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mesh_bsurfaces.py
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mesh_bsurfaces.py
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# SPDX-FileCopyrightText: 2010-2023 Blender Foundation
#
# SPDX-License-Identifier: GPL-2.0-or-later
bl_info = {
"name": "Bsurfaces GPL Edition",
"author": "Eclectiel, Vladimir Spivak (cwolf3d)",
"version": (1, 8, 2),
"blender": (4, 0, 0),
"location": "View3D EditMode > Sidebar > Edit Tab",
"description": "Modeling and retopology tool",
"doc_url": "{BLENDER_MANUAL_URL}/addons/mesh/bsurfaces.html",
"category": "Mesh",
}
import bpy
import bmesh
from bpy_extras import object_utils
import operator
from mathutils import Matrix, Vector
from mathutils.geometry import (
intersect_line_line,
intersect_point_line,
)
from math import (
degrees,
pi,
sqrt,
)
from bpy.props import (
BoolProperty,
FloatProperty,
IntProperty,
StringProperty,
PointerProperty,
EnumProperty,
FloatVectorProperty,
)
from bpy.types import (
Operator,
Panel,
PropertyGroup,
AddonPreferences,
)
# ----------------------------
# GLOBAL
global_shade_smooth = False
global_mesh_object = ""
global_gpencil_object = ""
global_curve_object = ""
# ----------------------------
# Panels
class VIEW3D_PT_tools_SURFSK_mesh(Panel):
bl_space_type = 'VIEW_3D'
bl_region_type = 'UI'
bl_category = 'Edit'
bl_label = "Bsurfaces"
def draw(self, context):
layout = self.layout
bs = context.scene.bsurfaces
col = layout.column(align=True)
row = layout.row()
row.separator()
col.operator("mesh.surfsk_init", text="Initialize (Add BSurface mesh)")
col.operator("mesh.surfsk_add_modifiers", text="Add Mirror and others modifiers")
col.label(text="Mesh of BSurface:")
col.prop(bs, "SURFSK_mesh", text="")
if bs.SURFSK_mesh != None:
try: mesh_object = bs.SURFSK_mesh
except: pass
try: col.prop(mesh_object.data.materials[0], "diffuse_color")
except: pass
try:
shrinkwrap = next(mod for mod in mesh_object.modifiers
if mod.type == 'SHRINKWRAP')
col.prop(shrinkwrap, "offset")
except:
pass
try: col.prop(mesh_object, "show_in_front")
except: pass
try: col.prop(bs, "SURFSK_shade_smooth")
except: pass
try: col.prop(mesh_object, "show_wire")
except: pass
col.label(text="Guide strokes:")
col.row().prop(bs, "SURFSK_guide", expand=True)
if bs.SURFSK_guide == 'GPencil':
col.prop(bs, "SURFSK_gpencil", text="")
col.separator()
if bs.SURFSK_guide == 'Curve':
col.prop(bs, "SURFSK_curve", text="")
col.separator()
col.separator()
col.operator("mesh.surfsk_add_surface", text="Add Surface")
col.operator("mesh.surfsk_edit_surface", text="Edit Surface")
col.separator()
if bs.SURFSK_guide == 'GPencil':
col.operator("gpencil.surfsk_add_strokes", text="Add Strokes")
col.operator("gpencil.surfsk_edit_strokes", text="Edit Strokes")
col.separator()
col.operator("gpencil.surfsk_strokes_to_curves", text="Strokes to curves")
if bs.SURFSK_guide == 'Annotation':
col.operator("gpencil.surfsk_add_annotation", text="Add Annotation")
col.separator()
col.operator("gpencil.surfsk_annotations_to_curves", text="Annotation to curves")
if bs.SURFSK_guide == 'Curve':
col.operator("curve.surfsk_edit_curve", text="Edit curve")
col.separator()
col.label(text="Initial settings:")
col.prop(bs, "SURFSK_edges_U")
col.prop(bs, "SURFSK_edges_V")
col.prop(bs, "SURFSK_cyclic_cross")
col.prop(bs, "SURFSK_cyclic_follow")
col.prop(bs, "SURFSK_loops_on_strokes")
col.prop(bs, "SURFSK_automatic_join")
