def read_step_file_shapes(filename):
_shapes = []
# create an handle to a document
h_doc = TDocStd_Document()
# Create the application
app = XCAFApp_Application.GetApplication().GetObject()
app.NewDocument(TCollection_ExtendedString("MDTV-CAF"), h_doc)
# Get root assembly
doc = h_doc.GetObject()
h_shape_tool = XCAFDoc_DocumentTool_ShapeTool(doc.Main())
step_reader = STEPCAFControl_Reader()
step_reader.SetNameMode(True)
status = step_reader.ReadFile(filename)
if status == IFSelect_RetDone:
step_reader.Transfer(doc)
labels = TDF_LabelSequence()
shape_tool = h_shape_tool.GetObject()
h_shape_tool.GetObject().GetFreeShapes(labels)
print("Number of shapes at root :%i" % labels.Length())
for i in range(labels.Length()):
label = labels.Value(i + 1)
a_shape = h_shape_tool.GetObject().GetShape(label)
_shapes.append(a_shape)
return _shapes
def test_read_step_file(self) -> None:
"""Reads the previous step file"""
# create an handle to a document
doc = TDocStd_Document(TCollection_ExtendedString("pythonocc-doc"))
# Get root assembly
shape_tool = XCAFDoc_DocumentTool.ShapeTool(doc.Main())
l_colors = XCAFDoc_DocumentTool.ColorTool(doc.Main())
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile("./test_io/test_ocaf.stp")
if status == IFSelect_RetDone:
step_reader.Transfer(doc)
labels = TDF_LabelSequence()
color_labels = TDF_LabelSequence()
shape_tool.GetFreeShapes(labels)
self.assertEqual(labels.Length(), 1)
sub_shapes_labels = TDF_LabelSequence()
self.assertFalse(shape_tool.IsAssembly(labels.Value(1)))
shape_tool.GetSubShapes(labels.Value(1), sub_shapes_labels)
self.assertEqual(sub_shapes_labels.Length(), 0)
l_colors.GetColors(color_labels)
self.assertEqual(color_labels.Length(), 1)
label_shp = labels.Value(1)
a_shape = shape_tool.GetShape(label_shp)
self.assertFalse(a_shape.IsNull())
def load_stp_at_top(self):
"""Get OCAF document from STEP file and assign it directly to self.doc.
This works as a surrogate for loading a CAD project that has previously
been saved as a STEP file."""
prompt = 'Select STEP file to import'
fnametuple = QFileDialog.getOpenFileName(
None, prompt, './', "STEP files (*.stp *.STP *.step)")
fname, _ = fnametuple
logger.debug("Load file name: %s", fname)
if not fname:
print("Load step cancelled")
return
tmodel = TreeModel("DOC")
step_shape_tool = tmodel.shape_tool
step_color_tool = tmodel.color_tool
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile(fname)
if status == IFSelect_RetDone:
logger.info("Transfer doc to STEPCAFControl_Reader")
step_reader.Transfer(tmodel.doc)
self.doc = tmodel.doc
# Build new self.part_dict & self.label_dict
self.parse_doc()
def doc_linter(self, doc=None):
"""Clean self.doc by cycling through a STEP save/load cycle."""
if doc is None:
doc = self.doc
# Create a file object to save to
fname = "deleteme.txt"
# Initialize STEP exporter
WS = XSControl_WorkSession()
step_writer = STEPCAFControl_Writer(WS, False)
# Transfer shapes and write file
step_writer.Transfer(doc, STEPControl_AsIs)
status = step_writer.Write(fname)
assert status == IFSelect_RetDone
# Create new TreeModel and read STEP data
tmodel = TreeModel("DOC")
shape_tool = tmodel.shape_tool
color_tool = tmodel.color_tool
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile(fname)
if status == IFSelect_RetDone:
logger.info("Transfer doc to STEPCAFControl_Reader")
step_reader.Transfer(tmodel.doc)
os.remove(fname)
return tmodel.doc
def read_file(self, fname):
"""Read STEP file and return <TDocStd_Document>."""
# Create the application, empty document and shape_tool
doc = TDocStd_Document(TCollection_ExtendedString("STEP"))
app = XCAFApp_Application_GetApplication()
app.NewDocument(TCollection_ExtendedString("MDTV-XCAF"), doc)
self.shape_tool = XCAFDoc_DocumentTool_ShapeTool(doc.Main())
self.shape_tool.SetAutoNaming(True)
# Read file and return populated doc
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile(fname)
if status == IFSelect_RetDone:
step_reader.Transfer(doc)
return doc
def read_step(self, fn):
"""
Read and translate a STEP file.
:param str fn: The filename.
:return: The shapes label.
:rtype: afem.exchange.xde.Label.
:raise RuntimeError: If the file cannot be read.
"""
reader = STEPCAFControl_Reader()
reader.SetNameMode(True)
reader.SetColorMode(True)
status = reader.Perform(fn, self._doc)
if not status:
raise RuntimeError("Error reading STEP file.")
self._shape = Shape.wrap(reader.Reader().OneShape())
label = XCAFDoc_DocumentTool.ShapesLabel_(self._doc.Main())
return XdeLabel(label)
def load_stp_cmpnt(self):
"""Get OCAF document from STEP file and add (as component) to doc root.
