# Copyright (c) 2020 Ultimaker B.V. # Cura is released under the terms of the LGPLv3 or higher. import numpy import math from PyQt5.QtGui import QImage, qRed, qGreen, qBlue, qAlpha from PyQt5.QtCore import Qt from UM.Mesh.MeshReader import MeshReader from UM.Mesh.MeshBuilder import MeshBuilder from UM.Math.Vector import Vector from UM.Job import Job from UM.Logger import Logger from .ImageReaderUI import ImageReaderUI from cura.Scene.CuraSceneNode import CuraSceneNode as SceneNode class ImageReader(MeshReader): def __init__(self) -> None: super().__init__() self._supported_extensions = [".jpg", ".jpeg", ".bmp", ".gif", ".png"] self._ui = ImageReaderUI(self) def preRead(self, file_name, *args, **kwargs): img = QImage(file_name) if img.isNull(): Logger.log("e", "Image is corrupt.") return MeshReader.PreReadResult.failed width = img.width() depth = img.height() largest = max(width, depth) width = width / largest * self._ui.default_width depth = depth / largest * self._ui.default_depth self._ui.setWidthAndDepth(width, depth) self._ui.showConfigUI() self._ui.waitForUIToClose() if self._ui.getCancelled(): return MeshReader.PreReadResult.cancelled return MeshReader.PreReadResult.accepted def _read(self, file_name): size = max(self._ui.getWidth(), self._ui.getDepth()) return self._generateSceneNode(file_name, size, self._ui.peak_height, self._ui.base_height, self._ui.smoothing, 512, self._ui.lighter_is_higher, self._ui.use_transparency_model, self._ui.transmittance_1mm) def _generateSceneNode(self, file_name, xz_size, height_from_base, base_height, blur_iterations, max_size, lighter_is_higher, use_transparency_model, transmittance_1mm): scene_node = SceneNode() mesh = MeshBuilder() img = QImage(file_name) if img.isNull(): Logger.log("e", "Image is corrupt.") return None width = max(img.width(), 2) height = max(img.height(), 2) aspect = height / width if img.width() < 2 or img.height() < 2: img = img.scaled(width, height, Qt.IgnoreAspectRatio) height_from_base = max(height_from_base, 0) base_height = max(base_height, 0) xz_size = max(xz_size, 1) scale_vector = Vector(xz_size, height_from_base, xz_size) if width > height: scale_vector = scale_vector.set(z=scale_vector.z * aspect) elif height > width: scale_vector = scale_vector.set(x=scale_vector.x / aspect) if width > max_size or height > max_size: scale_factor = max_size / width if height > width: scale_factor = max_size / height width = int(max(round(width * scale_factor), 2)) height = int(max(round(height * scale_factor), 2)) img = img.scaled(width, height, Qt.IgnoreAspectRatio) width_minus_one = width - 1 height_minus_one = height - 1 Job.yieldThread() texel_width = 1.0 / (width_minus_one) * scale_vector.x texel_height = 1.0 / (height_minus_one) * scale_vector.z height_data = numpy.zeros((height, width), dtype = numpy.float32) for x in range(0, width): for y in range(0, height): qrgb = img.pixel(x, y) if use_transparency_model: height_data[y, x] = (0.299 * math.pow(qRed(qrgb) / 255.0, 2.2) + 0.587 * math.pow(qGreen(qrgb) / 255.0, 2.2) + 0.114 * math.pow(qBlue(qrgb) / 255.0, 2.2)) else: height_data[y, x] = (0.212655 * qRed(qrgb) + 0.715158 * qGreen(qrgb) + 0.072187 * qBlue(qrgb)) / 255 # fast computation ignoring gamma and degamma Job.yieldThread() if lighter_is_higher == use_transparency_model: height_data = 1 - height_data for _ in range(0, blur_iterations): copy = numpy.pad(height_data, ((1, 1), (1, 1)), mode = "edge") height_data += copy[1:-1, 2:] height_data += copy[1:-1, :-2] height_data += copy[2:, 1:-1] height_data += copy[:-2, 1:-1] height_data += copy[2:, 2:] height_data += copy[:-2, 2:] height_data += copy[2:, :-2] height_data += copy[:-2, :-2] height_data /= 9 Job.yieldThread() if use_transparency_model: divisor = 1.0 / math.log(transmittance_1mm / 