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-rw-r--r--BakeVertexData.py789
1 files changed, 523 insertions, 266 deletions
diff --git a/BakeVertexData.py b/BakeVertexData.py
index 7b1e426..7493aef 100644
--- a/BakeVertexData.py
+++ b/BakeVertexData.py
@@ -11,7 +11,7 @@ import bpy
import mathutils
import bmesh
import math
-from bpy.props import BoolProperty, FloatProperty
+from bpy.props import BoolProperty, FloatProperty, IntProperty
from bpy.types import Panel, Operator
@@ -20,95 +20,95 @@ class MESH_OT_bake_vertex_vectors(Operator):
bl_label = "Bake Vertex Vectors"
bl_description = "Bake selected vertices with automatic center and scale calculation"
bl_options = {'REGISTER', 'UNDO'}
-
+
contiguous_mode: BoolProperty(
name="Contiguous Groups",
description="Process each contiguous group of vertices separately with its own center and scale",
default=False
)
-
+
@classmethod
def poll(cls, context):
obj = context.active_object
return (obj is not None and
obj.type == 'MESH' and
context.mode == 'EDIT_MESH')
-
+
def get_vertex_islands(self, mesh, selected_indices):
"""Find contiguous groups of vertices using edge connectivity"""
adjacency = {idx: set() for idx in selected_indices}
-
+
for edge in mesh.edges:
v0, v1 = edge.vertices
if v0 in selected_indices and v1 in selected_indices:
adjacency[v0].add(v1)
adjacency[v1].add(v0)
-
+
islands = []
visited = set()
-
+
for start_idx in selected_indices:
if start_idx in visited:
continue
-
+
island = set()
queue = [start_idx]
-
+
while queue:
current = queue.pop(0)
if current in visited:
continue
-
+
visited.add(current)
island.add(current)
-
+
for neighbor in adjacency[current]:
if neighbor not in visited:
queue.append(neighbor)
-
+
islands.append(island)
-
+
return islands
-
+
def get_island_info(self, mesh, island_indices):
"""Calculate center and scale for a single island"""
verts = []
for idx in island_indices:
verts.append(mesh.vertices[idx].co)
-
+
if not verts:
return None, None, None
-
+
center = mathutils.Vector((0, 0, 0))
for co in verts:
center += co
center /= len(verts)
-
+
max_dist = 0.0
for co in verts:
vec = co - center
max_component = max(abs(vec.x), abs(vec.y), abs(vec.z))
max_dist = max(max_dist, max_component)
-
+
if max_dist > 0:
scale = 1.0 / max_dist
else:
scale = 1.0
-
+
return center, max_dist, scale
-
+
def execute(self, context):
obj = context.active_object
mesh = obj.data
-
+
try:
bpy.ops.object.mode_set(mode='OBJECT')
except Exception as e:
self.report({'ERROR'}, f"Failed to switch to object mode: {str(e)}")
return {'CANCELLED'}
-
+
selected_indices = {v.index for v in mesh.vertices if v.select}
-
+
if not selected_indices:
self.report({'WARNING'}, "No vertices selected")
try:
@@ -116,7 +116,7 @@ class MESH_OT_bake_vertex_vectors(Operator):
except:
pass
return {'CANCELLED'}
-
+
# Check if mesh has faces
if not mesh.polygons:
self.report({'ERROR'}, "Mesh has no faces. Vertex colors require faces to store data.")
@@ -125,10 +125,10 @@ class MESH_OT_bake_vertex_vectors(Operator):
except:
pass
return {'CANCELLED'}
-
+
if not mesh.vertex_colors:
mesh.vertex_colors.new(name="BakedVectors")
-
+
color_layer = mesh.vertex_colors.active
if not color_layer:
self.report({'ERROR'}, "Failed to create vertex color layer")
@@ -137,9 +137,9 @@ class MESH_OT_bake_vertex_vectors(Operator):
except:
pass
return {'CANCELLED'}
-
+
source_matrix = obj.matrix_world
-
+
if self.contiguous_mode:
# Build vertex to polygon mapping for efficiency
vertex_to_polys = {}
@@ -149,113 +149,113 @@ class MESH_OT_bake_vertex_vectors(Operator):
if vertex_idx not in vertex_to_polys:
vertex_to_polys[vertex_idx] = []
vertex_to_polys[vertex_idx].append(poly_idx)
-
+
islands = self.get_vertex_islands(mesh, selected_indices)
total_updated = 0
-
+
for island_indices in islands:
center, max_dist, scale = self.get_island_info(mesh, island_indices)
if center is None:
continue
-
+
center_world = source_matrix @ center
-
+
# Collect all polygons that contain vertices from this island
relevant_polys = set()
for vertex_idx in island_indices:
if vertex_idx in vertex_to_polys:
relevant_polys.update(vertex_to_polys[vertex_idx])
-
+
# Only process relevant polygons
for poly_idx in relevant_polys:
poly = mesh.polygons[poly_idx]
for loop_idx in poly.loop_indices:
vertex_idx = mesh.loops[loop_idx].vertex_index
-
+
if vertex_idx in island_indices:
vertex = mesh.vertices[vertex_idx]
-
+
vertex_world = source_matrix @ vertex.co
vector_world = center_world - vertex_world
vector_object = source_matrix.inverted_safe().to_3x3() @ vector_world
vector_scaled = vector_object * scale
-
+
color = mathutils.Vector((
(vector_scaled.x + 1.0) * 0.5,
(vector_scaled.y + 1.0) * 0.5,
(vector_scaled.z + 1.0) * 0.5,
scale
))
-
+
color_layer.data[loop_idx].color = color
total_updated += 1
-
+
mesh.update()
-
+
try:
bpy.ops.object.mode_set(mode='EDIT')
except Exception as e:
self.report({'WARNING'}, f"Could not return to edit mode: {str(e)}")
-
+
self.report({'INFO'}, f"Baked {len(islands)} contiguous groups ({len(selected_indices)} vertices)")
return {'FINISHED'}
-
+
else:
verts = []
for idx in selected_indices:
verts.append(mesh.vertices[idx].co)
