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plot.py
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plot.py
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"""Plotting module for Sympy.
A plot is represented by the ``Plot`` class that contains a reference to the
backend and a list of the data series to be plotted. The data series are
instances of classes meant to simplify getting points and meshes from sympy
expressions. ``plot_backends`` is a dictionary with all the backends.
This module gives only the essential. For all the fancy stuff use directly
the backend. You can get the backend wrapper for every plot from the
``_backend`` attribute. Moreover the data series classes have various useful
methods like ``get_points``, ``get_segments``, ``get_meshes``, etc, that may
be useful if you wish to use another plotting library.
Especially if you need publication ready graphs and this module is not enough
for you - just get the ``_backend`` attribute and add whatever you want
directly to it. In the case of matplotlib (the common way to graph data in
python) just copy ``_backend.fig`` which is the figure and ``_backend.ax``
which is the axis and work on them as you would on any other matplotlib object.
Simplicity of code takes much greater importance than performance. Don't use it
if you care at all about performance. A new backend instance is initialized
every time you call ``show()`` and the old one is left to the garbage collector.
"""
from __future__ import print_function, division
from inspect import getargspec
from itertools import chain
from collections import Callable
import warnings
from sympy import sympify, Expr, Tuple, Dummy
from sympy.external import import_module
from sympy.utilities.decorator import doctest_depends_on
from .experimental_lambdify import (vectorized_lambdify, lambdify)
# N.B.
# When changing the minimum module version for matplotlib, please change
# the same in the `SymPyDocTestFinder`` in `sympy/utilities/runtests.py`
# Backend specific imports - textplot
from sympy.plotting.textplot import textplot
# Global variable
# Set to False when running tests / doctests so that the plots don't show.
_show = True
def unset_show():
global _show
_show = False
##############################################################################
# The public interface
##############################################################################
class Plot(object):
"""The central class of the plotting module.
For interactive work the function ``plot`` is better suited.
This class permits the plotting of sympy expressions using numerous
backends (matplotlib, textplot, the old pyglet module for sympy, Google
charts api, etc).
The figure can contain an arbitrary number of plots of sympy expressions,
lists of coordinates of points, etc. Plot has a private attribute _series that
contains all data series to be plotted (expressions for lines or surfaces,
lists of points, etc (all subclasses of BaseSeries)). Those data series are
instances of classes not imported by ``from sympy import *``.
The customization of the figure is on two levels. Global options that
concern the figure as a whole (eg title, xlabel, scale, etc) and
per-data series options (eg name) and aesthetics (eg. color, point shape,
line type, etc.).
The difference between options and aesthetics is that an aesthetic can be
a function of the coordinates (or parameters in a parametric plot). The
supported values for an aesthetic are:
- None (the backend uses default values)
- a constant
- a function of one variable (the first coordinate or parameter)
- a function of two variables (the first and second coordinate or
parameters)
- a function of three variables (only in nonparametric 3D plots)
Their implementation depends on the backend so they may not work in some
backends.
If the plot is parametric and the arity of the aesthetic function permits
it the aesthetic is calculated over parameters and not over coordinates.
If the arity does not permit calculation over parameters the calculation is
done over coordinates.
Only cartesian coordinates are supported for the moment, but you can use
the parametric plots to plot in polar, spherical and cylindrical
coordinates.
The arguments for the constructor Plot must be subclasses of BaseSeries.
Any global option can be specified as a keyword argument.
The global options for a figure are:
- title : str
- xlabel : str
- ylabel : str
- legend : bool
- xscale : {'linear', 'log'}
- yscale : {'linear', 'log'}
- axis : bool
- axis_center : tuple of two floats or {'center', 'auto'}
- xlim : tuple of two floats
- ylim : tuple of two floats
- aspect_ratio : tuple of two floats or {'auto'}
- autoscale : bool
- margin : float in [0, 1]
The per data series options and aesthetics are:
There are none in the base series. See below for options for subclasses.
Some data series support additional aesthetics or options:
ListSeries, LineOver1DRangeSeries, Parametric2DLineSeries,
Parametric3DLineSeries support the following:
Aesthetics:
- line_color : function which returns a float.
options:
- label : str
- steps : bool
- integers_only : bool
SurfaceOver2DRangeSeries, ParametricSurfaceSeries support the following:
aesthetics:
- surface_color : function which returns a float.