This is the way to load step files containing a single shape at root."""
prompt = 'Select STEP file to import'
fnametuple = QFileDialog.getOpenFileName(
None, prompt, './', "STEP files (*.stp *.STP *.step)")
fname, _ = fnametuple
logger.debug("Load file name: %s", fname)
if not fname:
print("Load step cancelled")
return
tmodel = TreeModel("DOC")
step_shape_tool = tmodel.shape_tool
step_color_tool = tmodel.color_tool
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile(fname)
if status == IFSelect_RetDone:
logger.info("Transfer doc to STEPCAFControl_Reader")
step_reader.Transfer(tmodel.doc)
# Get root label of step data
labels = TDF_LabelSequence()
step_shape_tool.GetShapes(labels)
for j in range(labels.Length()):
label = labels.Value(j + 1)
shape = step_shape_tool.GetShape(label)
color = Quantity_Color()
name = label.GetLabelName()
step_color_tool.GetColor(shape, XCAFDoc_ColorSurf, color)
isSimpleShape = step_shape_tool.IsSimpleShape(label)
if isSimpleShape:
_ = self.addComponent(shape, name, color)
def test_read_step_file(self):
''' Reads the previous step file '''
# create an handle to a document
h_doc = Handle_TDocStd_Document()
# Create the application
app = XCAFApp_Application.GetApplication().GetObject()
app.NewDocument(TCollection_ExtendedString("MDTV-CAF"), h_doc)
# Get root assembly
doc = h_doc.GetObject()
h_shape_tool = XCAFDoc_DocumentTool_ShapeTool(doc.Main())
l_colors = XCAFDoc_DocumentTool_ColorTool(doc.Main())
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile("./test_io/test_ocaf.stp")
if status == IFSelect_RetDone:
step_reader.Transfer(doc.GetHandle())
labels = TDF_LabelSequence()
color_labels = TDF_LabelSequence()
shape_tool = h_shape_tool.GetObject()
h_shape_tool.GetObject().GetFreeShapes(labels)
assert (labels.Length() == 1)
sub_shapes_labels = TDF_LabelSequence()
assert (not shape_tool.IsAssembly(labels.Value(1)))
shape_tool.GetSubShapes(labels.Value(1), sub_shapes_labels)
assert (sub_shapes_labels.Length() == 0)
l_colors.GetObject().GetColors(color_labels)
assert (color_labels.Length() == 1)
label_shp = labels.Value(1)
a_shape = h_shape_tool.GetObject().GetShape(label_shp)
assert (not a_shape.IsNull())
# Create the application
app = XCAFApp_Application.GetApplication().GetObject()
app.NewDocument(TCollection_ExtendedString("MDTV-CAF"), h_doc)
# Get root assembly
doc = h_doc.GetObject()
h_shape_tool = XCAFDoc_DocumentTool_ShapeTool(doc.Main())
h_color_tool = XCAFDoc_DocumentTool_ColorTool(doc.Main())
h_layer_tool = XCAFDoc_DocumentTool_LayerTool(doc.Main())
h_mat_tool = XCAFDoc_DocumentTool_MaterialTool(doc.Main())
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile(filename)
if status == IFSelect_RetDone:
step_reader.Transfer(doc.GetHandle())
shape_tool = h_shape_tool.GetObject()
shape_tool.SetAutoNaming(True)
color_tool = h_color_tool.GetObject()
lvl = 0
locs = []
cnt = 0
def read_file(self):
"""Build tree = treelib.Tree() to facilitate displaying the CAD model and
constructing the tree view showing the assembly/component relationships.
Each node of self.tree contains the following:
(Name, UID, ParentUID, {Data}) where the Data keys are:
'a' (isAssy?), 'l' (TopLoc_Location), 'c' (Quantity_Color), 's' (TopoDS_Shape)
"""
logger.info("Reading STEP file")
tmodel = TreeModel("STEP")
self.shape_tool = tmodel.shape_tool
self.color_tool = tmodel.color_tool
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile(self.filename)
if status == IFSelect_RetDone:
logger.info("Transfer doc to STEPCAFControl_Reader")
step_reader.Transfer(tmodel.doc)
labels = TDF_LabelSequence()
self.shape_tool.GetShapes(labels)
logger.info('Number of labels at root : %i', labels.Length())
try:
rootlabel = labels.Value(1) # First label at root
except RuntimeError:
return
name = self.getName(rootlabel)
logger.info('Name of root label: %s', name)
isAssy = self.shape_tool.IsAssembly(rootlabel)
logger.info("First label at root holds an assembly? %s", isAssy)
if isAssy:
