def processRefinements(self):
""" Process mesh refinements """
mr_objs = CfdTools.getMeshRefinementObjs(self.mesh_obj)
if self.mesh_obj.MeshUtility == "gmsh":
# mesh regions
self.ele_length_map = {} # { 'ElementString' : element length }
self.ele_node_map = {} # { 'ElementString' : [element nodes] }
if not mr_objs:
print(' No mesh refinements')
else:
print(' Mesh refinements found - getting elements')
if self.part_obj.Shape.ShapeType == 'Compound':
# see http://forum.freecadweb.org/viewtopic.php?f=18&t=18780&start=40#p149467 and http://forum.freecadweb.org/viewtopic.php?f=18&t=18780&p=149520#p149520
err = "GMSH could return unexpected meshes for a boolean split tools Compound. It is strongly recommended to extract the shape to mesh from the Compound and use this one."
FreeCAD.Console.PrintError(err + "\n")
for mr_obj in mr_objs:
if mr_obj.RelativeLength:
if mr_obj.References:
for sub in mr_obj.References:
# Check if the shape of the mesh region is an element of the Part to mesh;
# if not try to find the element in the shape to mesh
search_ele_in_shape_to_mesh = False
ref = FreeCAD.ActiveDocument.getObject(sub[0])
if not self.part_obj.Shape.isSame(ref.Shape):
search_ele_in_shape_to_mesh = True
elems = sub[1]
if search_ele_in_shape_to_mesh:
# Try to find the element in the Shape to mesh
ele_shape = FemGeomTools.get_element(
ref, elems
) # the method getElement(element) does not return Solid elements
found_element = CfdTools.findElementInShape(
self.part_obj.Shape, ele_shape)
if found_element:
elems = found_element
else:
FreeCAD.Console.PrintError(
"One element of the meshregion " +
mr_obj.Name +
" could not be found in the Part to mesh. It will be ignored.\n"
)
elems = None
if elems:
if elems not in self.ele_length_map:
# self.ele_length_map[elems] = Units.Quantity(mr_obj.CharacteristicLength).Value
mr_rellen = mr_obj.RelativeLength
if mr_rellen > 1.0:
mr_rellen = 1.0
FreeCAD.Console.PrintError(
"The meshregion: " +
mr_obj.Name +
" should not use a relative length greater than unity.\n"
)
elif mr_rellen < 0.01:
mr_rellen = 0.01 # Relative length should not be less than 1/100 of base length
FreeCAD.Console.PrintError(
"The meshregion: " +
mr_obj.Name +
" should not use a relative length smaller than 0.01.\n"
)
self.ele_length_map[
elems] = mr_rellen * self.clmax
else:
FreeCAD.Console.PrintError(
"The element " + elems +
" of the mesh refinement " +
mr_obj.Name +
" has been added to another mesh refinement.\n"
)
else:
FreeCAD.Console.PrintError(
"The meshregion: " + mr_obj.Name +
" is not used to create the mesh because the reference list is empty.\n"
)
else:
FreeCAD.Console.PrintError(
"The meshregion: " + mr_obj.Name +
" is not used to create the mesh because the CharacteristicLength is 0.0 mm.\n"
)
for eleml in self.ele_length_map:
ele_shape = FemGeomTools.get_element(
self.part_obj, eleml
) # the method getElement(element) does not return Solid elements
ele_vertexes = FemGeomTools.get_vertexes_by_element(
self.part_obj.Shape, ele_shape)
self.ele_node_map[eleml] = ele_vertexes
else:
cf_settings = self.cf_settings
cf_settings['MeshRegions'] = {}
cf_settings['BoundaryLayers'] = {}
cf_settings['InternalRegions'] = {}
snappy_settings = self.snappy_settings
snappy_settings['MeshRegions'] = {}
snappy_settings['InternalRegions'] = {}
from collections import defaultdict
ele_meshpatch_map = defaultdict(list)
if not mr_objs:
print(' No mesh refinement')
else:
print(' Mesh refinements - getting the elements')
if "Boolean" in self.part_obj.Name:
err = "Cartesian meshes should not be generated for boolean split compounds."
