LayerPolygon.py 12 KB

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  1. # Copyright (c) 2019 Ultimaker B.V.
  2. # Cura is released under the terms of the LGPLv3 or higher.
  3. import numpy
  4. from typing import Optional, cast
  5. from UM.Qt.Bindings.Theme import Theme
  6. from UM.Qt.QtApplication import QtApplication
  7. from UM.Logger import Logger
  8. class LayerPolygon:
  9. NoneType = 0
  10. Inset0Type = 1
  11. InsetXType = 2
  12. SkinType = 3
  13. SupportType = 4
  14. SkirtType = 5
  15. InfillType = 6
  16. SupportInfillType = 7
  17. MoveCombingType = 8
  18. MoveRetractionType = 9
  19. SupportInterfaceType = 10
  20. PrimeTowerType = 11
  21. __number_of_types = 12
  22. __jump_map = numpy.logical_or(numpy.logical_or(numpy.arange(__number_of_types) == NoneType,
  23. numpy.arange(__number_of_types) == MoveCombingType),
  24. numpy.arange(__number_of_types) == MoveRetractionType)
  25. def __init__(self, extruder: int, line_types: numpy.ndarray, data: numpy.ndarray,
  26. line_widths: numpy.ndarray, line_thicknesses: numpy.ndarray, line_feedrates: numpy.ndarray) -> None:
  27. """LayerPolygon, used in ProcessSlicedLayersJob
  28. :param extruder: The position of the extruder
  29. :param line_types: array with line_types
  30. :param data: new_points
  31. :param line_widths: array with line widths
  32. :param line_thicknesses: array with type as index and thickness as value
  33. :param line_feedrates: array with line feedrates
  34. """
  35. self._extruder = extruder
  36. self._types = line_types
  37. unknown_types = numpy.where(self._types >= self.__number_of_types, self._types, None)
  38. if unknown_types.any():
  39. # Got faulty line data from the engine.
  40. for idx in unknown_types:
  41. Logger.warning(f"Found an unknown line type at: {idx}")
  42. self._types[idx] = self.NoneType
  43. self._data = data
  44. self._line_widths = line_widths
  45. self._line_thicknesses = line_thicknesses
  46. self._line_feedrates = line_feedrates
  47. self._vertex_begin = 0
  48. self._vertex_end = 0
  49. self._index_begin = 0
  50. self._index_end = 0
  51. self._jump_mask = self.__jump_map[self._types]
  52. self._jump_count = numpy.sum(self._jump_mask)
  53. self._mesh_line_count = len(self._types) - self._jump_count
  54. self._vertex_count = self._mesh_line_count + numpy.sum(self._types[1:] == self._types[:-1])
  55. # Buffering the colors shouldn't be necessary as it is not
  56. # re-used and can save a lot of memory usage.
  57. self._color_map = LayerPolygon.getColorMap()
  58. self._colors: numpy.ndarray = self._color_map[self._types]
  59. # When type is used as index returns true if type == LayerPolygon.InfillType
  60. # or type == LayerPolygon.SkinType
  61. # or type == LayerPolygon.SupportInfillType
  62. # Should be generated in better way, not hardcoded.
  63. self._is_infill_or_skin_type_map = numpy.array([0, 0, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0], dtype=bool)
  64. self._build_cache_line_mesh_mask: Optional[numpy.ndarray] = None
  65. self._build_cache_needed_points: Optional[numpy.ndarray] = None
  66. def buildCache(self) -> None:
  67. # For the line mesh we do not draw Infill or Jumps. Therefore those lines are filtered out.
  68. self._build_cache_line_mesh_mask = numpy.ones(self._jump_mask.shape, dtype = bool)
  69. self._index_begin = 0
  70. self._index_end = cast(int, numpy.sum(self._build_cache_line_mesh_mask))
  71. self._build_cache_needed_points = numpy.ones((len(self._types), 2), dtype = bool)
  72. # Only if the type of line segment changes do we need to add an extra vertex to change colors
  73. self._build_cache_needed_points[1:, 0][:, numpy.newaxis] = self._types[1:] != self._types[:-1]
  74. # Mark points as unneeded if they are of types we don't want in the line mesh according to the calculated mask
  75. numpy.logical_and(self._build_cache_needed_points, self._build_cache_line_mesh_mask, self._build_cache_needed_points)
  76. self._vertex_begin = 0
  77. self._vertex_end = cast(int, numpy.sum(self._build_cache_needed_points))
  78. def build(self, vertex_offset: int, index_offset: int, vertices: numpy.ndarray,
  79. colors: numpy.ndarray, line_dimensions: numpy.ndarray, feedrates: numpy.ndarray,
  80. extruders: numpy.ndarray, line_types: numpy.ndarray, indices: numpy.ndarray) -> None:
  81. """Set all the arrays provided by the function caller, representing the LayerPolygon
