Exemplo n.º 1
0
    def __init__(self, path):
        self.helpers = Helpers()  # Image helpers
        if (path == 'error1'):
            self.errorimg = self.loadImage('input.jpeg')
            W = self.errorimg.shape[0]
            H = self.errorimg.shape[1]
            cv2.putText(self.errorimg, "Grid not Detected",
                        (0, int(H / 2)), cv2.FONT_HERSHEY_SIMPLEX,
                        int(1 * (W / 400)), (0, 0, 255), 3)
            self.helpers.show(self.errorimg, 'Final Sudoku grid')
            return
        if (path == 'error2'):
            self.errorimg = self.loadImage('input.jpeg')
            W = self.errorimg.shape[0]
            H = self.errorimg.shape[1]
            cv2.putText(self.errorimg, "Could not Solve",
                        (0, int(H / 2)), cv2.FONT_HERSHEY_SIMPLEX,
                        int(1 * (W / 400)), (0, 0, 255), 3)
            self.helpers.show(self.errorimg, 'Final Sudoku grid')
            return
        self.image = self.loadImage(path)
        self.preprocess()
        #self.helpers.show(self.image, 'After Preprocessing')
        self.sudoku = self.cropSudoku()
        #self.helpers.show(sudoku, 'After Cropping out grid')
        self.sudoku = self.straighten(self.sudoku)

        #self.helpers.show(self.sudoku, 'Final Sudoku grid')
        self.digits = Cells(self.sudoku).cells
Exemplo n.º 2
0
 def __init__(self, path):
     self.tools = Tools()
     self.image = self.loadImage(path)
     self.preprocess()
     sudoku_image = self.cropSudoku()
     sudoku_image = self.strengthen(sudoku_image)
     self.cells = Cells(sudoku_image).cells
Exemplo n.º 3
0
 def __init__(self, path):
     self.helpers = Helpers()  # Image helpers
     self.image = self.loadImage(path)
     self.preprocess()
     sudoku = self.cropSudoku()
     sudoku = self.straighten(sudoku)
     self.cells = Cells(sudoku).cells
Exemplo n.º 4
0
 def __init__(self, path):
     self.helpers = Helpers()  # Image helpers
     self.image = self.loadImage(path)
     self.preprocess()
     #self.helpers.show(self.image, 'After Preprocessing')
     sudoku = self.cropSudoku()
     self.helpers.show(sudoku, 'After Cropping out grid')
     sudoku = self.straighten(sudoku)
     #self.helpers.show(sudoku, 'Final Sudoku grid')
     self.cells = Cells(sudoku).cells
Exemplo n.º 5
0
    def __init__(self):
        # Initialise PyGame.
        pygame.init()

        # Set up the clock. This will tick every frame and thus maintain a relatively constant framerate. Hopefully.
        self.fpsClock = pygame.time.Clock()
        # Set up the window.
        self.width, self.height = 640, 640
        self.screen = pygame.display.set_mode((self.width, self.height))

        initial_state = [[0 for j in range(32)] for i in range(32)]
        self.cells = Cells(initial_state)
        self.paused = False
Exemplo n.º 6
0
def read_data(folder, fname):
    """ read simulation data through hdf5 file"""

    ### access the file

    fpath = folder + fname
    assert os.path.exists(fpath), "out_fil.h5 does NOT exist for " + fpath
    fl = h5py.File(fpath, 'r')

    ### read in the positions of filaments

    xi = np.array(fl['/positions/xi'],
                  dtype=np.float32)  # center of mass of MT
    ori = np.array(fl['/positions/ori'],
                   dtype=np.float32)  # <orientation> of MT

    ### read in the box info

    lx = fl['/info/box/x'][...]
    ly = fl['/info/box/y'][...]

    ### read in the general simulation info

    dt = fl['/info/dt'][...]
    nsteps = fl['/info/nsteps'][...]
    nbeads = fl['/info/nbeads'][...]
    nsamp = fl['/info/nsamp'][...]

    ### read in the filament information

    nfils = fl['/info/nfils'][...]
    nbpf = fl['/info/nbpf'][...]

    ### read in the simulation parameters

    density = fl['/param/density'][...]
    kappa = fl['/param/kappa'][...]
    km = fl['/param/km'][...]
    pa = fl['/param/pa'][...]
    bl = fl['/param/bl'][...]
    sigma = fl['/param/sigma'][...]

    ### close the file

    fl.close()

    sim = Simulation(lx, ly, dt, nsteps, nbeads, nsamp, nfils, nbpf, density,
                     kappa, km, pa, bl, sigma)
    fils = Cells(xi, ori, sim)
    return fils, sim
Exemplo n.º 7
0
def main(image_path):
    # get the final worksheet from the image
    ext = Extractor(image_path, False)
    final = ext.final

    # get the form code by checking the image's QR code
    decoded_qr_code = reader(final)

    # extract the cells and student's responses
    cells = Cells(final)

    # grade the worksheet by using a CNN to OCR the student's responses
    grader = Grader(decoded_qr_code)
    grader.grade(cells.student_responses)
    worksheet = grader.display(final, cells.sorted_contours)
    Helpers.save_image(f'{Helpers.IMAGE_DIRECTORY}/graded.png', worksheet)
Exemplo n.º 8
0
 def __init__(self,
              window,
              x,
              y,
              width,
              height,
              name="Game",
              background=(224, 224, 224)):
     self.name = name
     self.position = vector(x, y)
     self.window = window
     self.width = width
     self.height = height
     self.screen = pygame.Surface((self.width, self.height))
     self.grid = [[Cells(self.screen, x, y, 30, 30) for x in range(16)]
                  for y in range(25)]
     self.background = background
     self.rect = self.screen.get_rect()
Exemplo n.º 9
0
Arquivo: BR.py Projeto: lmorchard/PX8
B = Biomes()
BLOBS = Blobs()