# If first label at root holds an assembly, it is the Top Assembly.
# Through this label, the entire assembly is accessible.
# there is no need to examine other labels at root explicitly.
topLoc = TopLoc_Location()
topLoc = self.shape_tool.GetLocation(rootlabel)
self.assyLocStack.append(topLoc)
entry = rootlabel.EntryDumpToString()
logger.debug("Entry: %s", entry)
logger.debug("Top assy name: %s", name)
# Create root node for top assy
newAssyUID = self.getNewUID()
self.tree.create_node(name, newAssyUID, None,
{'a': True, 'l': None, 'c': None, 's': None})
self.assyUidStack.append(newAssyUID)
topComps = TDF_LabelSequence() # Components of Top Assy
subchilds = False
isAssy = self.shape_tool.GetComponents(rootlabel, topComps, subchilds)
logger.debug("Is Assembly? %s", isAssy)
logger.debug("Number of components: %s", topComps.Length())
logger.debug("Is Reference? %s", self.shape_tool.IsReference(rootlabel))
if topComps.Length():
self.findComponents(rootlabel, topComps)
else:
# Labels at root can hold solids or compounds (which are 'crude' assemblies)
# Either way, we will need to create a root node in self.tree
newAssyUID = self.getNewUID()
self.tree.create_node(os.path.basename(self.filename),
newAssyUID, None,
{'a': True, 'l': None, 'c': None, 's': None})
self.assyUidStack = [newAssyUID]
for j in range(labels.Length()):
label = labels.Value(j+1)
name = self.getName(label)
isAssy = self.shape_tool.IsAssembly(label)
logger.debug("Label %i is assembly?: %s", j+1, isAssy)
shape = self.shape_tool.GetShape(label)
color = self.getColor(shape)
isSimpleShape = self.shape_tool.IsSimpleShape(label)
logger.debug("Is Simple Shape? %s", isSimpleShape)
shapeType = shape.ShapeType()
logger.debug("The shape type is: %i", shapeType)
if shapeType == 0:
logger.debug("The shape type is OCC.Core.TopAbs.TopAbs_COMPOUND")
topo = TopologyExplorer(shape)
#topo = aocutils.topology.Topo(shape)
logger.debug("Nb of compounds : %i", topo.number_of_compounds())
logger.debug("Nb of solids : %i", topo.number_of_solids())
logger.debug("Nb of shells : %i", topo.number_of_shells())
newAssyUID = self.getNewUID()
for i, solid in enumerate(topo.solids()):
name = "P%s" % str(i+1)
self.tree.create_node(name, self.getNewUID(),
self.assyUidStack[-1],
{'a': False, 'l': None,
'c': color, 's': solid})
elif shapeType == 2:
logger.debug("The shape type is OCC.Core.TopAbs.TopAbs_SOLID")
self.tree.create_node(name, self.getNewUID(),
self.assyUidStack[-1],
{'a': False, 'l': None,
'c': color, 's': shape})
elif shapeType == 3:
logger.debug("The shape type is OCC.Core.TopAbs.TopAbs_SHELL")
self.tree.create_node(name, self.getNewUID(),
self.assyUidStack[-1],
{'a': False, 'l': None,
'c': color, 's': shape})
return tmodel.doc # <class 'OCC.Core.TDocStd.TDocStd_Document'>
def read_step_file_with_names_colors(filename):
""" Returns list of tuples (topods_shape, label, color)
Use OCAF.
"""
# the list:
output_shapes = []
# create an handle to a document
doc = TDocStd_Document(TCollection_ExtendedString("pythonocc-doc"))
# Get root assembly
shape_tool = XCAFDoc_DocumentTool_ShapeTool(doc.Main())
color_tool = XCAFDoc_DocumentTool_ColorTool(doc.Main())
#layer_tool = XCAFDoc_DocumentTool_LayerTool(doc.Main())
#mat_tool = XCAFDoc_DocumentTool_MaterialTool(doc.Main())
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile(filename)
if status == IFSelect_RetDone:
step_reader.Transfer(doc)
shape_tool.SetAutoNaming(True)
#lvl = 0
locs = []
#cnt = 0
def _get_label_name(lab):
entry = TCollection_AsciiString()
TDF_Tool.Entry(lab, entry)
n = TDataStd_Name()
lab.FindAttribute(TDataStd_Name_GetID(), n)
if n:
return n.Get().PrintToString()
return "No Name"
def _get_sub_shapes(lab, loc):
#global cnt, lvl
#cnt += 1
#print("\n[%d] level %d, handling LABEL %s\n" % (cnt, lvl, _get_label_name(lab)))
#print()
#print(lab.DumpToString())
#print()
#print("Is Assembly :", shape_tool.IsAssembly(lab))
#print("Is Free :", shape_tool.IsFree(lab))
#print("Is Shape :", shape_tool.IsShape(lab))
#print("Is Compound :", shape_tool.IsCompound(lab))
#print("Is Component :", shape_tool.IsComponent(lab))
#print("Is SimpleShape :", shape_tool.IsSimpleShape(lab))
#print("Is Reference :", shape_tool.IsReference(lab))
#users = TDF_LabelSequence()
#users_cnt = shape_tool.GetUsers(lab, users)
#print("Nr Users :", users_cnt)
l_subss = TDF_LabelSequence()
shape_tool.GetSubShapes(lab, l_subss)
#print("Nb subshapes :", l_subss.Length())
l_comps = TDF_LabelSequence()
shape_tool.GetComponents(lab, l_comps)
#print("Nb components :", l_comps.Length())
#print()
if shape_tool.IsAssembly(lab):
l_c = TDF_LabelSequence()
shape_tool.GetComponents(lab, l_c)
for i in range(l_c.Length()):
label = l_c.Value(i + 1)
if shape_tool.IsReference(label):
