""" This module contains all the 2D line class which can draw with a variety of line styles, markers and colors. """ # TODO: expose cap and join style attrs from __future__ import (absolute_import, division, print_function, unicode_literals) from matplotlib.externals import six import warnings import numpy as np from numpy import ma from matplotlib import verbose from . import artist from .artist import Artist from .cbook import (iterable, is_string_like, is_numlike, ls_mapper_r, pts_to_prestep, pts_to_poststep, pts_to_midstep) from .colors import colorConverter from .path import Path from .transforms import Bbox, TransformedPath, IdentityTransform from matplotlib import rcParams from .artist import allow_rasterization from matplotlib import docstring from matplotlib.markers import MarkerStyle # Imported here for backward compatibility, even though they don't # really belong. from matplotlib.markers import TICKLEFT, TICKRIGHT, TICKUP, TICKDOWN from matplotlib.markers import CARETLEFT, CARETRIGHT, CARETUP, CARETDOWN from matplotlib import _path def segment_hits(cx, cy, x, y, radius): """ Determine if any line segments are within radius of a point. Returns the list of line segments that are within that radius. """ # Process single points specially if len(x) < 2: res, = np.nonzero((cx - x) ** 2 + (cy - y) ** 2 <= radius ** 2) return res # We need to lop the last element off a lot. xr, yr = x[:-1], y[:-1] # Only look at line segments whose nearest point to C on the line # lies within the segment. dx, dy = x[1:] - xr, y[1:] - yr Lnorm_sq = dx ** 2 + dy ** 2 # Possibly want to eliminate Lnorm==0 u = ((cx - xr) * dx + (cy - yr) * dy) / Lnorm_sq candidates = (u >= 0) & (u <= 1) #if any(candidates): print "candidates",xr[candidates] # Note that there is a little area near one side of each point # which will be near neither segment, and another which will # be near both, depending on the angle of the lines. The # following radius test eliminates these ambiguities. point_hits = (cx - x) ** 2 + (cy - y) ** 2 <= radius ** 2 #if any(point_hits): print "points",xr[candidates] candidates = candidates & ~(point_hits[:-1] | point_hits[1:]) # For those candidates which remain, determine how far they lie away # from the line. px, py = xr + u * dx, yr + u * dy line_hits = (cx - px) ** 2 + (cy - py) ** 2 <= radius ** 2 #if any(line_hits): print "lines",xr[candidates] line_hits = line_hits & candidates points, = point_hits.ravel().nonzero() lines, = line_hits.ravel().nonzero() #print points,lines return np.concatenate((points, lines)) def _mark_every_path(markevery, tpath, affine, ax_transform): """ Helper function that sorts out how to deal the input `markevery` and returns the points where markers should be drawn. Takes in the `markevery` value and the line path and returns the sub-sampled path. """ # pull out the two bits of data we want from the path codes, verts = tpath.codes, tpath.vertices def _slice_or_none(in_v, slc): ''' Helper function to cope with `codes` being an ndarray or `None` ''' if in_v is None: return None return in_v[slc] # if just a float, assume starting at 0.0 and make a tuple if isinstance(markevery, float): markevery = (0.0, markevery) # if just an int, assume starting at 0 and make a tuple elif isinstance(markevery, int): markevery = (0, markevery) if isinstance(markevery, tuple): if len(markevery) != 2: raise ValueError('`markevery` is a tuple but its ' 'len is not 2; ' 'markevery=%s' % (markevery,)) start, step = markevery # if step is an int, old behavior if isinstance(step, int): #tuple of 2 int is for backwards compatibility, if not(isinstance(start, int)): raise ValueError('`markevery` is a tuple with ' 'len 2 and second element is an int, but ' 'the first element is not an int; ' 'markevery=%s' % (markevery,)) # just return, we are done here return Path(verts[slice(start, None, step)], _slice_or_none(codes, slice(start, None, step))) elif isinstance(step, float): if not (isinstance(start, int) or isinstance(start, float)): raise ValueError('`markevery` is a tuple with ' 'len 2 and second element is a float, but ' 'the first element is not a float or an ' 'int; ' 'markevery=%s' % (markevery,)) #calc cumulative distance along path (in display # coords): disp_coords = affine.transform(tpath.vertices) delta = np.empty((len(disp_coords), 2), dtype=float) delta[0, :] = 0.0 delta[1:, :] = (disp_coords[1:, :] - disp_coords[:-1, :]) delta = np.sum(delta**2, axis=1) delta = np.sqrt(delta) delta = np.cumsum(delta) #calc distance between markers along path based on # the axes bounding box diagonal being a distance # of unity: scale = ax_transform.transform( np.array([[0, 0], [1, 1]])) scale = np.diff(scale, axis=0) scale = np.sum(scale**2) scale = np.sqrt(scale) marker_delta = np.arange(start * scale, delta[-1], step * scale) #find closest actual data point that is closest to # the theoretical distance along the path: inds = np.abs(delta[np.newaxis, :] - marker_delta[:, np.newaxis]) inds = inds.argmin(axis=1) inds = np.unique(inds) # return, we are done here return Path(verts[inds], _slice_or_none(codes, inds)) else: raise ValueError('`markevery` is a tuple with ' 'len 2, but its second element is not an int ' 'or a float; ' 'markevery=%s' % (markevery,)) elif isinstance(markevery, slice): # mazol tov, it's already a slice, just return return Path(verts[markevery], _slice_or_none(codes, markevery)) elif iterable(markevery): #fancy indexing try: return Path(verts[markevery], _slice_or_none(codes, markevery)) except (ValueError, IndexError): raise ValueError('`markevery` is iterable but ' 'not a valid form of numpy fancy indexing; ' 'markevery=%s' % (markevery,)) else: raise ValueError('Value of `markevery` is not ' 'recognized; ' 'markevery=%s' % (markevery,)) class Line2D(Artist): """ A line - the line can have both a solid linestyle connecting all the vertices, and a marker at each vertex. Additionally, the drawing of the solid line is influenced by the drawstyle, e.g., one can create "stepped" lines in various styles. """ lineStyles = _lineStyles = { # hidden names deprecated '-': '_draw_solid', '--': '_draw_dashed', '-.': '_draw_dash_dot', ':': '_draw_dotted', 'None': '_draw_nothing', ' ': '_draw_nothing', '': '_draw_nothing', } _drawStyles_l = { 'default': '_draw_lines', 'steps-mid': '_draw_steps_mid', 'steps-pre': '_draw_steps_pre', 'steps-post': '_draw_steps_post', } _drawStyles_s = { 'steps': '_draw_steps_pre', } drawStyles = {} drawStyles.update(_drawStyles_l) drawStyles.update(_drawStyles_s) # Need a list ordered with long names first: drawStyleKeys = (list(six.iterkeys(_drawStyles_l)) + list(six.iterkeys(_drawStyles_s))) # Referenced here to maintain API. These are defined in # MarkerStyle markers = MarkerStyle.markers filled_markers = MarkerStyle.filled_markers fillStyles = MarkerStyle.fillstyles zorder = 2 validCap = ('butt', 'round', 'projecting') validJoin = ('miter', 'round', 'bevel') def __str__(self): if self._label != "": return "Line2D(%s)" % (self._label) elif self._x is None: return "Line2D()" elif len(self._x) > 3: return "Line2D((%g,%g),(%g,%g),...,(%g,%g))"\ % (self._x[0], self._y[0], self._x[0], self._y[0], self._x[-1], self._y[-1]) else: return "Line2D(%s)"\ % (",".join(["(%g,%g)" % (x, y) for x, y in zip(self._x, self._y)])) def __init__(self, xdata, ydata, linewidth=None, # all Nones default to rc linestyle=None, color=None, marker=None, markersize=None, markeredgewidth=None, markeredgecolor=None, markerfacecolor=None, markerfacecoloralt='none', fillstyle=None, antialiased=None, dash_capstyle=None, solid_capstyle=None, dash_joinstyle=None, solid_joinstyle=None, pickradius=5, drawstyle=None, markevery=None, **kwargs ): """ Create a :class:`~matplotlib.lines.Line2D` instance with *x* and *y* data in sequences *xdata*, *ydata*. The kwargs are :class:`~matplotlib.lines.Line2D` properties: %(Line2D)s See :meth:`set_linestyle` for a decription of the line styles, :meth:`set_marker` for a description of the markers, and :meth:`set_drawstyle` for a description of the draw styles. """ Artist.__init__(self) #convert sequences to numpy arrays if not iterable(xdata): raise RuntimeError('xdata must be a sequence') if not iterable(ydata): raise RuntimeError('ydata must be a sequence') if linewidth is None: linewidth = rcParams['lines.linewidth'] if linestyle is None: linestyle = rcParams['lines.linestyle'] if marker is None: marker = rcParams['lines.marker'] if color is None: color = rcParams['lines.color'] if markersize is None: markersize = rcParams['lines.markersize'] if antialiased is None: antialiased = rcParams['lines.antialiased'] if dash_capstyle is None: dash_capstyle = rcParams['lines.dash_capstyle'] if dash_joinstyle is None: dash_joinstyle = rcParams['lines.dash_joinstyle'] if solid_capstyle is None: solid_capstyle = rcParams['lines.solid_capstyle'] if solid_joinstyle is None: solid_joinstyle = rcParams['lines.solid_joinstyle'] if drawstyle is None: drawstyle = 'default' self._dashcapstyle = None self._dashjoinstyle = None self._solidjoinstyle = None self._solidcapstyle = None self.set_dash_capstyle(dash_capstyle) self.set_dash_joinstyle(dash_joinstyle) self.set_solid_capstyle(solid_capstyle) self.set_solid_joinstyle(solid_joinstyle) self._linestyles = None self._drawstyle = None self._linewidth = None self.set_linestyle(linestyle) self.set_drawstyle(drawstyle) self.set_linewidth(linewidth) self._color = None self.set_color(color) self._marker = MarkerStyle() self.set_marker(marker) self._markevery = None