of box 100x30x100:"
+print " Xmin = ", bb[0], ", Xmax = ", bb[1]
+print " Ymin = ", bb[2], ", Ymax = ", bb[3]
+print " Zmin = ", bb[4], ", Zmax = ", bb[5]
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_center_of_mass_page Center of masses
+
+\code
+import geompy
+import math
+
+# create a box
+box = geompy.MakeBoxDXDYDZ(100,30,100)
+cm = geompy.MakeCDG(box)
+if cm is None:
+ raise RuntimeError, "MakeCDG(box) failed"
+else:
+ print "\nCentre of gravity of box has been successfully obtained:"
+ coords = geompy.PointCoordinates(cm)
+ print "(", coords[0], ", ", coords[1], ", ", coords[2], ")"
+ dx = math.sqrt((coords[0] - 50)*(coords[0] - 50))
+ dy = math.sqrt((coords[1] - 15)*(coords[1] - 15))
+ dz = math.sqrt((coords[2] - 50)*(coords[2] - 50))
+ if dx > 1e-7 or dy > 1e-7 or dz > 1e-7:
+ print "But must be (50, 15, 50)"
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_check_compound_of_blocks_page Check Compound of Blocks
+
+\code
+import geompy
+import salome
+gg = salome.ImportComponentGUI("GEOM")
+
+# create boxes
+box1 = geompy.MakeBox(0,0,0,100,50,100)
+box2 = geompy.MakeBox(100,0,0,250,50,100)
+
+# make a compound
+compound = geompy.MakeCompound([box1, box2])
+
+# glue the faces of the compound
+tolerance = 1e-5
+glue = geompy.MakeGlueFaces(compound, tolerance)
+IsValid = geompy.CheckCompoundOfBlocks(glue)
+if IsValid == 0:
+ raise RuntimeError, "Invalid compound created"
+else:
+ print "\nCompound is valid"
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_check_self_intersections_page Detect Self-intersections
+
+\code
+import geompy
+
+# create a box
+box = geompy.MakeBoxDXDYDZ(100,30,100)
+IsValid = geompy.CheckSelfIntersections(box)
+if IsValid == 0:
+ raise RuntimeError, "Box with self-intersections created"
+else:
+ print "\nBox is valid"
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_check_shape_page Check Shape
+
+\code
+import geompy
+
+# create a box
+box = geompy.MakeBoxDXDYDZ(100,30,100)
+IsValid = geompy.CheckShape(box)
+if IsValid == 0:
+ raise RuntimeError, "Invalid box created"
+else:
+ print "\nBox is valid"
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_free_boundaries_page Check Free Boundaries
+
+\code
+import os
+import geompy
+import salome
+gg = salome.ImportComponentGUI("GEOM")
+
+# create boxes
+box1 = geompy.MakeBox(0,0,0,100,50,100)
+box2 = geompy.MakeBox(100,0,0,250,50,100)
+
+# make a compound
+compound = geompy.MakeCompound([box1, box2])
+
+# import from *.brep
+ImportFromBREP = geompy.ImportBREP(os.getenv("DATA_DIR")+"/Shapes/Brep/flight_solid.brep")
+
+# get a face
+faces = geompy.SubShapeAllSortedCentres(ImportFromBREP, geompy.ShapeType["FACE"])
+
+# get the free boundary for face 32
+Res = geompy.GetFreeBoundary(faces[32])
+isSuccess = Res[0]
+ClosedWires = Res[1]
+OpenWires = Res[2]
+
+if isSuccess == 1 :
+ print "Checking free boudaries is OK."
+else :
+ print "Checking free boudaries is KO!"
+print "len(ClosedWires) = ", len(ClosedWires)
+
+i = 0
+for wire in ClosedWires :
+ wire_name = "Face 32 -> Close wires : WIRE %d"%(i+1)
+ geompy.addToStudy(ClosedWires[i], wire_name)
+ if i < len(ClosedWires) :
+ i = i+ 1
+
+print "len(OpenWires) = ", len(OpenWires)
+
+i = 0
+for wire in OpenWires :
+ wire_name = "Face 32 -> Open wires : WIRE %d"%(i+1)
+ geompy.addToStudy(OpenWires[i], wire_name)
+ if i < len(OpenWires) :
+ i = i+ 1
+
+# get the free boundary for face 41
+Res = geompy.GetFreeBoundary(faces[41])
+isSuccess = Res[0]
+ClosedWires = Res[1]
+OpenWires = Res[2]
+
+if isSuccess == 1 :
+ print "Checking free boudaries is OK."
