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433 lines
15 KiB
433 lines
15 KiB
5 months ago
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"""Implicit plotting module for SymPy.
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Explanation
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===========
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The module implements a data series called ImplicitSeries which is used by
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``Plot`` class to plot implicit plots for different backends. The module,
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by default, implements plotting using interval arithmetic. It switches to a
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fall back algorithm if the expression cannot be plotted using interval arithmetic.
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It is also possible to specify to use the fall back algorithm for all plots.
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Boolean combinations of expressions cannot be plotted by the fall back
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algorithm.
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See Also
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========
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sympy.plotting.plot
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References
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==========
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.. [1] Jeffrey Allen Tupper. Reliable Two-Dimensional Graphing Methods for
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Mathematical Formulae with Two Free Variables.
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.. [2] Jeffrey Allen Tupper. Graphing Equations with Generalized Interval
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Arithmetic. Master's thesis. University of Toronto, 1996
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"""
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from .plot import BaseSeries, Plot
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from .experimental_lambdify import experimental_lambdify, vectorized_lambdify
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from .intervalmath import interval
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from sympy.core.relational import (Equality, GreaterThan, LessThan,
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Relational, StrictLessThan, StrictGreaterThan)
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from sympy.core.containers import Tuple
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from sympy.core.relational import Eq
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from sympy.core.symbol import (Dummy, Symbol)
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from sympy.core.sympify import sympify
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from sympy.external import import_module
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from sympy.logic.boolalg import BooleanFunction
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from sympy.polys.polyutils import _sort_gens
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from sympy.utilities.decorator import doctest_depends_on
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from sympy.utilities.iterables import flatten
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import warnings
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class ImplicitSeries(BaseSeries):
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""" Representation for Implicit plot """
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is_implicit = True
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def __init__(self, expr, var_start_end_x, var_start_end_y,
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has_equality, use_interval_math, depth, nb_of_points,
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line_color):
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super().__init__()
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self.expr = sympify(expr)
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self.label = self.expr
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self.var_x = sympify(var_start_end_x[0])
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self.start_x = float(var_start_end_x[1])
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self.end_x = float(var_start_end_x[2])
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self.var_y = sympify(var_start_end_y[0])
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self.start_y = float(var_start_end_y[1])
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self.end_y = float(var_start_end_y[2])
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self.get_points = self.get_raster
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self.has_equality = has_equality # If the expression has equality, i.e.
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#Eq, Greaterthan, LessThan.
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self.nb_of_points = nb_of_points
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self.use_interval_math = use_interval_math
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self.depth = 4 + depth
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self.line_color = line_color
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def __str__(self):
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return ('Implicit equation: %s for '
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'%s over %s and %s over %s') % (
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str(self.expr),
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str(self.var_x),
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str((self.start_x, self.end_x)),
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str(self.var_y),
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str((self.start_y, self.end_y)))
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def get_raster(self):
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func = experimental_lambdify((self.var_x, self.var_y), self.expr,
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use_interval=True)
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xinterval = interval(self.start_x, self.end_x)
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yinterval = interval(self.start_y, self.end_y)
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try:
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func(xinterval, yinterval)
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except AttributeError:
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# XXX: AttributeError("'list' object has no attribute 'is_real'")
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# That needs fixing somehow - we shouldn't be catching
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# AttributeError here.
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if self.use_interval_math:
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warnings.warn("Adaptive meshing could not be applied to the"
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" expression. Using uniform meshing.", stacklevel=7)
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self.use_interval_math = False
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if self.use_interval_math:
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return self._get_raster_interval(func)
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else:
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return self._get_meshes_grid()
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def _get_raster_interval(self, func):
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""" Uses interval math to adaptively mesh and obtain the plot"""
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k = self.depth
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interval_list = []
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#Create initial 32 divisions
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np = import_module('numpy')
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xsample = np.linspace(self.start_x, self.end_x, 33)
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ysample = np.linspace(self.start_y, self.end_y, 33)
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#Add a small jitter so that there are no false positives for equality.
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# Ex: y==x becomes True for x interval(1, 2) and y interval(1, 2)
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#which will draw a rectangle.