-
+
center = mathutils.Vector((0, 0, 0))
for co in verts:
center += co
center /= len(verts)
-
+
max_dist = 0.0
for co in verts:
vec = co - center
max_component = max(abs(vec.x), abs(vec.y), abs(vec.z))
max_dist = max(max_dist, max_component)
-
+
if max_dist > 0:
scale = 1.0 / max_dist
else:
scale = 1.0
-
+
center_world = source_matrix @ center
-
+
updated_count = 0
for poly in mesh.polygons:
for loop_idx in poly.loop_indices:
vertex_idx = mesh.loops[loop_idx].vertex_index
-
+
if vertex_idx in selected_indices:
vertex = mesh.vertices[vertex_idx]
-
+
vertex_world = source_matrix @ vertex.co
vector_world = center_world - vertex_world
vector_object = source_matrix.inverted_safe().to_3x3() @ vector_world
vector_scaled = vector_object * scale
-
+
color = mathutils.Vector((
(vector_scaled.x + 1.0) * 0.5,
(vector_scaled.y + 1.0) * 0.5,
(vector_scaled.z + 1.0) * 0.5,
scale
))
-
+
color_layer.data[loop_idx].color = color
updated_count += 1
-
+
mesh.update()
-
+
try:
bpy.ops.object.mode_set(mode='EDIT')
except Exception as e:
self.report({'WARNING'}, f"Could not return to edit mode: {str(e)}")
-
+
self.report({'INFO'}, f"Baked {len(selected_indices)} vertices with scale {scale:.3f}")
return {'FINISHED'}
-
+
def draw(self, context):
layout = self.layout
layout.prop(self, "contiguous_mode")
@@ -266,69 +266,69 @@ class MESH_OT_select_all_linked_submeshes(Operator):
bl_label = "Select All Linked Submeshes"
bl_description = "Select all vertices in any submesh that has at least one vertex selected"
bl_options = {'REGISTER', 'UNDO'}
-
+
@classmethod
def poll(cls, context):
obj = context.active_object
return (obj is not None and
obj.type == 'MESH' and
context.mode == 'EDIT_MESH')
-
+
def execute(self, context):
obj = context.active_object
mesh = obj.data
-
+
# Switch to object mode for reliable selection updates
bpy.ops.object.mode_set(mode='OBJECT')
-
+
# Get currently selected vertices
initially_selected = set()
for v in mesh.vertices:
if v.select:
initially_selected.add(v.index)
-
+
if not initially_selected:
self.report({'WARNING'}, "No vertices selected")
bpy.ops.object.mode_set(mode='EDIT')
return {'CANCELLED'}
-
+
# Build adjacency from edges
adjacency = {i: set() for i in range(len(mesh.vertices))}
for edge in mesh.edges:
v0, v1 = edge.vertices
adjacency[v0].add(v1)
adjacency[v1].add(v0)
-
+
# Find all islands
all_indices = set(range(len(mesh.vertices)))
islands = []
visited = set()
-
+
for start_idx in all_indices:
if start_idx in visited:
continue
-
+
island = set()
queue = [start_idx]
-
+
while queue:
current = queue.pop(0)
if current in visited:
continue
-
+
visited.add(current)
island.add(current)
-
+
for neighbor in adjacency[current]:
if neighbor not in visited:
queue.append(neighbor)
-
+
islands.append(island)
-
+
# Select vertices in islands that have any selected vertex
expanded_count = 0
affected_islands = 0
-
+
for island in islands:
if island & initially_selected: # If island has any selected vertices
new_selections = island - initially_selected
@@ -338,22 +338,22 @@ class MESH_OT_select_all_linked_submeshes(Operator):
# Select all vertices in this island
for idx in island:
mesh.vertices[idx].select = True
-
+
# Select edges where both vertices are selected
for edge in mesh.edges:
v0, v1 = edge.vertices
if mesh.vertices[v0].select and mesh.vertices[v1].select:
edge.select = True
-
+
# Select faces where all vertices are selected
for face in mesh.polygons:
all_verts_selected = all(mesh.vertices[v].select for v in face.vertices)
if all_verts_selected:
face.select = True
-
+
# Return to edit mode
bpy.ops.object.mode_set(mode='EDIT')
-
+
self.report({'INFO'}, f"Expanded selection in {affected_islands} submeshes ({expanded_count} new vertices)")
return {'FINISHED'}
@@ -363,7 +363,7 @@ class MESH_OT_select_linked_across_boundaries(Operator):
bl_label = "Select Linked (Cross Boundaries)"
bl_description = "Select linked vertices, crossing submesh boundaries where vertices share locations"
bl_options = {'REGISTER', 'UNDO'}
-
+
epsilon: FloatProperty(
name="Location Tolerance",
description="Maximum distance for vertices to be considered at the same location",
@@ -373,14 +373,14 @@ class MESH_OT_select_linked_across_boundaries(Operator):
precision=6,
subtype='DISTANCE'
)
-
+
@classmethod
def poll(cls, context):
obj = context.active_object
return (obj is not None and
obj.type == 'MESH' and
context.mode == 'EDIT_MESH')
-
+
def build_position_map(self, mesh, epsilon):
"""Build a map of vertices that share the same position within epsilon"""
# Use integer hashing for much faster performance
@@ -388,9 +388,9 @@ class MESH_OT_select_linked_across_boundaries(Operator):
scale = min(1.0 / epsilon, 1e7) # Cap scale to prevent overflow
else:
scale = 1e7 # Large scale for exact matching
-
+
position_map = {}
-
+
# Group vertices by their quantized positions
for v in mesh.vertices:
# Quantize to integer grid
@@ -399,15 +399,15 @@ class MESH_OT_select_linked_across_boundaries(Operator):
int(v.co.y * scale),
int(v.co.z * scale)
)
-
+
if key not in position_map:
position_map[key] = []
position_map[key].append(v.index)
-
+