+else :
+ print "Checking free boudaries is KO!"
+print "len(ClosedWires) = ", len(ClosedWires)
+
+i = 0
+for wire in ClosedWires :
+ wire_name = "Face 41 -> Close wires : WIRE %d"%(i+1)
+ geompy.addToStudy(ClosedWires[i], wire_name)
+ if i < len(ClosedWires) :
+ i = i+ 1
+
+print "len(OpenWires) = ", len(OpenWires)
+
+i = 0
+for wire in OpenWires :
+ wire_name = "Face 41 -> Open wires : WIRE %d"%(i+1)
+ geompy.addToStudy(OpenWires[i], wire_name)
+ if i < len(OpenWires) :
+ i = i+ 1
+
+# add the imported object to the study
+id_ImportFromBREP = geompy.addToStudy(ImportFromBREP, "ImportFromBREP")
+salome.sg.updateObjBrowser(1)
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_free_faces_page Check Free Faces
+
+\code
+import geompy
+import salome
+gg = salome.ImportComponentGUI("GEOM")
+
+# create a vertex and a vector
+p1 = geompy.MakeVertex(35, 35, 0)
+p2 = geompy.MakeVertex(35, 35, 50)
+v = geompy.MakeVector(p1, p2)
+
+# create a cylinder
+cylinder = geompy.MakeCone(p1, v, 30, 20, 20)
+
+# create a cone
+cone = geompy.MakeCone(p1, v, 70, 40, 60)
+
+# make cut
+cut = geompy.MakeCut(cone, cylinder)
+
+# get faces as sub-shapes
+faces = []
+faces = geompy.SubShapeAllSortedCentres(cut, geompy.ShapeType["FACE"])
+f_2 = geompy.GetSubShapeID(cut, faces[0])
+
+# remove one face from the shape
+cut_without_f_2 = geompy.SuppressFaces(cut, [f_2])
+
+# suppress the specified wire
+result = geompy.GetFreeFacesIDs(cut_without_f_2)
+print "A number of free faces is ", len(result)
+
+# add objects in the study
+all_faces = geompy.SubShapeAllSortedCentres(cut_without_f_2, geompy.ShapeType["FACE"])
+for face in all_faces :
+ sub_shape_id = geompy.GetSubShapeID(cut_without_f_2, face)
+ if result.count(sub_shape_id) > 0 :
+ face_name = "Free face %d"%(sub_shape_id)
+ geompy.addToStudy(face, face_name)
+
+# in this example all faces from cut_without_f_2 are free
+id_cut_without_f_2 = geompy.addToStudy(cut_without_f_2, "Cut without f_2")
+
+# display the results
+gg.createAndDisplayGO(id_cut_without_f_2)
+gg.setDisplayMode(id_cut_without_f_2,1)
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_inertia_page Inertia
+
+\code
+import geompy
+import math
+
+# create a box
+box = geompy.MakeBoxDXDYDZ(100,30,100)
+In = geompy.Inertia(box)
+print "\nInertia matrix of box 100x30x100:"
+print " (", In[0], ", ", In[1], ", ", In[2], ")"
+print " (", In[3], ", ", In[4], ", ", In[5], ")"
+print " (", In[6], ", ", In[7], ", ", In[8], ")"
+print "Main moments of inertia of box 100x30x100:"
+print " Ix = ", In[9], ", Iy = ", In[10], ", Iz = ", In[11]
+\endcode
+
+*/
\page tui_measurement_tools_page Measurement Tools
-<br><h2>Point Coordinates</h2>
-
-\code
-import math
-import geompy
-
-# create a point
-point = geompy.MakeVertex(15., 23., 80.)