CONFIG = Configuration(B, BLOBS)
P = Player(Vec2(82, 16).mul(32))
CAM = Camera(P.pos.sub(Vec2(64, 64 + 128)))
CLOUDS = Clouds()
TREES = Trees(CONFIG)
BUSHES = Bushes(CONFIG)
BUILDINGS = Buildings(CONFIG)
M = MapFormat(CreateRandomWorld())

P.pos.y -= 128

CELLS = Cells(flr(CAM.pos.x / CELL_SIZE), flr(CAM.pos.y / CELL_SIZE),
              M.mapdata, CONFIG)


def _init():
    print("CAMERA", CAM.pos.x, CAM.pos.y)
    palt(0, False)
    palt(14, True)


def _update():
    global PERSPECTIVE_OFFSET

    P.update()

    PERSPECTIVE_OFFSET = Vec2(64 + sin(px8_time() / 9) * 4,
                              80 + sin(px8_time() / 11) * 4)
Exemplo n.º 10
0
def test_maze_grid():
    cells = Cells(constants.FILENAME)
    maze = MazeGrid(cells)
Exemplo n.º 11
0
def cli(rbc, plt, verbose, output, axes, bounding_box, clip, stl):
    """Convert and visualise cell position files used in HemoCell [0].

    The script reads from any number of red blood cell position files (RBC.pos)
    and allows for direct visualisation with PyVista [1] or conversion to XDMF
    for inspection with Paraview through `-o, --output`.

    The RBC positions can be provided through `stdin` by specifying a dash
    (`-`) as argument and piping the input, e.g. `cat RBC.pos | pos_to_vtk -`.

    Optionally, any number of platelets position files (PLT.pos) can be
    supplied by the `--plt` argument, which might be repeated any number of
    times to specify multiple PLT.pos files.

    [0] https://hemocell.eu

    [1] https://dev.pyvista.org/index.html
    """
    if len(rbc) == 0 and len(plt) == 0:
        message = """No input files provided. When passing an RBC through
`stdin`, please provide a dash (`-`) as the argument."""
        raise click.UsageError(message)

    if (bounding_box is not None) and (stl is not None):
        message = """Options `--bounding-box` and `--stl` are exclusive and
cannot be combined. Please provide only one."""
        raise click.UsageError(message)

    rbcs = Cells(flatten([Cells.from_pos(rbc) for rbc in rbc]))
    plts = Cells(flatten([Cells.from_pos(plt) for plt in plt]))

    if len(rbcs) == 0:
        # The script terminates early when no RBCs are present. This
        # most-likely corresponds with users error, e.g. by providing the wrong
        # file path or an empty file.
        raise click.UsageError("No RBC cells to display." "")

    if bounding_box:
        bounds = flatten(zip((0, 0, 0), bounding_box))
        wireframe = pv.Box(bounds)

    if stl:
        wireframe = pv.get_reader(stl).read()
        wireframe.scale((1e3, 1e3, 1e3))

    if clip:
        rbcs = rbcs.clip(wireframe, bounding_box)
        plts = plts.clip(wireframe, bounding_box)

    if len(rbcs) == 0 and len(plts) == 0:
        raise click.UsageError("No cells remain after clipping.")

    if output:
        rbcs = create_glyphs(rbcs, CellType.RBC)
        merged_cells = rbcs.merge(plts) if plt else rbcs
        pv.save_meshio(output, merged_cells)

        if verbose:
            click.echo(f"Written to: '{click.format_filename(output)}'")
        return 0

    plotter = pv.Plotter()

    rbcs_glyph = create_glyphs(rbcs, CellType.RBC)
    rbcs_actor = plotter.add_mesh(rbcs_glyph, color="red")

    if plt:
        plts_glyph = create_glyphs(plts, CellType.PLT)
        plts_actor = plotter.add_mesh(plts_glyph, color="yellow")

    if bounding_box or stl:
        plotter.add_mesh(wireframe, style='wireframe')

    message = f'RBC: {len(rbcs)}\nPLT: {len(plts)}\n'

    if clip:
        # Only when the domain is clipped, a bounding domain is known either
        # through the given bounding box or by the given STL surface mesh.
        # These allow to determine an estimate of the domain's volume and
        # thereby estimate the expected hematocrit given the number of RBCs
        # left after clipping.
        volume = 1e-6 * wireframe.volume
        hc_percentage = 100 * rbcs.hematocrit(wireframe)
        message += f'Domain volume estimate (µm^3): {volume:.2f}\n'
        message += f'Hematocrit (vol%): {hc_percentage:.2f}\n'

    plotter.add_text(message, position='lower_right')

    # A simple widget illustrating the x-y-z axes orientation of the domain.
    if axes:
        plotter.add_axes(line_width=5, labels_off=False)

    # Two radio buttons are added that enable to show/hide the glyphs
    # corresponding to all RBCs or PLTs, where the lambda functions are given
    # to implement the callback function toggling the right set of glyphs.
    plotter.add_checkbox_button_widget(lambda x: rbcs_actor.SetVisibility(x),
                                       position=(5, 12),
                                       color_on="red",
                                       value=True)
    plotter.add_checkbox_button_widget(lambda x: plts_actor.SetVisibility(x),
                                       position=(5, 62),
                                       color_on="yellow",
                                       value=True)

    return plotter.show()