# Create adjacency only for vertices we'll actually use
# This avoids creating empty sets for all vertices
position_adjacency = {}
-
+
for vertices_at_pos in position_map.values():
if len(vertices_at_pos) > 1:
# For small groups, connect all to all
@@ -433,24 +433,24 @@ class MESH_OT_select_linked_across_boundaries(Operator):
position_adjacency[v] = set()
position_adjacency[hub].add(v)
position_adjacency[v].add(hub)
-
+
return position_adjacency
-
+
def execute(self, context):
obj = context.active_object
mesh = obj.data
-
+
# Switch to object mode
bpy.ops.object.mode_set(mode='OBJECT')
-
+
# Get initially selected vertices
initially_selected = {v.index for v in mesh.vertices if v.select}
-
+
if not initially_selected:
self.report({'WARNING'}, "No vertices selected")
bpy.ops.object.mode_set(mode='EDIT')
return {'CANCELLED'}
-
+
# Build edge adjacency only for vertices we might visit
edge_adjacency = {}
for edge in mesh.edges:
@@ -461,10 +461,10 @@ class MESH_OT_select_linked_across_boundaries(Operator):
edge_adjacency[v1] = set()
edge_adjacency[v0].add(v1)
edge_adjacency[v1].add(v0)
-
+
# Build position adjacency
position_adjacency = self.build_position_map(mesh, self.epsilon)
-
+
# Function to get combined neighbors efficiently
def get_neighbors(vertex_idx):
neighbors = set()
@@ -473,44 +473,44 @@ class MESH_OT_select_linked_across_boundaries(Operator):
if vertex_idx in position_adjacency:
neighbors.update(position_adjacency[vertex_idx])
return neighbors
-
+
# Flood fill from selected vertices using deque for better performance
from collections import deque
visited = set()
queue = deque(initially_selected)
-
+
while queue:
current = queue.popleft()
if current in visited:
continue
-
+
visited.add(current)
mesh.vertices[current].select = True
-
+
# Add all connected vertices to queue
for neighbor in get_neighbors(current):
if neighbor not in visited:
queue.append(neighbor)
-
+
# Select edges where both vertices are selected
for edge in mesh.edges:
v0, v1 = edge.vertices
if mesh.vertices[v0].select and mesh.vertices[v1].select:
edge.select = True
-
+
# Select faces where all vertices are selected
for face in mesh.polygons:
all_verts_selected = all(mesh.vertices[v].select for v in face.vertices)
if all_verts_selected:
face.select = True
-
+
# Return to edit mode
bpy.ops.object.mode_set(mode='EDIT')
-
+
expanded_count = len(visited) - len(initially_selected)
self.report({'INFO'}, f"Selected {len(visited)} vertices ({expanded_count} new)")
return {'FINISHED'}
-
+
def draw(self, context):
layout = self.layout
layout.prop(self, "epsilon")
@@ -522,7 +522,7 @@ class MESH_OT_deduplicate_submeshes(Operator):
bl_label = "Deduplicate Submeshes"
bl_description = "Remove duplicate submeshes from selection that have vertices at the same locations"
bl_options = {'REGISTER', 'UNDO'}
-
+
tolerance: FloatProperty(
name="Position Tolerance",
description="Maximum distance for vertices to be considered at the same position",
@@ -531,62 +531,62 @@ class MESH_OT_deduplicate_submeshes(Operator):
max=1.0,
precision=6
)
-
+
@classmethod
def poll(cls, context):
obj = context.active_object
return (obj is not None and
obj.type == 'MESH' and
context.mode == 'EDIT_MESH')
-
+
def get_selected_vertex_islands(self, mesh):
"""Find all contiguous groups of selected vertices in the mesh"""
# Get selected vertices
selected_indices = {v.index for v in mesh.vertices if v.select}
-
+
if not selected_indices:
return []
-
+
# Build adjacency only for selected vertices
adjacency = {idx: set() for idx in selected_indices}
-
+
for edge in mesh.edges:
v0, v1 = edge.vertices
if v0 in selected_indices and v1 in selected_indices:
adjacency[v0].add(v1)
adjacency[v1].add(v0)
-
+
islands = []
visited = set()
-
+
for start_idx in selected_indices:
if start_idx in visited:
continue
-
+
island = set()
queue = [start_idx]
-
+
while queue:
current = queue.pop(0)
if current in visited:
continue
-
+
visited.add(current)
island.add(current)
-
+
for neighbor in adjacency[current]:
if neighbor not in visited:
queue.append(neighbor)
-
+
islands.append(island)
-
+
return islands
-
+
def get_island_hash(self, mesh, island_indices):
"""Create a hash for an island based on vertex positions"""
# Round positions to handle tolerance
decimal_places = 6 if self.tolerance == 0 else max(0, int(-math.log10(self.tolerance)))
-
+
positions = []
for idx in island_indices:
co = mesh.vertices[idx].co
@@ -597,33 +597,33 @@ class MESH_OT_deduplicate_submeshes(Operator):
round(co.z, decimal_places)
)
positions.append(rounded)
-
+
# Sort positions to ensure consistent ordering
positions.sort()
-
+
# Convert to tuple for hashing
return tuple(positions)
-
+
def execute(self, context):
obj = context.active_object
mesh = obj.data
-
+
# Switch to object mode
bpy.ops.object.mode_set(mode='OBJECT')
-
+
# Find all selected islands
islands = self.get_selected_vertex_islands(mesh)
-
+
if not islands:
self.report({'WARNING'}, "No vertices selected")
bpy.ops.object.mode_set(mode='EDIT')
return {'CANCELLED'}
-
+
if len(islands) <= 1:
self.report({'INFO'}, "No duplicate submeshes found in selection (only 1 submesh)")
bpy.ops.object.mode_set(mode='EDIT')