col.prop(bs, "SURFSK_keep_strokes")
class VIEW3D_PT_tools_SURFSK_curve(Panel):
bl_space_type = 'VIEW_3D'
bl_region_type = 'UI'
bl_context = "curve_edit"
bl_category = 'Edit'
bl_label = "Bsurfaces"
@classmethod
def poll(cls, context):
return context.active_object
def draw(self, context):
layout = self.layout
col = layout.column(align=True)
row = layout.row()
row.separator()
col.operator("curve.surfsk_first_points", text="Set First Points")
col.operator("curve.switch_direction", text="Switch Direction")
col.operator("curve.surfsk_reorder_splines", text="Reorder Splines")
# ----------------------------
# Returns the type of strokes used
def get_strokes_type(context):
strokes_type = "NO_STROKES"
strokes_num = 0
# Check if they are annotation
if context.scene.bsurfaces.SURFSK_guide == 'Annotation':
try:
strokes = bpy.context.annotation_data.layers.active.active_frame.strokes
strokes_num = len(strokes)
if strokes_num > 0:
strokes_type = "GP_ANNOTATION"
except:
strokes_type = "NO_STROKES"
# Check if they are grease pencil
if context.scene.bsurfaces.SURFSK_guide == 'GPencil':
try:
global global_gpencil_object
gpencil = bpy.data.objects[global_gpencil_object]
strokes = gpencil.data.layers.active.active_frame.strokes
strokes_num = len(strokes)
if strokes_num > 0:
strokes_type = "GP_STROKES"
except:
strokes_type = "NO_STROKES"
# Check if they are curves, if there aren't grease pencil strokes
if context.scene.bsurfaces.SURFSK_guide == 'Curve':
try:
global global_curve_object
ob = bpy.data.objects[global_curve_object]
if ob.type == "CURVE":
strokes_type = "EXTERNAL_CURVE"
strokes_num = len(ob.data.splines)
# Check if there is any non-bezier spline
for i in range(len(ob.data.splines)):
if ob.data.splines[i].type != "BEZIER":
strokes_type = "CURVE_WITH_NON_BEZIER_SPLINES"
break
else:
strokes_type = "EXTERNAL_NO_CURVE"
except:
strokes_type = "NO_STROKES"
# Check if they are mesh
try:
global global_mesh_object
self.main_object = bpy.data.objects[global_mesh_object]
total_vert_sel = len([v for v in self.main_object.data.vertices if v.select])
# Check if there is a single stroke without any selection in the object
if strokes_num == 1 and total_vert_sel == 0:
if strokes_type == "EXTERNAL_CURVE":
strokes_type = "SINGLE_CURVE_STROKE_NO_SELECTION"
elif strokes_type == "GP_STROKES":
strokes_type = "SINGLE_GP_STROKE_NO_SELECTION"
if strokes_num == 0 and total_vert_sel > 0:
strokes_type = "SELECTION_ALONE"
except:
pass
return strokes_type
# ----------------------------
# Surface generator operator
class MESH_OT_SURFSK_add_surface(Operator):
bl_idname = "mesh.surfsk_add_surface"
bl_label = "Bsurfaces add surface"
bl_description = "Generates surfaces from grease pencil strokes, bezier curves or loose edges"
bl_options = {'REGISTER', 'UNDO'}
is_crosshatch: BoolProperty(
default=False
)
is_fill_faces: BoolProperty(
default=False
)
selection_U_exists: BoolProperty(
default=False
)
selection_V_exists: BoolProperty(
default=False
)
selection_U2_exists: BoolProperty(
default=False
)
selection_V2_exists: BoolProperty(
default=False
)
selection_V_is_closed: BoolProperty(
default=False
)
selection_U_is_closed: BoolProperty(
default=False
)
selection_V2_is_closed: BoolProperty(
default=False
)
selection_U2_is_closed: BoolProperty(
default=False
)
edges_U: IntProperty(
name="Cross",
description="Number of face-loops crossing the strokes",
default=1,
min=1,
max=200
)
edges_V: IntProperty(
name="Follow",
