Example #1
0
    def _on_display_change(self):
        parent = self.node.parent
        self.node.parent = None

        if self.layer.dims.ndisplay == 2:
            self.node = ImageNode(None, method='auto')
        else:
            self.node = VolumeNode(np.zeros((1, 1, 1)))

        self.node.parent = parent
        self.reset()
Example #2
0
    def _on_display_change(self, data=None):
        parent = self.node.parent
        self.node.parent = None

        if self.layer.dims.ndisplay == 2:
            self.node = ImageNode(data, method='auto')
        else:
            if data is None:
                data = np.zeros((1, 1, 1))
            self.node = VolumeNode(data, clim=self.layer.contrast_limits)

        self.node.parent = parent
        self.reset()
Example #3
0
def test_volume_draw():
    with TestingCanvas(bgcolor='w', size=(92, 92)) as c:
        # Create
        vol = np.zeros((20, 20, 20), 'float32')
        vol[8:16, 8:16, :] = 1.0
        V = Volume(vol)
        c.draw_visual(V)
Example #4
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def test_volume():
    
    vol = np.zeros((20, 20, 20), 'float32')
    vol[8:16, 8:16, :] = 1.0
    
    # Create
    V = Volume(vol)
    assert V.clim == (0, 1)
    assert V.method == 'mip'
    
    # Set wrong data
    assert_raises(ValueError, V.set_data, np.zeros((20, 20), 'float32'))
    
    # Clim
    V.set_data(vol, (0.5, 0.8))
    assert V.clim == (0.5, 0.8)
    assert_raises(ValueError, V.set_data, vol, (0.5, 0.8, 1.0))
    
    # Method
    V.method = 'iso'
    assert V.method == 'iso'
    
    # Step size
    V.relative_step_size = 1.1
    assert V.relative_step_size == 1.1
    # Disallow 0 step size to avoid GPU stalling
    assert_raises(ValueError, V.__class__.relative_step_size.fset, V, 0)
Example #5
0
 def init_visual(self, view):
     """Initialize the class visual."""
     ball_ln_dic = dict(color=self.color)
     dist_sq = np.zeros(self.meshgrid[0].shape)
     for i in range(3):
         axis_sq = np.multiply((self.meshgrid[i] - self.pos[i] * 4),
                             (self.meshgrid[i] - self.pos[i] * 4))
         dist_sq = dist_sq + axis_sq
     dist_sq = 4.0 - dist_sq
     dist_sq[dist_sq < 0] = 0
     self.visual = Volume(dist_sq, clim=(0.0, 10.0), method='mip',
                            emulate_texture=False, cmap='hot')
     self.visual.transform = scene.STTransform(scale=(.25, .25, .25))
     view.add(self.visual)
     self.last_dist_sq = dist_sq
Example #6
0
class VispyImageLayer(VispyBaseLayer):
    def __init__(self, layer):
        node = ImageNode(None, method='auto')
        super().__init__(layer, node)

        self.layer.events.rendering.connect(
            lambda e: self._on_rendering_change())
        self.layer.events.interpolation.connect(
            lambda e: self._on_interpolation_change())
        self.layer.events.colormap.connect(
            lambda e: self._on_colormap_change())
        self.layer.events.contrast_limits.connect(
            lambda e: self._on_contrast_limits_change())
        self.layer.events.gamma.connect(lambda e: self._on_gamma_change())

        self._on_display_change()
        self._on_data_change()

    def _on_display_change(self):
        parent = self.node.parent
        self.node.parent = None

        if self.layer.dims.ndisplay == 2:
            self.node = ImageNode(None, method='auto')
        else:
            self.node = VolumeNode(np.zeros((1, 1, 1)))

        self.node.parent = parent
        self.reset()

    def _on_data_change(self):
        # Check if ndisplay has changed current node type needs updating
        if (self.layer.dims.ndisplay == 3
                and not isinstance(self.node, VolumeNode)) or (
                    self.layer.dims.ndisplay == 2
                    and not isinstance(self.node, ImageNode)):
            self._on_display_change()

        data = self.layer._data_view
        dtype = np.dtype(data.dtype)
        if dtype not in texture_dtypes:
            try:
                dtype = dict(i=np.int16, f=np.float32, u=np.uint16,
                             b=np.uint8)[dtype.kind]
            except KeyError:  # not an int or float
                raise TypeError(
                    f'type {dtype} not allowed for texture; must be one of {set(texture_dtypes)}'  # noqa: E501
                )
            data = data.astype(dtype)

        if self.layer.dims.ndisplay == 3 and self.layer.dims.ndim == 2:
            data = np.expand_dims(data, axis=0)

        if self.layer.dims.ndisplay == 2:
            self.node._need_colortransform_update = True
            self.node.set_data(data)
        else:
            self.node.set_data(data, clim=self.layer.contrast_limits)
        self.node.update()

    def _on_interpolation_change(self):
        if self.layer.dims.ndisplay == 2:
            self.node.interpolation = self.layer.interpolation

    def _on_rendering_change(self):
        if not self.layer.dims.ndisplay == 2:
            self.node.method = self.layer.rendering

    def _on_colormap_change(self):
        cmap = self.layer.colormap[1]
        if self.layer.gamma != 1:
            # when gamma!=1, we instantiate a new colormap
            # with 256 control points from 0-1
            cmap = Colormap(cmap[np.linspace(0, 1, 256)**self.layer.gamma])