"""
def __init__(self, *args, **kwargs):
super(Plot, self).__init__()
# Options for the graph as a whole.
# The possible values for each option are described in the docstring of
# Plot. They are based purely on convention, no checking is done.
self.title = None
self.xlabel = None
self.ylabel = None
self.aspect_ratio = 'auto'
self.xlim = None
self.ylim = None
self.axis_center = 'auto'
self.axis = True
self.xscale = 'linear'
self.yscale = 'linear'
self.legend = False
self.autoscale = True
self.margin = 0
# Contains the data objects to be plotted. The backend should be smart
# enough to iterate over this list.
self._series = []
self._series.extend(args)
# The backend type. On every show() a new backend instance is created
# in self._backend which is tightly coupled to the Plot instance
# (thanks to the parent attribute of the backend).
self.backend = DefaultBackend
# The keyword arguments should only contain options for the plot.
for key, val in kwargs.items():
if hasattr(self, key):
setattr(self, key, val)
def show(self):
# TODO move this to the backend (also for save)
if hasattr(self, '_backend'):
self._backend.close()
self._backend = self.backend(self)
self._backend.show()
def save(self, path):
if hasattr(self, '_backend'):
self._backend.close()
self._backend = self.backend(self)
self._backend.save(path)
def __str__(self):
series_strs = [('[%d]: ' % i) + str(s)
for i, s in enumerate(self._series)]
return 'Plot object containing:\n' + '\n'.join(series_strs)
def __getitem__(self, index):
return self._series[index]
def __setitem__(self, index, *args):
if len(args) == 1 and isinstance(args[0], BaseSeries):
self._series[index] = args
def __delitem__(self, index):
del self._series[index]
def append(self, *args):
"""Adds one more graph to the figure."""
if len(args) == 1 and isinstance(args[0], BaseSeries):
self._series.append(*args)
else:
self._series.append(Series(*args))
def extend(self, arg):
"""Adds the series from another plot or a list of series."""
if isinstance(arg, Plot):
self._series.extend(arg._series)
else:
self._series.extend(arg)
##############################################################################
# Data Series
##############################################################################
#TODO more general way to calculate aesthetics (see get_color_array)
### The base class for all series
class BaseSeries(object):
"""Base class for the data objects containing stuff to be plotted.
The backend should check if it supports the data series that it's given.
(eg TextBackend supports only LineOver1DRange).
It's the backend responsibility to know how to use the class of
data series that it's given.
Some data series classes are grouped (using a class attribute like is_2Dline)
according to the api they present (based only on convention). The backend is
not obliged to use that api (eg. The LineOver1DRange belongs to the
is_2Dline group and presents the get_points method, but the
TextBackend does not use the get_points method).
"""
# Some flags follow. The rationale for using flags instead of checking base
# classes is that setting multiple flags is simpler than multiple
# inheritance.
is_2Dline = False
# Some of the backends expect:
# - get_points returning 1D np.arrays list_x, list_y
# - get_segments returning np.array (done in Line2DBaseSeries)
# - get_color_array returning 1D np.array (done in Line2DBaseSeries)
# with the colors calculated at the points from get_points
is_3Dline = False
# Some of the backends expect:
# - get_points returning 1D np.arrays list_x, list_y, list_y
# - get_segments returning np.array (done in Line2DBaseSeries)
# - get_color_array returning 1D np.array (done in Line2DBaseSeries)
# with the colors calculated at the points from get_points
is_3Dsurface = False
# Some of the backends expect:
# - get_meshes returning mesh_x, mesh_y, mesh_z (2D np.arrays)
# - get_points an alias for get_meshes
is_contour = False
# Some of the backends expect:
# - get_meshes returning mesh_x, mesh_y, mesh_z (2D np.arrays)
# - get_points an alias for get_meshes
is_implicit = False
# Some of the backends expect:
# - get_meshes returning mesh_x (1D array), mesh_y(1D array,
# mesh_z (2D np.arrays)
# - get_points an alias for get_meshes
#Different from is_contour as the colormap in backend will be
#different
is_parametric = False
# The calculation of aesthetics expects:
# - get_parameter_points returning one or two np.arrays (1D or 2D)
# used for calculation aesthetics
def __init__(self):
super(BaseSeries, self).__init__()
@property
def is_3D(self):
flags3D = [
self.is_3Dline,
self.is_3Dsurface
]
return any(flags3D)
@property
def is_line(self):
flagslines = [
self.is_2Dline,
self.is_3Dline
]
return any(flagslines)
### 2D lines
class Line2DBaseSeries(BaseSeries):
"""A base class for 2D lines.
