def _update_text(self):
vb = self.plot_item.getViewBox()
data_coords = vb.mapSceneToView(self.last_hover_event.scenePos())
# TODO: Draw text directly to graphics scene rather than going through
# pyqtgraph for performance - don't need any of the fancy interaction
# or layouting features that come with being a plot item.
def make_text():
text = pyqtgraph.TextItem()
# Don't take text item into account for auto-scaling; otherwise
# there will be positive feedback if the cursor is towards the
# bottom right of the screen.
text.setFlag(text.ItemHasNoContents)
self.plot_item.addItem(text)
return text
if not self.x_text:
self.x_text = make_text()
if not self.y_text:
self.y_text = make_text()
x_range, y_range = vb.state["viewRange"]
x_range = np.array(x_range) * self.x_data_to_display_scale
y_range = np.array(y_range) * self.y_data_to_display_scale
def num_digits_after_point(r):
# We want to be able to resolve at least 1000 points in the displayed
# range.
smallest_digit = np.floor(np.log10(r[1] - r[0])) - 3
return int(-smallest_digit) if smallest_digit < 0 else 0
self.x_text.setText("{0:.{width}f}{1}".format(
data_coords.x() * self.x_data_to_display_scale,
self.x_unit_suffix,
width=num_digits_after_point(x_range)))
self.x_text.setPos(data_coords)
self.last_x = data_coords.x()
y_text_pos = QtCore.QPointF(self.last_hover_event.scenePos())
y_text_pos.setY(self.last_hover_event.scenePos().y() + 10)
self.y_text.setText("{0:.{width}f}{1}".format(
data_coords.y() * self.y_data_to_display_scale,
self.y_unit_suffix,
width=num_digits_after_point(y_range)))
self.y_text.setPos(vb.mapSceneToView(y_text_pos))
self.last_y = data_coords.y()
def _update(self):
x_data = self.points["axis_0"]
y_data = self.points["axis_1"]
z_data = self.points["channel_" + self.active_channel_name]
# Figure out how many complete data points we have, and whether there are any
# not already shown.
num_to_show = min(len(x_data), len(y_data), len(z_data))
if num_to_show == self.num_shown:
return
num_skip = self.num_shown
self.num_shown = num_to_show
# Update z autorange if active.
if True: # TODO: Provide manual override.
data_min = np.min(z_data[num_skip:num_to_show])
data_max = np.max(z_data[num_skip:num_to_show])
if self.current_z_limits is None:
self.current_z_limits = (data_min, data_max)
num_skip = 0
else:
z_limits = (min(self.current_z_limits[0], data_min),
max(self.current_z_limits[1], data_max))
if z_limits != self.current_z_limits:
self.current_z_limits = z_limits
num_skip = 0
# Determine range of x/y values to show and prepare image buffer accordingly if
# it changed.
x_range = _calc_range_spec(self.x_min, self.x_max, self.x_increment,
x_data)
y_range = _calc_range_spec(self.y_min, self.y_max, self.y_increment,
y_data)
if x_range != self.x_range or y_range != self.y_range:
self.x_range = x_range
self.y_range = y_range
# TODO: Splat old data for progressively less blurry look on refining scans?
self.image_data = np.full((_num_points_in_range(x_range),
_num_points_in_range(y_range), 4),
0,
dtype="ubyte")
self.image_rect = QtCore.QRectF(
QtCore.QPointF(x_range[0] - x_range[2] / 2,
y_range[0] - y_range[2] / 2),
QtCore.QPointF(x_range[1] + x_range[2] / 2,
y_range[1] + y_range[2] / 2))
num_skip = 0
x_inds = _coords_to_indices(x_data[num_skip:num_to_show], self.x_range)
y_inds = _coords_to_indices(y_data[num_skip:num_to_show], self.y_range)
z_min, z_max = self.current_z_limits
z_scaled = (z_data[num_skip:num_to_show] - z_min) / (z_max - z_min)
cmap = colormaps.plasma
if self._get_display_hints().get("coordinate_type", "") == "cyclic":
cmap = colormaps.kovesi_c8
self.image_data[x_inds, y_inds, :] = cmap.map(z_scaled)
self.image_item.setImage(self.image_data, autoLevels=False)
if num_skip == 0:
# Image size has changed, set plot item size accordingly.
self.image_item.setRect(self.image_rect)