        # Below is fixed in #1712
        if not self.layer.dims.ndisplay == 2:
            self.node.view_program['texture2D_LUT'] = (cmap.texture_lut() if (
                hasattr(cmap, 'texture_lut')) else None)
        self.node.cmap = cmap

    def _on_contrast_limits_change(self):
        if self.layer.dims.ndisplay == 2:
            self.node.clim = self.layer.contrast_limits
        else:
            self._on_data_change()

    def _on_gamma_change(self):
        self._on_colormap_change()

    def _on_scale_change(self):
        self.scale = [
            self.layer.scale[d] * self.layer._scale_view[d]
            for d in self.layer.dims.displayed[::-1]
        ]
        if self.layer.is_pyramid:
            self.layer.top_left = self.find_top_left()
        self.layer.position = self._transform_position(self._position)

    def _on_translate_change(self):
        self.translate = [
            self.layer.translate[d] + self.layer._translate_view[d] +
            self.layer.translate_grid[d]
            for d in self.layer.dims.displayed[::-1]
        ]
        self.layer.position = self._transform_position(self._position)

    def compute_data_level(self, size):
        """Computed what level of the pyramid should be viewed given the
        current size of the requested field of view.

        Parameters
        ----------
        size : 2-tuple
            Requested size of field of view in image coordinates

        Returns
        ----------
        level : int
            Level of the pyramid to be viewing.
        """
        # Convert requested field of view from the camera into log units
        size = np.log2(np.max(size))

        # Max allowed tile in log units
        max_size = np.log2(self.layer._max_tile_shape)

        # Allow for more than 2x coverage of field of view with max tile
        diff = size - max_size + 1.25

        # Find closed downsample level to diff
        ds = self.layer.level_downsamples[:, self.layer.dims.displayed].max(
            axis=1)
        level = np.argmin(abs(np.log2(ds) - diff))

        return level

    def find_top_left(self):
        """Finds the top left pixel of the canvas. Depends on the current
        pan and zoom position

        Returns
        ----------
        top_left : tuple of int
            Coordinates of top left pixel.
        """
        nd = self.layer.dims.ndisplay
        # Find image coordinate of top left canvas pixel
        if self.node.canvas is not None:
            transform = self.node.canvas.scene.node_transform(self.node)
            pos = (transform.map([0, 0])[:nd] +
                   self.translate[:nd] / self.scale[:nd])
        else:
            pos = [0] * nd

        top_left = np.zeros(self.layer.ndim, dtype=int)
        for i, d in enumerate(self.layer.dims.displayed[::-1]):
            top_left[d] = pos[i]

        # Clip according to the max image shape
        top_left = np.clip(top_left, 0,
                           np.subtract(self.layer.level_shapes[0], 1))

        # Convert to offset for image array
        rounding_factor = self.layer._max_tile_shape / 4
        top_left = rounding_factor * np.floor(top_left / rounding_factor)

        return top_left.astype(int)

    def on_draw(self, event):
        """Called whenever the canvas is drawn, which happens whenever new
        data is sent to the canvas or the camera is moved.
        """
        self.layer.scale_factor = self.scale_factor
        if self.layer.is_pyramid:
            self.layer.scale_factor = self.scale_factor
            size = self.camera.rect.size
            data_level = self.compute_data_level(size)

            if data_level != self.layer.data_level:
                self.layer.data_level = data_level
            else:
                self.layer.top_left = self.find_top_left()

    def reset(self):
        self._reset_base()
        self._on_interpolation_change()
        self._on_rendering_change()
        self._on_colormap_change()
        if self.layer.dims.ndisplay == 2:
            self._on_contrast_limits_change()
class VispyImageLayer(VispyBaseLayer):
    def __init__(self, layer):
        node = ImageNode(None, method='auto')
        super().__init__(layer, node)

        self.layer.events.rendering.connect(
            lambda e: self._on_rendering_change())
        self.layer.events.interpolation.connect(
            lambda e: self._on_interpolation_change())
        self.layer.events.colormap.connect(
            lambda e: self._on_colormap_change())
        self.layer.events.contrast_limits.connect(
            lambda e: self._on_contrast_limits_change())
        self.layer.dims.events.ndisplay.connect(
            lambda e: self._on_display_change())

        self._on_display_change()

    def _on_display_change(self):
        parent = self.node.parent
        self.node.parent = None

        if self.layer.dims.ndisplay == 2:
            self.node = ImageNode(None, method='auto')
        else:
            self.node = VolumeNode(np.zeros((1, 1, 1)))

        self.node.parent = parent
        self.layer._update_dims()
        self.layer._set_view_slice()
        self.reset()

