kopia lustrzana https://github.com/inkstitch/inkstitch
210 wiersze
8.5 KiB
Python
210 wiersze
8.5 KiB
Python
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# Authors: see git history
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#
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# Copyright (c) 2024 Authors
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# Licensed under the GNU GPL version 3.0 or later. See the file LICENSE for details.
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import networkx as nx
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from inkex import Group, Path, PathElement, errormsg
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from shapely import unary_union, length
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from shapely.geometry import LineString, MultiLineString, Point
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from shapely.ops import linemerge, nearest_points, substring
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from ..elements import Stroke
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from ..i18n import _
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from ..svg import PIXELS_PER_MM, get_correction_transform
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from ..svg.tags import INKSTITCH_ATTRIBS
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from ..utils.geometry import ensure_multi_line_string
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from .base import InkstitchExtension
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class Redwork(InkstitchExtension):
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"""Takes a bunch of stroke elements and traverses them so,
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that every stroke has exactly two passes
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"""
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def __init__(self, *args, **kwargs):
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InkstitchExtension.__init__(self, *args, **kwargs)
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self.arg_parser.add_argument("--notebook")
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self.arg_parser.add_argument("-m", "--merge_distance", dest="merge_distance", type=float, default=0.5)
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self.arg_parser.add_argument("-p", "--minimum_path_length", dest="minimum_path_length", type=float, default=0.5)
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self.arg_parser.add_argument("-s", "--redwork_running_stitch_length_mm", dest="redwork_running_stitch_length_mm", type=float, default=2.5)
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self.arg_parser.add_argument("-b", "--redwork_bean_stitch_repeats", dest="redwork_bean_stitch_repeats", type=str, default='0')
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self.elements = None
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self.graph = None
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self.connected_components = None
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self.eulerian_circuits = None
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self.merge_distance = None
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self.minimum_path_length = None
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self.redwork_running_stitch_length_mm = None
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self.redwork_bean_stitch_repeats = None
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def effect(self):
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if not self.get_elements():
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return
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elements = [element for element in self.elements if isinstance(element, Stroke)]
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if not elements:
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errormsg(_("Please select one or more strokes."))
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return
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self.merge_distance = self.options.merge_distance * PIXELS_PER_MM
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self.minimum_path_length = self.options.minimum_path_length * PIXELS_PER_MM
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starting_point = self._get_starting_point('run_start')
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# as the resulting path starts and ends at same place we can also use ending point
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if not starting_point:
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starting_point = self._get_starting_point('run_end')
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multi_line_string = self._elements_to_multi_line_string(elements)
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if starting_point:
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multi_line_string = self._ensure_starting_point(multi_line_string, starting_point)
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self._build_graph(multi_line_string)
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self._generate_strongly_connected_components()
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self._generate_eulerian_circuits()
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self._eulerian_circuits_to_elements(elements)
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def _ensure_starting_point(self, multi_line_string, starting_point):
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# returns a MultiLineString whose first LineString starts close to starting_point
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starting_point = Point(*starting_point)
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new_lines = []
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start_applied = False
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for line in multi_line_string.geoms:
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if line.distance(starting_point) < 2 and not start_applied:
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project = line.project(starting_point, True)
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new_lines.append(substring(line, 0, project, True))
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new_lines = [substring(line, project, 1, True)] + new_lines
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start_applied = True
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else:
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new_lines.append(line)
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return MultiLineString(new_lines)
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def _get_starting_point(self, command_type):
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command = None
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for stroke in self.elements:
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command = stroke.get_command(command_type)
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if command:
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# remove command symbol
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command_group = command.connector.getparent()
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command_group.getparent().remove(command_group)
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# return the first occurence directly
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return command.target_point
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def _eulerian_circuits_to_elements(self, elements):
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node = elements[0].node
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index = node.getparent().index(node)
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style = node.style
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transform = get_correction_transform(node)
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nb_circuits = len(self.eulerian_circuit)
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# create redwork group
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redwork_group = Group()
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redwork_group.label = _("Redwork Group")
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node.getparent().insert(index, redwork_group)
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# insert lines grouped by underpath and top layer
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visited_lines = []
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i = 1
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for circuit in self.eulerian_circuit:
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connected_group = Group()
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connected_group.label = _("Connected Group")
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for edge in circuit:
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linestring = self.graph.get_edge_data(edge[0], edge[1], edge[2])['path']
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if length(linestring) > self.minimum_path_length:
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current_line = linestring
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if current_line in visited_lines:
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path_id = self.svg.get_unique_id('redwork_')
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label = _("Redwork") + f' {i}'
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redwork = True
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else:
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path_id = self.svg.get_unique_id('underpath_')
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label = _("Redwork Underpath") + f' {i}'
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visited_lines.append(current_line.reverse())
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redwork = False
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path = str(Path(list(current_line.coords)))
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if nb_circuits > 1:
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redwork_group.insert(i, connected_group)
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self._insert_element(path, connected_group, style, transform, label, path_id, redwork)
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else:
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self._insert_element(path, redwork_group, style, transform, label, path_id, redwork)
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i += 1
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# remove input elements
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for element in elements:
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element.node.getparent().remove(element.node)
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def _insert_element(self, path, group, style, transform, label, path_id, redwork=True):
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element = PathElement(
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id=path_id,
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style=str(style),
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transform=transform,
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d=path
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)
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element.label = label
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element.set(INKSTITCH_ATTRIBS['running_stitch_length_mm'], self.options.redwork_running_stitch_length_mm)
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if redwork:
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element.set(INKSTITCH_ATTRIBS['bean_stitch_repeats'], self.options.redwork_bean_stitch_repeats)
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group.add(element)
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def _build_graph(self, multi_line_string):
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self.graph = nx.MultiDiGraph()
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for geom in multi_line_string.geoms:
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start = geom.coords[0]
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end = geom.coords[-1]
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self.graph.add_edge(str(start), str(end), path=geom)
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geom = geom.reverse()
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self.graph.add_edge(str(end), str(start), path=geom)
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def _generate_strongly_connected_components(self):
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self.connected_components = list(nx.strongly_connected_components(self.graph))
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for i, cc in enumerate(self.connected_components):
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if list(self.graph.nodes)[0] in cc:
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break
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ordered_connected_components = [self.connected_components[i]] + self.connected_components[:i] + self.connected_components[i+1:]
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self.connected_components = ordered_connected_components
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def _generate_eulerian_circuits(self):
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G = self.graph.subgraph(self.connected_components[0]).copy()
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self.eulerian_circuit = [nx.eulerian_circuit(G, list(self.graph.nodes)[0], keys=True)]
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for c in self.connected_components[1:]:
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G = self.graph.subgraph(c).copy()
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self.eulerian_circuit.append(nx.eulerian_circuit(G, keys=True))
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def _elements_to_multi_line_string(self, elements):
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lines = []
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for element in elements:
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for geom in element.as_multi_line_string().geoms:
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lines.append(geom)
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multi_line_string = self._add_connectors(lines)
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multi_line_string = ensure_multi_line_string(unary_union(linemerge(multi_line_string), grid_size=0.001))
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return multi_line_string
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def _add_connectors(self, lines):
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connectors = []
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for i, line1 in enumerate(lines):
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for j in range(i + 1, len(lines)):
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line2 = lines[j]
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try:
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distance = line1.distance(line2)
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except FloatingPointError:
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continue
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if 0 < distance < self.merge_distance:
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# add nearest points
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near = nearest_points(line1, line2)
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connectors.append(LineString([near[0], near[1]]))
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return MultiLineString(lines + connectors)
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