self._markersize = None self._antialiased = None self.set_markevery(markevery) self.set_antialiased(antialiased) self.set_markersize(markersize) self._dashSeq = None self._markeredgecolor = None self._markeredgewidth = None self._markerfacecolor = None self._markerfacecoloralt = None self.set_markerfacecolor(markerfacecolor) self.set_markerfacecoloralt(markerfacecoloralt) self.set_markeredgecolor(markeredgecolor) self.set_markeredgewidth(markeredgewidth) self.set_fillstyle(fillstyle) self.verticalOffset = None # update kwargs before updating data to give the caller a # chance to init axes (and hence unit support) self.update(kwargs) self.pickradius = pickradius self.ind_offset = 0 if is_numlike(self._picker): self.pickradius = self._picker self._xorig = np.asarray([]) self._yorig = np.asarray([]) self._invalidx = True self._invalidy = True self._x = None self._y = None self._xy = None self._path = None self._transformed_path = None self._subslice = False self._x_filled = None # used in subslicing; only x is needed self.set_data(xdata, ydata) def __getstate__(self): state = super(Line2D, self).__getstate__() # _linefunc will be restored on draw time. state.pop('_lineFunc', None) return state def contains(self, mouseevent): """ Test whether the mouse event occurred on the line. The pick radius determines the precision of the location test (usually within five points of the value). Use :meth:`~matplotlib.lines.Line2D.get_pickradius` or :meth:`~matplotlib.lines.Line2D.set_pickradius` to view or modify it. Returns *True* if any values are within the radius along with ``{'ind': pointlist}``, where *pointlist* is the set of points within the radius. TODO: sort returned indices by distance """ if six.callable(self._contains): return self._contains(self, mouseevent) if not is_numlike(self.pickradius): raise ValueError("pick radius should be a distance") # Make sure we have data to plot if self._invalidy or self._invalidx: self.recache() if len(self._xy) == 0: return False, {} # Convert points to pixels transformed_path = self._get_transformed_path() path, affine = transformed_path.get_transformed_path_and_affine() path = affine.transform_path(path) xy = path.vertices xt = xy[:, 0] yt = xy[:, 1] # Convert pick radius from points to pixels if self.figure is None: warnings.warn('no figure set when check if mouse is on line') pixels = self.pickradius else: pixels = self.figure.dpi / 72. * self.pickradius # the math involved in checking for containment (here and inside of # segment_hits) assumes that it is OK to overflow. In case the # application has set the error flags such that an exception is raised # on overflow, we temporarily set the appropriate error flags here and # set them back when we are finished. olderrflags = np.seterr(all='ignore') try: # Check for collision if self._linestyle in ['None', None]: # If no line, return the nearby point(s) d = (xt - mouseevent.x) ** 2 + (yt - mouseevent.y) ** 2 ind, = np.nonzero(np.less_equal(d, pixels ** 2)) else: # If line, return the nearby segment(s) ind = segment_hits(mouseevent.x, mouseevent.y, xt, yt, pixels) finally: np.seterr(**olderrflags) ind += self.ind_offset # Debugging message if False and self._label != '': print("Checking line", self._label, "at", mouseevent.x, mouseevent.y) print('xt', xt) print('yt', yt) #print 'dx,dy', (xt-mouseevent.x)**2., (yt-mouseevent.y)**2. print('ind', ind) # Return the point(s) within radius return len(ind) > 0, dict(ind=ind) def get_pickradius(self): """return the pick radius used for containment tests""" return self.pickradius def set_pickradius(self, d): """Sets the pick radius used for containment tests ACCEPTS: float distance in points """ self.pickradius = d def get_fillstyle(self): """ return the marker fillstyle """ return self._marker.get_fillstyle() def set_fillstyle(self, fs): """ Set the marker fill style; 'full' means fill the whole marker. 'none' means no filling; other options are for half-filled markers. ACCEPTS: ['full' | 'left' | 'right' | 'bottom' | 'top' | 'none'] """ self._marker.set_fillstyle(fs) self.stale = True def set_markevery(self, every): """Set the markevery property to subsample the plot when using markers. e.g., if `every=5`, every 5-th marker will be plotted. ACCEPTS: [None | int | length-2 tuple of int | slice | list/array of int | float | length-2 tuple of float] Parameters ---------- every: None | int | length-2 tuple of int | slice | list/array of int | float | length-2 tuple of float Which markers to plot. - every=None, every point will be plotted. - every=N, every N-th marker will be plotted starting with marker 0. - every=(start, N), every N-th marker, starting at point start, will be plotted. - every=slice(start, end, N), every N-th marker, starting at point