- adding the label, steps and only_integers options
- making is_2Dline true
- defining get_segments and get_color_array
"""
is_2Dline = True
_dim = 2
def __init__(self):
super(Line2DBaseSeries, self).__init__()
self.label = None
self.steps = False
self.only_integers = False
self.line_color = None
def get_segments(self):
np = import_module('numpy')
points = self.get_points()
if self.steps is True:
x = np.array((points[0], points[0])).T.flatten()[1:]
y = np.array((points[1], points[1])).T.flatten()[:-1]
points = (x, y)
points = np.ma.array(points).T.reshape(-1, 1, self._dim)
return np.ma.concatenate([points[:-1], points[1:]], axis=1)
def get_color_array(self):
np = import_module('numpy')
c = self.line_color
if hasattr(c, '__call__'):
f = np.vectorize(c)
arity = len(getargspec(c)[0])
if arity == 1 and self.is_parametric:
x = self.get_parameter_points()
return f(centers_of_segments(x))
else:
variables = list(map(centers_of_segments, self.get_points()))
if arity == 1:
return f(variables[0])
elif arity == 2:
return f(*variables[:2])
else: # only if the line is 3D (otherwise raises an error)
return f(*variables)
else:
return c*np.ones(self.nb_of_points)
class List2DSeries(Line2DBaseSeries):
"""Representation for a line consisting of list of points."""
def __init__(self, list_x, list_y):
np = import_module('numpy')
super(List2DSeries, self).__init__()
self.list_x = np.array(list_x)
self.list_y = np.array(list_y)
self.label = 'list'
def __str__(self):
return 'list plot'
def get_points(self):
return (self.list_x, self.list_y)
class LineOver1DRangeSeries(Line2DBaseSeries):
"""Representation for a line consisting of a sympy expression over a range."""
def __init__(self, expr, var_start_end, **kwargs):
super(LineOver1DRangeSeries, self).__init__()
self.expr = sympify(expr)
self.label = str(self.expr)
self.var = sympify(var_start_end[0])
self.start = float(var_start_end[1])
self.end = float(var_start_end[2])
self.nb_of_points = kwargs.get('nb_of_points', 300)
self.adaptive = kwargs.get('adaptive', True)
self.depth = kwargs.get('depth', 12)
self.line_color = kwargs.get('line_color', None)
def __str__(self):
return 'cartesian line: %s for %s over %s' % (
str(self.expr), str(self.var), str((self.start, self.end)))
def get_segments(self):
"""
Adaptively gets segments for plotting.
The adaptive sampling is done by recursively checking if three
points are almost collinear. If they are not collinear, then more
points are added between those points.
References
==========
[1] Adaptive polygonal approximation of parametric curves,
Luiz Henrique de Figueiredo.
"""
if self.only_integers or not self.adaptive:
return super(LineOver1DRangeSeries, self).get_segments()
else:
f = lambdify([self.var], self.expr)
list_segments = []
def sample(p, q, depth):
""" Samples recursively if three points are almost collinear.
For depth < 6, points are added irrespective of whether they
satisfy the collinearity condition or not. The maximum depth
allowed is 12.