return {'FINISHED'}
-
+
# Group islands by their hash
island_groups = {}
for island in islands:
@@ -631,43 +631,43 @@ class MESH_OT_deduplicate_submeshes(Operator):
if island_hash not in island_groups:
island_groups[island_hash] = []
island_groups[island_hash].append(island)
-
+
# Find duplicates
duplicates_to_remove = []
duplicate_count = 0
-
+
for hash_key, group in island_groups.items():
if len(group) > 1:
# Keep the first island, mark others for removal
for island in group[1:]:
duplicates_to_remove.append(island)
duplicate_count += 1
-
+
if not duplicates_to_remove:
self.report({'INFO'}, "No duplicate submeshes found in selection")
bpy.ops.object.mode_set(mode='EDIT')
return {'FINISHED'}
-
+
# Enter edit mode and select vertices to delete
bpy.ops.object.mode_set(mode='EDIT')
bpy.ops.mesh.select_all(action='DESELECT')
bpy.ops.object.mode_set(mode='OBJECT')
-
+
# Select all vertices in duplicate islands
vertices_to_delete = set()
for island in duplicates_to_remove:
vertices_to_delete.update(island)
-
+
for idx in vertices_to_delete:
mesh.vertices[idx].select = True
-
+
# Delete selected vertices
bpy.ops.object.mode_set(mode='EDIT')
bpy.ops.mesh.delete(type='VERT')
-
+
self.report({'INFO'}, f"Removed {duplicate_count} duplicate submeshes from selection ({len(vertices_to_delete)} vertices)")
return {'FINISHED'}
-
+
def draw(self, context):
layout = self.layout
layout.prop(self, "tolerance")
@@ -679,7 +679,7 @@ class MESH_OT_pack_uv_islands_by_submesh(Operator):
bl_label = "Pack UV Islands by Submesh Z"
bl_description = "Pack UV islands vertically sorted by submesh Z position"
bl_options = {'REGISTER', 'UNDO'}
-
+
padding: FloatProperty(
name="Island Padding",
description="Padding between UV islands",
@@ -688,7 +688,27 @@ class MESH_OT_pack_uv_islands_by_submesh(Operator):
max=0.1,
precision=3
)
-
+
+ max_islands_per_row: IntProperty(
+ name="Max Islands Per Row",
+ description="Maximum number of islands per row (use high value for width-based packing only)",
+ default=100,
+ min=1,
+ max=1000
+ )
+
+ lock_overlapping: BoolProperty(
+ name="Lock Overlapping Islands",
+ description="Treat overlapping UV islands as a single island",
+ default=False
+ )
+
+ skip_overlap_check: BoolProperty(
+ name="Skip Overlap Check",
+ description="Skip overlap detection entirely for better performance on large meshes (overrides Lock Overlapping)",
+ default=False
+ )
+
@classmethod
def poll(cls, context):
obj = context.active_object
@@ -696,148 +716,315 @@ class MESH_OT_pack_uv_islands_by_submesh(Operator):
obj.type == 'MESH' and
context.mode == 'EDIT_MESH' and
obj.data.uv_layers.active is not None)
-
+
def get_uv_islands(self, bm, uv_layer):
"""Find all UV islands in the mesh"""
# Build UV edge connectivity
uv_vert_map = {} # Maps UV coordinates to vertex indices
uv_edges = set() # Set of UV edges as frozensets of UV coords
-
+
for face in bm.faces:
if not face.select:
continue
-
+
face_uvs = []
for loop in face.loops:
uv = loop[uv_layer].uv
uv_key = (round(uv.x, 6), round(uv.y, 6))
face_uvs.append(uv_key)
-
+
if uv_key not in uv_vert_map:
uv_vert_map[uv_key] = set()
uv_vert_map[uv_key].add(loop.vert.index) # Store index instead of BMVert
-
+
# Create UV edges
for i in range(len(face_uvs)):
j = (i + 1) % len(face_uvs)
edge = frozenset([face_uvs[i], face_uvs[j]])
uv_edges.add(edge)
-
+
# Find UV islands using connected components
uv_adjacency = {uv: set() for uv in uv_vert_map}
-
+
for edge in uv_edges:
uv_list = list(edge)
if len(uv_list) == 2:
uv_adjacency[uv_list[0]].add(uv_list[1])
uv_adjacency[uv_list[1]].add(uv_list[0])
-
+
# Find connected components
visited = set()
islands = []
-
+
for start_uv in uv_vert_map:
if start_uv in visited:
continue
-
+
island_uvs = set()
island_vert_indices = set() # Store indices instead of BMVerts
queue = [start_uv]
-
+
while queue:
current_uv = queue.pop(0)
if current_uv in visited:
continue
-
+
visited.add(current_uv)
island_uvs.add(current_uv)
island_vert_indices.update(uv_vert_map[current_uv])
-
+
for neighbor in uv_adjacency[current_uv]:
if neighbor not in visited:
queue.append(neighbor)
-
+
# Store island data with vertex indices
islands.append({
'uvs': island_uvs,
'vert_indices': island_vert_indices, # Store indices
'loops': [] # Will be filled later
})
-
+
# We'll assign loops later when we have a valid BMesh
return islands
-
+
def get_island_bounds(self, island, uv_layer):
"""Get bounding box of UV island"""
if not island['loops']:
return 0, 0, 0, 0
-
+
min_u = min_v = float('inf')
max_u = max_v = float('-inf')
-
+
for loop in island['loops']:
uv = loop[uv_layer].uv
min_u = min(min_u, uv.x)
max_u = max(max_u, uv.x)
min_v = min(min_v, uv.y)
max_v = max(max_v, uv.y)
-
+
return min_u, min_v, max_u, max_v
-
+
def get_submesh_of_island(self, island_vert_indices, submeshes):
"""Find which submesh an island belongs to"""
# island_vert_indices is already a set of indices
-
+
# Find submesh with most overlap
best_submesh = None
best_overlap = 0
-
+
for i, submesh in enumerate(submeshes):
overlap = len(island_vert_indices & submesh)
if overlap > best_overlap:
best_overlap = overlap
best_submesh = i
-
+