description="Number of face-loops following the strokes",
default=1,
min=1,
max=200
)
cyclic_cross: BoolProperty(
name="Cyclic Cross",
description="Make cyclic the face-loops crossing the strokes",
default=False
)
cyclic_follow: BoolProperty(
name="Cyclic Follow",
description="Make cyclic the face-loops following the strokes",
default=False
)
loops_on_strokes: BoolProperty(
name="Loops on strokes",
description="Make the loops match the paths of the strokes",
default=False
)
automatic_join: BoolProperty(
name="Automatic join",
description="Join automatically vertices of either surfaces generated "
"by crosshatching, or from the borders of closed shapes",
default=False
)
join_stretch_factor: FloatProperty(
name="Stretch",
description="Amount of stretching or shrinking allowed for "
"edges when joining vertices automatically",
default=1,
min=0,
max=3,
subtype='FACTOR'
)
keep_strokes: BoolProperty(
name="Keep strokes",
description="Keeps the sketched strokes or curves after adding the surface",
default=False
)
strokes_type: StringProperty()
initial_global_undo_state: BoolProperty()
def draw(self, context):
layout = self.layout
col = layout.column(align=True)
row = layout.row()
if not self.is_fill_faces:
row.separator()
if not self.is_crosshatch:
if not self.selection_U_exists:
col.prop(self, "edges_U")
row.separator()
if not self.selection_V_exists:
col.prop(self, "edges_V")
row.separator()
row.separator()
if not self.selection_U_exists:
if not (
(self.selection_V_exists and not self.selection_V_is_closed) or
(self.selection_V2_exists and not self.selection_V2_is_closed)
):
col.prop(self, "cyclic_cross")
if not self.selection_V_exists:
if not (
(self.selection_U_exists and not self.selection_U_is_closed) or
(self.selection_U2_exists and not self.selection_U2_is_closed)
):
col.prop(self, "cyclic_follow")
col.prop(self, "loops_on_strokes")
col.prop(self, "automatic_join")
if self.automatic_join:
row.separator()
col.separator()
row.separator()
col.prop(self, "join_stretch_factor")
col.prop(self, "keep_strokes")
# Get an ordered list of a chain of vertices
def get_ordered_verts(self, ob, all_selected_edges_idx, all_selected_verts_idx,
first_vert_idx, middle_vertex_idx, closing_vert_idx):
# Order selected vertices.
verts_ordered = []
if closing_vert_idx is not None:
verts_ordered.append(ob.data.vertices[closing_vert_idx])
verts_ordered.append(ob.data.vertices[first_vert_idx])
prev_v = first_vert_idx
prev_ed = None
finish_while = False
while True:
edges_non_matched = 0
for i in all_selected_edges_idx:
if ob.data.edges[i] != prev_ed and ob.data.edges[i].vertices[0] == prev_v and \
ob.data.edges[i].vertices[1] in all_selected_verts_idx:
verts_ordered.append(ob.data.vertices[ob.data.edges[i].vertices[1]])
prev_v = ob.data.edges[i].vertices[1]
prev_ed = ob.data.edges[i]
elif ob.data.edges[i] != prev_ed and ob.data.edges[i].vertices[1] == prev_v and \
ob.data.edges[i].vertices[0] in all_selected_verts_idx:
verts_ordered.append(ob.data.vertices[ob.data.edges[i].vertices[0]])
prev_v = ob.data.edges[i].vertices[0]
prev_ed = ob.data.edges[i]
else:
edges_non_matched += 1
if edges_non_matched == len(all_selected_edges_idx):
finish_while = True
if finish_while:
break
if closing_vert_idx is not None:
verts_ordered.append(ob.data.vertices[closing_vert_idx])
if middle_vertex_idx is not None:
verts_ordered.append(ob.data.vertices[middle_vertex_idx])
verts_ordered.reverse()
return tuple(verts_ordered)
