############################################################ # FlatCAM: 2D Post-processing for Manufacturing # # http://caram.cl/software/flatcam # # Author: Juan Pablo Caram (c) # # Date: 2/5/2014 # # MIT Licence # # Modified by Marius Stanciu 09/21/2019 # ############################################################ from PyQt5 import QtGui, QtCore, QtWidgets # Prevent conflict with Qt5 and above. from matplotlib import use as mpl_use from matplotlib.figure import Figure from matplotlib.backends.backend_qt5agg import FigureCanvasQTAgg as FigureCanvas from matplotlib.backends.backend_agg import FigureCanvasAgg from matplotlib.widgets import Cursor # needed for legacy mode # Used for solid polygons in Matplotlib from descartes.patch import PolygonPatch from shapely.geometry import Polygon, LineString, LinearRing, Point, MultiPolygon, MultiLineString import FlatCAMApp from copy import deepcopy import logging import gettext import FlatCAMTranslation as fcTranslate import builtins fcTranslate.apply_language('strings') if '_' not in builtins.__dict__: _ = gettext.gettext mpl_use("Qt5Agg") log = logging.getLogger('base') class CanvasCache(QtCore.QObject): """ Case story #1: 1) No objects in the project. 2) Object is created (new_object() emits object_created(obj)). on_object_created() adds (i) object to collection and emits (ii) new_object_available() then calls (iii) object.plot() 3) object.plot() creates axes if necessary on app.collection.figure. Then plots on it. 4) Plots on a cache-size canvas (in background). 5) Plot completes. Bitmap is generated. 6) Visible canvas is painted. """ # Signals: # A bitmap is ready to be displayed. new_screen = QtCore.pyqtSignal() def __init__(self, plotcanvas, app, dpi=50): super(CanvasCache, self).__init__() self.app = app self.plotcanvas = plotcanvas self.dpi = dpi self.figure = Figure(dpi=dpi) self.axes = self.figure.add_axes([0.0, 0.0, 1.0, 1.0], alpha=1.0) self.axes.set_frame_on(False) self.axes.set_xticks([]) self.axes.set_yticks([]) self.canvas = FigureCanvasAgg(self.figure) self.cache = None def run(self): log.debug("CanvasCache Thread Started!") self.plotcanvas.update_screen_request.connect(self.on_update_req) def on_update_req(self, extents): """ Event handler for an updated display request. :param extents: [xmin, xmax, ymin, ymax, zoom(optional)] """ # log.debug("Canvas update requested: %s" % str(extents)) # Note: This information below might be out of date. Establish # a protocol regarding when to change the canvas in the main # thread and when to check these values here in the background, # or pass this data in the signal (safer). # log.debug("Size: %s [px]" % str(self.plotcanvas.get_axes_pixelsize())) # log.debug("Density: %s [units/px]" % str(self.plotcanvas.get_density())) # Move the requested screen portion to the main thread # and inform about the update: self.new_screen.emit() # Continue to update the cache. # def on_new_object_available(self): # # log.debug("A new object is available. Should plot it!") class PlotCanvasLegacy(QtCore.QObject): """ Class handling the plotting area in the application. """ # Signals: # Request for new bitmap to display. The parameter # is a list with [xmin, xmax, ymin, ymax, zoom(optional)] update_screen_request = QtCore.pyqtSignal(list) double_click = QtCore.pyqtSignal(object) def __init__(self, container, app): """ The constructor configures the Matplotlib figure that will contain all plots, creates the base axes and connects events to the plotting area. :param container: The parent container in which to draw plots. :rtype: PlotCanvas """ super(PlotCanvasLegacy, self).__init__() self.app = app # Options self.x_margin = 15 # pixels self.y_margin = 25 # Pixels # Parent container self.container = container # Plots go onto a single matplotlib.figure self.figure = Figure(dpi=50) # TODO: dpi needed? self.figure.patch.set_visible(False) # These axes show the ticks and grid. No plotting done here. # New axes must have a label, otherwise mpl returns an existing one. self.axes = self.figure.add_axes([0.05, 0.05, 0.9, 0.9], label="base", alpha=0.0) self.axes.set_aspect(1) self.axes.grid(True) self.axes.axhline(color=(0.70, 0.3, 0.3), linewidth=2) self.axes.axvline(color=(0.70, 0.3, 0.3), linewidth=2) # The canvas is the top level container (FigureCanvasQTAgg) self.canvas = FigureCanvas(self.figure) self.canvas.setFocusPolicy(QtCore.Qt.ClickFocus) self.canvas.setFocus() self.native = self.canvas self.adjust_axes(-10, -10, 100, 100) # self.canvas.set_can_focus(True) # For key press # Attach to parent # self.container.attach(self.canvas, 0, 0, 600, 400) # TODO: Height and width are num. columns?? self.container.addWidget(self.canvas) # Qt # Copy a bitmap of the canvas for quick animation. # Update every time the canvas is re-drawn. self.background = self.canvas.copy_from_bbox(self.axes.bbox) # ## Bitmap Cache self.cache = CanvasCache(self, self.app) self.cache_thread = QtCore.QThread() self.cache.moveToThread(self.cache_thread) # super(PlotCanvas, self).connect(self.cache_thread, QtCore.SIGNAL("started()"), self.cache.run) self.cache_thread.started.connect(self.cache.run) self.cache_thread.start() self.cache.new_screen.connect(self.on_new_screen) # Events self.mp = self.graph_event_connect('button_press_event', self.on_mouse_press) self.mr = self.graph_event_connect('button_release_event', self.on_mouse_release) self.mm = self.graph_event_connect('motion_notify_event', self.on_mouse_move) # self.canvas.connect('configure-event', self.auto_adjust_axes) self.aaa = self.graph_event_connect('resize_event', self.auto_adjust_axes) # self.canvas.add_events(Gdk.EventMask.SMOOTH_SCROLL_MASK) # self.canvas.connect("scroll-event", self.on_scroll) self.osc = self.graph_event_connect('scroll_event', self.on_scroll) # self.graph_event_connect('key_press_event', self.on_key_down) # self.graph_event_connect('key_release_event', self.on_key_up) self.odr = self.graph_event_connect('draw_event', self.on_draw) self.mouse = [0, 0] self.key = None self.pan_axes = [] self.panning = False # signal is the mouse is dragging self.is_dragging = False # signal if there is a doubleclick self.is_dblclk = False def graph_event_connect(self, event_name, callback): """ Attach an event handler to the canvas through the Matplotlib interface. :param event_name: Name of the event :type event_name: str :param callback: Function to call :type callback: func :return: Connection id :rtype: int """ if event_name == 'mouse_move': event_name = 'motion_notify_event' if event_name == 'mouse_press': event_name = 'button_press_event' if event_name == 'mouse_release': event_name = 'button_release_event' if event_name == 'mouse_double_click': return self.double_click.connect(callback) if event_name == 'key_press': event_name = 'key_press_event' return self.canvas.mpl_connect(event_name, callback) def graph_event_disconnect(self, cid): """ Disconnect callback with the give id. :param cid: Callback id. :return: None """ # self.double_click.disconnect(cid) self.canvas.mpl_disconnect(cid) def on_new_screen(self): pass # log.debug("Cache updated the screen!") def new_cursor(self, axes=None): # if axes is None: # c = MplCursor(axes=self.axes, color='black', linewidth=1) # else: # c = MplCursor(axes=axes, color='black', linewidth=1) c = FakeCursor() return c def on_key_down(self, event): """ :param event: :return: """ FlatCAMApp.App.log.debug('on_key_down(): ' + str(event.key)) self.key = event.key def on_key_up(self, event): """ :param event: :return: """ self.key = None def connect(self, event_name, callback): """ Attach an event handler to the canvas through the native Qt interface. :param event_name: Name of the event :type event_name: str :param callback: Function to call :type callback: function :return: Nothing """ self.canvas.connect(event_name, callback) def clear(self): """ Clears axes and figure. :return: None """ # Clear self.axes.cla() try: self.figure.clf() except KeyError: FlatCAMApp.App.log.warning("KeyError in MPL figure.clf()") # Re-build self.figure.add_axes(self.axes) self.axes.set_aspect(1) self.axes.grid(True) # Re-draw self.canvas.draw_idle() def adjust_axes(self, xmin, ymin, xmax, ymax): """ Adjusts all axes while maintaining the use of the whole canvas and an aspect ratio to 1:1 between x and y axes. The parameters are an original request that will be modified to fit these restrictions. :param xmin: Requested minimum value for the X axis. :type xmin: float :param ymin: Requested minimum value for the Y axis. :type ymin: float :param xmax: Requested maximum value for the X axis. :type xmax: float :param ymax: Requested