return best_submesh
-
+
+ def get_submesh_of_island_fast(self, island_vert_indices, vertex_to_submesh):
+ """Find which submesh an island belongs to (optimized version)"""
+ # Count vertices per submesh
+ submesh_counts = {}
+
+ for vert_idx in island_vert_indices:
+ if vert_idx in vertex_to_submesh:
+ submesh_idx = vertex_to_submesh[vert_idx]
+ submesh_counts[submesh_idx] = submesh_counts.get(submesh_idx, 0) + 1
+
+ # Find submesh with most vertices
+ if not submesh_counts:
+ return None
+
+ best_submesh = max(submesh_counts.items(), key=lambda x: x[1])
+ return best_submesh[0]
+
+ def check_islands_overlap(self, island1, island2, uv_layer):
+ """Check if two UV islands overlap"""
+ # First check bounding box overlap
+ bounds1 = self.get_island_bounds(island1, uv_layer)
+ bounds2 = self.get_island_bounds(island2, uv_layer)
+
+ # Check if bounding boxes don't overlap
+ if (bounds1[2] < bounds2[0] or bounds2[2] < bounds1[0] or
+ bounds1[3] < bounds2[1] or bounds2[3] < bounds1[1]):
+ return False
+
+ # For precise overlap, check if any UV coordinates are shared
+ # This is sufficient for most use cases (exact overlapping vertices)
+ return bool(island1['uvs'] & island2['uvs'])
+
+ def merge_overlapping_islands(self, islands, uv_layer):
+ """Merge overlapping UV islands into groups"""
+ if not self.lock_overlapping:
+ return islands
+
+ num_islands = len(islands)
+
+ # Skip for very large numbers of islands
+ if num_islands > 1000:
+ self.report({'WARNING'}, f"Skipping overlap detection for {num_islands} islands (too many)")
+ return islands
+
+ # Pre-calculate bounds for all islands
+ island_bounds = []
+ for island in islands:
+ bounds = self.get_island_bounds(island, uv_layer)
+ island_bounds.append(bounds)
+
+ # Build overlap graph with bounding box pre-filtering
+ overlap_graph = {i: set() for i in range(num_islands)}
+
+ # Use spatial subdivision for large island counts
+ if num_islands > 200:
+ # Create spatial grid for broad phase
+ grid_size = 10
+ spatial_grid = {}
+
+ for i, bounds in enumerate(island_bounds):
+ if bounds[0] == bounds[2] and bounds[1] == bounds[3]:
+ continue # Skip degenerate islands
+
+ # Determine grid cells this island touches
+ min_x = int(bounds[0] * grid_size)
+ max_x = int(bounds[2] * grid_size)
+ min_y = int(bounds[1] * grid_size)
+ max_y = int(bounds[3] * grid_size)
+
+ for gx in range(min_x, max_x + 1):
+ for gy in range(min_y, max_y + 1):
+ grid_key = (gx, gy)
+ if grid_key not in spatial_grid:
+ spatial_grid[grid_key] = []
+ spatial_grid[grid_key].append(i)
+
+ # Check overlaps only within same grid cells
+ checked_pairs = set()
+ for cell_islands in spatial_grid.values():
+ for i, idx1 in enumerate(cell_islands):
+ for idx2 in cell_islands[i + 1:]:
+ pair = (min(idx1, idx2), max(idx1, idx2))
+ if pair in checked_pairs:
+ continue
+ checked_pairs.add(pair)
+
+ # Quick bounding box check
+ b1, b2 = island_bounds[idx1], island_bounds[idx2]
+ if not (b1[2] < b2[0] or b2[2] < b1[0] or
+ b1[3] < b2[1] or b2[3] < b1[1]):
+ # Detailed overlap check
+ if islands[idx1]['uvs'] & islands[idx2]['uvs']:
+ overlap_graph[idx1].add(idx2)
+ overlap_graph[idx2].add(idx1)
+ else:
+ # Original O(n²) algorithm for smaller counts
+ for i in range(num_islands):
+ for j in range(i + 1, num_islands):
+ # Quick bounding box check first
+ b1, b2 = island_bounds[i], island_bounds[j]
+ if not (b1[2] < b2[0] or b2[2] < b1[0] or
+ b1[3] < b2[1] or b2[3] < b1[1]):
+ # Detailed overlap check
+ if islands[i]['uvs'] & islands[j]['uvs']:
+ overlap_graph[i].add(j)
+ overlap_graph[j].add(i)
+
+ # Find connected components (groups of overlapping islands)
+ visited = set()
+ merged_islands = []
+
+ for start_idx in range(num_islands):
+ if start_idx in visited:
+ continue
+
+ # Find all islands connected to this one
+ group_indices = set()
+ queue = [start_idx]
+
+ while queue:
+ current = queue.pop(0)
+ if current in visited:
+ continue
+
+ visited.add(current)
+ group_indices.add(current)
+
+ for neighbor in overlap_graph[current]:
+ if neighbor not in visited:
+ queue.append(neighbor)
+
+ # Merge islands in this group
+ if len(group_indices) == 1:
+ # Single island, no merge needed
+ merged_islands.append(islands[start_idx])
+ else:
+ # Merge multiple islands
+ merged_uvs = set()
+ merged_vert_indices = set()
+ merged_loops = []
+
+ for idx in group_indices:
+ island = islands[idx]
+ merged_uvs.update(island['uvs'])
+ merged_vert_indices.update(island['vert_indices'])
+ merged_loops.extend(island['loops'])
+
+ merged_islands.append({
+ 'uvs': merged_uvs,
+ 'vert_indices': merged_vert_indices,
+ 'loops': merged_loops
+ })
+
+ return merged_islands
+
def get_submesh_avg_z(self, mesh, submesh_indices):
"""Calculate average Z position of a submesh"""
if not submesh_indices:
return 0.0
-
+
total_z = 0.0
for idx in submesh_indices:
total_z += mesh.vertices[idx].co.z
-
+
return total_z / len(submesh_indices)
-
+
def execute(self, context):
obj = context.active_object
mesh = obj.data
-
+
# Get UV layer
uv_layer = mesh.uv_layers.active
if not uv_layer:
self.report({'ERROR'}, "No active UV layer")
return {'CANCELLED'}
-
+