# Calculates length of a chain of points.
def get_chain_length(self, object, verts_ordered):
matrix = object.matrix_world
edges_lengths = []
edges_lengths_sum = 0
for i in range(0, len(verts_ordered)):
if i == 0:
prev_v_co = matrix @ verts_ordered[i].co
else:
v_co = matrix @ verts_ordered[i].co
v_difs = [prev_v_co[0] - v_co[0], prev_v_co[1] - v_co[1], prev_v_co[2] - v_co[2]]
edge_length = abs(sqrt(v_difs[0] * v_difs[0] + v_difs[1] * v_difs[1] + v_difs[2] * v_difs[2]))
edges_lengths.append(edge_length)
edges_lengths_sum += edge_length
prev_v_co = v_co
return edges_lengths, edges_lengths_sum
# Calculates the proportion of the edges of a chain of edges, relative to the full chain length.
def get_edges_proportions(self, edges_lengths, edges_lengths_sum, use_boundaries, fixed_edges_num):
edges_proportions = []
if use_boundaries:
verts_count = 1
for l in edges_lengths:
edges_proportions.append(l / edges_lengths_sum)
verts_count += 1
else:
verts_count = 1
for _n in range(0, fixed_edges_num):
edges_proportions.append(1 / fixed_edges_num)
verts_count += 1
return edges_proportions
# Calculates the angle between two pairs of points in space
def orientation_difference(self, points_A_co, points_B_co):
# each parameter should be a list with two elements,
# and each element should be a x,y,z coordinate
vec_A = points_A_co[0] - points_A_co[1]
vec_B = points_B_co[0] - points_B_co[1]
angle = vec_A.angle(vec_B)
if angle > 0.5 * pi:
angle = abs(angle - pi)
return angle
# Calculate the which vert of verts_idx list is the nearest one
# to the point_co coordinates, and the distance
def shortest_distance(self, object, point_co, verts_idx):
matrix = object.matrix_world
for i in range(0, len(verts_idx)):
dist = (point_co - matrix @ object.data.vertices[verts_idx[i]].co).length
if i == 0:
prev_dist = dist
nearest_vert_idx = verts_idx[i]
shortest_dist = dist
if dist < prev_dist:
prev_dist = dist
nearest_vert_idx = verts_idx[i]
shortest_dist = dist
return nearest_vert_idx, shortest_dist
# Returns the index of the opposite vert tip in a chain, given a vert tip index
# as parameter, and a multidimentional list with all pairs of tips
def opposite_tip(self, vert_tip_idx, all_chains_tips_idx):
opposite_vert_tip_idx = None
for i in range(0, len(all_chains_tips_idx)):
if vert_tip_idx == all_chains_tips_idx[i][0]:
opposite_vert_tip_idx = all_chains_tips_idx[i][1]
if vert_tip_idx == all_chains_tips_idx[i][1]:
opposite_vert_tip_idx = all_chains_tips_idx[i][0]
return opposite_vert_tip_idx
# Simplifies a spline and returns the new points coordinates
def simplify_spline(self, spline_coords, segments_num):
simplified_spline = []
points_between_segments = round(len(spline_coords) / segments_num)
simplified_spline.append(spline_coords[0])
for i in range(1, segments_num):
simplified_spline.append(spline_coords[i * points_between_segments])
simplified_spline.append(spline_coords[len(spline_coords) - 1])
return simplified_spline
# Returns a list with the coords of the points distributed over the splines
# passed to this method according to the proportions parameter
def distribute_pts(self, surface_splines, proportions):
# Calculate the length of each final surface spline
surface_splines_lengths = []
surface_splines_parsed = []
for sp_idx in range(0, len(surface_splines)):
# Calculate spline length
surface_splines_lengths.append(0)
for i in range(0, len(surface_splines[sp_idx].bezier_points)):
if i == 0:
prev_p = surface_splines[sp_idx].bezier_points[i]
else:
p = surface_splines[sp_idx].bezier_points[i]
edge_length = (prev_p.co - p.co).length
surface_splines_lengths[sp_idx] += edge_length
prev_p = p