-
-# get the coordinates of the point and check its values
-coords = geompy.PointCoordinates(point)
-
-# check the obtained coordinate values
-tolerance = 1.e-07
-def IsEqual(val1, val2): return (math.fabs(val1 - val2) < tolerance)
-
-if IsEqual(coords[0], 15.) and IsEqual(coords[1], 23.) and IsEqual(coords[2], 80.):
- print "All values are OK."
-else :
- print "Coordinates of point must be (15, 23, 80), but returned (",
- print coords[0], ", ", coords[1], ", ", coords[2], ")"
- pass
-\endcode
-
-<br><h2>Basic Properties</h2>
-
-\code
-import geompy
-import math
-
-# create a box
-box = geompy.MakeBoxDXDYDZ(100,30,100)
-props = geompy.BasicProperties(box)
-print "\nBox 100x30x100 Basic Properties:"
-print " Wires length: ", props[0]
-print " Surface area: ", props[1]
-print " Volume : ", props[2]
-length = math.sqrt((props[0] - 1840)*(props[0] - 1840))
-area = math.sqrt((props[1] - 32000)*(props[1] - 32000))
-volume = math.sqrt((props[2] - 300000)*(props[2] - 300000))
-if length > 1e-7 or area > 1e-7 or volume > 1e-7:
- print "While must be:"
- print " Wires length: ", 1840
- print " Surface area: ", 32000
- print " Volume : ", 300000.
-\endcode
-
-<br><h2>Center of masses</h2>
-
-\code
-import geompy
-import math
-
-# create a box
-box = geompy.MakeBoxDXDYDZ(100,30,100)
-cm = geompy.MakeCDG(box)
-if cm is None:
- raise RuntimeError, "MakeCDG(box) failed"
-else:
- print "\nCentre of gravity of box has been successfully obtained:"
- coords = geompy.PointCoordinates(cm)
- print "(", coords[0], ", ", coords[1], ", ", coords[2], ")"
- dx = math.sqrt((coords[0] - 50)*(coords[0] - 50))
- dy = math.sqrt((coords[1] - 15)*(coords[1] - 15))
- dz = math.sqrt((coords[2] - 50)*(coords[2] - 50))
- if dx > 1e-7 or dy > 1e-7 or dz > 1e-7:
- print "But must be (50, 15, 50)"
-\endcode
-
-<br><h2>Get vertex by index</h2>
-
-\code
-import geompy
-
-# Create auxiliary objects
-Vertex_1 = geompy.MakeVertex(0, 0, 0)
-Vertex_2 = geompy.MakeVertex(10, 20, 0)
-Vertex_3 = geompy.MakeVertex(0, 40, 0)
-Vertex_4 = geompy.MakeVertex(-10, 60, 0)
-Vertex_5 = geompy.MakeVertex(0, 80, 0)
-Curve_1 = geompy.MakeInterpol([Vertex_1, Vertex_2, Vertex_3])
-Curve_2 = geompy.MakeInterpol([Vertex_5, Vertex_4, Vertex_3])
-Wire_1 = geompy.MakeWire([Curve_1, Curve_2])
-Reversed_Wire = geompy.ChangeOrientationShellCopy(Wire_1)
-
-# Get The vertexes from Reversed Wire by different functions
-vertex_0 = geompy.GetFirstVertex(Reversed_Wire)
-vertex_1 = geompy.GetVertexByIndex(Reversed_Wire, 1)
-vertex_2 = geompy.GetLastVertex(Reversed_Wire)
-
-# Publish objects in study
-geompy.addToStudy( Wire_1, "Wire_1" )
-geompy.addToStudy( Reversed_Wire, "Reversed_Wire" )
-geompy.addToStudy( vertex_0, "vertex_0" )
-geompy.addToStudy( vertex_1, "vertex_1" )
-geompy.addToStudy( vertex_2, "vertex_2" )
-\endcode
-
-<br><h2>Inertia</h2>
-
-\code
-import geompy
-import math
-
-# create a box
-box = geompy.MakeBoxDXDYDZ(100,30,100)
-In = geompy.Inertia(box)
-print "\nInertia matrix of box 100x30x100:"
-print " (", In[0], ", ", In[1], ", ", In[2], ")"
-print " (", In[3], ", ", In[4], ", ", In[5], ")"