FreeCAD.Console.PrintError(err + "\n")
# Make list of list of all references for their corresponding mesh object
bl_matched_faces = []
if self.mesh_obj.MeshUtility == 'cfMesh':
CfdTools.cfdMessage("Matching refinement regions")
region_face_list = []
for mr_id, mr_obj in enumerate(mr_objs):
if mr_obj.NumberLayers > 1 and not mr_obj.Internal:
refs = mr_obj.References
for r in refs:
obj = FreeCAD.ActiveDocument.getObject(r[0])
if not obj:
raise RuntimeError(
"Referenced object '{}' not found - object may "
"have been deleted".format(r[0]))
try:
f = obj.Shape.getElement(r[1])
except Part.OCCError:
raise RuntimeError(
"Referenced face '{}:{}' not found - face may "
"have been deleted".format(r[0], r[1]))
region_face_list.append((f, mr_id))
# Make list of all faces in meshed shape with original index
mesh_face_list = \
list(zip(self.mesh_obj.Part.Shape.Faces, range(len(self.mesh_obj.Part.Shape.Faces))))
# Match them up
bl_matched_faces = CfdTools.matchFaces(
region_face_list, mesh_face_list)
for mr_id, mr_obj in enumerate(mr_objs):
Internal = mr_obj.Internal
if mr_obj.RelativeLength:
# Store parameters per region
mr_rellen = mr_obj.RelativeLength
if mr_rellen > 1.0:
mr_rellen = 1.0
FreeCAD.Console.PrintError(
"The meshregion: {} should not use a relative length greater "
"than unity.\n".format(mr_obj.Name))
elif mr_rellen < 0.001:
mr_rellen = 0.001 # Relative length should not be less than 0.1% of base length
FreeCAD.Console.PrintError(
"The meshregion: {} should not use a relative length smaller "
"than 0.001.\n".format(mr_obj.Name))
if not (self.mesh_obj.MeshUtility == 'snappyHexMesh'
and mr_obj.Baffle):
fid = open(
os.path.join(self.triSurfaceDir,
mr_obj.Name + '.stl'), 'w')
snappy_mesh_region_list = []
patch_list = []
for (si, sub) in enumerate(mr_obj.References):
shape = FreeCAD.ActiveDocument.getObject(
sub[0]).Shape
elem = sub[1]
if self.mesh_obj.MeshUtility == 'snappyHexMesh' and mr_obj.Baffle:
# Save baffle references or faces individually
baffle = "{}{}{}".format(
mr_obj.Name, sub[0], elem)
fid = open(
os.path.join(self.triSurfaceDir,
baffle + ".stl"), 'w')
snappy_mesh_region_list.append(baffle)
if elem.startswith(
'Solid'
): # getElement doesn't work with solids for some reason
elt = shape.Solids[int(elem.lstrip('Solid')) -
1]
else:
elt = shape.getElement(elem)
if elt.ShapeType == 'Face' or elt.ShapeType == 'Solid':
CfdTools.cfdMessage(
"Triangulating part: {}:{} ...".format(
FreeCAD.ActiveDocument.getObject(
sub[0]).Label, sub[1]))
facemesh = MeshPart.meshFromShape(
elt,
LinearDeflection=self.mesh_obj.
STLLinearDeflection)
CfdTools.cfdMessage(" writing to file\n")
fid.write("solid {}{}{}\n".format(
mr_obj.Name, sub[0], elem))
for face in facemesh.Facets:
fid.write(" facet normal 0 0 0\n")
fid.write(" outer loop\n")
for i in range(3):
p = [
i * self.scale
for i in face.Points[i]
]
fid.write(
" vertex {} {} {}\n".format(
p[0], p[1], p[2]))
fid.write(" endloop\n")
fid.write(" endfacet\n")
fid.write("endsolid {}{}{}\n".format(
mr_obj.Name, sub[0], elem))
if self.mesh_obj.MeshUtility == 'snappyHexMesh' and mr_obj.Baffle:
fid.close()
if not (self.mesh_obj.MeshUtility == 'snappyHexMesh'
and mr_obj.Baffle):
fid.close()
if self.mesh_obj.MeshUtility == 'cfMesh' and mr_obj.NumberLayers > 1 and not Internal:
for mf in bl_matched_faces:
if mr_id == mf[0]:
sfN = self.mesh_obj.ShapeFaceNames[mf[1]]
ele_meshpatch_map[mr_obj.Name].append(sfN)
patch_list.append(sfN)
# Limit expansion ratio to greater than 1.0 and less than 1.2
expratio = mr_obj.ExpansionRatio
expratio = min(1.2, max(1.0, expratio))
cf_settings['BoundaryLayers'][
self.mesh_obj.
