""" Abstract base classes define the primitives that renderers and graphics contexts must implement to serve as a matplotlib backend :class:`RendererBase` An abstract base class to handle drawing/rendering operations. :class:`FigureCanvasBase` The abstraction layer that separates the :class:`matplotlib.figure.Figure` from the backend specific details like a user interface drawing area :class:`GraphicsContextBase` An abstract base class that provides color, line styles, etc... :class:`Event` The base class for all of the matplotlib event handling. Derived classes such as :class:`KeyEvent` and :class:`MouseEvent` store the meta data like keys and buttons pressed, x and y locations in pixel and :class:`~matplotlib.axes.Axes` coordinates. :class:`ShowBase` The base class for the Show class of each interactive backend; the 'show' callable is then set to Show.__call__, inherited from ShowBase. :class:`ToolContainerBase` The base class for the Toolbar class of each interactive backend. :class:`StatusbarBase` The base class for the messaging area. """ from contextlib import contextmanager from enum import IntEnum import functools import importlib import io import logging import os import sys import time from weakref import WeakKeyDictionary import numpy as np import matplotlib as mpl from matplotlib import ( backend_tools as tools, cbook, colors, textpath, tight_bbox, transforms, widgets, get_backend, is_interactive, rcParams) from matplotlib._pylab_helpers import Gcf from matplotlib.transforms import Affine2D from matplotlib.path import Path try: from PIL import PILLOW_VERSION from distutils.version import LooseVersion if LooseVersion(PILLOW_VERSION) >= "3.4": _has_pil = True else: _has_pil = False del PILLOW_VERSION except ImportError: _has_pil = False _log = logging.getLogger(__name__) _default_filetypes = { 'ps': 'Postscript', 'eps': 'Encapsulated Postscript', 'pdf': 'Portable Document Format', 'pgf': 'PGF code for LaTeX', 'png': 'Portable Network Graphics', 'raw': 'Raw RGBA bitmap', 'rgba': 'Raw RGBA bitmap', 'svg': 'Scalable Vector Graphics', 'svgz': 'Scalable Vector Graphics' } _default_backends = { 'ps': 'matplotlib.backends.backend_ps', 'eps': 'matplotlib.backends.backend_ps', 'pdf': 'matplotlib.backends.backend_pdf', 'pgf': 'matplotlib.backends.backend_pgf', 'png': 'matplotlib.backends.backend_agg', 'raw': 'matplotlib.backends.backend_agg', 'rgba': 'matplotlib.backends.backend_agg', 'svg': 'matplotlib.backends.backend_svg', 'svgz': 'matplotlib.backends.backend_svg', } def register_backend(format, backend, description=None): """ Register a backend for saving to a given file format. Parameters ---------- format : str File extension backend : module string or canvas class Backend for handling file output description : str, optional Description of the file type. Defaults to an empty string """ if description is None: description = '' _default_backends[format] = backend _default_filetypes[format] = description def get_registered_canvas_class(format): """ Return the registered default canvas for given file format. Handles deferred import of required backend. """ if format not in _default_backends: return None backend_class = _default_backends[format] if isinstance(backend_class, str): backend_class = importlib.import_module(backend_class).FigureCanvas _default_backends[format] = backend_class return backend_class class RendererBase(object): """An abstract base class to handle drawing/rendering operations. The following methods must be implemented in the backend for full functionality (though just implementing :meth:`draw_path` alone would give a highly capable backend): * :meth:`draw_path` * :meth:`draw_image` * :meth:`draw_gouraud_triangle` The following methods *should* be implemented in the backend for optimization reasons: * :meth:`draw_text` * :meth:`draw_markers` * :meth:`draw_path_collection` * :meth:`draw_quad_mesh` """ def __init__(self): self._texmanager = None self._text2path = textpath.TextToPath() def open_group(self, s, gid=None): """ Open a grouping element with label *s* and *gid* (if set) as id. Only used by the SVG renderer. """ def close_group(self, s): """ Close a grouping element with label *s* Only used by the SVG renderer. """ def draw_path(self, gc, path, transform, rgbFace=None): """ Draws a :class:`~matplotlib.path.Path` instance using the given affine transform. """ raise NotImplementedError def draw_markers(self, gc, marker_path, marker_trans, path, trans, rgbFace=None): """ Draws a marker at each of the vertices in path. This includes all vertices, including control points on curves. To avoid that behavior, those vertices should be removed before calling this function. This provides a fallback implementation of draw_markers that makes multiple calls to :meth:`draw_path`. Some backends may want to override this method in order to draw the marker only once and reuse it multiple times. Parameters ---------- gc : `GraphicsContextBase` The graphics context marker_trans : `matplotlib.transforms.Transform` An affine transform applied to the marker. trans : `matplotlib.transforms.Transform` An affine transform applied to the path. """ for vertices, codes in path.iter_segments(trans, simplify=False): if len(vertices): x, y = vertices[-2:] self.draw_path(gc, marker_path, marker_trans + transforms.Affine2D().translate(x, y), rgbFace) def draw_path_collection(self, gc, master_transform, paths, all_transforms, offsets, offsetTrans, facecolors, edgecolors, linewidths, linestyles, antialiaseds, urls, offset_position): """ Draws a collection of paths selecting drawing properties from the lists *facecolors*, *edgecolors*, *linewidths*, *linestyles* and *antialiaseds*. *offsets* is a list of offsets to apply to each of the paths. The offsets in *offsets* are first transformed by *offsetTrans* before being applied. *offset_position* may be either "screen" or "data" depending on the space that the offsets are in. This provides a fallback implementation of :meth:`draw_path_collection` that makes multiple calls to :meth:`draw_path`. Some backends may want to override this in order to render each set of path data only once, and then reference that path multiple times with the different offsets, colors, styles etc. The generator methods :meth:`_iter_collection_raw_paths` and :meth:`_iter_collection` are provided to help with (and standardize) the implementation across backends. It is highly recommended to use those generators, so that changes to the behavior of :meth:`draw_path_collection` can be made globally. """ path_ids = [ (path, transforms.Affine2D(transform)) for path, transform in self._iter_collection_raw_paths( master_transform, paths, all_transforms)] for xo, yo, path_id, gc0, rgbFace in self._iter_collection( gc, master_transform, all_transforms, path_ids, offsets, offsetTrans, facecolors, edgecolors, linewidths, linestyles, antialiaseds, urls, offset_position): path, transform = path_id transform = transforms.Affine2D( transform.get_matrix()).translate(xo, yo) self.draw_path(gc0, path, transform, rgbFace) def draw_quad_mesh(self, gc, master_transform, meshWidth, meshHeight, coordinates, offsets, offsetTrans, facecolors, antialiased, edgecolors): """ This provides a fallback implementation of :meth:`draw_quad_mesh` that generates paths and then calls :meth:`draw_path_collection`. """ from matplotlib.collections import QuadMesh paths = QuadMesh.convert_mesh_to_paths( meshWidth, meshHeight, coordinates) if edgecolors is None: edgecolors = facecolors linewidths = np.array([gc.get_linewidth()], float) return self.draw_path_collection( gc, master_transform, paths, [], offsets, offsetTrans, facecolors, edgecolors, linewidths, [], [antialiased], [None], 'screen') def draw_gouraud_triangle(self, gc, points, colors, transform): """ Draw a Gouraud-shaded triangle. Parameters ---------- points : array_like, shape=(3, 2) Array of (x, y) points for the triangle. colors : array_like, shape=(3, 4) RGBA colors for each point of the triangle. transform : `matplotlib.transforms.Transform` An affine transform to apply to the points. """ raise NotImplementedError def draw_gouraud_triangles(self, gc, triangles_array, colors_array, transform): """ Draws a series of Gouraud triangles. Parameters ---------- points : array_like, shape=(N, 3, 2) Array of *N* (x, y) points for the triangles. colors : array_like, shape=(N, 3, 4) Array of *N* RGBA colors for each point of the triangles. transform : `matplotlib.transforms.Transform` An affine transform to apply to the points. """ transform = transform.frozen() for tri, col in zip(triangles_array, colors_array): self.draw_gouraud_triangle(gc, tri, col, transform) def _iter_collection_raw_paths(self, master_transform, paths, all_transforms): """ This is a helper method (along with :meth:`_iter_collection`) to make it easier to write a space-efficient :meth:`draw_path_collection` implementation in a backend. This method yields all of the base path/transform combinations, given a master transform, a list of paths and list of transforms. The arguments should be exactly what is passed in to :meth:`draw_path_collection`. The backend should take each yielded path and transform and create an object that can be referenced (reused) later. """ Npaths = len(paths) Ntransforms = len(all_transforms) N = max(Npaths, Ntransforms) if Npaths == 0: return transform = transforms.IdentityTransform() for i in range(N): path = paths[i % Npaths] if Ntransforms: transform = Affine2D(all_transforms[i % Ntransforms]) yield path, transform + master_transform def _iter_collection_uses_per_path(self, paths, all_transforms, offsets, facecolors, edgecolors): """ Compute how many times each raw path object returned by _iter_collection_raw_paths would be used when calling _iter_collection. This is intended for the backend to decide on the tradeoff between using the paths in-line and storing them once and reusing. Rounds up in case the number of uses is not the same for every path. """ Npaths = len(paths) if Npaths == 0 or len(facecolors) == len(edgecolors) == 0: return 0 Npath_ids = max(Npaths, len(all_transforms)) N = max(Npath_ids, len(offsets)) return (N + Npath_ids - 1) // Npath_ids def _iter_collection(self, gc, master_transform, all_transforms, path_ids, offsets, offsetTrans, facecolors, edgecolors, linewidths, linestyles, antialiaseds, urls, offset_position): """ This is a helper method (along with :meth:`_iter_collection_raw_paths`) to make it easier to write a space-efficient :meth:`draw_path_collection` implementation in a backend. This method yields all of the path, offset and graphics context combinations to draw the path collection. The caller should already have looped over the results of :meth:`_iter_collection_raw_paths` to draw this collection. The arguments should be the same as that passed into :meth:`draw_path_collection`, with the exception of *path_ids*, which is a list of arbitrary objects that the backend will use to reference one of the paths created in the :meth:`_iter_collection_raw_paths` stage. Each yielded result is of the form:: xo, yo, path_id, gc, rgbFace where *xo*, *yo* is an offset; *path_id* is one of the elements of *path_ids*; *gc* is a graphics context and *rgbFace* is a color to use for filling the path. """ Ntransforms = len(all_transforms) Npaths = len(path_ids) Noffsets = len(offsets) N = max(Npaths, Noffsets) Nfacecolors = len(facecolors) Nedgecolors = len(edgecolors) Nlinewidths = len(linewidths) Nlinestyles = len(linestyles) Naa = len(antialiaseds) Nurls = len(urls) if (Nfacecolors == 0 and Nedgecolors == 0) or Npaths == 0: return if Noffsets: toffsets = offsetTrans.transform(offsets) gc0 = self.new_gc() gc0.copy_properties(gc) if Nfacecolors == 0: rgbFace = None if Nedgecolors == 0: gc0.set_linewidth(0.0) xo, yo = 0, 0 for i in range(N): path_id = path_ids[i % Npaths] if Noffsets: xo, yo = toffsets[i % Noffsets] if offset_position == 'data': if Ntransforms: transform = ( Affine2D(all_transforms[i % Ntransforms]) + master_transform) else: transform = master_transform xo, yo = transform.transform_point((xo, yo)) xp, yp = transform.transform_point((0, 0)) xo = -(xp - xo) yo = -(yp - yo) if not (np.isfinite(xo) and np.isfinite(yo)): continue if Nfacecolors: rgbFace = facecolors[i % Nfacecolors] if Nedgecolors: if Nlinewidths: gc0.set_linewidth(linewidths[i % Nlinewidths]) if Nlinestyles: gc0.set_dashes(*linestyles[i % Nlinestyles]) fg = edgecolors[i % Nedgecolors] if len(fg) == 4: if fg[3] == 0.0: gc0.set_linewidth(0) else: gc0.set_foreground(fg) else: gc0.set_foreground(fg) if rgbFace is not None and len(rgbFace) == 4: if rgbFace[3] == 0: rgbFace = None gc0.set_antialiased(antialiaseds[i % Naa]) if Nurls: gc0.set_url(urls[i % Nurls]) yield xo, yo, path_id, gc0, rgbFace gc0.restore() def get_image_magnification(self): """ Get the factor by which to magnify images passed to :meth:`draw_image`. Allows a backend to have images at a different resolution to other artists. """ return 1.0 def draw_image(self, gc, x, y, im, transform=None): """ Draw an RGBA image. Parameters ---------- gc : `GraphicsContextBase` a graphics context with clipping information. x : scalar the distance in physical units (i.e., dots or pixels) from the left hand side of the canvas. y : scalar the distance in physical units (i.e., dots or pixels) from the bottom side of the canvas. im : array_like, shape=(N, M, 4), dtype=np.uint8 An array of RGBA pixels. transform : `matplotlib.transforms.Affine2DBase` If and only if the concrete backend is written such that :meth:`option_scale_image` returns ``True``, an affine transformation *may* be passed to :meth:`draw_image`. It takes the form of a :class:`~matplotlib.transforms.Affine2DBase` instance. The translation vector of the transformation is given in physical units (i.e., dots or pixels). Note that the transformation does not override `x` and `y`, and has to be applied *before* translating the result by `x` and `y` (this can be accomplished by adding `x` and `y` to the translation vector defined by `transform`). """ raise NotImplementedError def option_image_nocomposite(self): """ Return whether image composition by Matplotlib should be skipped. Raster backends should usually return False (letting the C-level rasterizer take care of image composition); vector backends should usually return ``not rcParams["image.composite_image"]``. """ return False def option_scale_image(self): """ Return whether arbitrary affine transformations in :meth:`draw_image` are supported (True for most vector backends). """ return False def draw_tex(self, gc, x, y, s, prop, angle, ismath='TeX!', mtext=None): """ """ self._draw_text_as_path(gc, x, y, s, prop, angle, ismath="TeX") def draw_text(self, gc, x, y, s, prop, angle, ismath=False, mtext=None): """ Draw the text instance. Parameters ---------- gc : `GraphicsContextBase` The graphics context. x : scalar The x location of the text in display coords. y : scalar The y location of the text baseline in display coords. s : str The text string. prop : `matplotlib.font_manager.FontProperties` The font properties. angle : scalar The rotation angle in degrees. mtext : `matplotlib.text.Text` The original text object to be rendered. Notes ----- **backend implementers note** When you are trying to determine if you have gotten your bounding box right (which is what enables the text layout/alignment to work properly), it helps to change the line in text.py:: if 0: bbox_artist(self, renderer) to if 1, and then the actual bounding box will be plotted along with your text. """ self._draw_text_as_path(gc, x, y, s, prop, angle, ismath) def _get_text_path_transform(self, x, y, s, prop, angle, ismath): """ Return the text path and transform. Parameters ---------- prop : `matplotlib.font_manager.FontProperties` The font property. s : str The text to be converted. ismath : bool or "TeX" If True, use mathtext parser. If "TeX", use *usetex* mode. """ text2path = self._text2path fontsize = self.points_to_pixels(prop.get_size_in_points()) verts, codes = text2path.get_text_path(prop, s, ismath=ismath) path = Path(verts, codes) angle = np.deg2rad(angle) if self.flipy(): transform = Affine2D().scale(fontsize / text2path.FONT_SCALE, fontsize / text2path.FONT_SCALE) transform = transform.rotate(angle).translate(x, self.height - y) else: transform = Affine2D().scale(fontsize / text2path.FONT_SCALE, fontsize / text2path.FONT_SCALE) transform = transform.rotate(angle).translate(x, y) return path, transform def _draw_text_as_path(self, gc, x, y, s, prop, angle, ismath): """ Draw the text by converting them to paths using textpath module. Parameters ---------- prop : `matplotlib.font_manager.FontProperties` The font property. s : str The text to be converted. usetex : bool Whether to use matplotlib usetex mode. ismath : bool or "TeX" If True, use mathtext parser. If "TeX", use *usetex* mode. """ path, transform = self._get_text_path_transform( x, y, s, prop, angle, ismath) color = gc.get_rgb() gc.set_linewidth(0.0) self.draw_path(gc, path, transform, rgbFace=color) def get_text_width_height_descent(self, s, prop, ismath): """ Get the width, height, and descent (offset from the bottom to the baseline), in display coords, of the string *s* with :class:`~matplotlib.font_manager.FontProperties` *prop* """ if ismath == 'TeX': # todo: handle props texmanager = self._text2path.get_texmanager() fontsize = prop.get_size_in_points() w, h, d = texmanager.get_text_width_height_descent( s, fontsize, renderer=self) return w, h, d dpi = self.points_to_pixels(72) if ismath: dims = self._text2path.mathtext_parser.parse(s, dpi, prop) return dims[0:3] # return width, height, descent flags = self._text2path._get_hinting_flag() font = self._text2path._get_font(prop) size = prop.get_size_in_points() font.set_size(size, dpi) # the width and height of unrotated string font.set_text(s, 0.0, flags=flags) w, h = font.get_width_height() d = font.get_descent() w /= 64.0 # convert from subpixels h /= 64.0 d /= 64.0 return w, h, d def flipy(self): """ Return whether y values increase from top to bottom. Note that this only affects drawing of texts and images. """ return True def get_canvas_width_height(self): """Return the canvas width and height in display coords.""" return 1, 1 def get_texmanager(self): """Return the `.TexManager` instance.""" if self._texmanager is None: from matplotlib.texmanager import TexManager self._texmanager = TexManager() return self._texmanager def new_gc(self): """Return an instance of a `GraphicsContextBase`.""" return GraphicsContextBase() def points_to_pixels(self, points): """ Convert points to display units. You need to override this function (unless your backend doesn't have a dpi, e.g., postscript or svg). Some imaging systems assume some value for pixels per inch:: points to pixels = points * pixels_per_inch/72.0 * dpi/72.0 Parameters ---------- points : scalar or array_like a float or a numpy array of float Returns ------- Points converted to pixels """ return points @cbook.deprecated("3.1", alternative="cbook.strip_math") def strip_math(self, s): return cbook.strip_math(s) def start_rasterizing(self): """ Switch to the raster renderer. Used by `MixedModeRenderer`. """ def stop_rasterizing(self): """ Switch back to the vector renderer and draw the contents of the raster renderer as an image on the vector renderer. Used by `MixedModeRenderer`. """ def start_filter(self): """ Switch to a temporary renderer for image filtering effects. Currently only supported by the agg renderer. """ def stop_filter(self, filter_func): """ Switch back to the original renderer. The contents of the temporary renderer is processed with the *filter_func* and is drawn on the original renderer as an image. Currently only supported by the agg renderer. """ class GraphicsContextBase(object): """An abstract base class that provides color, line styles, etc.""" def __init__(self): self._alpha = 1.0 self._forced_alpha = False # if True, _alpha overrides A from RGBA self._antialiased = 1 # use 0,1 not True, False for extension code self._capstyle = 'butt' self._cliprect = None self._clippath = None self._dashes = None, None self._joinstyle = 'round' self._linestyle = 'solid' self._linewidth = 1 self._rgb = (0.0, 0.0, 0.0, 1.0) self._hatch = None self._hatch_color = colors.to_rgba(rcParams['hatch.color']) self._hatch_linewidth = rcParams['hatch.linewidth'] self._url = None self._gid = None self._snap = None self._sketch = None def copy_properties(self, gc): 'Copy properties from gc to self' self._alpha = gc._alpha self._forced_alpha = gc._forced_alpha self._antialiased = gc._antialiased self._capstyle = gc._capstyle self._cliprect = gc._cliprect self._clippath = gc._clippath self._dashes = gc._dashes self._joinstyle = gc._joinstyle self._linestyle = gc._linestyle self._linewidth = gc._linewidth self._rgb = gc._rgb self._hatch = gc._hatch self._hatch_color = gc._hatch_color self._hatch_linewidth = gc._hatch_linewidth self._url = gc._url self._gid = gc._gid self._snap = gc._snap self._sketch = gc._sketch def restore(self): """ Restore the graphics context from the stack - needed only for backends that save graphics contexts on a stack. """ def get_alpha(self): """ Return the alpha value used for blending - not supported on all backends. """ return self._alpha def get_antialiased(self): "Return whether the object should try to do antialiased rendering." return self._antialiased def get_capstyle(self): """ Return the capstyle as a string in ('butt', 'round', 'projecting'). """ return self._capstyle def get_clip_rectangle(self): """ Return the clip rectangle as a `~matplotlib.transforms.Bbox` instance. """ return self._cliprect def get_clip_path(self): """ Return the clip path in the form (path, transform), where path is a :class:`~matplotlib.path.Path` instance, and transform is an affine transform to apply to the path before clipping. """ if self._clippath is not None: return self._clippath.get_transformed_path_and_affine() return None, None def get_dashes(self): """ Return the dash information as an offset dashlist tuple. The dash list is a even size list that gives the ink on, ink off in pixels. See p107 of to PostScript `BLUEBOOK `_ for more info. Default value is None """ return self._dashes def get_forced_alpha(self): """ Return whether the value given by get_alpha() should be used