#print("\n######## reference label :", label)
label_reference = TDF_Label()
shape_tool.GetReferredShape(label, label_reference)
loc = shape_tool.GetLocation(label)
#print(" loc :", loc)
#trans = loc.Transformation()
#print(" tran form :", trans.Form())
#rot = trans.GetRotation()
#print(" rotation :", rot)
#print(" X :", rot.X())
#print(" Y :", rot.Y())
#print(" Z :", rot.Z())
#print(" W :", rot.W())
#tran = trans.TranslationPart()
#print(" translation :", tran)
#print(" X :", tran.X())
#print(" Y :", tran.Y())
#print(" Z :", tran.Z())
locs.append(loc)
#print(">>>>")
#lvl += 1
_get_sub_shapes(label_reference, loc)
#lvl -= 1
#print("<<<<")
locs.pop()
elif shape_tool.IsSimpleShape(lab):
#print("\n######## simpleshape label :", lab)
shape = shape_tool.GetShape(lab)
#print(" all ass locs :", locs)
loc = TopLoc_Location()
for i in range(len(locs)):
#print(" take loc :", locs[i])
loc = loc.Multiplied(locs[i])
#trans = loc.Transformation()
#print(" FINAL loc :")
#print(" tran form :", trans.Form())
#rot = trans.GetRotation()
#print(" rotation :", rot)
#print(" X :", rot.X())
#print(" Y :", rot.Y())
#print(" Z :", rot.Z())
#print(" W :", rot.W())
#tran = trans.TranslationPart()
#print(" translation :", tran)
#print(" X :", tran.X())
#print(" Y :", tran.Y())
#print(" Z :", tran.Z())
shape = BRepBuilderAPI_Transform(shape,
loc.Transformation()).Shape()
c = Quantity_Color()
# colorSet = False
# if (color_tool.GetInstanceColor(shape, 0, c) or
# color_tool.GetInstanceColor(shape, 1, c) or
# color_tool.GetInstanceColor(shape, 2, c)):
# for i in (0, 1, 2):
# color_tool.SetInstanceColor(shape, i, c)
# colorSet = True
# n = c.Name(c.Red(), c.Green(), c.Blue())
# #print(' instance color Name & RGB: ', c, n, c.Red(), c.Green(), c.Blue())
# if not colorSet:
color_tool.GetColor(lab, 0, c)
color_tool.GetColor(lab, 1, c)
color_tool.GetColor(lab, 2, c)
#for i in (0, 1, 2):
# color_tool.SetInstanceColor(shape, i, c)
#n = c.Name(c.Red(), c.Green(), c.Blue())
#print(' shape color Name & RGB: ', c, n, c.Red(), c.Green(), c.Blue())
# for i in range(l_subss.Length()):
# lab = l_subss.Value(i+1)
# print("\n######## simpleshape subshape label :", lab)
# shape_sub = shape_tool.GetShape(lab)
# c = Quantity_Color()
# colorSet = False
# if (color_tool.GetInstanceColor(shape_sub, 0, c) or
# color_tool.GetInstanceColor(shape_sub, 1, c) or
# color_tool.GetInstanceColor(shape_sub, 2, c)):
# for i in (0, 1, 2):
# color_tool.SetInstanceColor(shape_sub, i, c)
# colorSet = True
# n = c.Name(c.Red(), c.Green(), c.Blue())
# #print(' instance color Name & RGB: ', c, n, c.Red(), c.Green(), c.Blue())
# if not colorSet:
# if (color_tool.GetColor(lab, 0, c) or
# color_tool.GetColor(lab, 1, c) or
# color_tool.GetColor(lab, 2, c)):
# for i in (0, 1, 2):
# color_tool.SetInstanceColor(shape, i, c)
# n = c.Name(c.Red(), c.Green(), c.Blue())
# #print(' shape color Name & RGB: ', c, n, c.Red(), c.Green(), c.Blue())
output_shapes.append([shape, _get_label_name(lab), c])
def _get_shapes():
labels = TDF_LabelSequence()
shape_tool.GetFreeShapes(labels)
#global cnt
#cnt += 1
print()
print("Number of shapes at root :", labels.Length())
print()
root = labels.Value(1)
_get_sub_shapes(root, None)
_get_shapes()
return output_shapes
def read_step_file_with_names_colors(filename):
""" Returns list of tuples (topods_shape, label, color)
Use OCAF.
"""
if not os.path.isfile(filename):
raise FileNotFoundError("%s not found." % filename)
# the list:
output_shapes = {}
# create an handle to a document
doc = TDocStd_Document(TCollection_ExtendedString("pythonocc-doc"))
# Get root assembly
shape_tool = XCAFDoc_DocumentTool_ShapeTool(doc.Main())
color_tool = XCAFDoc_DocumentTool_ColorTool(doc.Main())
#layer_tool = XCAFDoc_DocumentTool_LayerTool(doc.Main())
#mat_tool = XCAFDoc_DocumentTool_MaterialTool(doc.Main())
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
step_reader.SetGDTMode(True)
status = step_reader.ReadFile(filename)
if status == IFSelect_RetDone:
step_reader.Transfer(doc)
locs = []
def _get_sub_shapes(lab, loc):
#global cnt, lvl
#cnt += 1
#print("\n[%d] level %d, handling LABEL %s\n" % (cnt, lvl, _get_label_name(lab)))
#print()
#print(lab.DumpToString())
#print()
#print("Is Assembly :", shape_tool.IsAssembly(lab))
#print("Is Free :", shape_tool.IsFree(lab))
#print("Is Shape :", shape_tool.IsShape(lab))
#print("Is Compound :", shape_tool.IsCompound(lab))
#print("Is Component :", shape_tool.IsComponent(lab))
#print("Is SimpleShape :", shape_tool.IsSimpleShape(lab))
#print("Is Reference :", shape_tool.IsReference(lab))
#users = TDF_LabelSequence()
#users_cnt = shape_tool.GetUsers(lab, users)
#print("Nr Users :", users_cnt)
l_subss = TDF_LabelSequence()
shape_tool.GetSubShapes(lab, l_subss)
#print("Nb subshapes :", l_subss.Length())