  82. The arrays are either by vertex or by indices.
  83. :param vertex_offset: determines where to start and end filling the arrays
  84. :param index_offset: determines where to start and end filling the arrays
  85. :param vertices: vertex numpy array to be filled
  86. :param colors: vertex numpy array to be filled
  87. :param line_dimensions: vertex numpy array to be filled
  88. :param feedrates: vertex numpy array to be filled
  89. :param extruders: vertex numpy array to be filled
  90. :param line_types: vertex numpy array to be filled
  91. :param indices: index numpy array to be filled
  92. """
  93. if self._build_cache_line_mesh_mask is None or self._build_cache_needed_points is None:
  94. self.buildCache()
  95. if self._build_cache_line_mesh_mask is None or self._build_cache_needed_points is None:
  96. Logger.log("w", "Failed to build cache for layer polygon")
  97. return
  98. line_mesh_mask = self._build_cache_line_mesh_mask
  99. needed_points_list = self._build_cache_needed_points
  100. # Index to the points we need to represent the line mesh.
  101. # This is constructed by generating simple start and end points for each line.
  102. # For line segment n, these are points n and n+1. Row n reads [n n+1]
  103. # Then the indices for the points we don't need are thrown away based on the pre-calculated list.
  104. index_list = (numpy.arange(len(self._types)).reshape((-1, 1)) + numpy.array([[0, 1]])).reshape((-1, 1))[needed_points_list.reshape((-1, 1))]
  105. # The relative values of begin and end indices have already been set in buildCache, so we only need to offset them to the parents offset.
  106. self._vertex_begin += vertex_offset
  107. self._vertex_end += vertex_offset
  108. # Points are picked based on the index list to get the vertices needed.
  109. vertices[self._vertex_begin:self._vertex_end, :] = self._data[index_list, :]
  110. # Create an array with colors for each vertex and remove the color data for the points that has been thrown away.
  111. colors[self._vertex_begin:self._vertex_end, :] = numpy.tile(self._colors, (1, 2)).reshape((-1, 4))[needed_points_list.ravel()]
  112. # Create an array with line widths and thicknesses for each vertex.
  113. line_dimensions[self._vertex_begin:self._vertex_end, 0] = numpy.tile(self._line_widths, (1, 2)).reshape((-1, 1))[needed_points_list.ravel()][:, 0]
  114. line_dimensions[self._vertex_begin:self._vertex_end, 1] = numpy.tile(self._line_thicknesses, (1, 2)).reshape((-1, 1))[needed_points_list.ravel()][:, 0]
  115. # Create an array with feedrates for each line
  116. feedrates[self._vertex_begin:self._vertex_end] = numpy.tile(self._line_feedrates, (1, 2)).reshape((-1, 1))[needed_points_list.ravel()][:, 0]
  117. extruders[self._vertex_begin:self._vertex_end] = self._extruder
  118. # Convert type per vertex to type per line
  119. line_types[self._vertex_begin:self._vertex_end] = numpy.tile(self._types, (1, 2)).reshape((-1, 1))[needed_points_list.ravel()][:, 0]
  120. # The relative values of begin and end indices have already been set in buildCache,
  121. # so we only need to offset them to the parents offset.
  122. self._index_begin += index_offset
  123. self._index_end += index_offset
  124. indices[self._index_begin:self._index_end, :] = numpy.arange(self._index_end-self._index_begin, dtype=numpy.int32).reshape((-1, 1))
  125. # When the line type changes the index needs to be increased by 2.
  126. indices[self._index_begin:self._index_end, :] += numpy.cumsum(needed_points_list[line_mesh_mask.ravel(), 0], dtype = numpy.int32).reshape((-1, 1))
  127. # Each line segment goes from it's starting point p to p+1, offset by the vertex index.
  128. # The -1 is to compensate for the necessarily True value of needed_points_list[0,0] which causes an unwanted +1 in cumsum above.