-print " (", In[6], ", ", In[7], ", ", In[8], ")"
-print "Main moments of inertia of box 100x30x100:"
-print " Ix = ", In[9], ", Iy = ", In[10], ", Iz = ", In[11]
-\endcode
-
-<br><h2>Check Free Boundaries</h2>
-
-\code
-import os
-import geompy
-import salome
-gg = salome.ImportComponentGUI("GEOM")
-
-# create boxes
-box1 = geompy.MakeBox(0,0,0,100,50,100)
-box2 = geompy.MakeBox(100,0,0,250,50,100)
-
-# make a compound
-compound = geompy.MakeCompound([box1, box2])
-
-# import from *.brep
-ImportFromBREP = geompy.ImportBREP(os.getenv("DATA_DIR")+"/Shapes/Brep/flight_solid.brep")
-
-# get a face
-faces = geompy.SubShapeAllSortedCentres(ImportFromBREP, geompy.ShapeType["FACE"])
-
-# get the free boundary for face 32
-Res = geompy.GetFreeBoundary(faces[32])
-isSuccess = Res[0]
-ClosedWires = Res[1]
-OpenWires = Res[2]
-
-if isSuccess == 1 :
- print "Checking free boudaries is OK."
-else :
- print "Checking free boudaries is KO!"
-print "len(ClosedWires) = ", len(ClosedWires)
-
-i = 0
-for wire in ClosedWires :
- wire_name = "Face 32 -> Close wires : WIRE %d"%(i+1)
- geompy.addToStudy(ClosedWires[i], wire_name)
- if i < len(ClosedWires) :
- i = i+ 1
-
-print "len(OpenWires) = ", len(OpenWires)
-
-i = 0
-for wire in OpenWires :
- wire_name = "Face 32 -> Open wires : WIRE %d"%(i+1)
- geompy.addToStudy(OpenWires[i], wire_name)
- if i < len(OpenWires) :
- i = i+ 1
-
-# get the free boundary for face 41
-Res = geompy.GetFreeBoundary(faces[41])
-isSuccess = Res[0]
-ClosedWires = Res[1]
-OpenWires = Res[2]
-
-if isSuccess == 1 :
- print "Checking free boudaries is OK."
-else :
- print "Checking free boudaries is KO!"
-print "len(ClosedWires) = ", len(ClosedWires)
-
-i = 0
-for wire in ClosedWires :
- wire_name = "Face 41 -> Close wires : WIRE %d"%(i+1)
- geompy.addToStudy(ClosedWires[i], wire_name)
- if i < len(ClosedWires) :
- i = i+ 1
-
-print "len(OpenWires) = ", len(OpenWires)
-
-i = 0
-for wire in OpenWires :
- wire_name = "Face 41 -> Open wires : WIRE %d"%(i+1)
- geompy.addToStudy(OpenWires[i], wire_name)
- if i < len(OpenWires) :
- i = i+ 1
-
-# add the imported object to the study
-id_ImportFromBREP = geompy.addToStudy(ImportFromBREP, "ImportFromBREP")
-salome.sg.updateObjBrowser(1)
-\endcode
-
-
-<br><h2>Check Free Faces</h2>
-
-\code
-import geompy
-import salome
-gg = salome.ImportComponentGUI("GEOM")
-
-# create a vertex and a vector
-p1 = geompy.MakeVertex(35, 35, 0)
-p2 = geompy.MakeVertex(35, 35, 50)
-v = geompy.MakeVector(p1, p2)
-
-# create a cylinder
-cylinder = geompy.MakeCone(p1, v, 30, 20, 20)
-
-# create a cone
-cone = geompy.MakeCone(p1, v, 70, 40, 60)
-
-# make cut
-cut = geompy.MakeCut(cone, cylinder)
-
-# get faces as sub-shapes
-faces = []
-faces = geompy.SubShapeAllSortedCentres(cut, geompy.ShapeType["FACE"])
-f_2 = geompy.GetSubShapeID(cut, faces[0])
-
-# remove one face from the shape
-cut_without_f_2 = geompy.SuppressFaces(cut, [f_2])
-
-# suppress the specified wire
-result = geompy.GetFreeFacesIDs(cut_without_f_2)
-print "A number of free faces is ", len(result)
-
-# add objects in the study