maximum value for the Y axis. :type ymax: float :return: None """ # FlatCAMApp.App.log.debug("PC.adjust_axes()") width = xmax - xmin height = ymax - ymin try: r = width / height except ZeroDivisionError: FlatCAMApp.App.log.error("Height is %f" % height) return canvas_w, canvas_h = self.canvas.get_width_height() canvas_r = float(canvas_w) / canvas_h x_ratio = float(self.x_margin) / canvas_w y_ratio = float(self.y_margin) / canvas_h if r > canvas_r: ycenter = (ymin + ymax) / 2.0 newheight = height * r / canvas_r ymin = ycenter - newheight / 2.0 ymax = ycenter + newheight / 2.0 else: xcenter = (xmax + xmin) / 2.0 newwidth = width * canvas_r / r xmin = xcenter - newwidth / 2.0 xmax = xcenter + newwidth / 2.0 # Adjust axes for ax in self.figure.get_axes(): if ax._label != 'base': ax.set_frame_on(False) # No frame ax.set_xticks([]) # No tick ax.set_yticks([]) # No ticks ax.patch.set_visible(False) # No background ax.set_aspect(1) ax.set_xlim((xmin, xmax)) ax.set_ylim((ymin, ymax)) ax.set_position([x_ratio, y_ratio, 1 - 2 * x_ratio, 1 - 2 * y_ratio]) # Sync re-draw to proper paint on form resize self.canvas.draw() # #### Temporary place-holder for cached update ##### self.update_screen_request.emit([0, 0, 0, 0, 0]) def auto_adjust_axes(self, *args): """ Calls ``adjust_axes()`` using the extents of the base axes. :rtype : None :return: None """ xmin, xmax = self.axes.get_xlim() ymin, ymax = self.axes.get_ylim() self.adjust_axes(xmin, ymin, xmax, ymax) def fit_view(self): self.auto_adjust_axes() def zoom(self, factor, center=None): """ Zooms the plot by factor around a given center point. Takes care of re-drawing. :param factor: Number by which to scale the plot. :type factor: float :param center: Coordinates [x, y] of the point around which to scale the plot. :type center: list :return: None """ factor = 1 / factor xmin, xmax = self.axes.get_xlim() ymin, ymax = self.axes.get_ylim() width = xmax - xmin height = ymax - ymin if center is None or center == [None, None]: center = [(xmin + xmax) / 2.0, (ymin + ymax) / 2.0] # For keeping the point at the pointer location relx = (xmax - center[0]) / width rely = (ymax - center[1]) / height new_width = width / factor new_height = height / factor xmin = center[0] - new_width * (1 - relx) xmax = center[0] + new_width * relx ymin = center[1] - new_height * (1 - rely) ymax = center[1] + new_height * rely # Adjust axes for ax in self.figure.get_axes(): ax.set_xlim((xmin, xmax)) ax.set_ylim((ymin, ymax)) # Async re-draw self.canvas.draw_idle() # #### Temporary place-holder for cached update ##### self.update_screen_request.emit([0, 0, 0, 0, 0]) def pan(self, x, y): xmin, xmax = self.axes.get_xlim() ymin, ymax = self.axes.get_ylim() width = xmax - xmin height = ymax - ymin # Adjust axes for ax in self.figure.get_axes(): ax.set_xlim((xmin + x * width, xmax + x * width)) ax.set_ylim((ymin + y * height, ymax + y * height)) # Re-draw self.canvas.draw_idle() # #### Temporary place-holder for cached update ##### self.update_screen_request.emit([0, 0, 0, 0, 0]) def new_axes(self, name): """ Creates and returns an Axes object attached to this object's Figure. :param name: Unique label for the axes. :return: Axes attached to the figure. :rtype: Axes """ return self.figure.add_axes([0.05, 0.05, 0.9, 0.9], label=name) def on_scroll(self, event): """ Scroll event handler. :param event: Event object containing the event information. :return: None """ # So it can receive key presses # self.canvas.grab_focus() self.canvas.setFocus() # Event info # z, direction = event.get_scroll_direction() if self.key is None: if event.button == 'up': self.zoom(1 / 1.5, self.mouse) else: self.zoom(1.5, self.mouse) return if self.key == 'shift': if event.button == 'up': self.pan(0.3, 0) else: self.pan(-0.3, 0) return if self.key == 'control': if event.button == 'up': self.pan(0, 0.3) else: self.pan(0, -0.3) return def on_mouse_press(self, event): self.is_dragging = True # Check for middle mouse button press if self.app.defaults["global_pan_button"] == '2': pan_button = 3 # right button for Matplotlib else: pan_button = 2 # middle button for Matplotlib if event.button == pan_button: # Prepare axes for pan (using 'matplotlib' pan function) self.pan_axes = [] for a in self.figure.get_axes(): if (event.x is not None and event.y is not None and