# Create BMesh
bm = bmesh.from_edit_mesh(mesh)
bm_uv_layer = bm.loops.layers.uv.active
-
+
# Get UV islands from selected faces
uv_islands = self.get_uv_islands(bm, bm_uv_layer)
-
+
if not uv_islands:
self.report({'WARNING'}, "No UV islands found in selection")
return {'CANCELLED'}
-
+
+ # Performance warning for large meshes
+ if len(uv_islands) > 500 and self.lock_overlapping:
+ self.report({'WARNING'}, f"Processing {len(uv_islands)} islands with overlap detection may be slow")
+
+ # Merge overlapping islands if requested
+ original_count = len(uv_islands)
+ if self.skip_overlap_check:
+ merged_count = 0
+ else:
+ uv_islands = self.merge_overlapping_islands(uv_islands, bm_uv_layer)
+ merged_count = original_count - len(uv_islands)
+
# Get submeshes (vertex islands)
bpy.ops.object.mode_set(mode='OBJECT')
-
+
# Get selected vertices for submesh detection
selected_indices = {v.index for v in mesh.vertices if v.select}
-
+
# Build submeshes (reusing logic from other operators)
adjacency = {idx: set() for idx in selected_indices}
for edge in mesh.edges:
@@ -845,64 +1032,82 @@ class MESH_OT_pack_uv_islands_by_submesh(Operator):
if v0 in selected_indices and v1 in selected_indices:
adjacency[v0].add(v1)
adjacency[v1].add(v0)
-
+
submeshes = []
visited = set()
-
+
+ # Build vertex-to-submesh mapping for O(1) lookups
+ vertex_to_submesh = {}
+ submesh_idx = 0
+
for start_idx in selected_indices:
if start_idx in visited:
continue
-
+
submesh = set()
queue = [start_idx]
-
+
while queue:
current = queue.pop(0)
if current in visited:
continue
-
+
visited.add(current)
submesh.add(current)
-
+ vertex_to_submesh[current] = submesh_idx
+
for neighbor in adjacency[current]:
if neighbor not in visited:
queue.append(neighbor)
-
+
submeshes.append(submesh)
-
+ submesh_idx += 1
+
# Calculate average Z for each submesh
submesh_z_values = []
for submesh in submeshes:
avg_z = self.get_submesh_avg_z(mesh, submesh)
submesh_z_values.append(avg_z)
-
+
# Return to edit mode to work with BMesh
bpy.ops.object.mode_set(mode='EDIT')
bm = bmesh.from_edit_mesh(mesh)
bm_uv_layer = bm.loops.layers.uv.active
-
- # Assign loops to islands now that we're back in edit mode
+
+ # Build UV-to-loops mapping once for all islands
+ uv_to_loops = {}
+ for face in bm.faces:
+ if not face.select:
+ continue
+
+ for loop in face.loops:
+ uv = loop[bm_uv_layer].uv
+ uv_key = (round(uv.x, 6), round(uv.y, 6))
+
+ if uv_key not in uv_to_loops:
+ uv_to_loops[uv_key] = []
+ uv_to_loops[uv_key].append(loop)
+
+ # Assign loops to islands efficiently
for island in uv_islands:
- for face in bm.faces:
- if not face.select:
- continue
-
- for loop in face.loops:
- uv = loop[bm_uv_layer].uv
- uv_key = (round(uv.x, 6), round(uv.y, 6))
-
- if uv_key in island['uvs']:
- island['loops'].append(loop)
-
+ island['loops'] = []
+ for uv_key in island['uvs']:
+ if uv_key in uv_to_loops:
+ island['loops'].extend(uv_to_loops[uv_key])
+
# Assign UV islands to submeshes and get bounds
island_data = []
for island in uv_islands:
- submesh_idx = self.get_submesh_of_island(island['vert_indices'], submeshes)
+ submesh_idx = self.get_submesh_of_island_fast(island['vert_indices'], vertex_to_submesh)
if submesh_idx is not None and island['loops']: # Make sure we have loops
bounds = self.get_island_bounds(island, bm_uv_layer)
width = bounds[2] - bounds[0]
height = bounds[3] - bounds[1]
-
+
+ # Skip degenerate islands
+ if width <= 0 or height <= 0:
+ continue
+
island_data.append({
'island': island,
'submesh_idx': submesh_idx,
@@ -913,10 +1118,10 @@ class MESH_OT_pack_uv_islands_by_submesh(Operator):
'min_u': bounds[0],
'min_v': bounds[1]
})
-
+
# Sort islands by submesh Z (descending, so higher Z is at top of UV space)
island_data.sort(key=lambda x: x['submesh_z'], reverse=True)
-
+
# Calculate total area needed
total_area = 0
max_island_size = 0
@@ -924,11 +1129,27 @@ class MESH_OT_pack_uv_islands_by_submesh(Operator):
area = (data['width'] + self.padding) * (data['height'] + self.padding)
total_area += area
max_island_size = max(max_island_size, max(data['width'], data['height']))
-
- # Calculate optimal square dimensions
- # Start with square root of total area, but ensure it's at least as wide as largest island
- target_size = max(math.sqrt(total_area) * 1.2, max_island_size + 2 * self.padding) # 1.2 for some extra space
-
+
+ # Calculate optimal dimensions considering row constraints
+ num_islands = len(island_data)
+ min_rows_needed = math.ceil(num_islands / self.max_islands_per_row)
+
+ # Calculate average island dimensions
+ avg_width = sum(data['width'] for data in island_data) / num_islands if num_islands > 0 else 0
+ avg_height = sum(data['height'] for data in island_data) / num_islands if num_islands > 0 else 0
+
+ # Estimate dimensions based on constraints
+ if self.max_islands_per_row < 10: # User wants specific column layout
+ # Width based on max islands per row
+ estimated_width = self.max_islands_per_row * (avg_width + self.padding)
+ # Height based on minimum rows needed
+ estimated_height = min_rows_needed * (avg_height + self.padding)
+ # Use the larger dimension to maintain reasonable aspect ratio
