# SPDX-FileCopyrightText: 2011-2023 Blender Authors # # SPDX-License-Identifier: GPL-2.0-or-later __all__ = ( "mesh_linked_uv_islands", "mesh_linked_triangles", "edge_face_count_dict", "edge_face_count", "edge_loops_from_edges", "ngon_tessellate", "triangle_random_points", ) def mesh_linked_uv_islands(mesh): """ Returns lists of polygon indices connected by UV islands. :param mesh: the mesh used to group with. :type mesh: :class:`bpy.types.Mesh` :return: list of lists containing polygon indices :rtype: list[list[int]] """ if mesh.polygons and not mesh.uv_layers.active.data: # Currently, when in edit mode, UV Layer data will always be empty # when accessed though RNA. This may change in the future. raise ValueError( "UV Layers are not currently available from python in Edit Mode. " "Use bmesh and bpy_extras.bmesh_utils.bmesh_linked_uv_islands instead." ) uv_loops = [luv.uv[:] for luv in mesh.uv_layers.active.data] poly_loops = [poly.loop_indices for poly in mesh.polygons] luv_hash = {} luv_hash_get = luv_hash.get luv_hash_ls = [None] * len(uv_loops) for pi, poly_indices in enumerate(poly_loops): for li in poly_indices: uv = uv_loops[li] uv_hub = luv_hash_get(uv) if uv_hub is None: uv_hub = luv_hash[uv] = [pi] else: uv_hub.append(pi) luv_hash_ls[li] = uv_hub poly_islands = [] # 0 = none, 1 = added, 2 = searched poly_tag = [0] * len(poly_loops) while True: poly_index = -1 for i in range(len(poly_loops)): if poly_tag[i] == 0: poly_index = i break if poly_index != -1: island = [poly_index] poly_tag[poly_index] = 1 poly_islands.append(island) else: break # we're done added = True while added: added = False for poly_index in island[:]: if poly_tag[poly_index] == 1: for li in poly_loops[poly_index]: for poly_index_shared in luv_hash_ls[li]: if poly_tag[poly_index_shared] == 0: added = True poly_tag[poly_index_shared] = 1 island.append(poly_index_shared) poly_tag[poly_index] = 2 return poly_islands def mesh_linked_triangles(mesh): """ Splits the mesh into connected triangles, use this for separating cubes from other mesh elements within 1 mesh data-block. :param mesh: the mesh used to group with. :type mesh: :class:`bpy.types.Mesh` :return: Lists of lists containing triangles. :rtype: list[list[:class:`bpy.types.MeshLoopTriangle`]] """ # Build vert face connectivity vert_tris = [[] for i in range(len(mesh.vertices))] for t in mesh.loop_triangles: for v in t.vertices: vert_tris[v].append(t) # sort triangles into connectivity groups tri_groups = [[t] for t in mesh.loop_triangles] # map old, new tri location tri_mapping = list(range(len(mesh.loop_triangles))) # Now clump triangles iteratively ok = True while ok: ok = False for t in mesh.loop_triangles: mapped_index = tri_mapping[t.index] mapped_group = tri_groups[mapped_index] for v in t.vertices: for nxt_t in vert_tris[v]: if nxt_t != t: nxt_mapped_index = tri_mapping[nxt_t.index] # We are not a part of the same group if mapped_index != nxt_mapped_index: ok = True # Assign mapping to this group so they # all map to this group for grp_t in tri_groups[nxt_mapped_index]: tri_mapping[grp_t.index] = mapped_index # Move triangles into this group mapped_group.extend(tri_groups[nxt_mapped_index]) # remove reference to the list tri_groups[nxt_mapped_index] = None # return all tri groups that are not null # this is all the triangles that are connected in their own lists. return [tg for tg in tri_groups if tg] def edge_face_count_dict(mesh): """ :param mesh: The mesh to count edges for. :type mesh: :class:`bpy.types.Mesh` :return: Dictionary of edge keys with their value set to the number of faces using each edge. :rtype: dict[tuple[int, int], int] """ face_edge_count = {} loops = mesh.loops edges = mesh.edges for poly in mesh.polygons: for i in poly.loop_indices: key = edges[loops[i].edge_index].key