l_comps = TDF_LabelSequence()
shape_tool.GetComponents(lab, l_comps)
#print("Nb components :", l_comps.Length())
#print()
name = lab.GetLabelName()
print("Name :", name)
if shape_tool.IsAssembly(lab):
l_c = TDF_LabelSequence()
shape_tool.GetComponents(lab, l_c)
for i in range(l_c.Length()):
label = l_c.Value(i + 1)
if shape_tool.IsReference(label):
#print("\n######## reference label :", label)
label_reference = TDF_Label()
shape_tool.GetReferredShape(label, label_reference)
loc = shape_tool.GetLocation(label)
#print(" loc :", loc)
#trans = loc.Transformation()
#print(" tran form :", trans.Form())
#rot = trans.GetRotation()
#print(" rotation :", rot)
#print(" X :", rot.X())
#print(" Y :", rot.Y())
#print(" Z :", rot.Z())
#print(" W :", rot.W())
#tran = trans.TranslationPart()
#print(" translation :", tran)
#print(" X :", tran.X())
#print(" Y :", tran.Y())
#print(" Z :", tran.Z())
locs.append(loc)
#print(">>>>")
#lvl += 1
_get_sub_shapes(label_reference, loc)
#lvl -= 1
#print("<<<<")
locs.pop()
elif shape_tool.IsSimpleShape(lab):
#print("\n######## simpleshape label :", lab)
shape = shape_tool.GetShape(lab)
#print(" all ass locs :", locs)
loc = TopLoc_Location()
for l in locs:
#print(" take loc :", l)
loc = loc.Multiplied(l)
#trans = loc.Transformation()
#print(" FINAL loc :")
#print(" tran form :", trans.Form())
#rot = trans.GetRotation()
#print(" rotation :", rot)
#print(" X :", rot.X())
#print(" Y :", rot.Y())
#print(" Z :", rot.Z())
#print(" W :", rot.W())
#tran = trans.TranslationPart()
#print(" translation :", tran)
#print(" X :", tran.X())
#print(" Y :", tran.Y())
#print(" Z :", tran.Z())
c = Quantity_Color(0.5, 0.5, 0.5,
Quantity_TOC_RGB) # default color
colorSet = False
if (color_tool.GetInstanceColor(shape, 0, c)
or color_tool.GetInstanceColor(shape, 1, c)
or color_tool.GetInstanceColor(shape, 2, c)):
color_tool.SetInstanceColor(shape, 0, c)
color_tool.SetInstanceColor(shape, 1, c)
color_tool.SetInstanceColor(shape, 2, c)
colorSet = True
n = c.Name(c.Red(), c.Green(), c.Blue())
print(' instance color Name & RGB: ', c, n, c.Red(),
c.Green(), c.Blue())
if not colorSet:
if (color_tool.GetColor(lab, 0, c)
or color_tool.GetColor(lab, 1, c)
or color_tool.GetColor(lab, 2, c)):
color_tool.SetInstanceColor(shape, 0, c)
color_tool.SetInstanceColor(shape, 1, c)
color_tool.SetInstanceColor(shape, 2, c)
n = c.Name(c.Red(), c.Green(), c.Blue())
print(' shape color Name & RGB: ', c, n, c.Red(),
c.Green(), c.Blue())
shape_disp = BRepBuilderAPI_Transform(
shape, loc.Transformation()).Shape()
if not shape_disp in output_shapes:
output_shapes[shape_disp] = [lab.GetLabelName(), c]
for i in range(l_subss.Length()):
lab_subs = l_subss.Value(i + 1)
#print("\n######## simpleshape subshape label :", lab)
shape_sub = shape_tool.GetShape(lab_subs)
c = Quantity_Color(0.5, 0.5, 0.5,
Quantity_TOC_RGB) # default color
colorSet = False
if (color_tool.GetInstanceColor(shape_sub, 0, c)
or color_tool.GetInstanceColor(shape_sub, 1, c)
or color_tool.GetInstanceColor(shape_sub, 2, c)):
color_tool.SetInstanceColor(shape_sub, 0, c)
color_tool.SetInstanceColor(shape_sub, 1, c)
color_tool.SetInstanceColor(shape_sub, 2, c)
colorSet = True
n = c.Name(c.Red(), c.Green(), c.Blue())
print(' instance color Name & RGB: ', c, n, c.Red(),
c.Green(), c.Blue())
if not colorSet:
if (color_tool.GetColor(lab_subs, 0, c)
or color_tool.GetColor(lab_subs, 1, c)
or color_tool.GetColor(lab_subs, 2, c)):
color_tool.SetInstanceColor(shape, 0, c)
color_tool.SetInstanceColor(shape, 1, c)
color_tool.SetInstanceColor(shape, 2, c)
n = c.Name(c.Red(), c.Green(), c.Blue())
print(' shape color Name & RGB: ', c, n, c.Red(),
c.Green(), c.Blue())
shape_to_disp = BRepBuilderAPI_Transform(
shape_sub, loc.Transformation()).Shape()
# position the subshape to display
if not shape_to_disp in output_shapes:
output_shapes[shape_to_disp] = [lab_subs.GetLabelName(), c]
def _get_shapes():
labels = TDF_LabelSequence()
shape_tool.GetFreeShapes(labels)
#global cnt
#cnt += 1
print()
print("Number of shapes at root :", labels.Length())
print()
for i in range(labels.Length()):
root_item = labels.Value(i + 1)
_get_sub_shapes(root_item, None)
_get_shapes()
return output_shapes
def read_file(self):
r"""Read file"""
logger.info("Reading STEP file")
h_doc = Handle_TDocStd_Document()
# Create the application
app = _XCAFApp.XCAFApp_Application_GetApplication().GetObject()
app.NewDocument(TCollection_ExtendedString("MDTV-CAF"), h_doc)
# Get root assembly
doc = h_doc.GetObject()
h_shape_tool = XCAFDoc_DocumentTool().ShapeTool(doc.Main())
color_tool = XCAFDoc_DocumentTool().ColorTool(doc.Main())
layer_tool = XCAFDoc_DocumentTool().LayerTool(doc.Main())
_ = XCAFDoc_DocumentTool().MaterialTool(doc.Main())