start, upto but not including point end, will be plotted. - every=[i, j, m, n], only markers at points i, j, m, and n will be plotted. - every=0.1, (i.e. a float) then markers will be spaced at approximately equal distances along the line; the distance along the line between markers is determined by multiplying the display-coordinate distance of the axes bounding-box diagonal by the value of every. - every=(0.5, 0.1) (i.e. a length-2 tuple of float), the same functionality as every=0.1 is exhibited but the first marker will be 0.5 multiplied by the display-cordinate-diagonal-distance along the line. Notes ----- Setting the markevery property will only show markers at actual data points. When using float arguments to set the markevery property on irregularly spaced data, the markers will likely not appear evenly spaced because the actual data points do not coincide with the theoretical spacing between markers. When using a start offset to specify the first marker, the offset will be from the first data point which may be different from the first the visible data point if the plot is zoomed in. If zooming in on a plot when using float arguments then the actual data points that have markers will change because the distance between markers is always determined from the display-coordinates axes-bounding-box-diagonal regardless of the actual axes data limits. """ if self._markevery != every: self.stale = True self._markevery = every def get_markevery(self): """return the markevery setting""" return self._markevery def set_picker(self, p): """Sets the event picker details for the line. ACCEPTS: float distance in points or callable pick function ``fn(artist, event)`` """ if six.callable(p): self._contains = p else: self.pickradius = p self._picker = p def get_window_extent(self, renderer): bbox = Bbox([[0, 0], [0, 0]]) trans_data_to_xy = self.get_transform().transform bbox.update_from_data_xy(trans_data_to_xy(self.get_xydata()), ignore=True) # correct for marker size, if any if self._marker: ms = (self._markersize / 72.0 * self.figure.dpi) * 0.5 bbox = bbox.padded(ms) return bbox @Artist.axes.setter def axes(self, ax): # call the set method from the base-class property Artist.axes.fset(self, ax) if ax is not None: # connect unit-related callbacks if ax.xaxis is not None: self._xcid = ax.xaxis.callbacks.connect('units', self.recache_always) if ax.yaxis is not None: self._ycid = ax.yaxis.callbacks.connect('units', self.recache_always) def set_data(self, *args): """ Set the x and y data ACCEPTS: 2D array (rows are x, y) or two 1D arrays """ if len(args) == 1: x, y = args[0] else: x, y = args self.set_xdata(x) self.set_ydata(y) def recache_always(self): self.recache(always=True) def recache(self, always=False): if always or self._invalidx: xconv = self.convert_xunits(self._xorig) if ma.isMaskedArray(self._xorig): x = ma.asarray(xconv, np.float_).filled(np.nan) else: x = np.asarray(xconv, np.float_) x = x.ravel() else: x = self._x if always or self._invalidy: yconv = self.convert_yunits(self._yorig) if ma.isMaskedArray(self._yorig): y = ma.asarray(yconv, np.float_).filled(np.nan) else: y = np.asarray(yconv, np.float_) y = y.ravel() else: y = self._y if len(x) == 1 and len(y) > 1: x = x * np.ones(y.shape, np.float_) if len(y) == 1 and len(x) > 1: y = y * np.ones(x.shape, np.float_) if len(x) != len(y): raise RuntimeError('xdata and ydata must be the same length') self._xy = np.empty((len(x), 2), dtype=np.float_) self._xy[:, 0] = x self._xy[:, 1] = y self._x = self._xy[:, 0] # just a view self._y = self._xy[:, 1] # just a view self._subslice = False if (self.axes and len(x) > 1000 and self._is_sorted(x) and self.axes.name == 'rectilinear' and self.axes.get_xscale() == 'linear' and self._markevery is None and self.get_clip_on() is True): self._subslice = True nanmask = np.isnan(x) if nanmask.any(): self._x_filled = self._x.copy() indices = np.arange(len(x)) self._x_filled[nanmask] = np.interp(indices[nanmask], indices[~nanmask], self._x[~nanmask]) else: self._x_filled = self._x if self._path is not None: interpolation_steps = self._path._interpolation_steps else: interpolation_steps = 1 self._path = Path(self._xy, None, interpolation_steps) self._transformed_path = None self._invalidx = False self._invalidy = False def _transform_path(self, subslice=None): """ Puts a TransformedPath instance at self._transformed_path; all invalidation of the transform is then handled by the TransformedPath instance. """ # Masked arrays are now handled by the Path class itself if subslice is not None: _steps = self._path._interpolation_steps _path = Path(self._xy[subslice, :], _interpolation_steps=_steps) else: _path = self._path self._transformed_path = TransformedPath(_path, self.get_transform()) def _get_transformed_path(self): """ Return the :class:`~matplotlib.transforms.TransformedPath` instance of this line. """ if self._transformed_path is None: self._transform_path() return self._transformed_path def set_transform(self, t): """ set the Transformation instance used by this artist ACCEPTS: a :class:`matplotlib.transforms.Transform` instance """ Artist.set_transform(self, t) self._invalidx = True self._invalidy = True self.stale = True def _is_sorted(self, x): """return True if x is sorted in ascending order""" # We don't handle the monotonically decreasing case. return _path.is_sorted(x) @allow_rasterization def draw(self, renderer): """draw the Line with `renderer` unless visibility is False""" if not self.get_visible(): return if self._invalidy or self._invalidx: self.recache() self.ind_offset = 0 # Needed for contains() method. if self._subslice and self.axes: x0, x1 = self.axes.get_xbound() i0, = self._x_filled.searchsorted([x0], 'left') i1, = self._x_filled.searchsorted([x1], 'right') subslice = slice(max(i0 - 1, 0), i1 + 1) self.ind_offset = subslice.start self._transform_path(subslice) transf_path = self._get_transformed_path() if self.get_path_effects(): from matplotlib.patheffects import PathEffectRenderer renderer = PathEffectRenderer(self.get_path_effects(), renderer) renderer.open_group('line2d', self.get_gid()) funcname = self._lineStyles.get(self._linestyle, '_draw_nothing') if funcname != '_draw_nothing': tpath, affine = transf_path.get_transformed_path_and_affine() if len(tpath.vertices): self._lineFunc = getattr(self, funcname) funcname = self.drawStyles.get(self._drawstyle, '_draw_lines') drawFunc = getattr(self, funcname) gc = renderer.new_gc() self._set_gc_clip(gc) ln_color_rgba = self._get_rgba_ln_color() gc.set_foreground(ln_color_rgba, isRGBA=True) gc.set_alpha(ln_color_rgba[3]) gc.set_antialiased(self._antialiased) gc.set_linewidth(self._linewidth) if self.is_dashed(): cap = self._dashcapstyle join = self._dashjoinstyle else: cap = self._solidcapstyle join = self._solidjoinstyle gc.set_joinstyle(join) gc.set_capstyle(cap) gc.set_snap(self.get_snap()) if self.get_sketch_params() is not None: gc.set_sketch_params(*self.get_sketch_params()) drawFunc(renderer, gc, tpath, affine.frozen()) gc.restore() if self._marker: gc = renderer.new_gc() self._set_gc_clip(gc) rgbaFace = self._get_rgba_face() rgbaFaceAlt = self._get_rgba_face(alt=True) edgecolor = self.get_markeredgecolor() if is_string_like(edgecolor) and edgecolor.lower() == 'none': gc.set_linewidth(0) gc.set_foreground(rgbaFace, isRGBA=True) else: gc.set_foreground(edgecolor) gc.set_linewidth(self._markeredgewidth) mec = self._markeredgecolor if (is_string_like(mec) and mec == 'auto' and rgbaFace is not None): gc.set_alpha(rgbaFace[3]) else: gc.set_alpha(self.get_alpha()) marker = self._marker tpath, affine = transf_path.get_transformed_points_and_affine() if len(tpath.vertices): # subsample the markers if markevery is not None markevery = self.get_markevery() if markevery is not None: subsampled = _mark_every_path(markevery, tpath, affine, self.axes.transAxes) else: subsampled = tpath snap = marker.get_snap_threshold() if type(snap) == float: snap = renderer.points_to_pixels(self._markersize) >= snap gc.set_snap(snap) gc.set_joinstyle(marker.get_joinstyle()) gc.set_capstyle(marker.get_capstyle()) marker_path = marker.get_path() marker_trans = marker.get_transform() w = renderer.points_to_pixels(self._markersize) if marker.get_marker() != ',': # Don't scale for pixels, and don't stroke them marker_trans = marker_trans.scale(w) else: gc.set_linewidth(0) renderer.draw_markers(gc, marker_path, marker_trans, subsampled, affine.frozen(), rgbaFace) alt_marker_path = marker.get_alt_path() if alt_marker_path: alt_marker_trans = marker.get_alt_transform() alt_marker_trans = alt_marker_trans.scale(w) if (is_string_like(mec) and mec == 'auto' and rgbaFaceAlt is not None): gc.set_alpha(rgbaFaceAlt[3]) else: gc.set_alpha(self.get_alpha()) renderer.draw_markers( gc, alt_marker_path, alt_marker_trans, subsampled, affine.frozen(), rgbaFaceAlt) gc.restore() renderer.close_group('line2d') self.stale = False def get_antialiased(self): return self._antialiased def get_color(self): return self._color def get_drawstyle(self): return self._drawstyle def get_linestyle(self): return self._linestyle def get_linewidth(self): return self._linewidth def get_marker(self): return self._marker.get_marker() def get_markeredgecolor(self): mec = self._markeredgecolor if (is_string_like(mec) and mec == 'auto'): if self._marker.get_marker() in ('.', ','): return self._color if self._marker.is_filled() and self.get_fillstyle() != 'none': return 'k' # Bad hard-wired default... else: return self._color else: return mec def