"""
np = import_module('numpy')
#Randomly sample to avoid aliasing.
random = 0.45 + np.random.rand() * 0.1
xnew = p[0] + random * (q[0] - p[0])
ynew = f(xnew)
new_point = np.array([xnew, ynew])
#Maximum depth
if depth > self.depth:
list_segments.append([p, q])
#Sample irrespective of whether the line is flat till the
#depth of 6. We are not using linspace to avoid aliasing.
elif depth < 6:
sample(p, new_point, depth + 1)
sample(new_point, q, depth + 1)
#Sample ten points if complex values are encountered
#at both ends. If there is a real value in between, then
#sample those points further.
elif p[1] is None and q[1] is None:
xarray = np.linspace(p[0], q[0], 10)
yarray = list(map(f, xarray))
if any(y is not None for y in yarray):
for i in range(len(yarray) - 1):
if yarray[i] is not None or yarray[i + 1] is not None:
sample([xarray[i], yarray[i]],
[xarray[i + 1], yarray[i + 1]], depth + 1)
#Sample further if one of the end points in None( i.e. a complex
#value) or the three points are not almost collinear.
elif (p[1] is None or q[1] is None or new_point[1] is None
or not flat(p, new_point, q)):
sample(p, new_point, depth + 1)
sample(new_point, q, depth + 1)
else:
list_segments.append([p, q])
f_start = f(self.start)
f_end = f(self.end)
sample([self.start, f_start], [self.end, f_end], 0)
return list_segments
def get_points(self):
np = import_module('numpy')
if self.only_integers is True:
list_x = np.linspace(int(self.start), int(self.end),
num=int(self.end) - int(self.start) + 1)
else:
list_x = np.linspace(self.start, self.end, num=self.nb_of_points)
f = vectorized_lambdify([self.var], self.expr)
list_y = f(list_x)
return (list_x, list_y)
class Parametric2DLineSeries(Line2DBaseSeries):
"""Representation for a line consisting of two parametric sympy expressions
over a range."""
is_parametric = True
def __init__(self, expr_x, expr_y, var_start_end, **kwargs):
super(Parametric2DLineSeries, self).__init__()
self.expr_x = sympify(expr_x)
self.expr_y = sympify(expr_y)
self.label = "(%s, %s)" % (str(self.expr_x), str(self.expr_y))
self.var = sympify(var_start_end[0])
self.start = float(var_start_end[1])
self.end = float(var_start_end[2])
self.nb_of_points = kwargs.get('nb_of_points', 300)
self.adaptive = kwargs.get('adaptive', True)
self.depth = kwargs.get('depth', 12)
self.line_color = kwargs.get('line_color', None)
def __str__(self):
return 'parametric cartesian line: (%s, %s) for %s over %s' % (
str(self.expr_x), str(self.expr_y), str(self.var),
str((self.start, self.end)))
def get_parameter_points(self):
np = import_module('numpy')
return np.linspace(self.start, self.end, num=self.nb_of_points)
def get_points(self):
param = self.get_parameter_points()
fx = vectorized_lambdify([self.var], self.expr_x)
fy = vectorized_lambdify([self.var], self.expr_y)
list_x = fx(param)
list_y = fy(param)
return (list_x, list_y)
def get_segments(self):
"""
Adaptively gets segments for plotting.
The adaptive sampling is done by recursively checking if three
points are almost collinear. If they are not collinear, then more
points are added between those points.
References
==========
[1] Adaptive polygonal approximation of parametric curves,
Luiz Henrique de Figueiredo.
"""
if not self.adaptive:
return super(Parametric2DLineSeries, self).get_segments()
f_x = lambdify([self.var], self.expr_x)
f_y = lambdify([self.var], self.expr_y)
list_segments = []
def sample(param_p, param_q, p, q, depth):
""" Samples recursively if three points are almost collinear.
For depth < 6, points are added irrespective of whether they
satisfy the collinearity condition or not. The maximum depth
allowed is 12.