ShapeFaceNames[mf[1]]] = {
'NumberLayers':
mr_obj.NumberLayers,
'ExpansionRatio':
expratio,
'FirstLayerHeight':
self.scale * Units.Quantity(
mr_obj.FirstLayerHeight).Value
}
if self.mesh_obj.MeshUtility == 'cfMesh':
if not Internal:
cf_settings['MeshRegions'][mr_obj.Name] = {
'RelativeLength':
mr_rellen * self.clmax * self.scale,
'RefinementThickness':
self.scale * Units.Quantity(
mr_obj.RefinementThickness).Value,
}
else:
cf_settings['InternalRegions'][mr_obj.Name] = {
'RelativeLength':
mr_rellen * self.clmax * self.scale
}
elif self.mesh_obj.MeshUtility == 'snappyHexMesh':
refinement_level = CfdTools.relLenToRefinementLevel(
mr_obj.RelativeLength)
if not Internal:
if not mr_obj.Baffle:
snappy_mesh_region_list.append(mr_obj.Name)
edge_level = CfdTools.relLenToRefinementLevel(
mr_obj.RegionEdgeRefinement)
for rL in range(len(snappy_mesh_region_list)):
mrName = mr_obj.Name + snappy_mesh_region_list[
rL]
snappy_settings['MeshRegions'][mrName] = {
'RegionName':
snappy_mesh_region_list[rL],
'RefinementLevel':
refinement_level,
'EdgeRefinementLevel':
edge_level,
'MaxRefinementLevel':
max(refinement_level, edge_level),
'Baffle':
mr_obj.Baffle
}
else:
snappy_settings['InternalRegions'][
mr_obj.Name] = {
'RefinementLevel': refinement_level
}
else:
FreeCAD.Console.PrintError(
"The meshregion: " + mr_obj.Name +
" is not used to create the mesh because the "
"CharacteristicLength is 0.0 mm or the reference list is empty.\n"
)
def setupPatchNames(self):
print('Populating createPatchDict to update BC names')
import CfdMeshTools
# Init in case not meshed yet
CfdMeshTools.CfdMeshTools(self.mesh_obj)
settings = self.settings
settings['createPatches'] = {}
bc_group = self.bc_group
mobj = self.mesh_obj
# Make list of list of all boundary references for their corresponding boundary
boundary_ref_lists = []
for bc_id, bc_obj in enumerate(bc_group):
boundary_ref_lists.append(bc_obj.References)
# Match them up with faces in the meshed part
matched_faces = CfdTools.matchFacesToTargetShape(
boundary_ref_lists, mobj.Part.Shape)
bc_lists = []
for bc in bc_group:
bc_lists.append([])
for i in range(len(matched_faces)):
if matched_faces[i]:
nb, bref = matched_faces[i][0]
bc_lists[nb].append(mobj.ShapeFaceNames[i])
for k in range(len(matched_faces[i]) - 1):
nb2, bref2 = matched_faces[i][k + 1]
if nb2 != nb:
cfdMessage(
"Boundary '{}' reference {}:{} also assigned as "
"boundary '{}' reference {}:{}\n".format(
bc_group[nb].Label, bref[0], bref[1],
bc_group[nb2].Label, bref2[0], bref2[1]))
for bc_id, bc_obj in enumerate(bc_group):
bcType = bc_obj.BoundaryType
bcSubType = bc_obj.BoundarySubType
patchType = CfdTools.getPatchType(bcType, bcSubType)
settings['createPatches'][bc_obj.Label] = {
'PatchNamesList':
tuple(bc_lists[bc_id]
), # Tuple used so that case writer outputs as an array
'PatchType': patchType
}
if self.mesh_obj.MeshUtility == 'snappyHexMesh':
for regionObj in CfdTools.getMeshRefinementObjs(self.mesh_obj):
if regionObj.Baffle:
settings['createPatchesFromSnappyBaffles'] = True
if settings['createPatchesFromSnappyBaffles']:
settings['createPatchesSnappyBaffles'] = {}
# TODO Still need to include an error checker in the event that
# an internal baffle is created using snappy but is not linked up
# with a baffle boundary condition (as in there is no baffle boundary condition which
# corresponds. Currently openfoam will throw a contextually
# confusing error (only that the boundary does not exist). The primary difficulty with such a checker is
# that it is possible to define a boundary face as a baffle, which will be overridden
# by the actual boundary name and therefore won't exist anymore.
for bc_id, bc_obj in enumerate(bc_group):
bcType = bc_obj.BoundaryType
if bcType == "baffle":
tempBaffleList = []
tempBaffleListSlave = []
for regionObj in self.mesh_obj.Group:
if hasattr(regionObj, "Proxy") and \
isinstance(regionObj.Proxy, CfdMeshRefinement._CfdMeshRefinement):
# print regionObj.Name
if regionObj.Baffle:
for sub in regionObj.References:
# print sub[0].Name
elems = sub[1]
elt = FreeCAD.ActiveDocument.getObject(
sub[0]).Shape.getElement(elems)
if elt.ShapeType == 'Face':
bcFacesList = bc_obj.Shape.Faces
for bf in bcFacesList:
isSameGeo = CfdTools.isSameGeometry(
bf, elt)
if isSameGeo:
tempBaffleList.append(
regionObj.Name + sub[0] +
elems)
tempBaffleListSlave.append(
regionObj.Name + sub[0] +
elems + "_slave")
settings['createPatchesSnappyBaffles'][bc_obj.Label] = {
"PatchNamesList": tuple(tempBaffleList),
"PatchNamesListSlave": tuple(tempBaffleListSlave)
}
# Add default faces
flagName = False
def_bc_list = []
for i in range(len(matched_faces)):
if not matched_faces[i]:
def_bc_list.append(mobj.ShapeFaceNames[i])
flagName = True
if flagName:
settings['createPatches']['defaultFaces'] = {
'PatchNamesList': tuple(def_bc_list),
'PatchType': "patch"
}
def processRefinements(self):
""" Process mesh refinements """
mr_objs = CfdTools.getMeshRefinementObjs(self.mesh_obj)
if self.mesh_obj.MeshUtility == "gmsh":
# mesh regions
self.ele_length_map = {} # { 'ElementString' : element length }
self.ele_node_map = {} # { 'ElementString' : [element nodes] }
if not mr_objs:
print(' No mesh refinements')
else:
print(' Mesh refinements found - getting elements')
if self.part_obj.Shape.ShapeType == 'Compound':
# see http://forum.freecadweb.org/viewtopic.php?f=18&t=18780&start=40#p149467 and http://forum.freecadweb.org/viewtopic.php?f=18&t=18780&p=149520#p149520
err = "GMSH could return unexpected meshes for a boolean split tools Compound. It is strongly recommended to extract the shape to mesh from the Compound and use this one."
FreeCAD.Console.PrintError(err + "\n")
for mr_obj in mr_objs:
if mr_obj.RelativeLength:
if mr_obj.References:
for sub in mr_obj.References:
# Check if the shape of the mesh region is an element of the Part to mesh;
# if not try to find the element in the shape to mesh
search_ele_in_shape_to_mesh = False
ref = FreeCAD.ActiveDocument.getObject(sub[0])
if not self.part_obj.Shape.isSame(ref.Shape):
search_ele_in_shape_to_mesh = True
elems = sub[1]
if search_ele_in_shape_to_mesh:
# Try to find the element in the Shape to mesh
ele_shape = FemGeomTools.get_element(
ref, elems
) # the method getElement(element) does not return Solid elements
found_element = CfdTools.findElementInShape(
self.part_obj.Shape, ele_shape)
if found_element:
elems = found_element
else:
FreeCAD.Console.PrintError(
"One element of the meshregion " +
mr_obj.Name +
" could not be found in the Part to mesh. It will be ignored.\n"
)
elems = None
if elems:
if elems not in self.ele_length_map:
# self.ele_length_map[elems] = Units.Quantity(mr_obj.CharacteristicLength).Value
mr_rellen = mr_obj.RelativeLength
if mr_rellen > 1.0:
mr_rellen = 1.0
FreeCAD.Console.PrintError(
"The meshregion: " +
mr_obj.Name +
" should not use a relative length greater than unity.\n"
)
elif mr_rellen < 0.01:
mr_rellen = 0.01 # Relative length should not be less than 1/100 of base length
FreeCAD.Console.PrintError(
"The meshregion: " +
mr_obj.Name +
" should not use a relative length smaller than 0.01.\n"
)
self.ele_length_map[
elems] = mr_rellen * self.clmax
else:
FreeCAD.Console.PrintError(
"The element " + elems +
" of the mesh refinement " +
mr_obj.Name +
" has been added to another mesh refinement.\n"
)
else:
FreeCAD.Console.PrintError(
"The meshregion: " + mr_obj.Name +
" is not used to create the mesh because the reference list is empty.\n"
)