+ target_size = max(estimated_width, math.sqrt(total_area) * 1.1)
+ else:
+ # Default behavior: aim for square packing
+ target_size = max(math.sqrt(total_area) * 1.2, max_island_size + 2 * self.padding)
+
# Scale to fit in UV space (0-1)
if target_size > 1.0:
scale_factor = 0.95 / target_size # Leave some margin
@@ -936,85 +1157,121 @@ class MESH_OT_pack_uv_islands_by_submesh(Operator):
for data in island_data:
data['width'] *= scale_factor
data['height'] *= scale_factor
+ # Update bounds to scaled values
+ data['scaled_min_u'] = data['min_u'] * scale_factor
+ data['scaled_min_v'] = data['min_v'] * scale_factor
+ data['scaled_max_v'] = (data['bounds'][3] - data['bounds'][1]) * scale_factor + data['scaled_min_v']
target_size = 0.95
else:
scale_factor = 1.0
-
+ # Even without scaling, store the values for consistency
+ for data in island_data:
+ data['scaled_min_u'] = data['min_u']
+ data['scaled_min_v'] = data['min_v']
+ data['scaled_max_v'] = data['bounds'][3]
+
# Pack islands using a simple shelf packing algorithm
rows = []
current_row = []
current_row_height = 0
current_row_width = 0
-
+
for data in island_data:
width = data['width']
height = data['height']
-
- # Check if island fits in current row
- if current_row_width + width + self.padding <= target_size or not current_row:
+
+ # Check if island fits in current row (both width and count constraints)
+ fits_width = current_row_width + width + self.padding <= target_size or not current_row
+ under_max_count = len(current_row) < self.max_islands_per_row
+
+ if fits_width and under_max_count:
# Add to current row
current_row.append(data)
current_row_width += width + self.padding
current_row_height = max(current_row_height, height)
else:
- # Start new row
- rows.append((current_row, current_row_height))
+ # Start new row (only append if current row is not empty)
+ if current_row:
+ rows.append((current_row, current_row_height))
current_row = [data]
current_row_width = width + self.padding
current_row_height = height
-
+
# Add last row
if current_row:
rows.append((current_row, current_row_height))
-
+
# Calculate actual bounding box height
total_height = sum(row[1] for row in rows) + self.padding * (len(rows) + 1)
-
+
# Center the packed result in UV space
start_u = (1.0 - target_size) / 2.0
start_v = (1.0 - min(total_height, 1.0)) / 2.0 + min(total_height, 1.0)
-
+
# Place islands
current_v = start_v
-
- for row_islands, row_height in rows:
+
+ for row_idx, (row_islands, row_height) in enumerate(rows):
# Center row horizontally
row_actual_width = sum(data['width'] for data in row_islands) + self.padding * (len(row_islands) - 1)
current_u = start_u + (target_size - row_actual_width) / 2.0
-
+
+ # Find the actual top of this row (highest point of any island)
+ row_top = current_v
+
for data in row_islands:
- # Calculate offset, accounting for the scale factor
- offset_u = current_u - data['min_u'] * scale_factor
- offset_v = (current_v - row_height) - data['min_v'] * scale_factor
-
+ # Calculate offset to position island at current location
+ # We want the TOP of the island's bounding box at row_top
+ offset_u = current_u - data['scaled_min_u']
+ offset_v = row_top - data['scaled_max_v']
+
# Move all UVs in this island
for loop in data['island']['loops']:
uv = loop[bm_uv_layer].uv
uv.x = uv.x * scale_factor + offset_u
uv.y = uv.y * scale_factor + offset_v
-
+
current_u += data['width'] + self.padding
-
- current_v -= row_height + self.padding
-
+
+ # Move down by the full height of the row plus extra spacing
+ current_v = row_top - row_height - self.padding
+
# Update mesh
bmesh.update_edit_mesh(mesh)
-
- self.report({'INFO'}, f"Packed {len(island_data)} UV islands from {len(submeshes)} submeshes")
+
+ # Report results
+ if self.lock_overlapping and merged_count > 0:
+ self.report({'INFO'}, f"Packed {len(island_data)} UV islands ({merged_count} overlapping merged) from {len(submeshes)} submeshes")
+ else:
+ self.report({'INFO'}, f"Packed {len(island_data)} UV islands from {len(submeshes)} submeshes")
return {'FINISHED'}
-
+
def draw(self, context):
layout = self.layout
layout.prop(self, "padding")
+ layout.prop(self, "max_islands_per_row")
+ layout.prop(self, "lock_overlapping")
+ layout.prop(self, "skip_overlap_check")
+
+ if self.skip_overlap_check and self.lock_overlapping:
+ layout.label(text="Skip Overlap overrides Lock Overlapping", icon='INFO')
+
layout.label(text="Higher Z submeshes → Higher V position", icon='INFO')
+ # Performance hints
+ col = layout.column()
+ col.scale_y = 0.8
+ col.label(text="Performance tips:", icon='TIME')
+ col.label(text="• Use Skip Overlap for >500 islands")
+ col.label(text="• Set Max Islands/Row for control")
+
class MESH_OT_merge_by_distance_in_submeshes(Operator):
bl_idname = "mesh.merge_by_distance_in_submeshes"
bl_label = "Merge by Distance (Per Submesh)"
bl_description = "Merge vertices by distance within each submesh separately"
bl_options = {'REGISTER', 'UNDO'}
-
+
merge_distance: FloatProperty(
name="Merge Distance",
description="Maximum distance for merging vertices",
@@ -1024,167 +1281,167 @@ class MESH_OT_merge_by_distance_in_submeshes(Operator):