"""
#Randomly sample to avoid aliasing.
np = import_module('numpy')
random = 0.45 + np.random.rand() * 0.1
param_new = param_p + random * (param_q - param_p)
xnew = f_x(param_new)
ynew = f_y(param_new)
new_point = np.array([xnew, ynew])
#Maximum depth
if depth > self.depth:
list_segments.append([p, q])
#Sample irrespective of whether the line is flat till the
#depth of 6. We are not using linspace to avoid aliasing.
elif depth < 6:
sample(param_p, param_new, p, new_point, depth + 1)
sample(param_new, param_q, new_point, q, depth + 1)
#Sample ten points if complex values are encountered
#at both ends. If there is a real value in between, then
#sample those points further.
elif ((p[0] is None and q[1] is None) or
(p[1] is None and q[1] is None)):
param_array = np.linspace(param_p, param_q, 10)
x_array = list(map(f_x, param_array))
y_array = list(map(f_y, param_array))
if any(x is not None and y is not None
for x, y in zip(x_array, y_array)):
for i in range(len(y_array) - 1):
if ((x_array[i] is not None and y_array[i] is not None) or
(x_array[i + 1] is not None and y_array[i + 1] is not None)):
point_a = [x_array[i], y_array[i]]
point_b = [x_array[i + 1], y_array[i + 1]]
sample(param_array[i], param_array[i], point_a,
point_b, depth + 1)
#Sample further if one of the end points in None( ie a complex
#value) or the three points are not almost collinear.
elif (p[0] is None or p[1] is None
or q[1] is None or q[0] is None
or not flat(p, new_point, q)):
sample(param_p, param_new, p, new_point, depth + 1)
sample(param_new, param_q, new_point, q, depth + 1)
else:
list_segments.append([p, q])
f_start_x = f_x(self.start)
f_start_y = f_y(self.start)
start = [f_start_x, f_start_y]
f_end_x = f_x(self.end)
f_end_y = f_y(self.end)
end = [f_end_x, f_end_y]
sample(self.start, self.end, start, end, 0)
return list_segments
### 3D lines
class Line3DBaseSeries(Line2DBaseSeries):
"""A base class for 3D lines.
Most of the stuff is derived from Line2DBaseSeries."""
is_2Dline = False
is_3Dline = True
_dim = 3
def __init__(self):
super(Line3DBaseSeries, self).__init__()
class Parametric3DLineSeries(Line3DBaseSeries):
"""Representation for a 3D line consisting of two parametric sympy
expressions and a range."""
def __init__(self, expr_x, expr_y, expr_z, var_start_end, **kwargs):
super(Parametric3DLineSeries, self).__init__()
self.expr_x = sympify(expr_x)
self.expr_y = sympify(expr_y)
self.expr_z = sympify(expr_z)
self.label = "(%s, %s)" % (str(self.expr_x), str(self.expr_y))
self.var = sympify(var_start_end[0])
self.start = float(var_start_end[1])
self.end = float(var_start_end[2])
self.nb_of_points = kwargs.get('nb_of_points', 300)
self.line_color = kwargs.get('line_color', None)
def __str__(self):
return '3D parametric cartesian line: (%s, %s, %s) for %s over %s' % (
str(self.expr_x), str(self.expr_y), str(self.expr_z),
str(self.var), str((self.start, self.end)))
def get_parameter_points(self):
np = import_module('numpy')
return np.linspace(self.start, self.end, num=self.nb_of_points)
def get_points(self):
param = self.get_parameter_points()
fx = vectorized_lambdify([self.var], self.expr_x)
fy = vectorized_lambdify([self.var], self.expr_y)
fz = vectorized_lambdify([self.var], self.expr_z)
list_x = fx(param)
list_y = fy(param)
list_z = fz(param)
return (list_x, list_y, list_z)
### Surfaces
class SurfaceBaseSeries(BaseSeries):
"""A base class for 3D surfaces."""
is_3Dsurface = True
def __init__(self):
super(SurfaceBaseSeries, self).__init__()
self.surface_color = None
def get_color_array(self):
np = import_module('numpy')
c = self.surface_color
if isinstance(c, Callable):
f = np.vectorize(c)
arity = len(getargspec(c)[0])
if self.is_parametric:
variables = list(map(centers_of_faces, self.get_parameter_meshes()))
if arity == 1:
return f(variables[0])
elif arity == 2:
return f(*variables)
variables = list(map(centers_of_faces, self.get_meshes()))
if arity == 1:
return f(variables[0])
elif arity == 2:
return f(*variables[:2])
else:
return f(*variables)
else:
return c*np.ones(self.nb_of_points)
class SurfaceOver2DRangeSeries(SurfaceBaseSeries):
"""Representation for a 3D surface consisting of a sympy expression and 2D
range."""