    def _on_data_change(self):
        data = self.layer._data_view
        dtype = np.dtype(data.dtype)
        if dtype not in texture_dtypes:
            try:
                dtype = dict(i=np.int16, f=np.float32, u=np.uint16,
                             b=np.uint8)[dtype.kind]
            except KeyError:  # not an int or float
                raise TypeError(
                    f'type {dtype} not allowed for texture; must be one of {set(texture_dtypes)}'
                )
            data = data.astype(dtype)

        if self.layer.dims.ndisplay == 3:
            self.node.set_data(data, clim=self.layer.contrast_limits)
        else:
            self.node._need_colortransform_update = True
            self.node.set_data(data)
        self.node.update()

    def _on_interpolation_change(self):
        if self.layer.dims.ndisplay == 2:
            self.node.interpolation = self.layer.interpolation

    def _on_rendering_change(self):
        if self.layer.dims.ndisplay == 3:
            self.node.method = self.layer.rendering

    def _on_colormap_change(self):
        cmap = self.layer.colormap[1]
        if self.layer.dims.ndisplay == 3:
            self.node.view_program['texture2D_LUT'] = (cmap.texture_lut() if (
                hasattr(cmap, 'texture_lut')) else None)
        self.node.cmap = cmap

    def _on_contrast_limits_change(self):
        if self.layer.dims.ndisplay == 3:
            self._on_data_change()
        else:
            self.node.clim = self.layer.contrast_limits

    def reset(self):
        self._reset_base()
        self._on_interpolation_change()
        self._on_rendering_change()
        self._on_colormap_change()
        self._on_contrast_limits_change()
        self._on_data_change()
Example #8
0
class Ball:
    """Ball Class. It uses vispy to visualization."""
    def __init__(self, position, velocity, boundaries = None, color = (1.0, 1.0, 1.0, 1.0)):
        self.pos = position
        self.vel = velocity
        self.color = color
        self.rad = 0.1
        self.bound = None
        self.sizexyz = [None] * 3
        if boundaries is not None:
            self.set_bound(boundaries)
        self.visual = None

    def set_bound(self, boundaries):
        """Updates the boundaries."""
        self.bound = boundaries
        self.sizexyz = np.abs(boundaries[:,1] - boundaries[:,0])
        temp_mg = np.meshgrid(np.arange(41), np.arange(41), np.arange(41))
        self.meshgrid = np.asarray([temp_mg[0], temp_mg[2], temp_mg[1]])

    def step(self, time_step):
        """Calculate the new position and speed."""
        despl = self.vel * time_step
        self.pos = self.pos + despl
        for i in range(3):
#-INF            if self.sizexyz[i] is not None and self.pos[i] < self.bound[i,0]:
#-INF                self.pos[i] = self.pos[i] + self.sizexyz[i]
#-INF            elif self.sizexyz[i] is not None and self.pos[i] > self.bound[i,1]:
#-INF                self.pos[i] = self.pos[i] - self.sizexyz[i]
            if self.sizexyz[i] is not None:
                if self.pos[i] < self.bound[i,0] or self.pos[i] > self.bound[i,1]:
                    self.pos[i] = self.pos[i] - despl[i]
                    self.vel[i] = - self.vel[i] * 0.95
        self.vel[2] = self.vel[2] - 0.1
        self.update_visual()

    def init_visual(self, view):
        """Initialize the class visual."""
        ball_ln_dic = dict(color=self.color)
        dist_sq = np.zeros(self.meshgrid[0].shape)
        for i in range(3):
            axis_sq = np.multiply((self.meshgrid[i] - self.pos[i] * 4),
                                (self.meshgrid[i] - self.pos[i] * 4))
            dist_sq = dist_sq + axis_sq
        dist_sq = 4.0 - dist_sq
        dist_sq[dist_sq < 0] = 0
        self.visual = Volume(dist_sq, clim=(0.0, 10.0), method='mip',
                               emulate_texture=False, cmap='hot')
        self.visual.transform = scene.STTransform(scale=(.25, .25, .25))
        view.add(self.visual)
        self.last_dist_sq = dist_sq

    def update_visual(self):
        """Updates the class visual."""
        dist_sq = np.zeros(self.meshgrid[0].shape)
        for i in range(3):
            axis_sq = np.multiply((self.meshgrid[i] - self.pos[i] * 4),
                                (self.meshgrid[i] - self.pos[i] * 4))
            dist_sq = dist_sq + axis_sq
        dist_sq = 4.0 - dist_sq
        dist_sq[dist_sq < 0] = 0
        dist_sq = dist_sq + 0.99 * self.last_dist_sq
        self.visual.set_data(dist_sq)
        self.visual.update()
        self.last_dist_sq = dist_sq

    def shake(self):
        """Inverts the z position and gives the ball a random velocity."""
        if self.sizexyz[2] is not None:
            self.pos[2] = self.bound[2, 1] - (self.pos[2] - self.bound[2, 0])
            self.vel = (np.random.rand(3) - 0.5) * 10