try: face_edge_count[key] += 1 except KeyError: face_edge_count[key] = 1 return face_edge_count def edge_face_count(mesh): """ :param mesh: The mesh to count edges for. :type mesh: :class:`bpy.types.Mesh` :return: list of face users for each item in mesh.edges. :rtype: list[int] """ edge_face_count = edge_face_count_dict(mesh) get = dict.get return [get(edge_face_count, ed.key, 0) for ed in mesh.edges] def edge_loops_from_edges(mesh, edges=None): """ Edge loops defined by edges. Takes mesh.edges or a list of edges and returns the edge loops as a list of vertex indices. Closed loops have matching start and end values. :param mesh: The mesh to extract edge loops from. :type mesh: :class:`bpy.types.Mesh` :param edges: Edges to use, or None to use all edges in the mesh. :type edges: list[:class:`bpy.types.MeshEdge`] | None :return: A list of edge loops, each a list of vertex indices. :rtype: list[list[int]] """ line_polys = [] # Get edges not used by a face if edges is None: edges = mesh.edges if not hasattr(edges, "pop"): edges = edges[:] while edges: current_edge = edges.pop() vert_end, vert_start = current_edge.vertices[:] line_poly = [vert_start, vert_end] ok = True while ok: ok = False # for i, ed in enumerate(edges): i = len(edges) while i: i -= 1 ed = edges[i] v1, v2 = ed.vertices if v1 == vert_end: line_poly.append(v2) vert_end = line_poly[-1] ok = 1 del edges[i] # break elif v2 == vert_end: line_poly.append(v1) vert_end = line_poly[-1] ok = 1 del edges[i] # break elif v1 == vert_start: line_poly.insert(0, v2) vert_start = line_poly[0] ok = 1 del edges[i] # break elif v2 == vert_start: line_poly.insert(0, v1) vert_start = line_poly[0] ok = 1 del edges[i] # break line_polys.append(line_poly) return line_polys def ngon_tessellate(from_data, indices, fix_loops=True, debug_print=True): """ Takes a poly-line of indices (ngon) and returns a list of face index lists. Designed to be used for importers that need indices for an ngon to create from existing verts. :param from_data: Either a mesh, or a list/tuple of 3D vectors. :type from_data: :class:`bpy.types.Mesh` | list[Sequence[float]] | tuple[Sequence[float]] :param indices: a list of indices to use. This list is the ordered closed poly-line to fill, and can be a subset of the data given. :type indices: list[int] :param fix_loops: If this is enabled poly-lines that use loops to make multiple poly-lines are dealt with correctly. :type fix_loops: bool :param debug_print: Print debug information to the console. :type debug_print: bool :return: Tessellated faces as a list of triangle index tuples. :rtype: list[tuple[int, int, int]] """ from mathutils.geometry import tessellate_polygon from mathutils import Vector vector_to_tuple = Vector.to_tuple if not indices: return [] def mlen(co): # Manhatten length of a vector, faster then length. return abs(co[0]) + abs(co[1]) + abs(co[2]) def vert_from_vector_with_extra_data(v, i): # Calculate data per-vector, for reuse. return v, vector_to_tuple(v, 6), i, mlen(v) def ed_key_mlen(v1, v2): if v1[3] > v2[3]: return v2[1], v1[1] else: return v1[1], v2[1] if not fix_loops: # Normal single concave loop filling. if type(from_data) in {tuple, list}: verts = [Vector(from_data[i]) for ii, i in enumerate(indices)] else: verts = [from_data.vertices[i].co for ii, i in enumerate(indices)] # same as reversed(range(1, len(verts))): for i in range(len(verts) - 1, 0, -1): if verts[i][1] == verts[i - 1][0]: verts.pop(i - 1) fill = tessellate_polygon([verts]) else: # Separate this loop into multiple loops be finding edges that are # used twice. This is used by Light-Wave LWO files a lot. if type(from_data) in {tuple, list}: verts = [ vert_from_vector_with_extra_data(Vector(from_data[i]), ii) for ii, i in enumerate(indices) ] else: verts = [ vert_from_vector_with_extra_data(from_data.vertices[i].co, ii) for ii, i in enumerate(indices) ] edges = [(i, i - 1) for i in range(len(verts))] if edges: edges[0] = (0, len(verts) - 1) if not verts: return [] edges_used = set() edges_doubles = set() # We need to check if any edges are used twice location based. for ed in edges: edkey = ed_key_mlen(verts[ed[0]], verts[ed[1]]) if edkey in edges_used: edges_doubles.add(edkey) else: edges_used.add(edkey) # Store a list of unconnected loop segments split by double edges. # will join later loop_segments = [] v_prev = verts[0] context_loop = [v_prev] loop_segments = [context_loop] for v in verts: if v != v_prev: # Are we crossing an edge we removed? if ed_key_mlen(v, v_prev) in edges_doubles: context_loop = [v] loop_segments.append(context_loop) else: if context_loop and context_loop[-1][1] == v[1]: pass else: context_loop.append(v) v_prev = v # Now join loop segments def join_seg(s1, s2): if s2[-1][1] == s1[0][1]: s1, s2 = s2, s1 elif s1[-1][1] == s2[0][1]: pass else: return False # If were still here s1 and s2 are 2 segments in the same poly-line. s1.pop() # remove the last vert from s1 s1.extend(s2) # add segment 2 to segment 1 if s1[0][1] == s1[-1][1]: # remove endpoints double s1.pop() del s2[:] # Empty this segment s2 so we don't use it again. return True joining_segments = True while joining_segments: joining_segments = False segcount = len(loop_segments) for j in range(segcount - 1, -1, -1): # reversed(range(segcount)): seg_j = loop_segments[j] if seg_j: for k in range(j - 1, -1, -1): # reversed(range(j)): if not seg_j: break seg_k = loop_segments[k] if seg_k and join_seg(seg_j, seg_k): joining_segments = True loop_list = loop_segments for verts in loop_list: while verts and verts[0][1] == verts[-1][1]: verts.pop() loop_list = [verts for verts in loop_list if len(verts) > 2] # DONE DEALING WITH LOOP FIXING # vert mapping vert_map = [None] * len(indices) ii = 0 for verts in loop_list: if len(verts) > 2: for i, vert in enumerate(verts): vert_map[i + ii] = vert[2] ii += len(verts) fill = tessellate_polygon([[v[0] for v in loop] for loop in loop_list]) # draw_loops(loop_list) # raise Exception("done loop") # map to original indices fill = [[vert_map[i] for i in f] for f in fill] if not fill: if debug_print: print('Warning Cannot scan-fill, fallback on a triangle fan.') fill = [[0, i - 1, i] for i in range(2, len(indices))] else: # Use real scan-fill. # See if its flipped the wrong way. flip = None for fi in fill: if flip is not None: break for i, vi in enumerate(fi): if vi == 0 and fi[i - 1] == 1: flip = False break elif vi == 1 and fi[i - 1] == 0: flip = True break if not flip: for i, fi in enumerate(fill): fill[i] = tuple(reversed(fi)) return fill def triangle_random_points(num_points, loop_triangles): """ Generates a list of random points over mesh loop triangles. :param num_points: The number of random points to generate on each triangle. :type num_points: int :param loop_triangles: Sequence of the triangles to generate points on. :type loop_triangles: Sequence[:class:`bpy.types.MeshLoopTriangle`] :return: List of random points over all triangles. :rtype: list[:class:`mathutils.Vector`] """ from random import random # For each triangle, generate the required number of random points sampled_points = [None] * (num_points * len(loop_triangles)) for i, lt in enumerate(loop_triangles): # Get triangle vertex coordinates verts = lt.id_data.vertices ltv = lt.vertices[:] tv = (verts[ltv[0]].co, verts[ltv[1]].co, verts[ltv[2]].co) for k in range(num_points): u1 = random() u2 = random() u_tot = u1 + u2 if u_tot > 1: u1 = 1.0 - u1 u2 = 1.0 - u2 side1 = tv[1] - tv[0] side2 = tv[2] - tv[0] p = tv[0] + u1 * side1 + u2 * side2 sampled_points[num_points * i + k] = p return sampled_points