else:
FreeCAD.Console.PrintError(
"The meshregion: " + mr_obj.Name +
" is not used to create the mesh because the CharacteristicLength is 0.0 mm.\n"
)
for eleml in self.ele_length_map:
ele_shape = FemGeomTools.get_element(
self.part_obj, eleml
) # the method getElement(element) does not return Solid elements
ele_vertexes = FemGeomTools.get_vertexes_by_element(
self.part_obj.Shape, ele_shape)
self.ele_node_map[eleml] = ele_vertexes
else:
cf_settings = self.cf_settings
cf_settings['MeshRegions'] = {}
cf_settings['BoundaryLayers'] = {}
cf_settings['InternalRegions'] = {}
snappy_settings = self.snappy_settings
snappy_settings['MeshRegions'] = {}
snappy_settings['InternalRegions'] = {}
# Make list of all faces in meshed shape with original index
mesh_face_list = list(
zip(self.mesh_obj.Part.Shape.Faces,
range(len(self.mesh_obj.Part.Shape.Faces))))
# Make list of all boundary references
CfdTools.cfdMessage("Matching boundary patches\n")
bc_group = None
analysis_obj = CfdTools.getParentAnalysisObject(self.mesh_obj)
if not analysis_obj:
analysis_obj = CfdTools.getActiveAnalysis()
if analysis_obj:
bc_group = CfdTools.getCfdBoundaryGroup(analysis_obj)
boundary_face_list = []
for bc_id, bc_obj in enumerate(bc_group):
for ri, ref in enumerate(bc_obj.References):
try:
bf = CfdTools.resolveReference(ref)
except RuntimeError as re:
raise RuntimeError(
"Error processing boundary condition {}: {}".
format(bc_obj.Label, str(re)))
boundary_face_list.append((bf, (bc_id, ref, ri)))
# Match them up to faces in the main geometry
bc_matched_faces = CfdTools.matchFaces(boundary_face_list,
mesh_face_list)
# Make list of all boundary layer mesh regions for cfMesh
bl_matched_faces = []
if self.mesh_obj.MeshUtility == 'cfMesh':
CfdTools.cfdMessage("Matching boundary layer regions\n")
bl_face_list = []
for mr_id, mr_obj in enumerate(mr_objs):
if mr_obj.NumberLayers > 1 and not mr_obj.Internal:
for ri, r in enumerate(mr_obj.References):
try:
f = CfdTools.resolveReference(r)
except RuntimeError as re:
raise RuntimeError(
"Error processing mesh refinement {}: {}".
format(mr_obj.Label, str(re)))
bl_face_list.append((f, (mr_id, r, ri)))
# Match them up
bl_matched_faces = CfdTools.matchFaces(bl_face_list,
mesh_face_list)
# Check for and filter duplicates
bc_match_per_shape_face = [-1] * len(mesh_face_list)
for k in range(len(bc_matched_faces)):
match = bc_matched_faces[k][1]
prev_k = bc_match_per_shape_face[match]
if prev_k >= 0:
nb, bref, ri = bc_matched_faces[k][0]
nb2, bref2, ri2 = bc_matched_faces[prev_k][0]
CfdTools.cfdMessage(
"Boundary '{}' reference {}:{} also assigned as "
"boundary '{}' reference {}:{} - ignoring duplicate\n".
format(bc_group[nb].Label, bref[0], bref[1],
bc_group[nb2].Label, bref2[0], bref2[1]))
else:
bc_match_per_shape_face[match] = k
bl_match_per_shape_face = [-1] * len(mesh_face_list)
for k in range(len(bl_matched_faces)):
match = bl_matched_faces[k][1]
prev_k = bl_match_per_shape_face[match]
if prev_k >= 0:
nr, ref, ri = bl_matched_faces[k][0]
nr2, ref2, ri2 = bl_matched_faces[prev_k][0]
CfdTools.cfdMessage(
"Mesh refinement '{}' reference {}:{} also assigned as "
"mesh refinement '{}' reference {}:{} - ignoring duplicate\n"
.format(mr_objs[nr].Label, ref[0], ref[1],
mr_objs[nr2].Label, ref2[0], ref2[1]))
else:
bl_match_per_shape_face[match] = k
self.patch_faces = []
self.patch_names = []
for k in range(len(bc_group) + 1):
self.patch_faces.append([])
self.patch_names.append([])
for l in range(len(mr_objs) + 1):
self.patch_faces[k].append([])
self.patch_names[k].append("patch_" + str(k) + "_" +
str(l))
for i in range(len(mesh_face_list)):
k = bc_match_per_shape_face[i]
l = bl_match_per_shape_face[i]
nb = -1
nr = -1
if k >= 0:
nb, bref, bri = bc_matched_faces[k][0]
if l >= 0:
nr, ref, rri = bl_matched_faces[l][0]
self.patch_faces[nb + 1][nr + 1].append(i)
# Additionally for snappy, match baffles to any surface mesh refinements
# as well as matching each surface mesh refinement region to boundary conditions
mr_face_list = []
bc_mr_matched_faces = []
if self.mesh_obj.MeshUtility == 'snappyHexMesh':
CfdTools.cfdMessage("Matching surface geometries\n")
for mr_id, mr_obj in enumerate(mr_objs):
if not mr_obj.Internal:
for ri, r in enumerate(mr_obj.References):
try:
f = CfdTools.resolveReference(r)
except RuntimeError as re:
raise RuntimeError(
"Error processing mesh refinement {}: {}".