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile(str(self.filename))
if status == IFSelect_RetDone:
logger.info("Transfer doc to STEPCAFControl_Reader")
step_reader.Transfer(doc.GetHandle())
labels = TDF_LabelSequence()
_ = TDF_LabelSequence()
# TopoDS_Shape a_shape;
_ = h_shape_tool.GetObject()
h_shape_tool.GetObject().GetFreeShapes(labels)
logger.info('Number of shapes at root :%i' % labels.Length())
# for i in range(labels.Length()):
# a_shape = h_shape_tool.GetObject().GetShape(labels.Value(i+1))
# logger.debug("%i - type : %s" % (i, a_shape.ShapeType()))
# sub_shapes_labels = TDF_LabelSequence()
# print("Is Assembly?", shape_tool.IsAssembly(labels.Value(i + 1)))
# # sub_shapes = shape_tool.getsubshapes(labels.Value(i+1),
# sub_shapes_labels)
#
# sub_shapes = shape_tool.FindSubShape(labels.Value(i + 1),
# a_shape, labels.Value(i + 1))
# print('Number of subshapes in the assembly : %i' %
# sub_shapes_labels.Length())
#
# color_tool.GetObject().GetColors(color_labels)
# logger.info('Number of colors : %i' % color_labels.Length())
for i in range(labels.Length()):
# print i
label = labels.Value(i + 1)
logger.debug("Label : %s" % label)
a_shape = h_shape_tool.GetObject().GetShape(labels.Value(i + 1))
# string_seq = TColStd_HSequenceOfExtendedString()
# string_seq is an TColStd_HSequenceOfExtendedString
string_seq = layer_tool.GetObject().GetLayers(a_shape)
color = Quantity_Color()
_ = color_tool.GetObject().GetColor(a_shape, XCAFDoc_ColorSurf,
color)
logger.info("The shape type is : %i" % a_shape.ShapeType())
if a_shape.ShapeType() == TopAbs_COMPOUND:
logger.info("The shape type is TopAbs_COMPOUND")
topo = Topo(a_shape)
logger.info("Nb of compounds : %i" % topo.number_of_compounds)
logger.info("Nb of solids : %i" % topo.number_of_solids)
logger.info("Nb of shells : %i" % topo.number_of_shells)
for solid in topo.solids:
logger.info("Adding solid to the shapes list")
self._shapes.append(solid)
elif a_shape.ShapeType() == TopAbs_SOLID:
logger.info("The shape type is TopAbs_SOLID")
self._shapes.append(a_shape)
self._colors.append(color)
self._layers.append(string_seq)
return True
def load_stp_undr_top(self):
"""Paste step root label under 1st label at self.doc root
Add a simple component to the first label at self.doc root.
Set the component name to be the name of the step file.
Then assign the label of the referred shape to 'targetLabel'.
Finally, copy step root label onto 'targetLabel'.
This works when copying file 'as1-oc-214.stp' to 0:1:1:2 (n=2) but does
not get part color at higher values of n. Also doesn't work with file
'as1_pe_203.stp' loaded at any value of n. ???
"""
prompt = 'Select STEP file to import'
fnametuple = QFileDialog.getOpenFileName(
None, prompt, './', "STEP files (*.stp *.STP *.step)")
fname, _ = fnametuple # fname = /path/to/some/filename.ext
base = os.path.basename(fname) # filename.ext
filename, ext = os.path.splitext(base)
logger.debug("Load file name: %s", fname)
if not fname:
print("Load step cancelled")
return
# Get the step data
tmodel = TreeModel("STEP")
step_shape_tool = tmodel.shape_tool
step_color_tool = tmodel.color_tool
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile(fname)
if status == IFSelect_RetDone:
logger.info("Transfer doc to STEPCAFControl_Reader")
step_reader.Transfer(tmodel.doc)
# Delint tmodel.doc & make new tools
step_doc = self.doc_linter(tmodel.doc)
step_shape_tool = XCAFDoc_DocumentTool_ShapeTool(step_doc.Main())
step_color_tool = XCAFDoc_DocumentTool_ColorTool(step_doc.Main())
# Get root label of step data
step_labels = TDF_LabelSequence()
step_shape_tool.GetShapes(step_labels)
steprootLabel = step_labels.Value(1)
# Make a simple box and add it as a component
myBody = BRepPrimAPI_MakeBox(4, 4, 4).Shape()
_ = self.addComponent(myBody, filename, Quantity_ColorRGBA())
step_shape_tool.UpdateAssemblies()
# Get target label of self.doc
labels = TDF_LabelSequence() # labels at root
shape_tool = XCAFDoc_DocumentTool_ShapeTool(self.doc.Main())
color_tool = XCAFDoc_DocumentTool_ColorTool(self.doc.Main())
shape_tool.GetShapes(labels)
n = labels.Length() # number of labels at root
print(n)
targetLabel = labels.Value(n) # of ref shape of comp just added
# Copy source label to target label
self.copy_label(steprootLabel, targetLabel)
shape_tool.UpdateAssemblies()
# Repair self.doc by cycling through save/load
self.doc = self.doc_linter()
# Build new self.part_dict & tree view
self.parse_doc()
def OCC_read_file(self, filename):
#######################################################################
## HR 14/7/20
## All python-occ intialisation for 3D view
## Adapted from src/Extend/DataExchange.py script from python-occ, here:
## https://github.com/tpaviot/pythonocc-core
# Changed to odict to allow direct mapping to step_dict (see later)
output_shapes = odict()