def __init__(self, expr, var_start_end_x, var_start_end_y, **kwargs):
super(SurfaceOver2DRangeSeries, self).__init__()
self.expr = sympify(expr)
self.var_x = sympify(var_start_end_x[0])
self.start_x = float(var_start_end_x[1])
self.end_x = float(var_start_end_x[2])
self.var_y = sympify(var_start_end_y[0])
self.start_y = float(var_start_end_y[1])
self.end_y = float(var_start_end_y[2])
self.nb_of_points_x = kwargs.get('nb_of_points_x', 50)
self.nb_of_points_y = kwargs.get('nb_of_points_y', 50)
self.surface_color = kwargs.get('surface_color', None)
def __str__(self):
return ('cartesian surface: %s for'
' %s over %s and %s over %s') % (
str(self.expr),
str(self.var_x),
str((self.start_x, self.end_x)),
str(self.var_y),
str((self.start_y, self.end_y)))
def get_meshes(self):
np = import_module('numpy')
mesh_x, mesh_y = np.meshgrid(np.linspace(self.start_x, self.end_x,
num=self.nb_of_points_x),
np.linspace(self.start_y, self.end_y,
num=self.nb_of_points_y))
f = vectorized_lambdify((self.var_x, self.var_y), self.expr)
return (mesh_x, mesh_y, f(mesh_x, mesh_y))
class ParametricSurfaceSeries(SurfaceBaseSeries):
"""Representation for a 3D surface consisting of three parametric sympy
expressions and a range."""
is_parametric = True
def __init__(
self, expr_x, expr_y, expr_z, var_start_end_u, var_start_end_v,
**kwargs):
super(ParametricSurfaceSeries, self).__init__()
self.expr_x = sympify(expr_x)
self.expr_y = sympify(expr_y)
self.expr_z = sympify(expr_z)
self.var_u = sympify(var_start_end_u[0])
self.start_u = float(var_start_end_u[1])
self.end_u = float(var_start_end_u[2])
self.var_v = sympify(var_start_end_v[0])
self.start_v = float(var_start_end_v[1])
self.end_v = float(var_start_end_v[2])
self.nb_of_points_u = kwargs.get('nb_of_points_u', 50)
self.nb_of_points_v = kwargs.get('nb_of_points_v', 50)
self.surface_color = kwargs.get('surface_color', None)
def __str__(self):
return ('parametric cartesian surface: (%s, %s, %s) for'
' %s over %s and %s over %s') % (
str(self.expr_x),
str(self.expr_y),
str(self.expr_z),
str(self.var_u),
str((self.start_u, self.end_u)),
str(self.var_v),
str((self.start_v, self.end_v)))
def get_parameter_meshes(self):
np = import_module('numpy')
return np.meshgrid(np.linspace(self.start_u, self.end_u,
num=self.nb_of_points_u),
np.linspace(self.start_v, self.end_v,
num=self.nb_of_points_v))
def get_meshes(self):
mesh_u, mesh_v = self.get_parameter_meshes()
fx = vectorized_lambdify((self.var_u, self.var_v), self.expr_x)
fy = vectorized_lambdify((self.var_u, self.var_v), self.expr_y)
fz = vectorized_lambdify((self.var_u, self.var_v), self.expr_z)
return (fx(mesh_u, mesh_v), fy(mesh_u, mesh_v), fz(mesh_u, mesh_v))
### Contours
class ContourSeries(BaseSeries):
"""Representation for a contour plot."""
#The code is mostly repetition of SurfaceOver2DRange.
#XXX: Presently not used in any of those functions.