# Calculate vertex positions with appropriate edge proportions, and ordered, for each spline
for sp_idx in range(0, len(surface_splines)):
surface_splines_parsed.append([])
surface_splines_parsed[sp_idx].append(surface_splines[sp_idx].bezier_points[0].co)
prev_p_co = surface_splines[sp_idx].bezier_points[0].co
p_idx = 0
for prop_idx in range(len(proportions) - 1):
target_length = surface_splines_lengths[sp_idx] * proportions[prop_idx]
partial_segment_length = 0
finish_while = False
while True:
# if not it'll pass the p_idx as an index below and crash
if p_idx < len(surface_splines[sp_idx].bezier_points):
p_co = surface_splines[sp_idx].bezier_points[p_idx].co
new_dist = (prev_p_co - p_co).length
# The new distance that could have the partial segment if
# it is still shorter than the target length
potential_segment_length = partial_segment_length + new_dist
# If the potential is still shorter, keep adding
if potential_segment_length < target_length:
partial_segment_length = potential_segment_length
p_idx += 1
prev_p_co = p_co
# If the potential is longer than the target, calculate the target
# (a point between the last two points), and assign
elif potential_segment_length > target_length:
remaining_dist = target_length - partial_segment_length
vec = p_co - prev_p_co
vec.normalize()
intermediate_co = prev_p_co + (vec * remaining_dist)
surface_splines_parsed[sp_idx].append(intermediate_co)
partial_segment_length += remaining_dist
prev_p_co = intermediate_co
finish_while = True
# If the potential is equal to the target, assign
elif potential_segment_length == target_length:
surface_splines_parsed[sp_idx].append(p_co)
prev_p_co = p_co
finish_while = True
if finish_while:
break
# last point of the spline
surface_splines_parsed[sp_idx].append(
surface_splines[sp_idx].bezier_points[len(surface_splines[sp_idx].bezier_points) - 1].co
)
return surface_splines_parsed
# Counts the number of faces that belong to each edge
def edge_face_count(self, ob):
ed_keys_count_dict = {}
for face in ob.data.polygons:
for ed_keys in face.edge_keys:
if ed_keys not in ed_keys_count_dict:
ed_keys_count_dict[ed_keys] = 1
else:
ed_keys_count_dict[ed_keys] += 1
edge_face_count = []
for i in range(len(ob.data.edges)):
edge_face_count.append(0)
for i in range(len(ob.data.edges)):
ed = ob.data.edges[i]
v1 = ed.vertices[0]
v2 = ed.vertices[1]
if (v1, v2) in ed_keys_count_dict:
edge_face_count[i] = ed_keys_count_dict[(v1, v2)]
elif (v2, v1) in ed_keys_count_dict:
edge_face_count[i] = ed_keys_count_dict[(v2, v1)]
return edge_face_count
# Fills with faces all the selected vertices which form empty triangles or quads
def fill_with_faces(self, object):
all_selected_verts_count = self.main_object_selected_verts_count
bpy.ops.object.mode_set('INVOKE_REGION_WIN', mode='OBJECT')
# Calculate average length of selected edges
all_selected_verts = []
original_sel_edges_count = 0
for ed in object.data.edges:
if object.data.vertices[ed.vertices[0]].select and object.data.vertices[ed.vertices[1]].select:
coords = []
coords.append(object.data.vertices[ed.vertices[0]].co)
coords.append(object.data.vertices[ed.vertices[1]].co)
original_sel_edges_count += 1
if not ed.vertices[0] in all_selected_verts:
all_selected_verts.append(ed.vertices[0])
if not ed.vertices[1] in all_selected_verts:
all_selected_verts.append(ed.vertices[1])
tuple(all_selected_verts)
# Check if there is any edge selected. If not, interrupt the script
if original_sel_edges_count == 0 and all_selected_verts_count > 0:
return 0
# Get all edges connected to selected verts
all_edges_around_sel_verts = []
edges_connected_to_sel_verts = {}