precision=6,
subtype='DISTANCE'
)
-
+
@classmethod
def poll(cls, context):
obj = context.active_object
return (obj is not None and
obj.type == 'MESH' and
context.mode == 'EDIT_MESH')
-
+
def get_selected_vertex_islands(self, mesh):
"""Find all contiguous groups of selected vertices - works like other operators"""
# Get selected vertices
selected_indices = {v.index for v in mesh.vertices if v.select}
-
+
if not selected_indices:
return []
-
+
# Build adjacency only for selected vertices
adjacency = {idx: set() for idx in selected_indices}
-
+
# Only check edges that might connect selected vertices
for edge in mesh.edges:
v0, v1 = edge.vertices
if v0 in selected_indices and v1 in selected_indices:
adjacency[v0].add(v1)
adjacency[v1].add(v0)
-
+
islands = []
visited = set()
-
+
from collections import deque
-
+
for start_idx in selected_indices:
if start_idx in visited:
continue
-
+
island = set()
queue = deque([start_idx])
-
+
while queue:
current = queue.popleft()
if current in visited:
continue
-
+
visited.add(current)
island.add(current)
-
+
for neighbor in adjacency[current]:
if neighbor not in visited:
queue.append(neighbor)
-
+
islands.append(island)
-
+
return islands
-
+
def execute(self, context):
obj = context.active_object
mesh = obj.data
-
+
# Use the most efficient approach: single merge with island constraints
bm = bmesh.from_edit_mesh(mesh)
-
+
# Get selected vertices
selected_verts = [v for v in bm.verts if v.select]
if not selected_verts:
self.report({'WARNING'}, "No vertices selected")
return {'CANCELLED'}
-
+
# Build islands using optimized algorithm
selected_set = set(selected_verts)
vert_to_island = {}
island_id = 0
-
+
# Find islands with stack-based traversal
for v in selected_verts:
if v in vert_to_island:
continue
-
+
# Mark all vertices in this island
stack = [v]
while stack:
current = stack.pop()
if current in vert_to_island:
continue
-
+
vert_to_island[current] = island_id
-
+
# Add connected vertices
for edge in current.link_edges:
other = edge.other_vert(current)
if other in selected_set and other not in vert_to_island:
stack.append(other)
-
+
island_id += 1
-
+
# Build merge mapping manually to avoid repeated operations
merge_targets = {}
total_merged = 0
islands_with_merges = 0
-
+
# For each island, find vertices to merge
from collections import defaultdict
island_verts = defaultdict(list)
for v, iid in vert_to_island.items():
island_verts[iid].append(v)
-
+
# Process each island
for island_id, verts in island_verts.items():
if len(verts) < 2:
continue
-
+
# Build spatial hash for this island only
merge_dist_sq = self.merge_distance * self.merge_distance
merged_in_island = 0
-
+
# Simple O(n²) for small islands is often faster than spatial hashing
# Most submeshes have 10-50 verts, so this is actually efficient
processed = set()
for i, v1 in enumerate(verts):
if v1 in merge_targets or v1 in processed:
continue
-
+
processed.add(v1)
-
+
# Find vertices within merge distance
for v2 in verts[i+1:]:
if v2 in merge_targets or v2 in processed:
continue
-
+
# Check distance
diff = v1.co - v2.co
if diff.length_squared <= merge_dist_sq:
merge_targets[v2] = v1
processed.add(v2)
merged_in_island += 1
-
+
if merged_in_island > 0:
total_merged += merged_in_island
islands_with_merges += 1
-
+
# Now perform all merges in one go using BMesh weld
if merge_targets:
# Convert merge mapping to format expected by weld_verts
targetmap = {v: merge_targets[v] for v in merge_targets if v.is_valid}
-
+
if targetmap:
bmesh.ops.weld_verts(bm, targetmap=targetmap)
-
+
# Update the mesh
bmesh.update_edit_mesh(mesh)
-
+
total_islands = len(island_verts)
multi_vert_islands = sum(1 for verts in island_verts.values() if len(verts) >= 2)
single_vert_islands = total_islands - multi_vert_islands
-
+
if total_merged > 0:
self.report({'INFO'}, f"Merged {total_merged} vertices in {islands_with_merges} of {multi_vert_islands} submeshes (skipped {single_vert_islands} single-vertex)")
else:
self.report({'INFO'}, f"No vertices close enough to merge in {multi_vert_islands} submeshes")
-
+
return {'FINISHED'}
-
+
def draw(self, context):
layout = self.layout
layout.prop(self, "merge_distance")
@@ -1203,7 +1460,7 @@ class MESH_PT_bake_vertex_panel(Panel):
obj = context.active_object
col = layout.column()
-
+
if obj and obj.type == 'MESH':
if context.mode == 'EDIT_MESH':
col.operator("mesh.select_all_linked_submeshes", icon='SELECT_EXTEND')
@@ -1213,7 +1470,7 @@ class MESH_PT_bake_vertex_panel(Panel):
col.operator("mesh.pack_uv_islands_by_submesh", icon='UV')
col.separator()
col.operator("mesh.bake_vertex_vectors", icon='EXPORT')
-
+
box = col.box()
box.label(text="Info:", icon='INFO')
box.label(text="Select All Linked: Expand selection to full submeshes")
@@ -1224,7 +1481,7 @@ class MESH_PT_bake_vertex_panel(Panel):
box.label(text="Bake: Auto-scale selected vertices")
box.label(text="Toggle Contiguous Groups for separate islands")
box.label(text="Scale factor stored in alpha channel")
-
+
mesh = obj.data
if mesh.vertex_colors and len(mesh.vertex_colors) > 0:
col.separator()
generated by cgit v1.2.3 (git 2.39.1) at 2026-06-01 16:58:45 +0000