to override any other alpha-channel values. """ return self._forced_alpha def get_joinstyle(self): """Return the line join style as one of ('miter', 'round', 'bevel').""" return self._joinstyle def get_linewidth(self): """Return the line width in points.""" return self._linewidth def get_rgb(self): """Return a tuple of three or four floats from 0-1.""" return self._rgb def get_url(self): """Return a url if one is set, None otherwise.""" return self._url def get_gid(self): """Return the object identifier if one is set, None otherwise.""" return self._gid def get_snap(self): """ Returns the snap setting, which can be: * True: snap vertices to the nearest pixel center * False: leave vertices as-is * None: (auto) If the path contains only rectilinear line segments, round to the nearest pixel center """ return self._snap def set_alpha(self, alpha): """ Set the alpha value used for blending - not supported on all backends. If ``alpha=None`` (the default), the alpha components of the foreground and fill colors will be used to set their respective transparencies (where applicable); otherwise, ``alpha`` will override them. """ if alpha is not None: self._alpha = alpha self._forced_alpha = True else: self._alpha = 1.0 self._forced_alpha = False self.set_foreground(self._rgb, isRGBA=True) def set_antialiased(self, b): """Set whether object should be drawn with antialiased rendering.""" # Use ints to make life easier on extension code trying to read the gc. self._antialiased = int(bool(b)) def set_capstyle(self, cs): """Set the capstyle to be one of ('butt', 'round', 'projecting').""" if cs in ('butt', 'round', 'projecting'): self._capstyle = cs else: raise ValueError('Unrecognized cap style. Found %s' % cs) def set_clip_rectangle(self, rectangle): """ Set the clip rectangle with sequence (left, bottom, width, height) """ self._cliprect = rectangle def set_clip_path(self, path): """ Set the clip path and transformation. Path should be a :class:`~matplotlib.transforms.TransformedPath` instance. """ if (path is not None and not isinstance(path, transforms.TransformedPath)): raise ValueError("Path should be a " "matplotlib.transforms.TransformedPath instance") self._clippath = path def set_dashes(self, dash_offset, dash_list): """ Set the dash style for the gc. Parameters ---------- dash_offset : float is the offset (usually 0). dash_list : array_like specifies the on-off sequence as points. ``(None, None)`` specifies a solid line """ if dash_list is not None: dl = np.asarray(dash_list) if np.any(dl < 0.0): raise ValueError( "All values in the dash list must be positive") self._dashes = dash_offset, dash_list def set_foreground(self, fg, isRGBA=False): """ Set the foreground color. Parameters ---------- fg : color isRGBA : bool If *fg* is known to be an ``(r, g, b, a)`` tuple, *isRGBA* can be set to True to improve performance. """ if self._forced_alpha and isRGBA: self._rgb = fg[:3] + (self._alpha,) elif self._forced_alpha: self._rgb = colors.to_rgba(fg, self._alpha) elif isRGBA: self._rgb = fg else: self._rgb = colors.to_rgba(fg) def set_joinstyle(self, js): """Set the join style to be one of ('miter', 'round', 'bevel').""" if js in ('miter', 'round', 'bevel'): self._joinstyle = js else: raise ValueError('Unrecognized join style. Found %s' % js) def set_linewidth(self, w): """Set the linewidth in points.""" self._linewidth = float(w) def set_url(self, url): """Set the url for links in compatible backends.""" self._url = url def set_gid(self, id): """Set the id.""" self._gid = id def set_snap(self, snap): """ Set the snap setting which may be: * True: snap vertices to the nearest pixel center * False: leave vertices as-is * None: (auto) If the path contains only rectilinear line segments, round to the nearest pixel center """ self._snap = snap def set_hatch(self, hatch): """Set the hatch style (for fills).""" self._hatch = hatch def get_hatch(self): """Get the current hatch style.""" return self._hatch def get_hatch_path(self, density=6.0): """Return a `Path` for the current hatch.""" hatch = self.get_hatch() if hatch is None: return None return Path.hatch(hatch, density) def get_hatch_color(self): """Get the hatch color.""" return self._hatch_color def set_hatch_color(self, hatch_color): """Set the hatch color.""" self._hatch_color = hatch_color def get_hatch_linewidth(self): """Get the hatch linewidth.""" return self._hatch_linewidth def get_sketch_params(self): """ Return the sketch parameters for the artist. Returns ------- sketch_params : tuple or `None` A 3-tuple with the following elements: * `scale`: The amplitude of the wiggle perpendicular to the source line. * `length`: The length of the wiggle along the line. * `randomness`: The scale factor by which the length is shrunken or expanded. May return `None` if no sketch parameters were set. """ return self._sketch def set_sketch_params(self, scale=None, length=None, randomness=None): """ Set the sketch parameters. Parameters ---------- scale : float, optional The amplitude of the wiggle perpendicular to the source line, in pixels. If scale is `None`, or not provided, no sketch filter will be provided. length : float, optional The length of the wiggle along the line, in pixels (default 128). randomness : float, optional The scale factor by which the length is shrunken or expanded (default 16). """ self._sketch = ( None if scale is None else (scale, length or 128., randomness or 16.)) class TimerBase(object): """ A base class for providing timer events, useful for things animations. Backends need to implement a few specific methods in order to use their own timing mechanisms so that the timer events are integrated into their event loops. Mandatory functions that must be implemented: * `_timer_start`: Contains backend-specific code for starting the timer * `_timer_stop`: Contains backend-specific code for stopping the timer Optional overrides: * `_timer_set_single_shot`: Code for setting the timer to single shot operating mode, if supported by the timer object. If not, the `Timer` class itself will store the flag and the `_on_timer` method should be overridden to support such behavior. * `_timer_set_interval`: Code for setting the interval on the timer, if there is a method for doing so on the timer object. * `_on_timer`: This is the internal function that any timer object should call, which will handle the task of running all callbacks that have been set. Attributes ---------- interval : scalar The time between timer events in milliseconds. Default is 1000 ms. single_shot : bool Boolean flag indicating whether this timer should operate as single shot (run once and then stop). Defaults to `False`. callbacks : List[Tuple[callable, Tuple, Dict]] Stores list of (func, args, kwargs) tuples that will be called upon timer events. This list can be manipulated directly, or the functions `add_callback` and `remove_callback` can be used. """ def __init__(self, interval=None, callbacks=None): #Initialize empty callbacks list and setup default settings if necssary if callbacks is None: self.callbacks = [] else: self.callbacks = callbacks[:] # Create a copy if interval is None: self._interval = 1000 else: self._interval = interval self._single = False # Default attribute for holding the GUI-specific timer object self._timer = None def __del__(self): """Need to stop timer and possibly disconnect timer.""" self._timer_stop() def start(self, interval=None): """ Start the timer object. Parameters ---------- interval : int, optional Timer interval in milliseconds; overrides a previously set interval if provided. """ if interval is not None: self._set_interval(interval) self._timer_start() def stop(self): """Stop the timer.""" self._timer_stop() def _timer_start(self): pass def _timer_stop(self): pass @property def interval(self): return self._interval @interval.setter def interval(self, interval): # Force to int since none of the backends actually support fractional # milliseconds, and some error or give warnings. interval = int(interval) self._interval = interval self._timer_set_interval() @property def single_shot(self): return self._single @single_shot.setter def single_shot(self, ss): self._single = ss self._timer_set_single_shot() def add_callback(self, func, *args, **kwargs): """ Register *func* to be called by timer when the event fires. Any additional arguments provided will be passed to *func*. This function returns *func*, which makes it possible to use it as a decorator. """ self.callbacks.append((func, args, kwargs)) return func def remove_callback(self, func, *args, **kwargs): """ Remove *func* from list of callbacks. *args* and *kwargs* are optional and used to distinguish between copies of the same function registered to be called with different arguments. This behavior is deprecated. In the future, `*args, **kwargs` won't be considered anymore; to keep a specific callback removable by itself, pass it to `add_callback` as a `functools.partial` object. """ if args or kwargs: cbook.warn_deprecated( "3.1", "In a future version, Timer.remove_callback will not " "take *args, **kwargs anymore, but remove all callbacks where " "the callable matches; to keep a specific callback removable " "by itself, pass it to add_callback as a functools.partial " "object.") self.callbacks.remove((func, args, kwargs)) else: funcs = [c[0] for c in self.callbacks] if func in funcs: self.callbacks.pop(funcs.index(func)) def _timer_set_interval(self): """Used to set interval on underlying timer object.""" def _timer_set_single_shot(self): """Used to set single shot on underlying timer object.""" def _on_timer(self): """ Runs all function that have been registered as callbacks. Functions can return False (or 0) if they should not be called any more. If there are no callbacks, the timer is automatically stopped. """ for func, args, kwargs in self.callbacks: ret = func(*args, **kwargs) # docstring above explains why we use `if ret == 0` here, # instead of `if not ret`. # This will also catch `ret == False` as `False == 0` # but does not annoy the linters # https://docs.python.org/3/library/stdtypes.html#boolean-values if ret == 0: self.callbacks.remove((func, args, kwargs)) if len(self.callbacks) == 0: self.stop() class Event(object): """ A matplotlib event. Attach additional attributes as defined in :meth:`FigureCanvasBase.mpl_connect`. The following attributes are defined and shown with their default values Attributes ---------- name : str the event name canvas : `FigureCanvasBase` the backend-specific canvas instance generating the event guiEvent the GUI event that triggered the matplotlib event """ def __init__(self, name, canvas, guiEvent=None): self.name = name self.canvas = canvas self.guiEvent = guiEvent class DrawEvent(Event): """ An event triggered by a draw operation on the canvas In most backends callbacks subscribed to this callback will be fired after the rendering is complete but before the screen is updated. Any extra artists drawn to the canvas's renderer will be reflected without an explicit call to ``blit``. .. warning :: Calling ``canvas.draw`` and ``canvas.blit`` in these callbacks may not be safe with all backends and may cause infinite recursion. In addition to the :class:`Event` attributes, the following event attributes are defined: Attributes ---------- renderer : `RendererBase` the renderer for the draw event """ def __init__(self, name, canvas, renderer): Event.