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jitterx = (np.random.rand(
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len(xsample)) * 2 - 1) * (self.end_x - self.start_x) / 2**20
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jittery = (np.random.rand(
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len(ysample)) * 2 - 1) * (self.end_y - self.start_y) / 2**20
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xsample += jitterx
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ysample += jittery
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xinter = [interval(x1, x2) for x1, x2 in zip(xsample[:-1],
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xsample[1:])]
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yinter = [interval(y1, y2) for y1, y2 in zip(ysample[:-1],
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ysample[1:])]
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interval_list = [[x, y] for x in xinter for y in yinter]
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plot_list = []
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#recursive call refinepixels which subdivides the intervals which are
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#neither True nor False according to the expression.
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def refine_pixels(interval_list):
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""" Evaluates the intervals and subdivides the interval if the
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expression is partially satisfied."""
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temp_interval_list = []
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plot_list = []
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for intervals in interval_list:
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#Convert the array indices to x and y values
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intervalx = intervals[0]
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intervaly = intervals[1]
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func_eval = func(intervalx, intervaly)
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#The expression is valid in the interval. Change the contour
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#array values to 1.
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if func_eval[1] is False or func_eval[0] is False:
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pass
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elif func_eval == (True, True):
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plot_list.append([intervalx, intervaly])
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elif func_eval[1] is None or func_eval[0] is None:
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#Subdivide
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avgx = intervalx.mid
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avgy = intervaly.mid
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a = interval(intervalx.start, avgx)
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b = interval(avgx, intervalx.end)
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c = interval(intervaly.start, avgy)
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d = interval(avgy, intervaly.end)
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temp_interval_list.append([a, c])
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temp_interval_list.append([a, d])
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temp_interval_list.append([b, c])
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temp_interval_list.append([b, d])
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return temp_interval_list, plot_list
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while k >= 0 and len(interval_list):
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interval_list, plot_list_temp = refine_pixels(interval_list)
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plot_list.extend(plot_list_temp)
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k = k - 1
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#Check whether the expression represents an equality
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#If it represents an equality, then none of the intervals
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#would have satisfied the expression due to floating point
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#differences. Add all the undecided values to the plot.
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if self.has_equality:
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for intervals in interval_list:
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intervalx = intervals[0]
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intervaly = intervals[1]
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func_eval = func(intervalx, intervaly)
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if func_eval[1] and func_eval[0] is not False:
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plot_list.append([intervalx, intervaly])
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return plot_list, 'fill'
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def _get_meshes_grid(self):
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"""Generates the mesh for generating a contour.
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In the case of equality, ``contour`` function of matplotlib can
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be used. In other cases, matplotlib's ``contourf`` is used.
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"""
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equal = False
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if isinstance(self.expr, Equality):
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expr = self.expr.lhs - self.expr.rhs
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equal = True
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elif isinstance(self.expr, (GreaterThan, StrictGreaterThan)):
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expr = self.expr.lhs - self.expr.rhs
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elif isinstance(self.expr, (LessThan, StrictLessThan)):
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expr = self.expr.rhs - self.expr.lhs
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else:
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raise NotImplementedError("The expression is not supported for "
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"plotting in uniform meshed plot.")
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np = import_module('numpy')
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xarray = np.linspace(self.start_x, self.end_x, self.nb_of_points)
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yarray = np.linspace(self.start_y, self.end_y, self.nb_of_points)
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x_grid, y_grid = np.meshgrid(xarray, yarray)
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func = vectorized_lambdify((self.var_x, self.var_y), expr)
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z_grid = func(x_grid, y_grid)
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z_grid[np.ma.where(z_grid < 0)] = -1
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z_grid[np.ma.where(z_grid > 0)] = 1
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if equal:
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return xarray, yarray, z_grid, 'contour'
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else:
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return xarray, yarray, z_grid, 'contourf'
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@doctest_depends_on(modules=('matplotlib',))
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def plot_implicit(expr, x_var=None, y_var=None, adaptive=True, depth=0,
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points=300, line_color="blue", show=True, **kwargs):
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"""A plot function to plot implicit equations / inequalities.