a.in_axes(event) and a.get_navigate() and a.can_pan()): a.start_pan(event.x, event.y, 1) self.pan_axes.append(a) # Set pan view flag if len(self.pan_axes) > 0: self.panning = True if event.dblclick: self.double_click.emit(event) def on_mouse_release(self, event): self.is_dragging = False # Check for middle mouse button release to complete pan procedure # Check for middle mouse button press if self.app.defaults["global_pan_button"] == '2': pan_button = 3 # right button for Matplotlib else: pan_button = 2 # middle button for Matplotlib if event.button == pan_button: for a in self.pan_axes: a.end_pan() # Clear pan flag self.panning = False def on_mouse_move(self, event): """ Mouse movement event hadler. Stores the coordinates. Updates view on pan. :param event: Contains information about the event. :return: None """ try: x = float(event.xdata) y = float(event.ydata) except TypeError: return self.mouse = [event.xdata, event.ydata] self.canvas.restore_region(self.background) # Update pan view on mouse move if self.panning is True: # x_pan, y_pan = self.app.geo_editor.snap(event.xdata, event.ydata) # self.app.app_cursor.set_data(event, (x_pan, y_pan)) for a in self.pan_axes: a.drag_pan(1, event.key, event.x, event.y) # Async re-draw (redraws only on thread idle state, uses timer on backend) self.canvas.draw_idle() # #### Temporary place-holder for cached update ##### self.update_screen_request.emit([0, 0, 0, 0, 0]) x, y = self.app.geo_editor.snap(x, y) if self.app.app_cursor.enabled is True: # Pointer (snapped) elements = self.axes.plot(x, y, 'k+', ms=40, mew=2, animated=True) for el in elements: self.axes.draw_artist(el) self.canvas.blit(self.axes.bbox) def translate_coords(self, position): """ This does not do much. It's just for code compatibility :param position: Mouse event position :return: Tuple with mouse position """ return (position[0], position[1]) def on_draw(self, renderer): # Store background on canvas redraw self.background = self.canvas.copy_from_bbox(self.axes.bbox) def get_axes_pixelsize(self): """ Axes size in pixels. :return: Pixel width and height :rtype: tuple """ bbox = self.axes.get_window_extent().transformed(self.figure.dpi_scale_trans.inverted()) width, height = bbox.width, bbox.height width *= self.figure.dpi height *= self.figure.dpi return width, height def get_density(self): """ Returns unit length per pixel on horizontal and vertical axes. :return: X and Y density :rtype: tuple """ xpx, ypx = self.get_axes_pixelsize() xmin, xmax = self.axes.get_xlim() ymin, ymax = self.axes.get_ylim() width = xmax - xmin height = ymax - ymin return width / xpx, height / ypx class FakeCursor: """ This is a fake cursor to ensure compatibility with the OpenGL engine (VisPy). This way I don't have to chane (disable) things related to the cursor all over when using the low performance Matplotlib 2D graphic engine. """ def __init__(self): self._enabled = True @property def enabled(self): return True if self._enabled else False @enabled.setter def enabled(self, value): self._enabled = value def set_data(self, pos, **kwargs): """Internal event handler to draw the cursor when the mouse moves.""" pass class MplCursor(Cursor): """ Unfortunately this gets attached to the current axes and if a new axes is added it will not be showed until that axes is deleted. Not the kind of behavior needed here so I don't use it anymore. """ def __init__(self, axes, color='red', linewidth=1): super().__init__(ax=axes, useblit=True, color=color, linewidth=linewidth) self._enabled = True self.axes = axes self.color = color self.linewidth = linewidth self.x = None self.y = None @property def enabled(self): return True if self._enabled else False @enabled.setter def enabled(self, value): self._enabled = value self.visible = self._enabled self.canvas.draw() def onmove(self, event): pass def set_data(self, event, pos): """Internal event handler to draw the cursor when the mouse moves.""" self.x = pos[0] self.y = pos[1] if self.ignore(event): return if not self.canvas.widgetlock.available(self): return if event.inaxes != self.ax: self.linev.set_visible(False) self.lineh.set_visible(False) if self.needclear: self.canvas.draw() self.needclear = False return self.needclear = True if not self.visible: return