-all_faces = geompy.SubShapeAllSortedCentres(cut_without_f_2, geompy.ShapeType["FACE"])
-for face in all_faces :
- sub_shape_id = geompy.GetSubShapeID(cut_without_f_2, face)
- if result.count(sub_shape_id) > 0 :
- face_name = "Free face %d"%(sub_shape_id)
- geompy.addToStudy(face, face_name)
-
-# in this example all faces from cut_without_f_2 are free
-id_cut_without_f_2 = geompy.addToStudy(cut_without_f_2, "Cut without f_2")
-
-# display the results
-gg.createAndDisplayGO(id_cut_without_f_2)
-gg.setDisplayMode(id_cut_without_f_2,1)
-\endcode
-
-
-
-<br><h2>Bounding Box</h2>
-
-\code
-import geompy
-
-# create a box
-box = geompy.MakeBoxDXDYDZ(100,30,100)
-bb = geompy.BoundingBox(box)
-print "\nBounding Box of box 100x30x100:"
-print " Xmin = ", bb[0], ", Xmax = ", bb[1]
-print " Ymin = ", bb[2], ", Ymax = ", bb[3]
-print " Zmin = ", bb[4], ", Zmax = ", bb[5]
-\endcode
-
-<br><h2>Minimal Distance</h2>
-
-\code
-import geompy
-
-# create boxes
-box1 = geompy.MakeBoxDXDYDZ(100,30,100)
-box2 = geompy.MakeBox(105,0,0,200,30,100)
-min_dist = geompy.MinDistance(box1,box2)
-print "\nMinimal distance between box1 and box2 = ", min_dist
-\endcode
-
-<br><h2>Tolerance</h2>
-
-\code
-import geompy
-
-# create a box
-box = geompy.MakeBoxDXDYDZ(100,30,100)
-Toler = geompy.Tolerance(box)
-print "\nBox 100x30x100 tolerance:"
-print " Face min. tolerance: ", Toler[0]
-print " Face max. tolerance: ", Toler[1]
-print " Edge min. tolerance: ", Toler[2]
-print " Edge max. tolerance: ", Toler[3]
-print " Vertex min. tolerance: ", Toler[4]
-print " Vertex max. tolerance: ", Toler[5]
-\endcode
-
-<br><h2>Angle</h2>
-
-\code
-import salome
-salome.salome_init()
-
-import math
-import geompy
-geompy.init_geom(salome.myStudy)
-
-OX = geompy.MakeVectorDXDYDZ(10, 0,0)
-OXY = geompy.MakeVectorDXDYDZ(10,10,0)
-
-# in one plane
-Angle = geompy.GetAngle(OX, OXY)
-
-print "\nAngle between OX and OXY = ", Angle
-if math.fabs(Angle - 45.0) > 1e-05:
- print " Error: returned angle is", Angle, "while must be 45.0"
- pass
-
-Angle = geompy.GetAngleRadians(OX, OXY)
-
-print "\nAngle between OX and OXY in radians = ", Angle
-if math.fabs(Angle - math.pi/4) > 1e-05:
- print " Error: returned angle is", Angle, "while must be pi/4"
- pass
-
-# not in one plane
-OXY_shift = geompy.MakeTranslation(OXY,10,-10,20)
-Angle = geompy.GetAngle(OX, OXY_shift)
-
-print "Angle between OX and OXY_shift = ", Angle
-if math.fabs(Angle - 45.0) > 1e-05:
- print " Error: returned angle is", Angle, "while must be 45.0"
- pass
-
-# not linear
-pnt1 = geompy.MakeVertex(0, 0, 0)
-pnt2 = geompy.MakeVertex(10, 0, 0)
-pnt3 = geompy.MakeVertex(20, 10, 0)
-arc = geompy.MakeArc(pnt1, pnt2, pnt3)
-Angle = geompy.GetAngle(OX, arc)
-
-if (math.fabs(Angle + 1.0) > 1e-6 or geompy.MeasuOp.IsDone()):
- print "Error. Angle must not be computed on curvilinear edges"
- pass
-
-\endcode
-
-
-<br><h2>What Is</h2>
-
-\code
-import geompy
-
-# create a box
-box = geompy.MakeBoxDXDYDZ(100,30,100)
-Descr = geompy.WhatIs(box)
-print "\nBox 100x30x100 description:"
-print Descr
-\endcode
-