format(mr_obj.Label, str(re)))
mr_face_list.append((f, (mr_id, r, ri)))
# Match mesh regions to the boundary conditions, to identify boundary conditions on supplementary
# geometry (including on baffles)
bc_mr_matched_faces = CfdTools.matchFaces(
boundary_face_list, mr_face_list)
for bc_id, bc_obj in enumerate(bc_group):
if bc_obj.BoundaryType == 'baffle':
baffle_matches = [
m for m in bc_mr_matched_faces if m[0][0] == bc_id
]
mr_match_per_baffle_ref = [-1] * len(bc_obj.References)
for m in baffle_matches:
mr_match_per_baffle_ref[m[0][2]] = m[1][0]
# For each mesh region, the refs that are part of this baffle
baffle_patch_refs = [[] for ri in range(len(mr_objs) + 1)]
for ri, mri in enumerate(mr_match_per_baffle_ref):
baffle_patch_refs[mri + 1].append(
bc_obj.References[ri])
# Write these geometries
for ri, refs in enumerate(baffle_patch_refs):
try:
shape = CfdTools.makeShapeFromReferences(refs)
except RuntimeError as re:
raise RuntimeError(
"Error processing baffle {}: {}".format(
bc_obj.Label, str(re)))
solid_name = bc_obj.Name + "_" + str(ri)
if shape:
CfdTools.cfdMessage(
"Triangulating baffle {}, section {} ...".
format(bc_obj.Label, ri))
facemesh = MeshPart.meshFromShape(
shape,
LinearDeflection=self.mesh_obj.
STLLinearDeflection)
CfdTools.cfdMessage(" writing to file\n")
with open(
os.path.join(self.triSurfaceDir,
solid_name + '.stl'),
'w') as fid:
CfdTools.writePatchToStl(
solid_name, facemesh, fid, self.scale)
if ri > 0: # The parts of the baffle corresponding to a surface mesh region obj
mr_obj = mr_objs[ri - 1]
refinement_level = CfdTools.relLenToRefinementLevel(
mr_obj.RelativeLength)
edge_level = CfdTools.relLenToRefinementLevel(
mr_obj.RegionEdgeRefinement)
else: # The parts of the baffle with no refinement obj
refinement_level = 0
edge_level = 0
snappy_settings['MeshRegions'][solid_name] = {
'RefinementLevel':
refinement_level,
'EdgeRefinementLevel':
edge_level,
'MaxRefinementLevel':
max(refinement_level, edge_level),
'Baffle':
True
}
mr_matched_faces = []
if self.mesh_obj.MeshUtility == 'snappyHexMesh':
# Match mesh regions to the primary geometry
mr_matched_faces = CfdTools.matchFaces(mr_face_list,
mesh_face_list)
for mr_id, mr_obj in enumerate(mr_objs):
Internal = mr_obj.Internal
mr_rellen = mr_obj.RelativeLength
if mr_rellen > 1.0:
mr_rellen = 1.0
FreeCAD.Console.PrintError(
"The mesh refinement region '{}' should not use a relative length greater "
"than unity.\n".format(mr_obj.Name))
elif mr_rellen < 0.001:
mr_rellen = 0.001 # Relative length should not be less than 0.1% of base length
FreeCAD.Console.PrintError(
"The mesh refinement region '{}' should not use a relative length smaller "
"than 0.001.\n".format(mr_obj.Name))
# Find any matches with boundary conditions; mark those matching baffles for removal
bc_matches = [
m for m in bc_mr_matched_faces if m[1][0] == mr_id
]
bc_match_per_mr_ref = [-1] * len(mr_obj.References)
for m in bc_matches:
bc_match_per_mr_ref[m[1][2]] = -2 if bc_group[
m[0][0]].BoundaryType == 'baffle' else m[0][0]
# Unmatch those in primary geometry
main_geom_matches = [
m for m in mr_matched_faces if m[0][0] == mr_id
]
for m in main_geom_matches:
bc_match_per_mr_ref[m[0][2]] = -1
# For each boundary, the refs that are part of this mesh region
mr_patch_refs = [[] for ri in range(len(bc_group) + 1)]
for ri, bci in enumerate(bc_match_per_mr_ref):
if bci > -2:
mr_patch_refs[bci + 1].append(mr_obj.References[ri])
# Loop over and write the sub-sections of this mesh object
for bi in range(len(mr_patch_refs)):
if len(mr_patch_refs[bi]):
if bi == 0:
mr_patch_name = mr_obj.Name
else:
mr_patch_name = self.patch_names[bi][mr_id + 1]
CfdTools.cfdMessage(
"Triangulating mesh refinement region {}, section {} ..."