get_markeredgewidth(self): return self._markeredgewidth def _get_markerfacecolor(self, alt=False): if alt: fc = self._markerfacecoloralt else: fc = self._markerfacecolor if (is_string_like(fc) and fc.lower() == 'auto'): if self.get_fillstyle() == 'none': return 'none' else: return self._color else: return fc def get_markerfacecolor(self): return self._get_markerfacecolor(alt=False) def get_markerfacecoloralt(self): return self._get_markerfacecolor(alt=True) def get_markersize(self): return self._markersize def get_data(self, orig=True): """ Return the xdata, ydata. If *orig* is *True*, return the original data. """ return self.get_xdata(orig=orig), self.get_ydata(orig=orig) def get_xdata(self, orig=True): """ Return the xdata. If *orig* is *True*, return the original data, else the processed data. """ if orig: return self._xorig if self._invalidx: self.recache() return self._x def get_ydata(self, orig=True): """ Return the ydata. If *orig* is *True*, return the original data, else the processed data. """ if orig: return self._yorig if self._invalidy: self.recache() return self._y def get_path(self): """ Return the :class:`~matplotlib.path.Path` object associated with this line. """ if self._invalidy or self._invalidx: self.recache() return self._path def get_xydata(self): """ Return the *xy* data as a Nx2 numpy array. """ if self._invalidy or self._invalidx: self.recache() return self._xy def set_antialiased(self, b): """ True if line should be drawin with antialiased rendering ACCEPTS: [True | False] """ if self._antialiased != b: self.stale = True self._antialiased = b def set_color(self, color): """ Set the color of the line ACCEPTS: any matplotlib color """ self._color = color self.stale = True def set_drawstyle(self, drawstyle): """ Set the drawstyle of the plot 'default' connects the points with lines. The steps variants produce step-plots. 'steps' is equivalent to 'steps-pre' and is maintained for backward-compatibility. ACCEPTS: ['default' | 'steps' | 'steps-pre' | 'steps-mid' | 'steps-post'] """ if self._drawstyle != drawstyle: self.stale = True self._drawstyle = drawstyle def set_linewidth(self, w): """ Set the line width in points ACCEPTS: float value in points """ w = float(w) if self._linewidth != w: self.stale = True self._linewidth = w def set_linestyle(self, ls): """ Set the linestyle of the line (also accepts drawstyles, e.g., ``'steps--'``) =========================== ================= linestyle description =========================== ================= ``'-'`` or ``'solid'`` solid line ``'--'`` or ``'dashed'`` dashed line ``'-.'`` or ``'dash_dot'`` dash-dotted line ``':'`` or ``'dotted'`` dotted line ``'None'`` draw nothing ``' '`` draw nothing ``''`` draw nothing =========================== ================= 'steps' is equivalent to 'steps-pre' and is maintained for backward-compatibility. Alternatively a dash tuple of the following form can be provided:: (offset, onoffseq), where ``onoffseq`` is an even length tuple of on and off ink in points. ACCEPTS: ['solid' | 'dashed', 'dashdot', 'dotted' | (offset, on-off-dash-seq) | ``'-'`` | ``'--'`` | ``'-.'`` | ``':'`` | ``'None'`` | ``' '`` | ``''``] .. seealso:: :meth:`set_drawstyle` To set the drawing style (stepping) of the plot. Parameters ---------- ls : { '-', '--', '-.', ':'} and more see description The line style. """ if not is_string_like(ls): if len(ls) != 2: raise ValueError() self.set_dashes(ls[1]) self._linestyle = "--" return for ds in self.drawStyleKeys: # long names are first in the list if ls.startswith(ds): self.set_drawstyle(ds) if len(ls) > len(ds): ls = ls[len(ds):] else: ls = '-' break if ls in [' ', '', 'none']: ls = 'None' if ls not in self._lineStyles: try: ls = ls_mapper_r[ls] except KeyError: raise ValueError(("You passed in an invalid linestyle, " "`{}`. See " "docs of Line2D.set_linestyle for " "valid values.").format(ls)) self._linestyle = ls @docstring.dedent_interpd def set_marker(self, marker): """ Set the line marker ACCEPTS: :mod:`A valid marker style ` Parameters ----------- marker: marker style See `~matplotlib.markers` for full description of possible argument """ self._marker.set_marker(marker) self.stale = True def set_markeredgecolor(self, ec): """ Set the marker edge color ACCEPTS: any matplotlib color """ if ec is None: ec = 'auto' if self._markeredgecolor != ec: self.stale = True self._markeredgecolor = ec def set_markeredgewidth(self, ew): """ Set the marker edge width in points ACCEPTS: float value in points """ if ew is None: ew = rcParams['lines.markeredgewidth'] if self._markeredgewidth != ew: self.stale = True self._markeredgewidth = ew def set_markerfacecolor(self, fc): """ Set the marker face color. ACCEPTS: any matplotlib color """ if fc is None: fc = 'auto' if