self.linev.set_xdata((self.x, self.x)) self.lineh.set_ydata((self.y, self.y)) self.linev.set_visible(self.visible and self.vertOn) self.lineh.set_visible(self.visible and self.horizOn) self._update() class ShapeCollectionLegacy: """ This will create the axes for each collection of shapes and will also hold the collection of shapes into a dict self._shapes. This handles the shapes redraw on canvas. """ def __init__(self, obj, app, name=None, annotation_job=None): """ :param obj: this is the object to which the shapes collection is attached and for which it will have to draw shapes :param app: this is the FLatCAM.App usually, needed because we have to access attributes there :param name: this is the name given to the Matplotlib axes; it needs to be unique due of Matplotlib requurements :param annotation_job: make this True if the job needed is just for annotation """ self.obj = obj self.app = app self.annotation_job = annotation_job self._shapes = dict() self.shape_dict = dict() self.shape_id = 0 self._color = None self._face_color = None self._visible = True self._update = False self._alpha = None self._tool_tolerance = None self._tooldia = None self._obj = None self._gcode_parsed = None if name is None: axes_name = self.obj.options['name'] else: axes_name = name # Axes must exist and be attached to canvas. if axes_name not in self.app.plotcanvas.figure.axes: self.axes = self.app.plotcanvas.new_axes(axes_name) def add(self, shape=None, color=None, face_color=None, alpha=None, visible=True, update=False, layer=1, tolerance=0.01, obj=None, gcode_parsed=None, tool_tolerance=None, tooldia=None): """ This function will add shapes to the shape collection :param shape: the Shapely shape to be added to the shape collection :param color: edge color of the shape, hex value :param face_color: the body color of the shape, hex value :param alpha: level of transparency of the shape [0.0 ... 1.0]; Float :param visible: if True will allow the shapes to be added :param update: not used; just for compatibility with VIsPy canvas :param layer: just for compatibility with VIsPy canvas :param tolerance: just for compatibility with VIsPy canvas :param obj: not used :param gcode_parsed: not used; just for compatibility with VIsPy canvas :param tool_tolerance: just for compatibility with VIsPy canvas :param tooldia: :return: """ self._color = color[:-2] if color is not None else None self._face_color = face_color[:-2] if face_color is not None else None self._alpha = int(face_color[-2:], 16) / 255 if face_color is not None else 0.75 if alpha is not None: self._alpha = alpha self._visible = visible self._update = update # CNCJob object related arguments self._obj = obj self._gcode_parsed = gcode_parsed self._tool_tolerance = tool_tolerance self._tooldia = tooldia # if self._update: # self.clear() try: for sh in shape: self.shape_id += 1 self.shape_dict.update({ 'color': self._color, 'face_color': self._face_color, 'alpha': self._alpha, 'shape': sh }) self._shapes.update({ self.shape_id: deepcopy(self.shape_dict) }) except TypeError: self.shape_id += 1 self.shape_dict.update({ 'color': self._color, 'face_color': self._face_color, 'alpha': self._alpha, 'shape': shape }) self._shapes.update({ self.shape_id: deepcopy(self.shape_dict) }) return self.shape_id def clear(self, update=None): """ Clear the canvas of the shapes. :param update: :return: None """ self._shapes.clear() self.shape_id = 0 self.axes.cla() self.app.plotcanvas.auto_adjust_axes() if update is True: self.redraw() def redraw(self): """ This draw the shapes in the shapes collection, on canvas :return: None """ path_num = 0 local_shapes = deepcopy(self._shapes) try: obj_type = self.obj.kind except AttributeError: obj_type = 'utility' if self._visible: for element in local_shapes: if obj_type == 'excellon': # Plot excellon (All polygons?) if self.obj.options["solid"] and isinstance(local_shapes[element]['shape'], Polygon): patch = PolygonPatch(local_shapes[element]['shape'], facecolor="#C40000", edgecolor="#750000", alpha=local_shapes[element]['alpha'], zorder=3) self.axes.add_patch(patch) else: x, y = local_shapes[element]['shape'].exterior.coords.xy self.axes.plot(x, y, 'r-') for ints in local_shapes[element]['shape'].interiors: x, y = ints.coords.xy self.axes.plot(x, y, 'o-') elif obj_type == 'geometry': if type(local_shapes[element]['shape']) == Polygon: x, y = local_shapes[element]['shape'].exterior.coords.xy self.axes.plot(x, y, local_shapes[element]['color'], linestyle='-') for ints in local_shapes[element]['shape'].interiors: x, y = ints.coords.xy self.axes.plot(x, y, local_shapes[element]['color'], linestyle='-') elif type(local_shapes[element]['shape']) == LineString or \ type(local_shapes[element]['shape']) == LinearRing: x, y = local_shapes[element]['shape'].coords.xy self.axes.plot(x, y, local_shapes[element]['color'], linestyle='-') elif obj_type == 'gerber': if self.obj.options["multicolored"]: linespec = '-' else: linespec = 'k-' if self.obj.options["solid"]: try: patch = PolygonPatch(local_shapes[element]['shape'], facecolor=local_shapes[element]['face_color'], edgecolor=local_shapes[element]['color'], alpha=local_shapes[element]['alpha'], zorder=2) self.axes.add_patch(patch) except AssertionError: FlatCAMApp.App.log.warning("A geometry component was not a polygon:") FlatCAMApp.App.log.warning(str(element)) else: x, y = local_shapes[element]['shape'].exterior.xy self.axes.plot(x, y, linespec) for ints in local_shapes[element]['shape'].interiors: x, y = ints.coords.xy self.axes.plot(x, y, linespec) elif obj_type == 'cncjob': if local_shapes[element]['face_color'] is None: linespec = '--' linecolor = local_shapes[element]['color'] # if geo['kind'][0] == 'C': # linespec = 'k-' x, y = local_shapes[element]['shape'].coords.xy self.axes.plot(x, y, linespec, color=linecolor) else: path_num += 1 if isinstance(local_shapes[element]['shape'], Polygon): self.axes.annotate(str(path_num), xy=local_shapes[element]['shape'].exterior.coords[0], xycoords='data', fontsize=20) else: self.axes.annotate(str(path_num), xy=local_shapes[element]['shape'].coords[0], xycoords='data', fontsize=20) patch = PolygonPatch(local_shapes[element]['shape'], facecolor=local_shapes[element]['face_color'], edgecolor=local_shapes[element]['color'], alpha=local_shapes[element]['alpha'], zorder=2) self.axes.add_patch(patch) elif obj_type == 'utility': # not a FlatCAM object, must be utility if local_shapes[element]['face_color']: try: patch = PolygonPatch(local_shapes[element]['shape'], facecolor=local_shapes[element]['face_color'], edgecolor=local_shapes[element]['color'], alpha=local_shapes[element]['alpha'], zorder=2) self.axes.add_patch(patch) except Exception as e: log.debug("ShapeCollectionLegacy.redraw() --> %s" % str(e)) else: if isinstance(local_shapes[element]['shape'], Polygon): x, y = local_shapes[element]['shape'].exterior.xy self.axes.plot(x, y, local_shapes[element]['color'], linestyle='-') for ints in local_shapes[element]['shape'].interiors: x, y = ints.coords.xy self.axes.plot(x, y, local_shapes[element]['color'], linestyle='-') else: x, y = local_shapes[element]['shape'].coords.xy self.axes.plot(x, y, local_shapes[element]['color'], linestyle='-') self.app.plotcanvas.auto_adjust_axes() def set(self, text, pos, visible=True, font_size=16, color=None): """ This will set annotations on the canvas. :param text: a list of text elements to be used as annotations :param pos: a list of positions for showing the text elements above :param visible: if True will display annotations, if False will clear them on canvas :param font_size: the font size or the annotations :param color: color of the annotations :return: None """ if color is None: color = "#000000FF" if visible is not True: self.clear() return if len(text) != len(pos): self.app.inform.emit('[ERROR_NOTCL] %s' % _("Could not annotate due of a difference between the number " "of text elements and the number of text positions.")) return for idx in range(len(text)): try: self.axes.annotate(text[idx], xy=pos[idx], xycoords='data', fontsize=font_size, color=color) except Exception as e: log.debug("ShapeCollectionLegacy.set() --> %s" % str(e)) self.app.plotcanvas.auto_adjust_axes() @property def visible(self): return self._visible @visible.setter def visible(self, value): if value is False: self.axes.cla() self.app.plotcanvas.auto_adjust_axes() else: if self._visible is False: self.redraw() self._visible = value @property def enabled(self): return self._visible @enabled.setter def enabled(self, value): if value is False: self.axes.cla() self.app.plotcanvas.auto_adjust_axes() else: if self._visible is False: self.redraw() self._visible = value