.format(mr_obj.Label, bi))
try:
shape = CfdTools.makeShapeFromReferences(
mr_patch_refs[bi])
except RuntimeError as re:
raise RuntimeError(
"Error processing mesh refinement region {}: {}"
.format(mr_obj.Label, str(re)))
if shape:
facemesh = MeshPart.meshFromShape(
shape,
LinearDeflection=self.mesh_obj.
STLLinearDeflection)
CfdTools.cfdMessage(" writing to file\n")
with open(
os.path.join(self.triSurfaceDir,
mr_patch_name + '.stl'),
'w') as fid:
CfdTools.writePatchToStl(
mr_patch_name, facemesh, fid, self.scale)
if self.mesh_obj.MeshUtility == 'cfMesh':
if not Internal:
cf_settings['MeshRegions'][mr_patch_name] = {
'RelativeLength':
mr_rellen * self.clmax * self.scale,
'RefinementThickness':
self.scale * Units.Quantity(
mr_obj.RefinementThickness).Value,
}
else:
cf_settings['InternalRegions'][mr_obj.Name] = {
'RelativeLength':
mr_rellen * self.clmax * self.scale
}
elif self.mesh_obj.MeshUtility == 'snappyHexMesh':
refinement_level = CfdTools.relLenToRefinementLevel(
mr_obj.RelativeLength)
if not Internal:
edge_level = CfdTools.relLenToRefinementLevel(
mr_obj.RegionEdgeRefinement)
snappy_settings['MeshRegions'][
mr_patch_name] = {
'RefinementLevel':
refinement_level,
'EdgeRefinementLevel':
edge_level,
'MaxRefinementLevel':
max(refinement_level, edge_level),
'Baffle':
False
}
else:
snappy_settings['InternalRegions'][
mr_patch_name] = {
'RefinementLevel': refinement_level
}
# In addition, for cfMesh, record matched boundary layer patches
if self.mesh_obj.MeshUtility == 'cfMesh' and mr_obj.NumberLayers > 1 and not Internal:
for k in range(len(self.patch_faces)):
# Limit expansion ratio to greater than 1.0 and less than 1.2
expratio = mr_obj.ExpansionRatio
expratio = min(1.2, max(1.0, expratio))
cf_settings['BoundaryLayers'][
self.patch_names[k][mr_id]] = {
'NumberLayers':
mr_obj.NumberLayers,
'ExpansionRatio':
expratio,
'FirstLayerHeight':
self.scale *
Units.Quantity(mr_obj.FirstLayerHeight).Value
}
def setupPatchNames(self):
print('Populating createPatchDict to update BC names')
import CfdMeshTools
# Init in case not meshed yet
CfdMeshTools.CfdMeshTools(self.mesh_obj)
settings = self.settings
settings['createPatches'] = {}
bc_group = self.bc_group
mobj = self.mesh_obj
# Make list of all boundary references
boundary_face_list = []
for bc_id, bc_obj in enumerate(bc_group):
for ref in bc_obj.References:
obj = FreeCAD.ActiveDocument.getObject(ref[0])
if not obj:
raise RuntimeError(
"Referenced object '{}' not found - object may "
"have been deleted".format(ref[0]))
try:
bf = obj.Shape.getElement(ref[1])
except Part.OCCError:
raise RuntimeError(
"Referenced face '{}:{}' not found - face may "
"have been deleted".format(ref[0], ref[1]))
boundary_face_list.append((bf, (bc_id, ref)))
# Make list of all faces in meshed shape with original index
mesh_face_list = list(
zip(mobj.Part.Shape.Faces, range(len(mobj.Part.Shape.Faces))))
# Match them up
matched_faces = CfdTools.matchFaces(boundary_face_list, mesh_face_list)
# Check for and filter duplicates
match_per_shape_face = [-1] * len(mesh_face_list)
for k in range(len(matched_faces)):
match = matched_faces[k][1]
prev_k = match_per_shape_face[match]
if prev_k >= 0:
nb, bref = matched_faces[k][0]
nb2, bref2 = matched_faces[prev_k][0]
cfdMessage(
"Boundary '{}' reference {}:{} also assigned as "
"boundary '{}' reference {}:{} - ignoring duplicate\n".