self._markerfacecolor != fc: self.stale = True self._markerfacecolor = fc def set_markerfacecoloralt(self, fc): """ Set the alternate marker face color. ACCEPTS: any matplotlib color """ if fc is None: fc = 'auto' if self._markerfacecoloralt != fc: self.stale = True self._markerfacecoloralt = fc def set_markersize(self, sz): """ Set the marker size in points ACCEPTS: float """ sz = float(sz) if self._markersize != sz: self.stale = True self._markersize = sz def set_xdata(self, x): """ Set the data np.array for x ACCEPTS: 1D array """ self._xorig = x self._invalidx = True self.stale = True def set_ydata(self, y): """ Set the data np.array for y ACCEPTS: 1D array """ self._yorig = y self._invalidy = True self.stale = True def set_dashes(self, seq): """ Set the dash sequence, sequence of dashes with on off ink in points. If seq is empty or if seq = (None, None), the linestyle will be set to solid. ACCEPTS: sequence of on/off ink in points """ if seq == (None, None) or len(seq) == 0: self.set_linestyle('-') else: self.set_linestyle('--') if self._dashSeq != seq: self.stale = True self._dashSeq = seq # TODO: offset ignored for now def _draw_lines(self, renderer, gc, path, trans): self._lineFunc(renderer, gc, path, trans) def _draw_steps_pre(self, renderer, gc, path, trans): steps = np.vstack(pts_to_prestep(*self._xy.T)).T path = Path(steps) path = path.transformed(self.get_transform()) self._lineFunc(renderer, gc, path, IdentityTransform()) def _draw_steps_post(self, renderer, gc, path, trans): steps = np.vstack(pts_to_poststep(*self._xy.T)).T path = Path(steps) path = path.transformed(self.get_transform()) self._lineFunc(renderer, gc, path, IdentityTransform()) def _draw_steps_mid(self, renderer, gc, path, trans): steps = np.vstack(pts_to_midstep(*self._xy.T)).T path = Path(steps) path = path.transformed(self.get_transform()) self._lineFunc(renderer, gc, path, IdentityTransform()) def _draw_solid(self, renderer, gc, path, trans): gc.set_linestyle('solid') renderer.draw_path(gc, path, trans) def _draw_dashed(self, renderer, gc, path, trans): gc.set_linestyle('dashed') if self._dashSeq is not None: gc.set_dashes(0, self._dashSeq) renderer.draw_path(gc, path, trans) def _draw_dash_dot(self, renderer, gc, path, trans): gc.set_linestyle('dashdot') renderer.draw_path(gc, path, trans) def _draw_dotted(self, renderer, gc, path, trans): gc.set_linestyle('dotted') renderer.draw_path(gc, path, trans) def update_from(self, other): """copy properties from other to self""" Artist.update_from(self, other) self._linestyle = other._linestyle self._linewidth = other._linewidth self._color = other._color self._markersize = other._markersize self._markerfacecolor = other._markerfacecolor self._markerfacecoloralt = other._markerfacecoloralt self._markeredgecolor = other._markeredgecolor self._markeredgewidth = other._markeredgewidth self._dashSeq = other._dashSeq self._dashcapstyle = other._dashcapstyle self._dashjoinstyle = other._dashjoinstyle self._solidcapstyle = other._solidcapstyle self._solidjoinstyle = other._solidjoinstyle self._linestyle = other._linestyle self._marker = MarkerStyle(other._marker.get_marker(), other._marker.get_fillstyle()) self._drawstyle = other._drawstyle def _get_rgb_face(self, alt=False): facecolor = self._get_markerfacecolor(alt=alt) if is_string_like(facecolor) and facecolor.lower() == 'none': rgbFace = None else: rgbFace = colorConverter.to_rgb(facecolor) return rgbFace def _get_rgba_face(self, alt=False): facecolor = self._get_markerfacecolor(alt=alt) if is_string_like(facecolor) and facecolor.lower() == 'none': rgbaFace = None else: rgbaFace = colorConverter.to_rgba(facecolor, self._alpha) return rgbaFace def _get_rgba_ln_color(self, alt=False): return colorConverter.to_rgba(self._color, self._alpha) # some aliases.... def set_aa(self, val): 'alias for set_antialiased' self.set_antialiased(val) def set_c(self, val): 'alias for set_color' self.set_color(val) def set_ls(self, val): """alias for set_linestyle""" self.set_linestyle(val) def set_lw(self, val): """alias for set_linewidth""" self.set_linewidth(val) def set_mec(self, val): """alias for set_markeredgecolor""" self.set_markeredgecolor(val) def set_mew(self, val): """alias for set_markeredgewidth""" self.set_markeredgewidth(val) def set_mfc(self, val): """alias for set_markerfacecolor""" self.set_markerfacecolor(val) def set_mfcalt(self, val): """alias for set_markerfacecoloralt""" self.set_markerfacecoloralt(val) def set_ms(self, val): """alias for set_markersize""" self.set_markersize(val) def get_aa(self): """alias for get_antialiased""" return self.get_antialiased() def get_c(self): """alias for get_color""" return self.get_color() def get_ls(self): """alias for get_linestyle""" return self.get_linestyle() def