verts_connected_to_every_vert = {}
for ed_idx in range(len(object.data.edges)):
ed = object.data.edges[ed_idx]
include_edge = False
if ed.vertices[0] in all_selected_verts:
if not ed.vertices[0] in edges_connected_to_sel_verts:
edges_connected_to_sel_verts[ed.vertices[0]] = []
edges_connected_to_sel_verts[ed.vertices[0]].append(ed_idx)
include_edge = True
if ed.vertices[1] in all_selected_verts:
if not ed.vertices[1] in edges_connected_to_sel_verts:
edges_connected_to_sel_verts[ed.vertices[1]] = []
edges_connected_to_sel_verts[ed.vertices[1]].append(ed_idx)
include_edge = True
if include_edge is True:
all_edges_around_sel_verts.append(ed_idx)
# Get all connected verts to each vert
if not ed.vertices[0] in verts_connected_to_every_vert:
verts_connected_to_every_vert[ed.vertices[0]] = []
if not ed.vertices[1] in verts_connected_to_every_vert:
verts_connected_to_every_vert[ed.vertices[1]] = []
verts_connected_to_every_vert[ed.vertices[0]].append(ed.vertices[1])
verts_connected_to_every_vert[ed.vertices[1]].append(ed.vertices[0])
# Get all verts connected to faces
all_verts_part_of_faces = []
all_edges_faces_count = []
all_edges_faces_count += self.edge_face_count(object)
# Get only the selected edges that have faces attached.
count_faces_of_edges_around_sel_verts = {}
selected_verts_with_faces = []
for ed_idx in all_edges_around_sel_verts:
count_faces_of_edges_around_sel_verts[ed_idx] = all_edges_faces_count[ed_idx]
if all_edges_faces_count[ed_idx] > 0:
ed = object.data.edges[ed_idx]
if not ed.vertices[0] in selected_verts_with_faces:
selected_verts_with_faces.append(ed.vertices[0])
if not ed.vertices[1] in selected_verts_with_faces:
selected_verts_with_faces.append(ed.vertices[1])
all_verts_part_of_faces.append(ed.vertices[0])
all_verts_part_of_faces.append(ed.vertices[1])
tuple(selected_verts_with_faces)
# Discard unneeded verts from calculations
participating_verts = []
movable_verts = []
for v_idx in all_selected_verts:
vert_has_edges_with_one_face = False
# Check if the actual vert has at least one edge connected to only one face
for ed_idx in edges_connected_to_sel_verts[v_idx]:
if count_faces_of_edges_around_sel_verts[ed_idx] == 1:
vert_has_edges_with_one_face = True
# If the vert has two or less edges connected and the vert is not part of any face.
# Or the vert is part of any face and at least one of
# the connected edges has only one face attached to it.
if (len(edges_connected_to_sel_verts[v_idx]) == 2 and
v_idx not in all_verts_part_of_faces) or \
len(edges_connected_to_sel_verts[v_idx]) == 1 or \
(v_idx in all_verts_part_of_faces and
vert_has_edges_with_one_face):
participating_verts.append(v_idx)
if v_idx not in all_verts_part_of_faces:
movable_verts.append(v_idx)
# Remove from movable verts list those that are part of closed geometry (ie: triangles, quads)
for mv_idx in movable_verts:
freeze_vert = False
mv_connected_verts = verts_connected_to_every_vert[mv_idx]
for actual_v_idx in all_selected_verts:
count_shared_neighbors = 0
checked_verts = []
for mv_conn_v_idx in mv_connected_verts:
if mv_idx != actual_v_idx:
if mv_conn_v_idx in verts_connected_to_every_vert[actual_v_idx] and \
mv_conn_v_idx not in checked_verts:
count_shared_neighbors += 1
checked_verts.append(mv_conn_v_idx)
if actual_v_idx in mv_connected_verts:
freeze_vert = True
break
if count_shared_neighbors == 2:
freeze_vert = True
break
if freeze_vert:
break
if freeze_vert:
movable_verts.remove(mv_idx)
# Calculate merge distance for participating verts
shortest_edge_length = None
for ed in object.data.edges:
if ed.vertices[0] in movable_verts and ed.vertices[1] in movable_verts:
v1 = object.data.vertices[ed.vertices[0]]
v2 = object.data.vertices[ed.vertices[1]]
length = (v1.co - v2.co).length
if shortest_edge_length is None:
shortest_edge_length = length
else:
if length < shortest_edge_length:
shortest_edge_length = length
if shortest_edge_length is not None:
edges_merge_distance = shortest_edge_length * 0.5
else:
edges_merge_distance = 0
# Get together the verts near enough. They will be merged later
remaining_verts = []
remaining_verts += participating_verts
for v1_idx in participating_verts:
if v1_idx in remaining_verts and v1_idx in movable_verts:
verts_to_merge = []
coords_verts_to_merge = {}
verts_to_merge.append(v1_idx)
v1_co = object.data.vertices[v1_idx].co
coords_verts_to_merge[v1_idx] = (v1_co[0], v1_co[1], v1_co[2])
for v2_idx in remaining_verts:
if v1_idx != v2_idx:
v2_co = object.data.vertices[v2_idx].co
dist = (v1_co - v2_co).length
if dist <= edges_merge_distance: # Add the verts which are near enough
verts_to_merge.append(v2_idx)
coords_verts_to_merge[v2_idx] = (v2_co[0], v2_co[1], v2_co[2])
for vm_idx in verts_to_merge:
remaining_verts.remove(vm_idx)
if len(verts_to_merge) > 1:
# Calculate middle point of the verts to merge.
sum_x_co = 0
sum_y_co = 0
sum_z_co = 0
movable_verts_to_merge_count = 0
for i in range(len(verts_to_merge)):
if verts_to_merge[i] in movable_verts:
v_co = object.data.vertices[verts_to_merge[i]].co
sum_x_co += v_co[0]
sum_y_co += v_co[1]
sum_z_co += v_co[2]
movable_verts_to_merge_count += 1
middle_point_co = [
sum_x_co / movable_verts_to_merge_count,
sum_y_co / movable_verts_to_merge_count,
sum_z_co / movable_verts_to_merge_count
]
# Check if any vert to be merged is not movable
shortest_dist = None
are_verts_not_movable = False
verts_not_movable = []
for v_merge_idx in verts_to_merge:
if v_merge_idx in participating_verts and v_merge_idx not in movable_verts:
are_verts_not_movable = True
verts_not_movable.append(v_merge_idx)
if are_verts_not_movable:
# Get the vert connected to faces, that is nearest to
# the middle point of the movable verts
shortest_dist = None
for vcf_idx in verts_not_movable:
dist = abs((object.data.vertices[vcf_idx].co -
Vector(middle_point_co)).length)
if shortest_dist is None:
shortest_dist = dist
nearest_vert_idx = vcf_idx
else:
if dist < shortest_dist:
shortest_dist = dist
nearest_vert_idx = vcf_idx
coords = object.data.vertices[nearest_vert_idx].co
target_point_co = [coords[0], coords[1], coords[2]]
else:
target_point_co = middle_point_co
# Move verts to merge to the middle position
for v_merge_idx in verts_to_merge:
if v_merge_idx in movable_verts: # Only move the verts that are not part of faces
object.data.vertices[v_merge_idx].co[0] = target_point_co[0]
object.data.vertices[v_merge_idx].co[1] = target_point_co[1]
object.data.vertices[v_merge_idx].co[2] = target_point_co[2]
# Perform "Remove Doubles" to weld all the disconnected verts
bpy.ops.object.mode_set('INVOKE_REGION_WIN', mode='EDIT')
bpy.ops.mesh.remove_doubles(threshold=0.0001)
bpy.ops.object.mode_set('INVOKE_REGION_WIN', mode='OBJECT')
# Get all the definitive selected edges, after weldding
selected_edges = []
edges_per_vert = {} # Number of faces of each selected edge
for ed in object.data.edges:
if object.data.vertices[ed.vertices[0]].select and object.data.vertices[ed.vertices[1]].select:
selected_edges.append(ed.index)
# Save all the edges that belong to each vertex.
if not ed.vertices[0] in edges_per_vert:
edges_per_vert[ed.vertices[0]] = []
if not ed.vertices[1] in edges_per_vert:
edges_per_vert[ed.vertices[1]] = []
edges_per_vert[ed.vertices[0]].append(ed.index)
edges_per_vert[ed.vertices[1]].append(ed.index)