format(bc_group[nb].Label, bref[0], bref[1],
bc_group[nb2].Label, bref2[0], bref2[1]))
else:
match_per_shape_face[match] = k
bc_lists = [[] for g in bc_group]
for i in range(len(match_per_shape_face)):
k = match_per_shape_face[i]
if k >= 0:
nb, bref = matched_faces[k][0]
bc_lists[nb].append(mobj.ShapeFaceNames[i])
for bc_id, bc_obj in enumerate(bc_group):
bcType = bc_obj.BoundaryType
bcSubType = bc_obj.BoundarySubType
patchType = CfdTools.getPatchType(bcType, bcSubType)
settings['createPatches'][bc_obj.Label] = {
'PatchNamesList':
tuple(bc_lists[bc_id]
), # Tuple used so that case writer outputs as an array
'PatchType': patchType
}
if self.mesh_obj.MeshUtility == 'snappyHexMesh':
for regionObj in CfdTools.getMeshRefinementObjs(self.mesh_obj):
if regionObj.Baffle:
settings['createPatchesFromSnappyBaffles'] = True
if settings['createPatchesFromSnappyBaffles']:
settings['createPatchesSnappyBaffles'] = {}
baffle_geoms = []
for regionObj in self.mesh_obj.Group:
if hasattr(regionObj, "Proxy") and isinstance(
regionObj.Proxy, CfdMeshRefinement._CfdMeshRefinement):
if regionObj.Baffle:
for sub in regionObj.References:
elems = sub[1]
elt = FreeCAD.ActiveDocument.getObject(
sub[0]).Shape.getElement(elems)
if elt.ShapeType == 'Face':
baffle_geoms.append(
(elt, (regionObj.Name + sub[0] + elems,
len(baffle_geoms))))
print(boundary_face_list)
matched_baffle_faces = CfdTools.matchFaces(boundary_face_list,
baffle_geoms)
# Check for duplicates
match_per_baffle_face = [-1] * len(baffle_geoms)
for matchi, mf in enumerate(matched_baffle_faces):
if match_per_baffle_face[mf[1][1]] > -1:
cfdMessage("Baffle face matches to boundary " + mf[0][1] +
" and " + matched_baffle_faces[
match_per_baffle_face[mf[1][1]]][0][1] +
" - discarding duplicate")
else:
match_per_baffle_face[mf[1][1]] = matchi
for bfi, mi in enumerate(match_per_baffle_face):
if mi > -1:
mf = matched_baffle_faces[mi]
bc_label = bc_group[mf[0][0]].Label
settings['createPatchesSnappyBaffles'][bc_label] = \
settings['createPatchesSnappyBaffles'].get(bc_label, {})
settings['createPatchesSnappyBaffles'][bc_label]['PatchNamesList'] = \
settings['createPatchesSnappyBaffles'][bc_label].get('PatchNamesList', ()) + \
(mf[1][0],)
settings['createPatchesSnappyBaffles'][bc_label]['PatchNamesListSlave'] = \
settings['createPatchesSnappyBaffles'][bc_label].get('PatchNamesListSlave', ()) + \
((mf[1][0]+"_slave"),)
else:
cfdMessage(
"No boundary condition specified for baffle face " +
baffle_geoms[bfi][1][0])
# Add default faces
flagName = False
def_bc_list = []
for i in range(len(match_per_shape_face)):
if match_per_shape_face[i] < 0:
def_bc_list.append(mobj.ShapeFaceNames[i])
flagName = True
if flagName:
settings['createPatches']['defaultFaces'] = {
'PatchNamesList': tuple(def_bc_list),
'PatchType': "patch"
}