-<br><h2>NbShapes and ShapeInfo</h2>
-
-\code
-import geompy
-
-# create a box
-box = geompy.MakeBoxDXDYDZ(100,30,100)
-nbSolids = geompy.NbShapes(box, geompy.ShapeType["SOLID"])
-print "\nBox 100x30x100 quantity of solids:", nbSolids
-boxInfo = geompy.ShapeInfo(box)
-print "\nBox 100x30x100 shapes:"
-print boxInfo
-\endcode
-
-<br><h2>Check Shape</h2>
-
-\code
-import geompy
-
-# create a box
-box = geompy.MakeBoxDXDYDZ(100,30,100)
-IsValid = geompy.CheckShape(box)
-if IsValid == 0:
- raise RuntimeError, "Invalid box created"
-else:
- print "\nBox is valid"
-\endcode
-
-<br><h2>Detect Self-intersections</h2>
-
-\code
-import geompy
-
-# create a box
-box = geompy.MakeBoxDXDYDZ(100,30,100)
-IsValid = geompy.CheckSelfIntersections(box)
-if IsValid == 0:
- raise RuntimeError, "Box with self-intersections created"
-else:
- print "\nBox is valid"
-\endcode
-
-<br><h2>Check Compound of Blocks</h2>
-
-\code
-import geompy
-import salome
-gg = salome.ImportComponentGUI("GEOM")
-
-# create boxes
-box1 = geompy.MakeBox(0,0,0,100,50,100)
-box2 = geompy.MakeBox(100,0,0,250,50,100)
-
-# make a compound
-compound = geompy.MakeCompound([box1, box2])
-
-# glue the faces of the compound
-tolerance = 1e-5
-glue = geompy.MakeGlueFaces(compound, tolerance)
-IsValid = geompy.CheckCompoundOfBlocks(glue)
-if IsValid == 0:
- raise RuntimeError, "Invalid compound created"
-else:
- print "\nCompound is valid"
-\endcode
+<ul>
+<li>\subpage tui_point_coordinates_page</li>
+<li>\subpage tui_basic_properties_page</li>
+<li>\subpage tui_center_of_mass_page</li>
+<li>\subpage tui_inertia_page</li>
+<li>\subpage tui_normal_face_page</li>
+<li>\subpage tui_bounding_box_page</li>
+<li>\subpage tui_min_distance_page</li>
+<li>\subpage tui_angle_page</li>
+<li>\subpage tui_tolerance_page</li>
+<li>\subpage tui_whatis_page</li>
+<li>\subpage tui_free_boundaries_page</li>
+<li>\subpage tui_free_faces_page</li>
+<li>\subpage tui_check_shape_page</li>
+<li>\subpage tui_check_compound_of_blocks_page</li>
+<li>\subpage tui_check_self_intersections_page</li>
+</ul>
*/
--- /dev/null
+/*!
+
+\page tui_min_distance_page Minimal Distance
+
+\code
+import geompy
+
+# create boxes
+box1 = geompy.MakeBoxDXDYDZ(100,30,100)
+box2 = geompy.MakeBox(105,0,0,200,30,100)
+min_dist = geompy.MinDistance(box1,box2)
+print "\nMinimal distance between box1 and box2 = ", min_dist
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_normal_face_page Normal to a Face
+
+\code
+import geompy
+import math
+
+# create a box
+box = geompy.MakeBoxDXDYDZ(100,30,100)
+
+faces = geompy.SubShapeAllSortedCentres(box, geompy.ShapeType["FACE"])
+face0 = faces[0]
+vnorm = geompy.GetNormal(face0)
+if vnorm is None:
+ raise RuntimeError, "GetNormal(face0) failed"
+else:
+ geompy.addToStudy(face0, "Face0")
+ geompy.addToStudy(vnorm, "Normale to Face0")
+ print "\nNormale of face has been successfully obtained"
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_point_coordinates_page Point Coordinates
+
+\code
+import math
+import geompy
+
+# create a point
+point = geompy.MakeVertex(15., 23., 80.)