# Create an handle to a document
doc = TDocStd_Document(TCollection_ExtendedString("pythonocc-doc"))
# Get root assembly
shape_tool = XCAFDoc_DocumentTool_ShapeTool(doc.Main())
color_tool = XCAFDoc_DocumentTool_ColorTool(doc.Main())
#layer_tool = XCAFDoc_DocumentTool_LayerTool(doc.Main())
#mat_tool = XCAFDoc_DocumentTool_MaterialTool(doc.Main())
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
step_reader.SetGDTMode(True)
status = step_reader.ReadFile(filename)
if status == IFSelect_RetDone:
step_reader.Transfer(doc)
print('Transfer done')
locs = []
def _get_sub_shapes(lab, loc):
l_subss = TDF_LabelSequence()
shape_tool.GetSubShapes(lab, l_subss)
#print("Nb subshapes :", l_subss.Length())
l_comps = TDF_LabelSequence()
shape_tool.GetComponents(lab, l_comps)
#print("Nb components :", l_comps.Length())
#print()
name = lab.GetLabelName()
print("Name :", name)
if shape_tool.IsAssembly(lab):
l_c = TDF_LabelSequence()
shape_tool.GetComponents(lab, l_c)
for i in range(l_c.Length()):
label = l_c.Value(i + 1)
if shape_tool.IsReference(label):
label_reference = TDF_Label()
shape_tool.GetReferredShape(label, label_reference)
loc = shape_tool.GetLocation(label)
locs.append(loc)
_get_sub_shapes(label_reference, loc)
locs.pop()
elif shape_tool.IsSimpleShape(lab):
shape = shape_tool.GetShape(lab)
loc = TopLoc_Location()
for l in locs:
loc = loc.Multiplied(l)
c = Quantity_Color(0.5, 0.5, 0.5,
Quantity_TOC_RGB) # default color
colorSet = False
if (color_tool.GetInstanceColor(shape, 0, c)
or color_tool.GetInstanceColor(shape, 1, c)
or color_tool.GetInstanceColor(shape, 2, c)):
color_tool.SetInstanceColor(shape, 0, c)
color_tool.SetInstanceColor(shape, 1, c)
color_tool.SetInstanceColor(shape, 2, c)
colorSet = True
n = c.Name(c.Red(), c.Green(), c.Blue())
print(' Instance color Name & RGB: ', c, n, c.Red(),
c.Green(), c.Blue())
if not colorSet:
if (color_tool.GetColor(lab, 0, c)
or color_tool.GetColor(lab, 1, c)
or color_tool.GetColor(lab, 2, c)):
color_tool.SetInstanceColor(shape, 0, c)
color_tool.SetInstanceColor(shape, 1, c)
color_tool.SetInstanceColor(shape, 2, c)
n = c.Name(c.Red(), c.Green(), c.Blue())
print(' Shape color Name & RGB: ', c, n, c.Red(),
c.Green(), c.Blue())
shape_disp = BRepBuilderAPI_Transform(
shape, loc.Transformation()).Shape()
if not shape_disp in output_shapes:
output_shapes[shape_disp] = [lab.GetLabelName(), c]
for i in range(l_subss.Length()):
lab_subs = l_subss.Value(i + 1)
shape_sub = shape_tool.GetShape(lab_subs)
c = Quantity_Color(0.5, 0.5, 0.5,
Quantity_TOC_RGB) # default color
colorSet = False
if (color_tool.GetInstanceColor(shape_sub, 0, c)
or color_tool.GetInstanceColor(shape_sub, 1, c)
or color_tool.GetInstanceColor(shape_sub, 2, c)):
color_tool.SetInstanceColor(shape_sub, 0, c)
color_tool.SetInstanceColor(shape_sub, 1, c)
color_tool.SetInstanceColor(shape_sub, 2, c)
colorSet = True
n = c.Name(c.Red(), c.Green(), c.Blue())
print(' Instance color Name & RGB: ', c, n, c.Red(),
c.Green(), c.Blue())
if not colorSet:
if (color_tool.GetColor(lab_subs, 0, c)
or color_tool.GetColor(lab_subs, 1, c)
or color_tool.GetColor(lab_subs, 2, c)):
color_tool.SetInstanceColor(shape, 0, c)
color_tool.SetInstanceColor(shape, 1, c)
color_tool.SetInstanceColor(shape, 2, c)
n = c.Name(c.Red(), c.Green(), c.Blue())
print(' Shape color Name & RGB: ', c, n,
c.Red(), c.Green(), c.Blue())
shape_to_disp = BRepBuilderAPI_Transform(
shape_sub, loc.Transformation()).Shape()
# position the subshape to display
if not shape_to_disp in output_shapes:
output_shapes[shape_to_disp] = [
lab_subs.GetLabelName(), c
]
def _get_shapes():
labels = TDF_LabelSequence()
shape_tool.GetFreeShapes(labels)
print("Number of shapes at root: ", labels.Length())
for i in range(labels.Length()):
root_item = labels.Value(i + 1)
print('Root item: ', root_item)
_get_sub_shapes(root_item, None)
# HR 15/7/20
#
# Want to link existing node IDs from create_tree() with OCC
# First try: assume file-read order is same for both...
# ...and also OCC only gets "simple parts", i.e. leaves...
# ...which is corrected for below
#
# MUST CORRECT IN FUTURE TO BE SINGLE FILE-READ METHOD...
# ...FOR BOTH GRAPH AND OCC/SHAPE DATA
_get_shapes()
self.shapes = output_shapes
# return self.output_shapes
# Get all TopoDS_Solid objects in OCC dict
OCC_list = [
k for k in self.shapes.keys() if type(k) in self.topo_types
]
# Get all leaves in step_dict (could also just get list from leaves method)
tree_list = [k for k in self.step_dict.keys() if k in self.leaves]
# Map master IDs to OCC objects
self.OCC_dict = dict(zip(tree_list, OCC_list))
def read_file(self):
"""Build self.tree (treelib.Tree()) containing CAD data read from a step file.
