Exemplo n.º 1
0
    def __insert_node(self, root, dim, parent, data_point):  # TODO implement recursive insertion
        if root is None:
            pos = parent.bounding_box.get_centroid()
            x_offset = dim[0] / 2.0
            y_offset = dim[1] / 2.0
            z_offset = dim[2] / 2.0
            branch = self.__find_branch(parent, data_point)
            if branch == 0:
                new_box = AxisAlignedBox3D.init_box_center(
                    np.asarray([pos[0] - x_offset, pos[1] - y_offset, pos[2] - z_offset]), x_offset, y_offset, z_offset)
            if branch == 1:
                new_box = AxisAlignedBox3D.init_box_center(
                    np.asarray([pos[0] - x_offset, pos[1] - y_offset, pos[2] + z_offset]), x_offset, y_offset, z_offset)
            if branch == 2:
                new_box = AxisAlignedBox3D.init_box_center(
                    np.asarray([pos[0] - x_offset, pos[1] + y_offset, pos[2] - z_offset]), x_offset, y_offset, z_offset)
            if branch == 3:
                new_box = AxisAlignedBox3D.init_box_center(
                    np.asarray([pos[0] - x_offset, pos[1] + y_offset, pos[2] + z_offset]), x_offset, y_offset, z_offset)
            if branch == 4:
                new_box = AxisAlignedBox3D.init_box_center(
                    np.asarray([pos[0] + x_offset, pos[1] - y_offset, pos[2] - z_offset]), x_offset, y_offset, z_offset)
            if branch == 5:
                new_box = AxisAlignedBox3D.init_box_center(
                    np.asarray([pos[0] + x_offset, pos[1] - y_offset, pos[2] + z_offset]), x_offset, y_offset, z_offset)
            if branch == 6:
                new_box = AxisAlignedBox3D.init_box_center(
                    np.asarray([pos[0] + x_offset, pos[1] + y_offset, pos[2] - z_offset]), x_offset, y_offset, z_offset)
            if branch == 7:
                new_box = AxisAlignedBox3D.init_box_center(
                    np.asarray([pos[0] + x_offset, pos[1] + y_offset, pos[2] + z_offset]), x_offset, y_offset, z_offset)

            return OctreeNode(new_box, parent.depth + 1, [data_point])

        elif not root.isLeafNode and (np.any(root.bounding_box.get_centroid() != data_point)
                                      or root.bounding_box.get_centroid() != data_point):
            branch = self.__find_branch(root, data_point)
            new_dim = root.bounding_box.get_dimensions() / 2.0
            root.branches[branch] = self.__insert_node(root.branches[branch], new_dim, root, data_point)
        elif root.isLeafNode:
            if len(root.data_points) < self.MAX_OBJECTS_PER_CUBE:
                root.data_points.append(data_point)
                # print(len(root.data_points))
                # try:
                #     root.data_points.append(data_point)
                # except AttributeError:
                #     print(root.data_points)
                #     print(type(root.data_points))
                #     exit(1)
            else:
                root.data_points.append(data_point)
                objects = copy.deepcopy(root.data_points)  # TODO do we need deepcopy here?
                root.data_points = []
                root.isLeafNode = False
                new_dim = root.bounding_box.get_dimensions() / 2.0
                for k in objects:
                    branch = self.__find_branch(root, k)
                    root.branches[branch] = self.__insert_node(root.branches[branch], new_dim, root, k)
        return root
Exemplo n.º 2
0
def naive_slice(data, slice_box=AxisAlignedBox3D()):
    points = []
    lower_corner = slice_box.min_corner()
    upper_corner = slice_box.max_corner()
    for datum in tqdm(data, total=len(data), desc="Slicing"):
        if lower_corner[0] <= datum[0] <= upper_corner[0] and lower_corner[1] <= datum[1]\
                <= upper_corner[1] and lower_corner[2] <= datum[2] <= upper_corner[2]:
            points.append(np.array(datum))
    return points
Exemplo n.º 3
0
    def __init__(self,
                 bounding_box=AxisAlignedBox3D(),
                 depth=0,
                 data_points=[]):
        """
        branch: 0 1 2 3 4 5 6 7
        x:      - - - - + + + +
        y:      - - + + - - + +
        z:      - + - + - + - +
        """
        self.bounding_box = bounding_box
        self.depth = depth
        self.data_points = data_points