get_lw(self): """alias for get_linewidth""" return self.get_linewidth() def get_mec(self): """alias for get_markeredgecolor""" return self.get_markeredgecolor() def get_mew(self): """alias for get_markeredgewidth""" return self.get_markeredgewidth() def get_mfc(self): """alias for get_markerfacecolor""" return self.get_markerfacecolor() def get_mfcalt(self, alt=False): """alias for get_markerfacecoloralt""" return self.get_markerfacecoloralt() def get_ms(self): """alias for get_markersize""" return self.get_markersize() def set_dash_joinstyle(self, s): """ Set the join style for dashed linestyles ACCEPTS: ['miter' | 'round' | 'bevel'] """ s = s.lower() if s not in self.validJoin: raise ValueError('set_dash_joinstyle passed "%s";\n' % (s,) + 'valid joinstyles are %s' % (self.validJoin,)) if self._dashjoinstyle != s: self.stale = True self._dashjoinstyle = s def set_solid_joinstyle(self, s): """ Set the join style for solid linestyles ACCEPTS: ['miter' | 'round' | 'bevel'] """ s = s.lower() if s not in self.validJoin: raise ValueError('set_solid_joinstyle passed "%s";\n' % (s,) + 'valid joinstyles are %s' % (self.validJoin,)) if self._solidjoinstyle != s: self.stale = True self._solidjoinstyle = s def get_dash_joinstyle(self): """ Get the join style for dashed linestyles """ return self._dashjoinstyle def get_solid_joinstyle(self): """ Get the join style for solid linestyles """ return self._solidjoinstyle def set_dash_capstyle(self, s): """ Set the cap style for dashed linestyles ACCEPTS: ['butt' | 'round' | 'projecting'] """ s = s.lower() if s not in self.validCap: raise ValueError('set_dash_capstyle passed "%s";\n' % (s,) + 'valid capstyles are %s' % (self.validCap,)) if self._dashcapstyle != s: self.stale = True self._dashcapstyle = s def set_solid_capstyle(self, s): """ Set the cap style for solid linestyles ACCEPTS: ['butt' | 'round' | 'projecting'] """ s = s.lower() if s not in self.validCap: raise ValueError('set_solid_capstyle passed "%s";\n' % (s,) + 'valid capstyles are %s' % (self.validCap,)) if self._solidcapstyle != s: self.stale = True self._solidcapstyle = s def get_dash_capstyle(self): """ Get the cap style for dashed linestyles """ return self._dashcapstyle def get_solid_capstyle(self): """ Get the cap style for solid linestyles """ return self._solidcapstyle def is_dashed(self): 'return True if line is dashstyle' return self._linestyle in ('--', '-.', ':') class VertexSelector(object): """ Manage the callbacks to maintain a list of selected vertices for :class:`matplotlib.lines.Line2D`. Derived classes should override :meth:`~matplotlib.lines.VertexSelector.process_selected` to do something with the picks. Here is an example which highlights the selected verts with red circles:: import numpy as np import matplotlib.pyplot as plt import matplotlib.lines as lines class HighlightSelected(lines.VertexSelector): def __init__(self, line, fmt='ro', **kwargs): lines.VertexSelector.__init__(self, line) self.markers, = self.axes.plot([], [], fmt, **kwargs) def process_selected(self, ind, xs, ys): self.markers.set_data(xs, ys) self.canvas.draw() fig = plt.figure() ax = fig.add_subplot(111) x, y = np.random.rand(2, 30) line, = ax.plot(x, y, 'bs-', picker=5) selector = HighlightSelected(line) plt.show() """ def __init__(self, line): """ Initialize the class with a :class:`matplotlib.lines.Line2D` instance. The line should already be added to some :class:`matplotlib.axes.Axes` instance and should have the picker property set. """ if line.axes is None: raise RuntimeError('You must first add the line to the Axes') if line.get_picker() is None: raise RuntimeError('You must first set the picker property ' 'of the line') self.axes = line.axes self.line = line self.canvas = self.axes.figure.canvas self.cid = self.canvas.mpl_connect('pick_event', self.onpick) self.ind = set() def process_selected(self, ind, xs, ys): """ Default "do nothing" implementation of the :meth:`process_selected` method. *ind* are the indices of the selected vertices. *xs* and *ys* are the coordinates of the selected vertices. """ pass def onpick(self, event): """When the line is picked, update the set of selected indicies.""" if event.artist is not self.line: return for i in event.ind: if i in self.ind: self.ind.remove(i) else: self.ind.add(i) ind = list(self.ind) ind.sort() xdata, ydata = self.line.get_data() self.process_selected(ind, xdata[ind], ydata[ind]) lineStyles = Line2D._lineStyles lineMarkers = MarkerStyle.markers drawStyles = Line2D.drawStyles fillStyles = MarkerStyle.fillstyles docstring.interpd.update(Line2D=artist.kwdoc(Line2D)) # You can not set the docstring of an instancemethod, # but you can on the underlying function. Go figure. docstring.dedent_interpd(Line2D.__init__)