# Check if all the edges connected to each vert have two faces attached to them.
# To discard them later and make calculations faster
a = []
a += self.edge_face_count(object)
tuple(a)
verts_surrounded_by_faces = {}
for v_idx in edges_per_vert:
edges_with_two_faces_count = 0
for ed_idx in edges_per_vert[v_idx]:
if a[ed_idx] == 2:
edges_with_two_faces_count += 1
if edges_with_two_faces_count == len(edges_per_vert[v_idx]):
verts_surrounded_by_faces[v_idx] = True
else:
verts_surrounded_by_faces[v_idx] = False
# Get all the selected vertices
selected_verts_idx = []
for v in object.data.vertices:
if v.select:
selected_verts_idx.append(v.index)
# Get all the faces of the object
all_object_faces_verts_idx = []
for face in object.data.polygons:
face_verts = []
face_verts.append(face.vertices[0])
face_verts.append(face.vertices[1])
face_verts.append(face.vertices[2])
if len(face.vertices) == 4:
face_verts.append(face.vertices[3])
all_object_faces_verts_idx.append(face_verts)
# Deselect all vertices
bpy.ops.object.mode_set('INVOKE_REGION_WIN', mode='EDIT')
bpy.ops.mesh.select_all('INVOKE_REGION_WIN', action='DESELECT')
bpy.ops.object.mode_set('INVOKE_REGION_WIN', mode='OBJECT')
# Make a dictionary with the verts related to each vert
related_key_verts = {}
for ed_idx in selected_edges:
ed = object.data.edges[ed_idx]
if not verts_surrounded_by_faces[ed.vertices[0]]:
if not ed.vertices[0] in related_key_verts:
related_key_verts[ed.vertices[0]] = []
if not ed.vertices[1] in related_key_verts[ed.vertices[0]]:
related_key_verts[ed.vertices[0]].append(ed.vertices[1])
if not verts_surrounded_by_faces[ed.vertices[1]]:
if not ed.vertices[1] in related_key_verts:
related_key_verts[ed.vertices[1]] = []
if not ed.vertices[0] in related_key_verts[ed.vertices[1]]:
related_key_verts[ed.vertices[1]].append(ed.vertices[0])
# Get groups of verts forming each face
faces_verts_idx = []
for v1 in related_key_verts: # verts-1 ....
for v2 in related_key_verts: # verts-2
if v1 != v2:
related_verts_in_common = []
v2_in_rel_v1 = False
v1_in_rel_v2 = False
for rel_v1 in related_key_verts[v1]:
# Check if related verts of verts-1 are related verts of verts-2
if rel_v1 in related_key_verts[v2]:
related_verts_in_common.append(rel_v1)
if v2 in related_key_verts[v1]:
v2_in_rel_v1 = True
if v1 in related_key_verts[v2]:
v1_in_rel_v2 = True
repeated_face = False
# If two verts have two related verts in common, they form a quad
if len(related_verts_in_common) == 2:
# Check if the face is already saved
all_faces_to_check_idx = faces_verts_idx + all_object_faces_verts_idx
for f_verts in all_faces_to_check_idx:
repeated_verts = 0
if len(f_verts) == 4:
if v1 in f_verts:
repeated_verts += 1
if v2 in f_verts:
repeated_verts += 1
if related_verts_in_common[0] in f_verts:
repeated_verts += 1
if related_verts_in_common[1] in f_verts:
repeated_verts += 1
if repeated_verts == len(f_verts):
repeated_face = True
break
if not repeated_face:
faces_verts_idx.append(
[v1, related_verts_in_common[0], v2, related_verts_in_common[1]]
)
# If Two verts have one related vert in common and
# they are related to each other, they form a triangle
elif v2_in_rel_v1 and v1_in_rel_v2 and len(related_verts_in_common) == 1:
# Check if the face is already saved.
all_faces_to_check_idx = faces_verts_idx + all_object_faces_verts_idx