+
+# get the coordinates of the point and check its values
+coords = geompy.PointCoordinates(point)
+
+# check the obtained coordinate values
+tolerance = 1.e-07
+def IsEqual(val1, val2): return (math.fabs(val1 - val2) < tolerance)
+
+if IsEqual(coords[0], 15.) and IsEqual(coords[1], 23.) and IsEqual(coords[2], 80.):
+ print "All values are OK."
+else :
+ print "Coordinates of point must be (15, 23, 80), but returned (",
+ print coords[0], ", ", coords[1], ", ", coords[2], ")"
+ pass
+\endcode
+
+*/
\ No newline at end of file
<li>\subpage tui_test_others_page</li>
<li>\subpage tui_test_spanner_page</li>
<li>\subpage tui_test_all_page</li>
+ <li>\subpage tui_test_measures_page</li>
</ul>
*/
--- /dev/null
+/*!
+
+\page tui_test_measures_page GEOM_TestMeasures.py
+
+\anchor swig_TestMeasures
+<br><h2>GEOM_TestMeasures.py</h2>
+
+\dontinclude GEOM_TestMeasures.py
+\skipline def TestMeasureOperations
+
+\until PointCoordinates
+
+\anchor swig_PointCoordinates
+\until CheckShape
+
+\anchor swig_CheckShape
+\until MakeCompound
+
+\anchor swig_CheckSelfIntersections
+\until WhatIs
+
+\anchor swig_WhatIs
+\until BasicProperties
+
+\anchor swig_BasicProperties
+\until BoundingBox
+
+\anchor swig_BoundingBox
+\until Inertia
+
+\anchor swig_Inertia
+\until Tolerance
+
+\anchor swig_Tolerance
+\until MakeCDG
+
+\anchor swig_MakeCDG
+\until But must be
+
+\until face0
+
+\anchor swig_GetNormal
+\until MinDistance
+
+\anchor swig_MinDistance
+\until in one plane
+
+\anchor swig_GetAngle
+\until Error
+
+\anchor swig_GetAngleRadians
+\until pass
+
+*/
--- /dev/null
+/*!
+
+\page tui_tolerance_page Tolerance
+
+\code
+import geompy
+
+# create a box
+box = geompy.MakeBoxDXDYDZ(100,30,100)
+Toler = geompy.Tolerance(box)
+print "\nBox 100x30x100 tolerance:"
+print " Face min. tolerance: ", Toler[0]
+print " Face max. tolerance: ", Toler[1]
+print " Edge min. tolerance: ", Toler[2]
+print " Edge max. tolerance: ", Toler[3]
+print " Vertex min. tolerance: ", Toler[4]
+print " Vertex max. tolerance: ", Toler[5]
+\endcode
+
+*/
--- /dev/null
+/*!
+
+\page tui_whatis_page What Is
+
+\code
+import geompy
+
+# create a box
+box = geompy.MakeBoxDXDYDZ(100,30,100)
+Descr = geompy.WhatIs(box)
+print "\nBox 100x30x100 description:"
+print Descr
+\endcode
+
+*/
<ul>
<li>\subpage boundaries_page "Check Free Boundaries"</li>
-<li>\subpage faces_page "Check Free Faces"</li>
-<li>\subpage check_page "Check Shape"</li>
-<li>\subpage check_compound_page "Check compound of blocks"</li>
+<li>\subpage free_faces_page "Check Free Faces"</li>
+<li>\subpage check_shape_page "Check Shape"</li>
+<li>\subpage check_compound_of_blocks_page "Check compound of blocks"</li>
<li>\subpage check_self_intersections_page "Detect Self-intersections"</li>
</ul>
\n <b>TUI Command:</b> <em>geompy.WhatIs(Shape),</em> where \em Shape is a
shape from which a description is returned.
+See also a \ref tui_whatis_page "TUI example".
+
\image html measures8.png
\n <b>Kind of Shape</b> field characterises the