Each node of self.tree contains the following:
(Name, UID, ParentUID, {Data}) where the Data keys are:
'a' (isAssy?), 'l' (TopLoc_Location), 'c' (Quantity_Color), 's' (TopoDS_Shape)
"""
logger.info("Reading STEP file")
doc = TDocStd_Document(TCollection_ExtendedString("STEP"))
# Create the application
app = XCAFApp_Application_GetApplication()
app.NewDocument(TCollection_ExtendedString("MDTV-CAF"), doc)
# Get root shapes
shape_tool = XCAFDoc_DocumentTool_ShapeTool(doc.Main())
shape_tool.SetAutoNaming(True)
self.color_tool = XCAFDoc_DocumentTool_ColorTool(doc.Main())
layer_tool = XCAFDoc_DocumentTool_LayerTool(doc.Main())
l_materials = XCAFDoc_DocumentTool_MaterialTool(doc.Main())
step_reader = STEPCAFControl_Reader()
step_reader.SetColorMode(True)
step_reader.SetLayerMode(True)
step_reader.SetNameMode(True)
step_reader.SetMatMode(True)
status = step_reader.ReadFile(self.filename)
if status == IFSelect_RetDone:
logger.info("Transfer doc to STEPCAFControl_Reader")
step_reader.Transfer(doc)
# Test round trip by writing doc back to another file.
logger.info("Doing a 'short-circuit' Round Trip test")
doctype = type(doc) # <class 'OCC.Core.TDocStd.TDocStd_Document'>
logger.info(f"Writing {doctype} back to another STEP file")
self.testRTStep(doc)
# Save doc to file (for educational purposes) (not working yet)
logger.debug("Saving doc to file")
savefilename = TCollection_ExtendedString('../doc.txt')
app.SaveAs(doc, savefilename)
labels = TDF_LabelSequence()
color_labels = TDF_LabelSequence()
shape_tool.GetShapes(labels)
self.shape_tool = shape_tool
logger.info('Number of labels at root : %i' % labels.Length())
try:
label = labels.Value(1) # First label at root
except RuntimeError:
return
name = self.getName(label)
logger.info('Name of root label: %s' % name)
isAssy = shape_tool.IsAssembly(label)
logger.info("First label at root holds an assembly? %s" % isAssy)
if isAssy:
# If first label at root holds an assembly, it is the Top Assembly.
# Through this label, the entire assembly is accessible.
# No need to examine other labels at root explicitly.
topLoc = TopLoc_Location()
topLoc = shape_tool.GetLocation(label)
self.assyLocStack.append(topLoc)
entry = label.EntryDumpToString()
logger.debug("Entry: %s" % entry)
logger.debug("Top assy name: %s" % name)
# Create root node for top assy
newAssyUID = self.getNewUID()
self.tree.create_node(name, newAssyUID, None, {
'a': True,
'l': None,
'c': None,
's': None
})
self.assyUidStack.append(newAssyUID)
topComps = TDF_LabelSequence() # Components of Top Assy
subchilds = False
isAssy = shape_tool.GetComponents(label, topComps, subchilds)
logger.debug("Is Assembly? %s" % isAssy)
logger.debug("Number of components: %s" % topComps.Length())
logger.debug("Is Reference? %s" % shape_tool.IsReference(label))
if topComps.Length():
self.findComponents(label, topComps)
else:
# Labels at root can hold solids or compounds (which are 'crude' assemblies)
# Either way, we will need to create a root node in self.tree
newAssyUID = self.getNewUID()
self.tree.create_node(os.path.basename(self.filename), newAssyUID,
None, {
'a': True,
'l': None,
'c': None,
's': None
})
self.assyUidStack = [newAssyUID]
for j in range(labels.Length()):
label = labels.Value(j + 1)
name = self.getName(label)
isAssy = shape_tool.IsAssembly(label)
logger.debug("Label %i is assembly?: %s" % (j + 1, isAssy))
shape = shape_tool.GetShape(label)
color = self.getColor(shape)
isSimpleShape = self.shape_tool.IsSimpleShape(label)
logger.debug("Is Simple Shape? %s" % isSimpleShape)
shapeType = shape.ShapeType()
logger.debug("The shape type is: %i" % shapeType)
if shapeType == 0:
logger.debug(
"The shape type is OCC.Core.TopAbs.TopAbs_COMPOUND")
topo = TopologyExplorer(shape)
#topo = aocutils.topology.Topo(shape)
logger.debug("Nb of compounds : %i" %
topo.number_of_compounds())
logger.debug("Nb of solids : %i" % topo.number_of_solids())
logger.debug("Nb of shells : %i" % topo.number_of_shells())
newAssyUID = self.getNewUID()
for i, solid in enumerate(topo.solids()):
name = "P%s" % str(i + 1)
self.tree.create_node(name, self.getNewUID(),
self.assyUidStack[-1], {
'a': False,
'l': None,
'c': color,
's': solid
})
elif shapeType == 2:
logger.debug(
"The shape type is OCC.Core.TopAbs.TopAbs_SOLID")
self.tree.create_node(name, self.getNewUID(),
self.assyUidStack[-1], {
'a': False,
'l': None,
'c': color,
's': shape
})
elif shapeType == 3:
logger.debug(
"The shape type is OCC.Core.TopAbs.TopAbs_SHELL")
self.tree.create_node(name, self.getNewUID(),
self.assyUidStack[-1], {
'a': False,
'l': None,
'c': color,
's': shape
})
return True