# Copyright (c) 2018 Ultimaker B.V. # Cura is released under the terms of the LGPLv3 or higher. from typing import Optional import os.path import zipfile import numpy import Savitar from UM.Application import Application from UM.Logger import Logger from UM.Math.Matrix import Matrix from UM.Math.Vector import Vector from UM.Mesh.MeshBuilder import MeshBuilder from UM.Mesh.MeshReader import MeshReader from UM.Scene.GroupDecorator import GroupDecorator from UM.MimeTypeDatabase import MimeTypeDatabase, MimeType from cura.Settings.ExtruderManager import ExtruderManager from cura.Scene.CuraSceneNode import CuraSceneNode from cura.Scene.BuildPlateDecorator import BuildPlateDecorator from cura.Scene.SliceableObjectDecorator import SliceableObjectDecorator from cura.Scene.ZOffsetDecorator import ZOffsetDecorator from cura.Machines.QualityManager import getMachineDefinitionIDForQualitySearch MYPY = False try: if not MYPY: import xml.etree.cElementTree as ET except ImportError: Logger.log("w", "Unable to load cElementTree, switching to slower version") import xml.etree.ElementTree as ET ## Base implementation for reading 3MF files. Has no support for textures. Only loads meshes! class ThreeMFReader(MeshReader): def __init__(self) -> None: super().__init__() MimeTypeDatabase.addMimeType( MimeType( name = "application/vnd.ms-package.3dmanufacturing-3dmodel+xml", comment="3MF", suffixes=["3mf"] ) ) self._supported_extensions = [".3mf"] self._root = None self._base_name = "" self._unit = None self._object_count = 0 # Used to name objects as there is no node name yet. def _createMatrixFromTransformationString(self, transformation): if transformation == "": return Matrix() split_transformation = transformation.split() ## Transformation is saved as: ## M00 M01 M02 0.0 ## M10 M11 M12 0.0 ## M20 M21 M22 0.0 ## M30 M31 M32 1.0 ## We switch the row & cols as that is how everyone else uses matrices! temp_mat = Matrix() # Rotation & Scale temp_mat._data[0, 0] = split_transformation[0] temp_mat._data[1, 0] = split_transformation[1] temp_mat._data[2, 0] = split_transformation[2] temp_mat._data[0, 1] = split_transformation[3] temp_mat._data[1, 1] = split_transformation[4] temp_mat._data[2, 1] = split_transformation[5] temp_mat._data[0, 2] = split_transformation[6] temp_mat._data[1, 2] = split_transformation[7] temp_mat._data[2, 2] = split_transformation[8] # Translation temp_mat._data[0, 3] = split_transformation[9] temp_mat._data[1, 3] = split_transformation[10] temp_mat._data[2, 3] = split_transformation[11] return temp_mat ## Convenience function that converts a SceneNode object (as obtained from libSavitar) to a Uranium scene node. # \returns Uranium scene node. def _convertSavitarNodeToUMNode(self, savitar_node): self._object_count += 1 node_name = "Object %s" % self._object_count active_build_plate = Application.getInstance().getMultiBuildPlateModel().activeBuildPlate um_node = CuraSceneNode() # This adds a SettingOverrideDecorator um_node.addDecorator(BuildPlateDecorator(active_build_plate)) um_node.setName(node_name) transformation = self._createMatrixFromTransformationString(savitar_node.getTransformation()) um_node.setTransformation(transformation) mesh_builder = MeshBuilder() data = numpy.fromstring(savitar_node.getMeshData().getFlatVerticesAsBytes(), dtype=numpy.float32) vertices = numpy.resize(data, (int(data.size / 3), 3)) mesh_builder.setVertices(vertices) mesh_builder.calculateNormals(fast=True) mesh_data = mesh_builder.build() if len(mesh_data.getVertices()): um_node.setMeshData(mesh_data) for child in savitar_node.getChildren(): child_node = self._convertSavitarNodeToUMNode(child) if child_node: um_node.addChild(child_node) if um_node.getMeshData() is None and len(um_node.getChildren()) == 0: return None settings = savitar_node.getSettings() # Add the setting override decorator, so we can add settings to this node. if settings: global_container_stack = Application.getInstance().getGlobalContainerStack() # Ensure the correct next container for the SettingOverride decorator is set. if global_container_stack: default_stack = ExtruderManager.getInstance().getExtruderStack(0) if default_stack: um_node.callDecoration("setActiveExtruder", default_stack.getId()) # Get the definition & set it definition_id = getMachineDefinitionIDForQualitySearch(global_container_stack.definition) um_node.callDecoration("getStack").getTop().setDefinition(definition_id) setting_container = um_node.callDecoration("getStack").getTop() for key in settings: setting_value = settings[key] # Extruder_nr is a special case. if key == "extruder_nr": extruder_stack = ExtruderManager.getInstance().getExtruderStack(int(setting_value)) if extruder_stack: um_node.callDecoration("setActiveExtruder", extruder_stack.getId()) else: Logger.log("w", "Unable to find extruder in position %s", setting_value) continue setting_container.setProperty(key, "value", setting_value) if len(um_node.getChildren()) > 0 and um_node.getMeshData() is None: group_decorator = GroupDecorator() um_node.addDecorator(group_decorator) um_node.setSelectable(True) if um_node.getMeshData(): # Assuming that all nodes with mesh data are printable objects # affects (auto) slicing sliceable_decorator = SliceableObjectDecorator() um_node.addDecorator(sliceable_decorator) return um_node def _read(self, file_name): result = [] self._object_count = 0 # Used to name objects as there is no node name yet. # The base object of 3mf is a zipped archive. try: archive = zipfile.ZipFile(file_name, "r") self._base_name = os.path.basename(file_name) parser = Savitar.ThreeMFParser() scene_3mf = parser.parse(archive.open("3D/3dmodel.model").read()) self._unit = scene_3mf.getUnit() for node in scene_3mf.getSceneNodes(): um_node = self._convertSavitarNodeToUMNode(node) if um_node is None: continue # compensate for original center position, if object(s) is/are not around its zero position transform_matrix = Matrix() mesh_data = um_node.getMeshData() if mesh_data is not None: extents = mesh_data.getExtents() center_vector = Vector(extents.center.x, extents.center.y, extents.center.z) transform_matrix.setByTranslation(center_vector) transform_matrix.multiply(um_node.getLocalTransformation()) um_node.setTransformation(transform_matrix) global_container_stack = Application.getInstance().getGlobalContainerStack() # Create a transformation Matrix to convert from 3mf worldspace into ours. # First step: flip the y and z axis. transformation_matrix = Matrix() transformation_matrix._data[1, 1] = 0 transformation_matrix._data[1, 2] = 1 transformation_matrix._data[2, 1] = -1 transformation_matrix._data[2, 2] = 0 # Second step: 3MF defines the left corner of the machine as center, whereas cura uses the center of the # build volume. if global_container_stack: translation_vector = Vector(x = -global_container_stack.getProperty("machine_width", "value") / 2, y = -global_container_stack.getProperty("machine_depth", "value") / 2, z = 0) translation_matrix = Matrix() translation_matrix.setByTranslation(translation_vector) transformation_matrix.multiply(translation_matrix) # Third step: 3MF also defines a unit, whereas Cura always assumes mm. scale_matrix = Matrix() scale_matrix.setByScaleVector(self._getScaleFromUnit(self._unit)) transformation_matrix.multiply(scale_matrix) # Pre multiply the transformation with the loaded transformation, so the data is handled correctly. um_node.setTransformation(um_node.getLocalTransformation().preMultiply(transformation_matrix)) # Check if the model is positioned below the build plate and honor that when loading project files. if um_node.getMeshData() is not None: minimum_z_value = um_node.getMeshData().getExtents(um_node.getWorldTransformation()).minimum.y # y is z in transformation coordinates if minimum_z_value < 0: um_node.addDecorator(ZOffsetDecorator()) um_node.callDecoration("setZOffset", minimum_z_value) result.append(um_node) except Exception: Logger.logException("e", "An exception occurred in 3mf reader.") return None return result ## Create a scale vector based on a unit string. # The core spec defines the following: # * micron # * millimeter (default) # * centimeter # * inch # * foot # * meter def _getScaleFromUnit(self, unit: Optional[str]) -> Vector: conversion_to_mm = { "micron": 0.001, "millimeter": 1, "centimeter": 10, "meter": 1000, "inch": 25.4, "foot": 304.8 } if unit is None: unit = "millimeter" elif unit not in conversion_to_mm: Logger.log("w", "Unrecognised unit {unit} used. Assuming mm instead.".format(unit = unit)) unit = "millimeter" scale = conversion_to_mm[unit] return Vector(scale, scale, scale)