#XXX: Add contour plot and use this seties.
is_contour = True
def __init__(self, expr, var_start_end_x, var_start_end_y):
super(ContourSeries, self).__init__()
self.nb_of_points_x = 50
self.nb_of_points_y = 50
self.expr = sympify(expr)
self.var_x = sympify(var_start_end_x[0])
self.start_x = float(var_start_end_x[1])
self.end_x = float(var_start_end_x[2])
self.var_y = sympify(var_start_end_y[0])
self.start_y = float(var_start_end_y[1])
self.end_y = float(var_start_end_y[2])
self.get_points = self.get_meshes
def __str__(self):
return ('contour: %s for '
'%s over %s and %s over %s') % (
str(self.expr),
str(self.var_x),
str((self.start_x, self.end_x)),
str(self.var_y),
str((self.start_y, self.end_y)))
def get_meshes(self):
np = import_module('numpy')
mesh_x, mesh_y = np.meshgrid(np.linspace(self.start_x, self.end_x,
num=self.nb_of_points_x),
np.linspace(self.start_y, self.end_y,
num=self.nb_of_points_y))
f = vectorized_lambdify((self.var_x, self.var_y), self.expr)
return (mesh_x, mesh_y, f(mesh_x, mesh_y))
##############################################################################
# Backends
##############################################################################
class BaseBackend(object):
def __init__(self, parent):
super(BaseBackend, self).__init__()
self.parent = parent
## don't have to check for the success of importing matplotlib in each case;
## we will only be using this backend if we can successfully import matploblib
class MatplotlibBackend(BaseBackend):
def __init__(self, parent):
super(MatplotlibBackend, self).__init__(parent)
are_3D = [s.is_3D for s in self.parent._series]
self.matplotlib = import_module('matplotlib',
__import__kwargs={'fromlist': ['pyplot', 'cm', 'collections']},
min_module_version='1.1.0', catch=(RuntimeError,))
self.plt = self.matplotlib.pyplot
self.cm = self.matplotlib.cm
self.LineCollection = self.matplotlib.collections.LineCollection
if any(are_3D) and not all(are_3D):
raise ValueError('The matplotlib backend can not mix 2D and 3D.')
elif not any(are_3D):
self.fig = self.plt.figure()
self.ax = self.fig.add_subplot(111)
self.ax.spines['left'].set_position('zero')
self.ax.spines['right'].set_color('none')
self.ax.spines['bottom'].set_position('zero')
self.ax.spines['top'].set_color('none')
self.ax.spines['left'].set_smart_bounds(True)
self.ax.spines['bottom'].set_smart_bounds(True)
self.ax.xaxis.set_ticks_position('bottom')
self.ax.yaxis.set_ticks_position('left')
elif all(are_3D):
## mpl_toolkits.mplot3d is necessary for
## projection='3d'
mpl_toolkits = import_module('mpl_toolkits',
__import__kwargs={'fromlist': ['mplot3d']})
self.fig = self.plt.figure()
self.ax = self.fig.add_subplot(111, projection='3d')
def process_series(self):
parent = self.parent
for s in self.parent._series:
# Create the collections
if s.is_2Dline:
collection = self.LineCollection(s.get_segments())
self.ax.add_collection(collection)
elif s.is_contour:
self.ax.contour(*s.get_meshes())
elif s.is_3Dline:
# TODO too complicated, I blame matplotlib
mpl_toolkits = import_module('mpl_toolkits',
__import__kwargs={'fromlist': ['mplot3d']})
art3d = mpl_toolkits.mplot3d.art3d
collection = art3d.Line3DCollection(s.get_segments())
self.ax.add_collection(collection)
x, y, z = s.get_points()
self.ax.set_xlim((min(x), max(x)))
self.ax.set_ylim((min(y), max(y)))
self.ax.set_zlim((min(z), max(z)))
elif s.is_3Dsurface:
x, y, z = s.get_meshes()
collection = self.ax.plot_surface(x, y, z, cmap=self.cm.jet,
rstride=1, cstride=1,
linewidth=0.1)
elif s.is_implicit:
#Smart bounds have to be set to False for implicit plots.
self.ax.spines['left'].set_smart_bounds(False)
self.ax.spines['bottom'].set_smart_bounds(False)
points = s.get_raster()
if len(points) == 2:
#interval math plotting
x, y = _matplotlib_list(points[0])
self.ax.fill(x, y, facecolor='b', edgecolor='None' )
else:
# use contourf or contour depending on whether it is
# an inequality or equality.
#XXX: ``contour`` plots multiple lines. Should be fixed.