        #self.bounding_box_center = bounding_box.get_centroid()
        #self.bounding_box_dimensions = bounding_box.get_dimensions()
        self.isLeafNode = True
        self.branches = [None] * 8
        self.lower_corner = bounding_box.min_corner()
        self.upper_corner = bounding_box.max_corner()
Exemplo n.º 4
0
def naive_slice_from_las(filename, slice_box=AxisAlignedBox3D()):
    points = []

    with File(filename, mode='r') as in_file:
        scales = in_file.header.scale
        offsets = in_file.header.offset
        x_s, y_s, z_s = scales[0], scales[1], scales[2]
        x_o, y_o, z_o = offsets[0], offsets[1], offsets[2]

        lower_corner = slice_box.min_corner()
        upper_corner = slice_box.max_corner()
        for datum in tqdm(in_file.points, total=len(in_file.points), desc="Slicing"):
            # print([datum[0][0], datum[0][1], datum[0][2]])
            s0 = scale(datum[0][0], x_s, x_o)
            s1 = scale(datum[0][1], y_s, y_o)
            s2 = scale(datum[0][2], z_s, z_o)
            if lower_corner[0] <= s0 <= upper_corner[0]\
                    and lower_corner[1] <= s1 <= upper_corner[1]\
                    and lower_corner[2] <= s2 <= upper_corner[2]:
                points.append(np.array([s0, s1, s2]))
        print("sliced %d points" % len(points))
    return points
Exemplo n.º 5
0
from laspy.file import File
import numpy as np
from Utils.AxisAlignedBox3D import AxisAlignedBox3D
from SliceFunctions.NaiveSliceFromLAS import naive_slice_from_las
from PlotUtils.VtkPointCloud import VtkPointCloud

input_file = "../MantecaDock/dock.las"
output_file = "../MantecaDock/fourPallets.las"

inFile = File(input_file, mode='r')
outFile = File(output_file, mode='w', header=inFile.header)

pointCloud = VtkPointCloud()

sliced = naive_slice_from_las(
    input_file, AxisAlignedBox3D([204.24, -6.7, -1.9], [208.46, -3.24, 3.5]))
# sliced = [[1, 1, 1]]
print("Number of points sliced: %d" % len(sliced))
# for point in sliced:
#     pointCloud.addPoint(point)
#
#     outFile.write(point)
# pdb.set_trace()
allx = np.array([sliced[i][0] for i in range(len(sliced))])
ally = np.array([sliced[i][1] for i in range(len(sliced))])
allz = np.array([sliced[i][2] for i in range(len(sliced))])
outFile.x = allx
outFile.y = ally
outFile.z = allz
# print("Number of points: %d" % len(sliced))
# print('Plotting')
Exemplo n.º 6
0
import numpy as np
from Utils.AxisAlignedBox3D import AxisAlignedBox3D

x = AxisAlignedBox3D(np.array([0, 0, 0], dtype=np.float32), np.array([1, 1, 1], dtype=np.float32))
y = AxisAlignedBox3D.init_box_center(np.array([.5, .5, .5], dtype=np.float32), .5, .5, .5)

print(x.get_corners())
print(y.get_corners())

assert x.equals_box(y), "fail equality"
    # pc2 = create_vtkpc_from_array(points2)
    # to_plot.append(pc2)

    # points2 = read_raw_las_data(input2)
    # pc2 = create_vtkpc_from_array(points2)
    # to_plot.append(pc2)

    # points = read_raw_las_data(input1)
    # warehouse = subsample_frac_from_las_data(input2, .1)
    #
    # # points = subsample_frac_from_las_data(input1, .01)
    # pc = create_vtkpc_from_array(points+warehouse)
    # to_plot.append(pc)

    points = naive_slice_from_las(input1,
                                  AxisAlignedBox3D([7, -13, -.5], [9, -11, 3]))
    # points = subsample_frac_from_las_data(input1, .01)
    points = ann_guided_filter(points, num_neighbors=50, filter_eps=.07)
    # points = subsample_frac_from_las_data(input1, .1)
    pc = create_vtkpc_from_array(points)
    to_plot.append(pc)

    # points2 = threshold_filter(points, threshold=.01)
    # pc2 = create_vtkpc_from_array(points2)
    # to_plot.append(pc2)

    # points2 = read_raw_las_data(input2)
    # pc2 = create_vtkpc_from_array(points2)
    # to_plot.append(pc2)

    # points2 = threshold_filter(points, threshold=.015)
Exemplo n.º 8
0
 def __init__(self, bounding_box=AxisAlignedBox3D(np.asarray([0., 0., 0.]), np.asarray([2048., 2048., 2048.]))):
     self.MAX_OBJECTS_PER_CUBE = 1000
     self.root = OctreeNode(bounding_box, 0, [])
Exemplo n.º 9
0
    def __on_keep_points_inside_box_click(self):
        """
        A function that prompts for two points to define an AxisAlignedBox3D and all points INSIDE the box are kept
        """
        prompt = QInputDialog.getInt(self, "Plot index to cull", "Index")
        # note that prompt returns as ('int_inputted', bool) where bool represents if the prompt was taken
        if prompt[1]:
            try:
                i = prompt[0]
                w = self.widgets[
                    i]  # only to throw the Index Error if invalid index given
            except IndexError:
                QMessageBox.about(
                    self, "Error",
                    "Index out of bounds exception, remember to zero index.")
                return
        else:
            return
        corner0 = QInputDialog.getText(self, "Bounding Point 1", "")
        # regex from https://stackoverflow.com/questions/12929308/
        #                                   python-regular-expression-that-matches-floating-point-numbers/12929311
        comp = re.compile(
            '\([+-]?(\d+(\.\d*)?|\.\d+)([eE][+-]?\d+)?'
            '(\s*,\s*[+-]?(\d+(\.\d*)?|\.\d+)([eE][+-]?\d+)?){2}\)')
        if corner0[1]:
            m = comp.match(corner0[0])
            if m:
                # print("Match found: ", m.group())
                temp = m.group().replace("(", "")
                temp = temp.replace(")", "")
                temp = re.sub(r"\s+", "", temp).split(",")
                corner_float0 = [float(i) for i in temp]
                # print(corner_float0)
            else:
                print("Invalid point syntax")
                return
        else:
            return