100.0) # log-base doesn't matter here. Precompute this value for faster computation of each pixel. min_luminance = (transmittance_1mm / 100.0) ** height_from_base for (y, x) in numpy.ndindex(height_data.shape): mapped_luminance = min_luminance + (1.0 - min_luminance) * height_data[y, x] height_data[y, x] = base_height + divisor * math.log(mapped_luminance) # use same base as a couple lines above this else: height_data *= scale_vector.y height_data += base_height if img.hasAlphaChannel(): for x in range(0, width): for y in range(0, height): height_data[y, x] *= qAlpha(img.pixel(x, y)) / 255.0 heightmap_face_count = 2 * height_minus_one * width_minus_one total_face_count = heightmap_face_count + (width_minus_one * 2) * (height_minus_one * 2) + 2 mesh.reserveFaceCount(total_face_count) # initialize to texel space vertex offsets. # 6 is for 6 vertices for each texel quad. heightmap_vertices = numpy.zeros((width_minus_one * height_minus_one, 6, 3), dtype = numpy.float32) heightmap_vertices = heightmap_vertices + numpy.array([[ [0, base_height, 0], [0, base_height, texel_height], [texel_width, base_height, texel_height], [texel_width, base_height, texel_height], [texel_width, base_height, 0], [0, base_height, 0] ]], dtype = numpy.float32) offsetsz, offsetsx = numpy.mgrid[0: height_minus_one, 0: width - 1] offsetsx = numpy.array(offsetsx, numpy.float32).reshape(-1, 1) * texel_width offsetsz = numpy.array(offsetsz, numpy.float32).reshape(-1, 1) * texel_height # offsets for each texel quad heightmap_vertex_offsets = numpy.concatenate([offsetsx, numpy.zeros((offsetsx.shape[0], offsetsx.shape[1]), dtype = numpy.float32), offsetsz], 1) heightmap_vertices += heightmap_vertex_offsets.repeat(6, 0).reshape(-1, 6, 3) # apply height data to y values heightmap_vertices[:, 0, 1] = heightmap_vertices[:, 5, 1] = height_data[:-1, :-1].reshape(-1) heightmap_vertices[:, 1, 1] = height_data[1:, :-1].reshape(-1) heightmap_vertices[:, 2, 1] = heightmap_vertices[:, 3, 1] = height_data[1:, 1:].reshape(-1) heightmap_vertices[:, 4, 1] = height_data[:-1, 1:].reshape(-1) heightmap_indices = numpy.array(numpy.mgrid[0:heightmap_face_count * 3], dtype = numpy.int32).reshape(-1, 3) mesh._vertices[0:(heightmap_vertices.size // 3), :] = heightmap_vertices.reshape(-1, 3) mesh._indices[0:(heightmap_indices.size // 3), :] = heightmap_indices mesh._vertex_count = heightmap_vertices.size // 3 mesh._face_count = heightmap_indices.size // 3 geo_width = width_minus_one * texel_width geo_height = height_minus_one * texel_height # bottom mesh.addFaceByPoints(0, 0, 0, 0, 0, geo_height, geo_width, 0, geo_height) mesh.addFaceByPoints(geo_width, 0, geo_height, geo_width, 0, 0, 0, 0, 0) # north and south walls for n in range(0, width_minus_one): x = n * texel_width nx = (n + 1) * texel_width hn0 = height_data[0, n] hn1 = height_data[0, n + 1] hs0 = height_data[height_minus_one, n] hs1 = height_data[height_minus_one, n + 1] mesh.addFaceByPoints(x, 0, 0, nx, 0, 0, nx, hn1, 0) mesh.addFaceByPoints(nx, hn1, 0, x, hn0, 0, x, 0, 0) mesh.addFaceByPoints(x, 0, geo_height, nx, 0, geo_height, nx, hs1, geo_height) mesh.addFaceByPoints(nx, hs1, geo_height, x, hs0, geo_height, x, 0, geo_height) # west and east walls for n in range(0, height_minus_one): y = n * texel_height ny = (n + 1) * texel_height hw0 = height_data[n, 0] hw1 = height_data[n + 1, 0] he0 = height_data[n, width_minus_one] he1 = height_data[n + 1, width_minus_one] mesh.addFaceByPoints(0, 0, y, 0, 0, ny, 0, hw1, ny) mesh.addFaceByPoints(0, hw1, ny, 0, hw0, y, 0, 0, y) mesh.addFaceByPoints(geo_width, 0, y, geo_width, 0, ny, geo_width, he1, ny) mesh.addFaceByPoints(geo_width, he1, ny, geo_width, he0, y, geo_width, 0, y) mesh.calculateNormals(fast = True) scene_node.setMeshData(mesh.build()) return scene_node