__init__(self, name, canvas) self.renderer = renderer class ResizeEvent(Event): """ An event triggered by a canvas resize In addition to the :class:`Event` attributes, the following event attributes are defined: Attributes ---------- width : scalar width of the canvas in pixels height : scalar height of the canvas in pixels """ def __init__(self, name, canvas): Event.__init__(self, name, canvas) self.width, self.height = canvas.get_width_height() class CloseEvent(Event): """An event triggered by a figure being closed.""" class LocationEvent(Event): """ An event that has a screen location. The following additional attributes are defined and shown with their default values. In addition to the :class:`Event` attributes, the following event attributes are defined: Attributes ---------- x : scalar x position - pixels from left of canvas y : scalar y position - pixels from bottom of canvas inaxes : bool the :class:`~matplotlib.axes.Axes` instance if mouse is over axes xdata : scalar x coord of mouse in data coords ydata : scalar y coord of mouse in data coords """ lastevent = None # the last event that was triggered before this one def __init__(self, name, canvas, x, y, guiEvent=None): """ *x*, *y* in figure coords, 0,0 = bottom, left """ Event.__init__(self, name, canvas, guiEvent=guiEvent) # x position - pixels from left of canvas self.x = int(x) if x is not None else x # y position - pixels from right of canvas self.y = int(y) if y is not None else y self.inaxes = None # the Axes instance if mouse us over axes self.xdata = None # x coord of mouse in data coords self.ydata = None # y coord of mouse in data coords if x is None or y is None: # cannot check if event was in axes if no x,y info self._update_enter_leave() return if self.canvas.mouse_grabber is None: self.inaxes = self.canvas.inaxes((x, y)) else: self.inaxes = self.canvas.mouse_grabber if self.inaxes is not None: try: trans = self.inaxes.transData.inverted() xdata, ydata = trans.transform_point((x, y)) except ValueError: pass else: self.xdata = xdata self.ydata = ydata self._update_enter_leave() def _update_enter_leave(self): 'process the figure/axes enter leave events' if LocationEvent.lastevent is not None: last = LocationEvent.lastevent if last.inaxes != self.inaxes: # process axes enter/leave events try: if last.inaxes is not None: last.canvas.callbacks.process('axes_leave_event', last) except Exception: pass # See ticket 2901582. # I think this is a valid exception to the rule # against catching all exceptions; if anything goes # wrong, we simply want to move on and process the # current event. if self.inaxes is not None: self.canvas.callbacks.process('axes_enter_event', self) else: # process a figure enter event if self.inaxes is not None: self.canvas.callbacks.process('axes_enter_event', self) LocationEvent.lastevent = self class MouseButton(IntEnum): LEFT = 1 MIDDLE = 2 RIGHT = 3 BACK = 8 FORWARD = 9 class MouseEvent(LocationEvent): """ A mouse event ('button_press_event', 'button_release_event', 'scroll_event', 'motion_notify_event'). In addition to the :class:`Event` and :class:`LocationEvent` attributes, the following attributes are defined: Attributes ---------- button : {None, MouseButton.LEFT, MouseButton.MIDDLE, MouseButton.RIGHT, \ 'up', 'down'} The button pressed. 'up' and 'down' are used for scroll events. Note that in the nbagg backend, both the middle and right clicks return RIGHT since right clicking will bring up the context menu in some browsers. Note that LEFT and RIGHT actually refer to the "primary" and "secondary" buttons, i.e. if the user inverts their left and right buttons ("left-handed setting") then the LEFT button will be the one physically on the right. key : None or str The key pressed when the mouse event triggered, e.g. 'shift'. See `KeyEvent`. step : scalar The number of scroll steps (positive for 'up', negative for 'down'). This applies only to 'scroll_event' and defaults to 0 otherwise. dblclick : bool Whether the event is a double-click. This applies only to 'button_press_event' and is False otherwise. In particular, it's not used in 'button_release_event'. Examples -------- Usage:: def on_press(event): print('you pressed', event.button, event.xdata, event.ydata) cid = fig.canvas.mpl_connect('button_press_event', on_press) """ def __init__(self, name, canvas, x, y, button=None, key=None, step=0, dblclick=False, guiEvent=None): """ x, y in figure coords, 0,0 = bottom, left button pressed None, 1, 2, 3, 'up', 'down' """ LocationEvent.__init__(self, name, canvas, x, y, guiEvent=guiEvent) if button in MouseButton.__members__.values(): button = MouseButton(button) self.button = button self.key = key self.step = step self.dblclick = dblclick def __str__(self): return (f"{self.name}: " f"xy=({self.x}, {self.y}) xydata=({self.xdata}, {self.ydata}) " f"button={self.button} dblclick={self.dblclick} " f"inaxes={self.inaxes}") class PickEvent(Event): """ a pick event, fired when the user picks a location on the canvas sufficiently close to an artist. Attrs: all the :class:`Event` attributes plus Attributes ---------- mouseevent : `MouseEvent` the mouse event that generated the pick artist : `matplotlib.artist.Artist` the picked artist other extra class dependent attrs -- e.g., a :class:`~matplotlib.lines.Line2D` pick may define different extra attributes than a :class:`~matplotlib.collections.PatchCollection` pick event Examples -------- Usage:: ax.plot(np.rand(100), 'o', picker=5) # 5 points tolerance def on_pick(event): line = event.artist xdata, ydata = line.get_data() ind = event.ind print('on pick line:', np.array([xdata[ind], ydata[ind]]).T) cid = fig.canvas.mpl_connect('pick_event', on_pick) """ def __init__(self, name, canvas, mouseevent, artist, guiEvent=None, **kwargs): Event.__init__(self, name, canvas, guiEvent) self.mouseevent = mouseevent self.artist = artist self.__dict__.update(kwargs) class KeyEvent(LocationEvent): """ A key event (key press, key release). Attach additional attributes as defined in :meth:`FigureCanvasBase.mpl_connect`. In addition to the :class:`Event` and :class:`LocationEvent` attributes, the following attributes are defined: Attributes ---------- key : None or str the key(s) pressed. Could be **None**, a single case sensitive ascii character ("g", "G", "#", etc.), a special key ("control", "shift", "f1", "up", etc.) or a combination of the above (e.g., "ctrl+alt+g", "ctrl+alt+G"). Notes ----- Modifier keys will be prefixed to the pressed key and will be in the order "ctrl", "alt", "super". The exception to this rule is when the pressed key is itself a modifier key, therefore "ctrl+alt" and "alt+control" can both be valid key values. Examples -------- Usage:: def on_key(event): print('you pressed', event.key, event.xdata, event.ydata) cid = fig.canvas.mpl_connect('key_press_event', on_key) """ def __init__(self, name, canvas, key, x=0, y=0, guiEvent=None): LocationEvent.__init__(self, name, canvas, x, y, guiEvent=guiEvent) self.key = key def _is_non_interactive_terminal_ipython(ip): """ Return whether we are in a a terminal IPython, but non interactive. When in _terminal_ IPython, ip.parent will have and `interact` attribute, if this attribute is False we do not setup eventloop integration as the user will _not_ interact with IPython. In all other case (ZMQKernel, or is interactive), we do. """ return (hasattr(ip, 'parent') and (ip.parent is not None) and getattr(ip.parent, 'interact', None) is False) class FigureCanvasBase(object): """ The canvas the figure renders into. Public attributes Attributes ---------- figure : `matplotlib.figure.Figure` A high-level figure instance """ events = [ 'resize_event', 'draw_event', 'key_press_event', 'key_release_event', 'button_press_event', 'button_release_event', 'scroll_event', 'motion_notify_event', 'pick_event', 'idle_event', 'figure_enter_event', 'figure_leave_event', 'axes_enter_event', 'axes_leave_event', 'close_event' ] supports_blit = True fixed_dpi = None filetypes = _default_filetypes if _has_pil: # JPEG support register_backend('jpg', 'matplotlib.backends.backend_agg', 'Joint Photographic Experts Group') register_backend('jpeg', 'matplotlib.backends.backend_agg', 'Joint Photographic Experts Group') # TIFF support register_backend('tif', 'matplotlib.backends.backend_agg', 'Tagged Image File Format') register_backend('tiff', 'matplotlib.backends.backend_agg', 'Tagged Image File Format') def __init__(self, figure): self._fix_ipython_backend2gui() self._is_idle_drawing = True self._is_saving = False figure.set_canvas(self) self.figure = figure # a dictionary from event name to a dictionary that maps cid->func self.callbacks = cbook.CallbackRegistry() self.widgetlock = widgets.LockDraw() self._button = None # the button pressed self._key = None # the key pressed self._lastx, self._lasty = None, None self.button_pick_id = self.mpl_connect('button_press_event', self.pick) self.scroll_pick_id = self.mpl_connect('scroll_event', self.pick) self.mouse_grabber = None # the axes currently grabbing mouse self.toolbar = None # NavigationToolbar2 will set me self._is_idle_drawing = False @classmethod @functools.lru_cache() def _fix_ipython_backend2gui(cls): # Fix hard-coded module -> toolkit mapping in IPython (used for # `ipython --auto`). This cannot be done at import time due to # ordering issues, so we do it when creating a canvas, and should only # be done once per class (hence the `lru_cache(1)`). if "IPython" not in sys.modules: return import IPython ip = IPython.get_ipython() if not ip: return from IPython.core import pylabtools as pt if (not hasattr(pt, "backend2gui") or not hasattr(ip, "enable_matplotlib")): # In case we ever move the patch to IPython and remove these APIs, # don't break on our side. return backend_mod = sys.modules[cls.