        corner1 = QInputDialog.getText(self, "Bounding Point 2", "")
        if corner1[1]:
            m = comp.match(corner1[0])
            if m:
                # print("Match found: ", m.group())
                temp = m.group().replace("(", "")
                temp = temp.replace(")", "")
                temp = re.sub(r"\s+", "", temp).split(",")
                corner_float1 = [float(i) for i in temp]
                # print(corner_float0)
            else:
                print("Invalid point syntax")
                return
        else:
            return

        # print(corner_float0)
        # print(corner_float1)
        bounding_box = AxisAlignedBox3D(corner_float0, corner_float1)
        new_min = bounding_box.min_corner()
        points_to_keep = []
        point_array = self.plots[i].getPointsAsArray()
        for point in tqdm(point_array,
                          total=len(point_array),
                          desc="Clearing Points"):
            if bounding_box.contains_point(point):
                points_to_keep.append(point[:])
        del point_array
        self.plots[i].clearPoints()
        for point in tqdm(points_to_keep,
                          total=len(points_to_keep),
                          desc="Constructing PC"):
            self.plots[i].addPoint(point)
        del points_to_keep
        self.__translate_helper(i, -new_min)
Exemplo n.º 10
0

class TestObject:
    def __init__(self, name, position):
        self.name = name
        self.position = position

    @property
    def __str__(self):
        return u"name: {0} position: {1}".format(self.name, self.position)


NUM_TEST_OBJECTS = 20000
NUM_LOOKUPS = 20000

enclosure = AxisAlignedBox3D(np.asarray([0., 0., 0.]),
                             np.asarray([128., 128., 128.]))
center = enclosure.get_centroid()

testObjects = []
for x in range(NUM_TEST_OBJECTS):
    name = "Node__" + str(x)
    pos = np.array(center + np.random.uniform(0., 64., 3))
    testObjects.append(TestObject(name, pos))

tree = Octree(enclosure)
Start = time.time()
for test in testObjects:
    tree.insert_node(test.position)
End = time.time() - Start
print("%d node tree generated in %f seconds" % (NUM_TEST_OBJECTS, End))
Exemplo n.º 11
0
input_file = "../MantecaRoom1/room1.las"
# out_file = "../MantecaDock/smallArea.las"
pointCloud = VtkPointCloud()
filteredPointCloud = VtkPointCloud()

with File(input_file, mode='r') as f:
    input_header = f.header

    print("reading %s" % input_file)

    points = read_raw_las_data(input_file)
    for point in tqdm(points, total=len(points), desc="Adding"):
        pointCloud.addPoint(point)

    filtered_points = naive_slice(
        points, AxisAlignedBox3D([-70, -20, 1.94], [10, 90, 2.54]))
    for filtered_point in tqdm(filtered_points,
                               total=len(filtered_points),
                               desc="Adding"):
        filteredPointCloud.addPoint(filtered_point)

    print("Original has %d points" % len(points))
    print("Sliced has %d points" % len(filtered_points))

    to_plot = [pointCloud, filteredPointCloud]
    create_point_cloud_plot_qt(to_plot)

# # inFile = File(out_file, mode='r')
# # outFile = File(out_file, mode='w', header=inFile.header)
#
# pointCloud = VtkPointCloud()
from PlotUtils.VtkPointCloud import VtkPointCloud

input_file = "../MantecaRoom1/rack.las"
out_file = "../MantecaDock/smallArea.las"
pointCloud = VtkPointCloud()
filteredPointCloud = VtkPointCloud()

# inFile = File(out_file, mode='r')
# outFile = File(out_file, mode='w', header=inFile.header)

pointCloud = VtkPointCloud()

print("reading from %s" % input_file)
sliced = naive_slice_from_las(
    input_file,
    AxisAlignedBox3D([197.5000, -6.7000, -.2000], [209.5000, 1.0600, 8.6000]))
# pdb.set_trace()
# 1975000, 2095000, -67000, 10600, -2000, 86000 minx maxx miny maxy minz maxz
for point in tqdm(sliced, total=len(sliced), desc="Adding"):
    pointCloud.addPoint(point)

print("Number of points: %d" % len(sliced))
print('Plotting')
# Renderer
renderer = vtk.vtkRenderer()
renderer.AddActor(pointCloud.vtkActor)
renderer.SetBackground(.2, .3, .4)
renderer.ResetCamera()

# Render Window
renderWindow = vtk.vtkRenderWindow()