  129. indices[self._index_begin:self._index_end, :] += numpy.array([self._vertex_begin - 1, self._vertex_begin])
  130. self._build_cache_line_mesh_mask = None
  131. self._build_cache_needed_points = None
  132. def getColors(self):
  133. return self._colors
  134. def mapLineTypeToColor(self, line_types: numpy.ndarray) -> numpy.ndarray:
  135. return self._color_map[line_types]
  136. def isInfillOrSkinType(self, line_types: numpy.ndarray) -> numpy.ndarray:
  137. return self._is_infill_or_skin_type_map[line_types]
  138. def lineMeshVertexCount(self) -> int:
  139. return self._vertex_end - self._vertex_begin
  140. def lineMeshElementCount(self) -> int:
  141. return self._index_end - self._index_begin
  142. @property
  143. def extruder(self):
  144. return self._extruder
  145. @property
  146. def types(self):
  147. return self._types
  148. @property
  149. def lineLengths(self):
  150. data_array = numpy.array(self._data)
  151. return numpy.linalg.norm(data_array[1:] - data_array[:-1], axis=1)
  152. @property
  153. def data(self):
  154. return self._data
  155. @property
  156. def elementCount(self):
  157. return (self._index_end - self._index_begin) * 2 # The range of vertices multiplied by 2 since each vertex is used twice
  158. @property
  159. def lineWidths(self):
  160. return self._line_widths
  161. @property
  162. def lineThicknesses(self):
  163. return self._line_thicknesses
  164. @property
  165. def lineFeedrates(self):
  166. return self._line_feedrates
  167. @property
  168. def jumpMask(self):
  169. return self._jump_mask
  170. @property
  171. def meshLineCount(self):
  172. return self._mesh_line_count
  173. @property
  174. def jumpCount(self):
  175. return self._jump_count
  176. def getNormals(self) -> numpy.ndarray:
  177. """Calculate normals for the entire polygon using numpy.
  178. :return: normals for the entire polygon
  179. """
  180. normals = numpy.copy(self._data)
  181. normals[:, 1] = 0.0 # We are only interested in 2D normals
  182. # Calculate the edges between points.
  183. # The call to numpy.roll shifts the entire array by one
  184. # so that we end up subtracting each next point from the current, wrapping around.
  185. # This gives us the edges from the next point to the current point.
  186. normals = numpy.diff(normals, 1, 0)
  187. # Calculate the length of each edge using standard Pythagoras
  188. lengths = numpy.sqrt(normals[:, 0] ** 2 + normals[:, 2] ** 2)
  189. # The normal of a 2D vector is equal to its x and y coordinates swapped
  190. # and then x inverted. This code does that.
  191. normals[:, [0, 2]] = normals[:, [2, 0]]
  192. normals[:, 0] *= -1
  193. # Normalize the normals.
  194. normals[:, 0] /= lengths
  195. normals[:, 2] /= lengths
  196. return normals
  197. __color_map = None # type: numpy.ndarray
  198. @classmethod
  199. def getColorMap(cls) -> numpy.ndarray:
  200. """Gets the instance of the VersionUpgradeManager, or creates one."""
  201. if cls.__color_map is None:
  202. theme = cast(Theme, QtApplication.getInstance().getTheme())
  203. cls.__color_map = numpy.array([
  204. theme.getColor("layerview_none").getRgbF(), # NoneType
  205. theme.getColor("layerview_inset_0").getRgbF(), # Inset0Type
  206. theme.getColor("layerview_inset_x").getRgbF(), # InsetXType
  207. theme.getColor("layerview_skin").getRgbF(), # SkinType
  208. theme.getColor("layerview_support").getRgbF(), # SupportType
  209. theme.getColor("layerview_skirt").getRgbF(), # SkirtType
  210. theme.getColor("layerview_infill").getRgbF(), # InfillType
  211. theme.getColor("layerview_support_infill").getRgbF(), # SupportInfillType
  212. theme.getColor("layerview_move_combing").getRgbF(), # MoveCombingType
  213. theme.getColor("layerview_move_retraction").getRgbF(), # MoveRetractionType
  214. theme.getColor("layerview_support_interface").getRgbF(), # SupportInterfaceType
  215. theme.getColor("layerview_prime_tower").getRgbF() # PrimeTowerType
  216. ])
  217. return cls.__color_map