__module__] rif = getattr(backend_mod, "required_interactive_framework", None) backend2gui_rif = {"qt5": "qt", "qt4": "qt", "gtk3": "gtk3", "wx": "wx", "macosx": "osx"}.get(rif) if backend2gui_rif: if _is_non_interactive_terminal_ipython(ip): ip.enable_gui(backend2gui_rif) @contextmanager def _idle_draw_cntx(self): self._is_idle_drawing = True yield self._is_idle_drawing = False def is_saving(self): """ Returns whether the renderer is in the process of saving to a file, rather than rendering for an on-screen buffer. """ return self._is_saving def pick(self, mouseevent): if not self.widgetlock.locked(): self.figure.pick(mouseevent) def blit(self, bbox=None): """Blit the canvas in bbox (default entire canvas).""" def resize(self, w, h): """Set the canvas size in pixels.""" def draw_event(self, renderer): """Pass a `DrawEvent` to all functions connected to ``draw_event``.""" s = 'draw_event' event = DrawEvent(s, self, renderer) self.callbacks.process(s, event) def resize_event(self): """Pass a `ResizeEvent` to all functions connected to ``resize_event``. """ s = 'resize_event' event = ResizeEvent(s, self) self.callbacks.process(s, event) self.draw_idle() def close_event(self, guiEvent=None): """Pass a `CloseEvent` to all functions connected to ``close_event``. """ s = 'close_event' try: event = CloseEvent(s, self, guiEvent=guiEvent) self.callbacks.process(s, event) except (TypeError, AttributeError): pass # Suppress the TypeError when the python session is being killed. # It may be that a better solution would be a mechanism to # disconnect all callbacks upon shutdown. # AttributeError occurs on OSX with qt4agg upon exiting # with an open window; 'callbacks' attribute no longer exists. def key_press_event(self, key, guiEvent=None): """Pass a `KeyEvent` to all functions connected to ``key_press_event``. """ self._key = key s = 'key_press_event' event = KeyEvent( s, self, key, self._lastx, self._lasty, guiEvent=guiEvent) self.callbacks.process(s, event) def key_release_event(self, key, guiEvent=None): """ Pass a `KeyEvent` to all functions connected to ``key_release_event``. """ s = 'key_release_event' event = KeyEvent( s, self, key, self._lastx, self._lasty, guiEvent=guiEvent) self.callbacks.process(s, event) self._key = None def pick_event(self, mouseevent, artist, **kwargs): """ This method will be called by artists who are picked and will fire off :class:`PickEvent` callbacks registered listeners """ s = 'pick_event' event = PickEvent(s, self, mouseevent, artist, guiEvent=mouseevent.guiEvent, **kwargs) self.callbacks.process(s, event) def scroll_event(self, x, y, step, guiEvent=None): """ Backend derived classes should call this function on any scroll wheel event. x,y are the canvas coords: 0,0 is lower, left. button and key are as defined in MouseEvent. This method will be call all functions connected to the 'scroll_event' with a :class:`MouseEvent` instance. """ if step >= 0: self._button = 'up' else: self._button = 'down' s = 'scroll_event' mouseevent = MouseEvent(s, self, x, y, self._button, self._key, step=step, guiEvent=guiEvent) self.callbacks.process(s, mouseevent) def button_press_event(self, x, y, button, dblclick=False, guiEvent=None): """ Backend derived classes should call this function on any mouse button press. x,y are the canvas coords: 0,0 is lower, left. button and key are as defined in :class:`MouseEvent`. This method will be call all functions connected to the 'button_press_event' with a :class:`MouseEvent` instance. """ self._button = button s = 'button_press_event' mouseevent = MouseEvent(s, self, x, y, button, self._key, dblclick=dblclick, guiEvent=guiEvent) self.callbacks.process(s, mouseevent) def button_release_event(self, x, y, button, guiEvent=None): """ Backend derived classes should call this function on any mouse button release. This method will call all functions connected to the 'button_release_event' with a :class:`MouseEvent` instance. Parameters ---------- x : scalar the canvas coordinates where 0=left y : scalar the canvas coordinates where 0=bottom guiEvent the native UI event that generated the mpl event """ s = 'button_release_event' event = MouseEvent(s, self, x, y, button, self._key, guiEvent=guiEvent) self.callbacks.process(s, event) self._button = None def motion_notify_event(self, x, y, guiEvent=None): """ Backend derived classes should call this function on any motion-notify-event. This method will call all functions connected to the 'motion_notify_event' with a :class:`MouseEvent` instance. Parameters ---------- x : scalar the canvas coordinates where 0=left y : scalar the canvas coordinates where 0=bottom guiEvent the native UI event that generated the mpl event """ self._lastx, self._lasty = x, y s = 'motion_notify_event' event = MouseEvent(s, self, x, y, self._button, self._key, guiEvent=guiEvent) self.callbacks.process(s, event) def leave_notify_event(self, guiEvent=None): """ Backend derived classes should call this function when leaving canvas Parameters ---------- guiEvent the native UI event that generated the mpl event """ self.callbacks.process('figure_leave_event', LocationEvent.lastevent) LocationEvent.lastevent = None self._lastx, self._lasty = None, None def enter_notify_event(self, guiEvent=None, xy=None): """ Backend derived classes should call this function when entering canvas Parameters ---------- guiEvent the native UI event that generated the mpl event xy : (float, float) the coordinate location of the pointer when the canvas is entered """ if xy is not None: x, y = xy self._lastx, self._lasty = x, y else: x = None y = None cbook.warn_deprecated( '3.0', message='enter_notify_event expects a location but ' 'your backend did not pass one.') event = LocationEvent('figure_enter_event', self, x, y, guiEvent) self.callbacks.process('figure_enter_event', event) def inaxes(self, xy): """ Check if a point is in an axes. Parameters ---------- xy : tuple or list (x,y) coordinates. x position - pixels from left of canvas. y position - pixels from bottom of canvas. Returns ------- axes: topmost axes containing the point, or None if no axes. """ axes_list = [a for a in self.figure.get_axes() if a.patch.contains_point(xy)] if axes_list: axes = cbook._topmost_artist(axes_list) else: axes = None return axes def grab_mouse(self, ax): """ Set the child axes which are currently grabbing the mouse events. Usually called by the widgets themselves. It is an error to call this if the mouse is already grabbed by another axes. """ if self.mouse_grabber not in (None, ax): raise RuntimeError("Another Axes already grabs mouse input") self.mouse_grabber = ax def release_mouse(self, ax): """ Release the mouse grab held by the axes, ax. Usually called by the widgets. It is ok to call this even if you ax doesn't have the mouse grab currently. """ if self.mouse_grabber is ax: self.mouse_grabber = None def draw(self, *args, **kwargs): """Render the :class:`~matplotlib.figure.Figure`.""" def draw_idle(self, *args, **kwargs): """ Request a widget redraw once control returns to the GUI event loop. Even if multiple calls to `draw_idle` occur before control returns to the GUI event loop, the figure will only be rendered once. Notes ----- Backends may choose to override the method and implement their own strategy to prevent multiple renderings. """ if not self._is_idle_drawing: with self._idle_draw_cntx(): self.draw(*args, **kwargs) def draw_cursor(self, event): """ Draw a cursor in the event.axes if inaxes is not None. Use native GUI drawing for efficiency if possible """ def get_width_height(self): """ Return the figure width and height in points or pixels (depending on the backend), truncated to integers """ return int(self.figure.bbox.width), int(self.figure.bbox.height) @classmethod def get_supported_filetypes(cls): """Return dict of savefig file formats supported by this backend""" return cls.filetypes @classmethod def get_supported_filetypes_grouped(cls): """Return a dict of savefig file formats supported by this backend, where the keys are a file type name, such as 'Joint Photographic Experts Group', and the values are a list of filename extensions used for that filetype, such as ['jpg', 'jpeg'].""" groupings = {} for ext, name in cls.filetypes.items(): groupings.setdefault(name, []).append(ext) groupings[name].sort() return groupings def _get_output_canvas(self, fmt): """ Return a canvas suitable for saving figures to a specified file format. If necessary, this function will switch to a registered backend that supports the format. """ # Return the current canvas if it supports the requested format. if hasattr(self, 'print_{}'.format(fmt)): return self # Return a default canvas for the requested format, if it exists. canvas_class = get_registered_canvas_class(fmt) if canvas_class: return self.switch_backends(canvas_class) # Else report error for unsupported format. raise ValueError( "Format {!r} is not supported (supported formats: {})" .format(fmt, ", ".join(sorted(self.get_supported_filetypes())))) def print_figure(self, filename, dpi=None, facecolor=None, edgecolor=None, orientation='portrait', format=None, *, bbox_inches=None, **kwargs): """ Render the figure to hardcopy. Set the figure patch face and edge colors. This is useful because some of the GUIs have a gray figure face color background and you'll probably want to override this on hardcopy. Parameters ---------- filename can also be a file object on image backends orientation : {'landscape', 'portrait'}, optional only currently applies to PostScript printing. dpi : scalar, optional the dots per inch to save the figure in; if None, use savefig.dpi facecolor : color or None, optional the facecolor of the figure; if None, defaults to savefig.facecolor edgecolor : color or None, optional the edgecolor of the figure; if None, defaults to savefig.edgecolor format : str, optional when set, forcibly set the file format to save to bbox_inches : str or `~matplotlib.transforms.Bbox`, optional Bbox in inches. Only the given portion of the figure is saved. If 'tight', try to figure out the tight bbox of the figure. If None, use savefig.bbox pad_inches : scalar, optional Amount of padding around the figure when bbox_inches is 'tight'. If None, use savefig.pad_inches bbox_extra_artists : list of `~matplotlib.artist.Artist`, optional A list of extra artists that will be considered when the tight bbox is calculated. """ if format is None: # get format from filename, or from backend's default filetype if isinstance(filename, os.PathLike): filename = os.fspath(filename) if isinstance(filename, str): format = os.path.splitext(filename)[1][1:] if format is None or format == '': format = self.get_default_filetype() if isinstance(filename, str): filename = filename.rstrip('.') + '.' + format format = format.lower() # get canvas object and print method for format canvas = self._get_output_canvas(format) print_method = getattr(canvas, 'print_%s' % format) if dpi is None: dpi = rcParams['savefig.dpi'] if dpi == 'figure': dpi = getattr(self.figure, '_original_dpi', self.figure.dpi) # Remove the figure manager, if any, to avoid resizing the GUI widget. # Some code (e.g. Figure.show) differentiates between having *no* # manager and a *None* manager, which should be fixed at some point, # but this should be fine. with cbook._setattr_cm(self, _is_saving=True, manager=None), \ cbook._setattr_cm(self.figure, dpi=dpi): if facecolor is None: facecolor = rcParams['savefig.facecolor'] if edgecolor is None: edgecolor = rcParams['savefig.edgecolor'] origfacecolor = self.figure.get_facecolor() origedgecolor = self.figure.get_edgecolor() self.figure.set_facecolor(facecolor) self.figure.set_edgecolor(edgecolor) if bbox_inches is None: bbox_inches = rcParams['savefig.bbox'] if bbox_inches: # call adjust_bbox to save only the given area if bbox_inches == "tight": # When bbox_inches == "tight", it saves the figure twice. # The first save command (to a BytesIO) is just to estimate # the bounding box of the figure. result = print_method( io.BytesIO(), dpi=dpi, facecolor=facecolor, edgecolor=edgecolor, orientation=orientation, dryrun=True, **kwargs) renderer = self.figure._cachedRenderer bbox_artists = kwargs.pop("bbox_extra_artists", None) bbox_inches = self.figure.get_tightbbox(renderer, bbox_extra_artists=bbox_artists) pad = kwargs.pop("pad_inches", None) if pad is None: pad = rcParams['savefig.pad_inches'] bbox_inches = bbox_inches.padded(pad) restore_bbox = tight_bbox.adjust_bbox(self.figure, bbox_inches, canvas.fixed_dpi) _bbox_inches_restore = (bbox_inches, restore_bbox) else: _bbox_inches_restore = None try: result = print_method( filename, dpi=dpi, facecolor=facecolor, edgecolor=edgecolor, orientation=orientation, bbox_inches_restore=_bbox_inches_restore, **kwargs) finally: if bbox_inches and restore_bbox: restore_bbox() self.figure.set_facecolor(origfacecolor) self.figure.set_edgecolor(origedgecolor) self.figure.set_canvas(self) return result @classmethod def get_default_filetype(cls): """ Get the default savefig file format as specified in rcParam ``savefig.format``. Returned string excludes period. Overridden in backends that only support a single file type. """ return rcParams['savefig.format'] def get_window_title(self): """ Get the title text of the window containing the figure. Return None if there is no window (e.g., a PS backend). """ if hasattr(self, "manager"): return self.manager.get_window_title() def set_window_title(self, title): """ Set the title text of the window containing the figure. Note that this has no effect if there is no window (e.g., a PS backend). """ if hasattr(self, "manager"): self.manager.set_window_title(title) def get_default_filename(self): """ Return a string, which includes extension, suitable for use as a default filename. """ default_basename = self.get_window_title() or 'image' default_basename = default_basename.replace(' ', '_') default_filetype = self.get_default_filetype() default_filename = default_basename + '.' + default_filetype return default_filename def switch_backends(self, FigureCanvasClass): """ Instantiate an instance of FigureCanvasClass This is used for backend switching, e.g., to instantiate a FigureCanvasPS from a FigureCanvasGTK. Note, deep copying is not done, so any changes to one of the instances (e.g., setting figure size or line props), will be reflected in the other """ newCanvas = FigureCanvasClass(self.figure) newCanvas._is_saving = self._is_saving return newCanvas def mpl_connect(self, s, func): """ Connect event with string *s* to *func*. The signature of *func* is:: def func(event) where event is a :class:`matplotlib.backend_bases.Event`. The following events are recognized - 'button_press_event' - 'button_release_event' - 'draw_event' - 'key_press_event' - 'key_release_event' - 'motion_notify_event' - 'pick_event' - 'resize_event' - 'scroll_event' - 'figure_enter_event', - 'figure_leave_event', - 'axes_enter_event', - 'axes_leave_event' - 'close_event' For the location events (button and key press/release), if the mouse is over the axes, the variable ``event.inaxes`` will be set to the :class:`~matplotlib.axes.Axes` the event occurs is over, and additionally, the variables ``event.xdata`` and ``event.ydata`` will be defined. This is the mouse location in data coords. See :class:`~matplotlib.backend_bases.KeyEvent` and :class:`~matplotlib.backend_bases.MouseEvent` for more info. Return value is a connection id that can be used with :meth:`~matplotlib.backend_bases.Event.mpl_disconnect`. Examples -------- Usage:: def on_press(event): print('you pressed', event.button, event.xdata, event.ydata) cid = canvas.mpl_connect('button_press_event', on_press) """ return self.callbacks.connect(s, func) def mpl_disconnect(self, cid): """ Disconnect callback id cid Examples -------- Usage:: cid = canvas.mpl_connect('button_press_event', on_press) #...later canvas.mpl_disconnect(cid) """ return self.callbacks.disconnect(cid) def new_timer(self, *args, **kwargs): """ Creates a new backend-specific subclass of :class:`backend_bases.Timer`. This is useful for getting periodic events through the backend's native event loop. Implemented only for backends with GUIs. Other Parameters ---------------- interval : scalar Timer interval in milliseconds callbacks : List[Tuple[callable, Tuple, Dict]] Sequence of (func, args, kwargs) where ``func(*args, **kwargs)`` will be executed by the timer every *interval*. callbacks which return ``False`` or ``0`` will be removed from the timer. Examples -------- >>> timer = fig.canvas.new_timer(callbacks=[(f1, (1, ), {'a': 3}),]) """ return TimerBase(*args, **kwargs) def flush_events(self): """ Flush the GUI events for the figure. Interactive backends need to reimplement this method. """ def start_event_loop(self, timeout=0): """Start a blocking event loop. Such an event loop is used by interactive functions, such as `ginput` and `waitforbuttonpress`, to wait for events. The event loop blocks until a callback function triggers `stop_event_loop`, or *timeout* is reached. If *timeout* is negative, never timeout. Only interactive backends need to reimplement this method and it relies on `flush_events` being properly implemented. Interactive backends should implement this in a more native way. """ if timeout <= 0: timeout = np.inf timestep = 0.01 counter = 0 self._looping = True while self._looping and counter * timestep < timeout: self.flush_events() time.sleep(timestep) counter += 1 def stop_event_loop(self): """Stop the current blocking event loop. Interactive backends need to reimplement this to match `start_event_loop` """ self._looping = False def key_press_handler(event, canvas, toolbar=None): """ Implement the default mpl key bindings for the canvas and toolbar described at :ref:`key-event-handling` Parameters ---------- event : :class:`KeyEvent` a key press/release event canvas : :class:`FigureCanvasBase` the backend-specific canvas instance toolbar : :class:`NavigationToolbar2` the navigation cursor toolbar """ # these bindings happen whether you are over an axes or not if event.key is None: return # Load key-mappings from rcParams. fullscreen_keys = rcParams['keymap.fullscreen'] home_keys = rcParams['keymap.home'] back_keys = rcParams['keymap.back'] forward_keys = rcParams['keymap.forward'] pan_keys = rcParams['keymap.pan'] zoom_keys = rcParams['keymap.zoom'] save_keys = rcParams['keymap.save'] quit_keys = rcParams['keymap.quit'] grid_keys = rcParams['keymap.grid'] grid_minor_keys = rcParams['keymap.grid_minor'] toggle_yscale_keys = rcParams['keymap.yscale'] toggle_xscale_keys = rcParams['keymap.xscale'] all_keys = rcParams['keymap.all_axes'] # toggle fullscreen mode ('f', 'ctrl + f') if event.key in fullscreen_keys: try: canvas.manager.full_screen_toggle() except AttributeError: pass # quit the figure (default key 'ctrl+w') if event.key in quit_keys: Gcf.destroy_fig(canvas.figure) if toolbar is not None: # home or reset mnemonic (default key 'h', 'home' and 'r') if event.key in home_keys: toolbar.home() # forward / backward keys to enable left handed quick navigation # (default key for backward: 'left', 'backspace' and 'c') elif event.key in back_keys: toolbar.back() # (default key for forward: 'right' and 'v') elif event.key in forward_keys: toolbar.forward() # pan mnemonic (default key 'p') elif event.key in pan_keys: toolbar.pan() toolbar._set_cursor(event) # zoom mnemonic (default key 'o') elif event.key in zoom_keys: toolbar.zoom() toolbar._set_cursor(event) # saving current figure (default key 's') elif event.key in save_keys: toolbar.save_figure() if event.inaxes is None: return # these bindings require the mouse to be over an axes to trigger def _get_uniform_gridstate(ticks): # Return True/False if all grid lines are on or off, None if they are # not all in the same state. if all(tick.gridline.get_visible() for tick in ticks): return True elif not any(tick.gridline.get_visible() for tick in ticks): return False else: return None ax = event.inaxes # toggle major grids in current axes (default key 'g') # Both here and below (for 'G'), we do nothing if *any* grid (major or # minor, x or y) is not in a uniform state, to avoid messing up user # customization. if (event.key in grid_keys # Exclude minor grids not in a uniform state. and None not in [_get_uniform_gridstate(ax.xaxis.minorTicks), _get_uniform_gridstate(ax.yaxis.minorTicks)]): x_state = _get_uniform_gridstate(ax.xaxis.majorTicks) y_state = _get_uniform_gridstate(ax.yaxis.majorTicks) cycle = [(False, False), (True, False), (True, True), (False, True)] try: x_state, y_state = ( cycle[(cycle.index((x_state, y_state)) + 1) % len(cycle)]) except ValueError: # Exclude major grids not in a uniform state. pass else: # If turning major grids off, also turn minor grids off. ax.grid(x_state, which="major" if x_state else "both", axis="x") ax.grid(y_state, which="major" if y_state else "both", axis="y") canvas.draw_idle() # toggle major and minor grids in current axes (default key 'G') if (event.key in grid_minor_keys # Exclude major grids not in a uniform state. and None not in [_get_uniform_gridstate(ax.xaxis.majorTicks), _get_uniform_gridstate(ax.yaxis.majorTicks)]): x_state = _get_uniform_gridstate(ax.xaxis.minorTicks) y_state = _get_uniform_gridstate(ax.yaxis.minorTicks) cycle = [(False, False), (True, False), (True, True), (False, True)] try: x_state, y_state = ( cycle[(cycle.index((x_state, y_state)) + 1) % len(cycle)]) except ValueError: # Exclude minor grids not in a uniform state. pass else: ax.grid(x_state, which="both", axis="x") ax.grid(y_state, which="both", axis="y") canvas.draw_idle() # toggle scaling of y-axes between 'log and 'linear' (default key 'l') elif event.key in toggle_yscale_keys: scale = ax.get_yscale() if scale == 'log': ax.set_yscale('linear') ax.figure.canvas.draw_idle() elif scale == 'linear': try: ax.set_yscale('log') except ValueError as exc: _log.warning(str(exc)) ax.set_yscale('linear') ax.figure.canvas.draw_idle() # toggle scaling of x-axes between 'log and 'linear' (default key 'k') elif event.key in toggle_xscale_keys: scalex = ax.get_xscale() if scalex == 'log': ax.set_xscale('linear') ax.figure.canvas.draw_idle() elif scalex == 'linear': try: ax.set_xscale('log') except ValueError as exc: _log.warning(str(exc)) ax.set_xscale('linear') ax.figure.canvas.draw_idle() # enable nagivation for all axes that contain the event (default key 'a') elif event.key in all_keys: for a in canvas.figure.get_axes(): if (event.x is not None and event.y is not None and a.in_axes(event)): # FIXME: Why only these? a.set_navigate(True) # enable navigation only for axes with this index (if such an axes exist, # otherwise do nothing) elif event.key.isdigit() and event.key != '0': n = int(event.key) - 1 if n < len(canvas.figure.get_axes()): for i, a in enumerate(canvas.figure.get_axes()): if (event.x is not None and event.y is not None and a.in_axes(event)): # FIXME: Why only these? a.set_navigate(i == n) def button_press_handler(event, canvas, toolbar=None): """ The default Matplotlib button actions for extra mouse buttons. """ if toolbar is not None: button_name = str(MouseButton(event.button)) if button_name in rcParams['keymap.back']: toolbar.back() elif button_name in rcParams['keymap.forward']: toolbar.forward() class NonGuiException(Exception): pass class FigureManagerBase(object): """ Helper class for pyplot mode, wraps everything up into a neat bundle Attributes ---------- canvas : :class:`FigureCanvasBase` The