ListedColormap = self.matplotlib.colors.ListedColormap
colormap = ListedColormap(["white", "blue"])
xarray, yarray, zarray, plot_type = points
if plot_type == 'contour':
self.ax.contour(xarray, yarray, zarray,
contours=(0, 0), fill=False, cmap=colormap)
else:
self.ax.contourf(xarray, yarray, zarray, cmap=colormap)
else:
raise ValueError('The matplotlib backend supports only '
'is_2Dline, is_3Dline, is_3Dsurface and '
'is_contour objects.')
# Customise the collections with the corresponding per-series
# options.
if hasattr(s, 'label'):
collection.set_label(s.label)
if s.is_line and s.line_color:
if isinstance(s.line_color, (float, int)) or isinstance(s.line_color, Callable):
color_array = s.get_color_array()
collection.set_array(color_array)
else:
collection.set_color(s.line_color)
if s.is_3Dsurface and s.surface_color:
if self.matplotlib.__version__ < "1.2.0": # TODO in the distant future remove this check
warnings.warn('The version of matplotlib is too old to use surface coloring.')
elif isinstance(s.surface_color, (float, int)) or isinstance(s.surface_color, Callable):
color_array = s.get_color_array()
color_array = color_array.reshape(color_array.size)
collection.set_array(color_array)
else:
collection.set_color(s.surface_color)
# Set global options.
# TODO The 3D stuff
# XXX The order of those is important.
mpl_toolkits = import_module('mpl_toolkits',
__import__kwargs={'fromlist': ['mplot3d']})
Axes3D = mpl_toolkits.mplot3d.Axes3D
if parent.xscale and not isinstance(self.ax, Axes3D):
self.ax.set_xscale(parent.xscale)
if parent.yscale and not isinstance(self.ax, Axes3D):
self.ax.set_yscale(parent.yscale)
if parent.xlim:
self.ax.set_xlim(parent.xlim)
if parent.ylim:
self.ax.set_ylim(parent.ylim)
if not isinstance(self.ax, Axes3D) or self.matplotlib.__version__ >= '1.2.0': # XXX in the distant future remove this check
self.ax.set_autoscale_on(parent.autoscale)
if parent.axis_center:
val = parent.axis_center
if isinstance(self.ax, Axes3D):
pass
elif val == 'center':
self.ax.spines['left'].set_position('center')
self.ax.spines['bottom'].set_position('center')
elif val == 'auto':
xl, xh = self.ax.get_xlim()
yl, yh = self.ax.get_ylim()
pos_left = ('data', 0) if xl*xh <= 0 else 'center'
pos_bottom = ('data', 0) if yl*yh <= 0 else 'center'
self.ax.spines['left'].set_position(pos_left)
self.ax.spines['bottom'].set_position(pos_bottom)
else:
self.ax.spines['left'].set_position(('data', val[0]))
self.ax.spines['bottom'].set_position(('data', val[1]))
if not parent.axis:
self.ax.set_axis_off()
if parent.legend:
self.ax.legend()
self.ax.legend_.set_visible(parent.legend)
if parent.margin:
self.ax.set_xmargin(parent.margin)
self.ax.set_ymargin(parent.margin)
if parent.title:
self.ax.set_title(parent.title)
if parent.xlabel:
self.ax.set_xlabel(parent.xlabel, position=(1, 0))
if parent.ylabel:
self.ax.set_ylabel(parent.ylabel, position=(0, 1))
def show(self):
self.process_series()
#TODO after fixing https://github.com/ipython/ipython/issues/1255
# you can uncomment the next line and remove the pyplot.show() call
#self.fig.show()
if _show:
self.plt.show()
def save(self, path):
self.process_series()
self.fig.savefig(path)
def close(self):
self.plt.close(self.fig)
class TextBackend(BaseBackend):
def __init__(self, parent):
super(TextBackend, self).__init__(parent)
def show(self):
if len(self.parent._series) != 1:
raise ValueError(
'The TextBackend supports only one graph per Plot.')
elif not isinstance(self.parent._series[0], LineOver1DRangeSeries):
raise ValueError(
'The TextBackend supports only expressions over a 1D range')
else:
ser = self.parent._series[0]
textplot(ser.expr, ser.start, ser.end)
def close(self):
pass
class DefaultBackend(BaseBackend):
def __new__(cls, parent):