backend-specific canvas instance num : int or str The figure number key_press_handler_id : int The default key handler cid, when using the toolmanager. To disable the default key press handling use:: figure.canvas.mpl_disconnect( figure.canvas.manager.key_press_handler_id) button_press_handler_id : int The default mouse button handler cid, when using the toolmanager. To disable the default button press handling use:: figure.canvas.mpl_disconnect( figure.canvas.manager.button_press_handler_id) """ def __init__(self, canvas, num): self.canvas = canvas canvas.manager = self # store a pointer to parent self.num = num self.key_press_handler_id = None self.button_press_handler_id = None if rcParams['toolbar'] != 'toolmanager': self.key_press_handler_id = self.canvas.mpl_connect( 'key_press_event', self.key_press) self.button_press_handler_id = self.canvas.mpl_connect( 'button_press_event', self.button_press) self.toolmanager = None self.toolbar = None @self.canvas.figure.add_axobserver def notify_axes_change(fig): # Called whenever the current axes is changed. if self.toolmanager is None and self.toolbar is not None: self.toolbar.update() def show(self): """ For GUI backends, show the figure window and redraw. For non-GUI backends, raise an exception to be caught by :meth:`~matplotlib.figure.Figure.show`, for an optional warning. """ raise NonGuiException() def destroy(self): pass def full_screen_toggle(self): pass def resize(self, w, h): """"For GUI backends, resize the window (in pixels).""" def key_press(self, event): """ Implement the default mpl key bindings defined at :ref:`key-event-handling` """ if rcParams['toolbar'] != 'toolmanager': key_press_handler(event, self.canvas, self.canvas.toolbar) def button_press(self, event): """ The default Matplotlib button actions for extra mouse buttons. """ if rcParams['toolbar'] != 'toolmanager': button_press_handler(event, self.canvas, self.canvas.toolbar) def get_window_title(self): """Get the title text of the window containing the figure. Return None for non-GUI (e.g., PS) backends. """ return 'image' def set_window_title(self, title): """Set the title text of the window containing the figure. This has no effect for non-GUI (e.g., PS) backends. """ cursors = tools.cursors class NavigationToolbar2(object): """ Base class for the navigation cursor, version 2 backends must implement a canvas that handles connections for 'button_press_event' and 'button_release_event'. See :meth:`FigureCanvasBase.mpl_connect` for more information They must also define :meth:`save_figure` save the current figure :meth:`set_cursor` if you want the pointer icon to change :meth:`_init_toolbar` create your toolbar widget :meth:`draw_rubberband` (optional) draw the zoom to rect "rubberband" rectangle :meth:`press` (optional) whenever a mouse button is pressed, you'll be notified with the event :meth:`release` (optional) whenever a mouse button is released, you'll be notified with the event :meth:`set_message` (optional) display message :meth:`set_history_buttons` (optional) you can change the history back / forward buttons to indicate disabled / enabled state. That's it, we'll do the rest! """ # list of toolitems to add to the toolbar, format is: # ( # text, # the text of the button (often not visible to users) # tooltip_text, # the tooltip shown on hover (where possible) # image_file, # name of the image for the button (without the extension) # name_of_method, # name of the method in NavigationToolbar2 to call # ) toolitems = ( ('Home', 'Reset original view', 'home', 'home'), ('Back', 'Back to previous view', 'back', 'back'), ('Forward', 'Forward to next view', 'forward', 'forward'), (None, None, None, None), ('Pan', 'Pan axes with left mouse, zoom with right', 'move', 'pan'), ('Zoom', 'Zoom to rectangle', 'zoom_to_rect', 'zoom'), ('Subplots', 'Configure subplots', 'subplots', 'configure_subplots'), (None, None, None, None), ('Save', 'Save the figure', 'filesave', 'save_figure'), ) def __init__(self, canvas): self.canvas = canvas canvas.toolbar = self self._nav_stack = cbook.Stack() self._xypress = None # the location and axis info at the time # of the press self._idPress = None self._idRelease = None self._active = None # This cursor will be set after the initial draw. self._lastCursor = cursors.POINTER self._init_toolbar() self._idDrag = self.canvas.mpl_connect( 'motion_notify_event', self.mouse_move) self._ids_zoom = [] self._zoom_mode = None self._button_pressed = None # determined by the button pressed # at start self.mode = '' # a mode string for the status bar self.set_history_buttons() def set_message(self, s): """Display a message on toolbar or in status bar.""" def back(self, *args): """move back up the view lim stack""" self._nav_stack.back() self.set_history_buttons() self._update_view() def draw_rubberband(self, event, x0, y0, x1, y1): """Draw a rectangle rubberband to indicate zoom limits. Note that it is not guaranteed that ``x0 <= x1`` and ``y0 <= y1``. """ def remove_rubberband(self): """Remove the rubberband.""" def forward(self, *args): """Move forward in the view lim stack.""" self._nav_stack.forward() self.set_history_buttons() self._update_view() def home(self, *args): """Restore the original view.""" self._nav_stack.home() self.set_history_buttons() self._update_view() def _init_toolbar(self): """ This is where you actually build the GUI widgets (called by __init__). The icons ``home.xpm``, ``back.xpm``, ``forward.xpm``, ``hand.xpm``, ``zoom_to_rect.xpm`` and ``filesave.xpm`` are standard across backends (there are ppm versions in CVS also). You just need to set the callbacks home : self.home back : self.back forward : self.forward hand : self.pan zoom_to_rect : self.zoom filesave : self.save_figure You only need to define the last one - the others are in the base class implementation. """ raise NotImplementedError def _set_cursor(self, event): if not event.inaxes or not self._active: if self._lastCursor != cursors.POINTER: self.set_cursor(cursors.POINTER) self._lastCursor = cursors.POINTER else: if (self._active == 'ZOOM' and self._lastCursor != cursors.SELECT_REGION): self.set_cursor(cursors.SELECT_REGION) self._lastCursor = cursors.SELECT_REGION elif (self._active == 'PAN' and self._lastCursor != cursors.MOVE): self.set_cursor(cursors.MOVE) self._lastCursor = cursors.MOVE def mouse_move(self, event): self._set_cursor(event) if event.inaxes and event.inaxes.get_navigate(): try: s = event.inaxes.format_coord(event.xdata, event.ydata) except (ValueError, OverflowError): pass else: artists = [a for a in event.inaxes._mouseover_set if a.contains(event)[0] and a.get_visible()] if artists: a = cbook._topmost_artist(artists) if a is not event.inaxes.patch: data = a.get_cursor_data(event) if data is not None: data_str = a.format_cursor_data(data) if data_str is not None: s = s + ' ' + data_str if len(self.mode): self.set_message('%s, %s' % (self.mode, s)) else: self.set_message(s) else: self.set_message(self.mode) def pan(self, *args): """Activate the pan/zoom tool. pan with left button, zoom with right""" # set the pointer icon and button press funcs to the # appropriate callbacks if self._active == 'PAN': self._active = None else: self._active = 'PAN' if self._idPress is not None: self._idPress = self.canvas.mpl_disconnect(self._idPress) self.mode = '' if self._idRelease is not None: self._idRelease = self.canvas.mpl_disconnect(self._idRelease) self.mode = '' if self._active: self._idPress = self.canvas.mpl_connect( 'button_press_event', self.press_pan) self._idRelease = self.canvas.mpl_connect( 'button_release_event', self.release_pan) self.mode = 'pan/zoom' self.canvas.widgetlock(self) else: self.canvas.widgetlock.release(self) for a in self.canvas.figure.get_axes(): a.set_navigate_mode(self._active) self.set_message(self.mode) def press(self, event): """Called whenever a mouse button is pressed.""" def press_pan(self, event): """Callback for mouse button press in pan/zoom mode.""" if event.button == 1: self._button_pressed = 1 elif event.button == 3: self._button_pressed = 3 else: self._button_pressed = None return if self._nav_stack() is None: # set the home button to this view self.push_current() x, y = event.x, event.y self._xypress = [] for i, a in enumerate(self.canvas.figure.get_axes()): if (x is not None and y is not None and a.in_axes(event) and a.get_navigate() and a.can_pan()): a.start_pan(x, y, event.button) self._xypress.append((a, i)) self.canvas.mpl_disconnect(self._idDrag) self._idDrag = self.canvas.mpl_connect('motion_notify_event', self.drag_pan) self.press(event) def press_zoom(self, event): """Callback for mouse button press in zoom to rect mode.""" # If we're already in the middle of a zoom, pressing another # button works to "cancel" if self._ids_zoom != []: for zoom_id in self._ids_zoom: self.canvas.mpl_disconnect(zoom_id) self.release(event) self.draw() self._xypress = None self._button_pressed = None self._ids_zoom = [] return if event.button == 1: self._button_pressed = 1 elif event.button == 3: self._button_pressed = 3 else: self._button_pressed = None return if self._nav_stack() is None: # set the home button to this view self.push_current() x, y = event.x, event.y self._xypress = [] for i, a in enumerate(self.canvas.figure.get_axes()): if (x is not None and y is not None and a.in_axes(event) and a.get_navigate() and a.can_zoom()): self._xypress.append((x, y, a, i, a._get_view())) id1 = self.canvas.mpl_connect('motion_notify_event', self.drag_zoom) id2 = self.canvas.mpl_connect('key_press_event', self._switch_on_zoom_mode) id3 = self.canvas.mpl_connect('key_release_event', self._switch_off_zoom_mode) self._ids_zoom = id1, id2, id3 self._zoom_mode = event.key self.press(event) def _switch_on_zoom_mode(self, event): self._zoom_mode = event.key self.mouse_move(event) def _switch_off_zoom_mode(self, event): self._zoom_mode = None self.mouse_move(event) def push_current(self): """Push the current view limits and position onto the stack.""" self._nav_stack.push( WeakKeyDictionary( {ax: (ax._get_view(), # Store both the original and modified positions. (ax.get_position(True).frozen(), ax.get_position().frozen())) for ax in self.canvas.figure.axes})) self.set_history_buttons() def release(self, event): """Callback for mouse button release.""" def release_pan(self, event): """Callback for mouse button release in pan/zoom mode.""" if self._button_pressed is None: return self.canvas.mpl_disconnect(self._idDrag) self._idDrag = self.canvas.mpl_connect( 'motion_notify_event', self.mouse_move) for a, ind in self._xypress: a.end_pan() if not self._xypress: return self._xypress = [] self._button_pressed = None self.push_current() self.release(event) self.draw() def drag_pan(self, event): """Callback for dragging in pan/zoom mode.""" for a, ind in self._xypress: #safer to use the recorded button at the press than current button: #multiple button can get pressed during motion... a.drag_pan(self._button_pressed, event.key, event.x, event.y) self.canvas.draw_idle() def drag_zoom(self, event): """Callback for dragging in zoom mode.""" if self._xypress: x, y = event.x, event.y lastx, lasty, a, ind, view = self._xypress[0] (x1, y1), (x2, y2) = np.clip( [[lastx, lasty], [x, y]], a.bbox.min, a.bbox.max) if self._zoom_mode == "x": y1, y2 = a.bbox.intervaly elif self._zoom_mode == "y": x1, x2 = a.bbox.intervalx self.draw_rubberband(event, x1, y1, x2, y2) def release_zoom(self, event): """Callback for mouse button release in zoom to rect mode.""" for zoom_id in self._ids_zoom: self.canvas.mpl_disconnect(zoom_id) self._ids_zoom = [] self.remove_rubberband() if not self._xypress: return last_a = [] for cur_xypress in self._xypress: x, y = event.x, event.y lastx, lasty, a, ind, view = cur_xypress # ignore singular clicks - 5 pixels is a threshold # allows the user to "cancel" a zoom action # by zooming by less than 5 pixels if ((abs(x - lastx) < 5 and self._zoom_mode != "y") or (abs(y - lasty) < 5 and self._zoom_mode != "x")): self._xypress = None self.release(event) self.draw() return # detect twinx,y axes and avoid double zooming twinx, twiny = False, False if last_a: for la in last_a: if a.get_shared_x_axes().joined(a, la): twinx = True if a.get_shared_y_axes().joined(a, la): twiny = True last_a.append(a) if self._button_pressed == 1: direction = 'in' elif self._button_pressed == 3: direction = 'out' else: continue a._set_view_from_bbox((lastx, lasty, x, y), direction, self._zoom_mode, twinx, twiny) self.draw() self._xypress = None self._button_pressed = None self._zoom_mode = None self.push_current() self.release(event) def draw(self): """Redraw the canvases, update the locators.""" for a in self.canvas.figure.get_axes(): xaxis = getattr(a, 'xaxis', None) yaxis = getattr(a, 'yaxis', None) locators = [] if xaxis is not None: locators.append(xaxis.get_major_locator()) locators.append(xaxis.get_minor_locator()) if yaxis is not None: locators.append(yaxis.get_major_locator()) locators.append(yaxis.get_minor_locator()) for loc in locators: loc.refresh() self.canvas.draw_idle() def _update_view(self): """Update the viewlim and position from the view and position stack for each axes. """ nav_info = self._nav_stack() if nav_info is None: return # Retrieve all items at once to avoid any risk of GC deleting an Axes # while in the middle of the loop below. items = list(nav_info.items()) for ax, (view, (pos_orig, pos_active)) in items: ax._set_view(view) # Restore both the original and modified positions ax._set_position(pos_orig, 'original') ax._set_position(pos_active, 'active') self.canvas.draw_idle() def save_figure(self, *args): """Save the current figure.""" raise NotImplementedError def set_cursor(self, cursor): """Set the current cursor to one of the :class:`Cursors` enums values. If required by the backend, this method should trigger an update in the backend event loop after the cursor is set, as this method may be called e.g. before a long-running task during which the GUI is not updated. """ def update(self): """Reset the axes stack.""" self._nav_stack.clear() self.set_history_buttons() def zoom(self, *args): """Activate zoom to rect mode.""" if self._active == 'ZOOM': self._active = None else: self._active = 'ZOOM' if self._idPress is not None: self._idPress = self.canvas.mpl_disconnect(self._idPress) self.mode = '' if self._idRelease is not None: self._idRelease = self.canvas.mpl_disconnect(self._idRelease) self.mode = '' if self._active: self._idPress = self.canvas.mpl_connect('button_press_event', self.press_zoom) self._idRelease = self.canvas.mpl_connect('button_release_event', self.release_zoom) self.mode = 'zoom rect' self.canvas.widgetlock(self) else: self.canvas.widgetlock.release(self) for a in self.canvas.figure.get_axes(): a.set_navigate_mode(self._active) self.set_message(self.mode) def set_history_buttons(self): """Enable or disable the back/forward button.""" class ToolContainerBase(object): """ Base class for all tool containers, e.g. toolbars. Attributes ---------- toolmanager : `ToolManager` The tools with which this `ToolContainer` wants to communicate. """ _icon_extension = '.png' """ Toolcontainer button icon image format extension **String**: Image extension """ def __init__(self, toolmanager): self.toolmanager = toolmanager self.toolmanager.toolmanager_connect('tool_removed_event', self._remove_tool_cbk) def _tool_toggled_cbk(self, event): """ Captures the 'tool_trigger_[name]' This only gets used for toggled tools """ self.toggle_toolitem(event.tool.name, event.tool.toggled) def add_tool(self, tool, group, position=-1): """ Adds a tool to this container Parameters ---------- tool : tool_like The tool to add, see `ToolManager.get_tool`. group : str The name of the group to add this tool to. position : int (optional) The position within the group to place this tool. Defaults to end. """ tool = self.toolmanager.get_tool(tool) image = self._get_image_filename(tool.image) toggle = getattr(tool, 'toggled', None) is not None self.add_toolitem(tool.name, group, position, image, tool.description, toggle) if toggle: self.toolmanager.toolmanager_connect('tool_trigger_%s' % tool.name, self._tool_toggled_cbk) # If initially toggled if tool.toggled: self.toggle_toolitem(tool.name, True) def _remove_tool_cbk(self, event): """Captures the 'tool_removed_event' signal and removes the tool.""" self.remove_toolitem(event.tool.name) def _get_image_filename(self, image): """Find the image based on its name.""" if not image: return None basedir = os.path.join(rcParams['datapath'], 'images') possible_images = ( image, image + self._icon_extension, os.path.join(basedir, image), os.path.join(basedir, image) + self._icon_extension) for fname in possible_images: if os.path.isfile(fname): return fname def trigger_tool(self, name): """ Trigger the tool Parameters ---------- name : string Name (id) of the tool triggered from within the container """ self.toolmanager.trigger_tool(name, sender=self) def add_toolitem(self, name, group, position, image, description, toggle): """ Add a toolitem to the container This method must get implemented per backend The callback associated with the button click event, must be **EXACTLY** `self.trigger_tool(name)` Parameters ---------- name : string Name of the tool to add, this gets used as the tool's ID and as the default label of the buttons group : String Name of the group that this tool belongs to position : Int Position of the tool within its group, if -1 it goes at the End image_file : String Filename of the image for the button or `None` description : String Description of the tool, used for the tooltips toggle : Bool * `True` : The button is a toggle (change the pressed/unpressed state between consecutive clicks) * `False` : The button is a normal button (returns to unpressed state after release) """ raise NotImplementedError def toggle_toolitem(self, name, toggled): """ Toggle the toolitem without firing event Parameters ---------- name : String Id of the tool to toggle toggled : bool Whether to set this tool as toggled or not. """ raise NotImplementedError def remove_toolitem(self, name): """ Remove a toolitem from the `ToolContainer` This method must get implemented per backend Called when `ToolManager` emits a `tool_removed_event` Parameters ---------- name : string Name of the tool to remove """ raise NotImplementedError class StatusbarBase(object): """Base class for the statusbar""" def __init__(self, toolmanager): self.toolmanager = toolmanager self.toolmanager.toolmanager_connect('tool_message_event', self._message_cbk) def _message_cbk(self, event): """Captures the 'tool_message_event' and set the message""" self.set_message(event.message) def set_message(self, s): """ Display a message on toolbar or in status bar Parameters ---------- s : str Message text """ pass class _Backend(object): # A backend can be defined by using the following pattern: # # @_Backend.export # class FooBackend(_Backend): # # override the attributes and methods documented below. # Set to one of {"qt5", "qt4", "gtk3", "wx", "tk", "macosx"} if an # interactive framework is required, or None otherwise. required_interactive_framework = None # `backend_version` may be overridden by the subclass. backend_version = "unknown" # The `FigureCanvas` class must be defined. FigureCanvas = None # For interactive backends, the `FigureManager` class must be overridden. FigureManager = FigureManagerBase # The following methods must be left as None for non-interactive backends. # For interactive backends, `trigger_manager_draw` should be a function # taking a manager as argument and triggering a canvas draw, and `mainloop` # should be a function taking no argument and starting the backend main # loop. trigger_manager_draw = None mainloop = None # The following methods will be automatically defined and exported, but # can be overridden. @classmethod def new_figure_manager(cls, num, *args, **kwargs): """Create a new figure manager instance. """ # This import needs to happen here due to circular imports. from matplotlib.figure import Figure fig_cls = kwargs.pop('FigureClass', Figure) fig = fig_cls(*args, **kwargs) return cls.new_figure_manager_given_figure(num, fig) @classmethod def new_figure_manager_given_figure(cls, num, figure): """Create a new figure manager instance for the given figure. """ canvas = cls.FigureCanvas(figure) manager = cls.FigureManager(canvas, num) return manager @classmethod def draw_if_interactive(cls): if cls.trigger_manager_draw is not None and is_interactive(): manager = Gcf.get_active() if manager: cls.trigger_manager_draw(manager) @classmethod @cbook._make_keyword_only("3.1", "block") def show(cls, block=None): """ Show all figures. `show` blocks by calling `mainloop` if *block* is ``True``, or if it is ``None`` and we are neither in IPython's ``%pylab`` mode, nor in `interactive` mode. """ managers = Gcf.get_all_fig_managers() if not managers: return for manager in managers: # Emits a warning if the backend is non-interactive. manager.canvas.figure.show() if cls.mainloop is None: return if block is None: # Hack: Are we in IPython's pylab mode? from matplotlib import pyplot try: # IPython versions >= 0.10 tack the _needmain attribute onto # pyplot.show, and always set it to False, when in %pylab mode. ipython_pylab = not pyplot.show._needmain except AttributeError: ipython_pylab = False block = not ipython_pylab and not is_interactive() # TODO: The above is a hack to get the WebAgg backend working with # ipython's `%pylab` mode until proper integration is implemented. if get_backend() == "WebAgg": block = True if block: cls.mainloop() # This method is the one actually exporting the required methods. @staticmethod def export(cls): for name in ["required_interactive_framework", "backend_version", "FigureCanvas", "FigureManager", "new_figure_manager", "new_figure_manager_given_figure", "draw_if_interactive", "show"]: setattr(sys.modules[cls.__module__], name, getattr(cls, name)) # For back-compatibility, generate a shim `Show` class. class Show(ShowBase): def mainloop(self): return cls.mainloop() setattr(sys.modules[cls.__module__], "Show", Show) return cls class ShowBase(_Backend): """ Simple base class to generate a show() callable in backends. Subclass must override mainloop() method. """ def __call__(self, block=None): return self.show(block=block)