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Arguments
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=========
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- expr : The equation / inequality that is to be plotted.
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- x_var (optional) : symbol to plot on x-axis or tuple giving symbol
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and range as ``(symbol, xmin, xmax)``
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- y_var (optional) : symbol to plot on y-axis or tuple giving symbol
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and range as ``(symbol, ymin, ymax)``
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If neither ``x_var`` nor ``y_var`` are given then the free symbols in the
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expression will be assigned in the order they are sorted.
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The following keyword arguments can also be used:
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- ``adaptive`` Boolean. The default value is set to True. It has to be
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set to False if you want to use a mesh grid.
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- ``depth`` integer. The depth of recursion for adaptive mesh grid.
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Default value is 0. Takes value in the range (0, 4).
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- ``points`` integer. The number of points if adaptive mesh grid is not
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used. Default value is 300.
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- ``show`` Boolean. Default value is True. If set to False, the plot will
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not be shown. See ``Plot`` for further information.
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- ``title`` string. The title for the plot.
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- ``xlabel`` string. The label for the x-axis
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- ``ylabel`` string. The label for the y-axis
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Aesthetics options:
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- ``line_color``: float or string. Specifies the color for the plot.
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See ``Plot`` to see how to set color for the plots.
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Default value is "Blue"
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plot_implicit, by default, uses interval arithmetic to plot functions. If
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the expression cannot be plotted using interval arithmetic, it defaults to
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a generating a contour using a mesh grid of fixed number of points. By
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setting adaptive to False, you can force plot_implicit to use the mesh
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grid. The mesh grid method can be effective when adaptive plotting using
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interval arithmetic, fails to plot with small line width.
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Examples
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========
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Plot expressions:
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.. plot::
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:context: reset
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:format: doctest
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:include-source: True
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>>> from sympy import plot_implicit, symbols, Eq, And
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>>> x, y = symbols('x y')
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Without any ranges for the symbols in the expression:
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.. plot::
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:context: close-figs
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:format: doctest
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:include-source: True
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>>> p1 = plot_implicit(Eq(x**2 + y**2, 5))
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With the range for the symbols:
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.. plot::
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:context: close-figs
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:format: doctest
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:include-source: True
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>>> p2 = plot_implicit(
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... Eq(x**2 + y**2, 3), (x, -3, 3), (y, -3, 3))
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With depth of recursion as argument:
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.. plot::
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:context: close-figs
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:format: doctest
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:include-source: True
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>>> p3 = plot_implicit(
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... Eq(x**2 + y**2, 5), (x, -4, 4), (y, -4, 4), depth = 2)
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Using mesh grid and not using adaptive meshing:
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.. plot::
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:context: close-figs
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:format: doctest
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:include-source: True
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>>> p4 = plot_implicit(
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... Eq(x**2 + y**2, 5), (x, -5, 5), (y, -2, 2),
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... adaptive=False)
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Using mesh grid without using adaptive meshing with number of points
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specified:
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.. plot::
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:context: close-figs
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:format: doctest
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:include-source: True
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>>> p5 = plot_implicit(
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... Eq(x**2 + y**2, 5), (x, -5, 5), (y, -2, 2),
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... adaptive=False, points=400)
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Plotting regions:
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.. plot::
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:context: close-figs
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:format: doctest
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:include-source: True
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>>> p6 = plot_implicit(y > x**2)
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Plotting Using boolean conjunctions:
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.. plot::
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:context: close-figs
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:format: doctest
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:include-source: True
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>>> p7 = plot_implicit(And(y > x, y > -x))
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When plotting an expression with a single variable (y - 1, for example),
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specify the x or the y variable explicitly:
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.. plot::
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:context: close-figs
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:format: doctest
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:include-source: True
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>>> p8 = plot_implicit(y - 1, y_var=y)
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>>> p9 = plot_implicit(x - 1, x_var=x)
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"""
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has_equality = False # Represents whether the expression contains an Equality,
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#GreaterThan or LessThan
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def arg_expand(bool_expr):
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"""
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Recursively expands the arguments of an Boolean Function
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"""
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for arg in bool_expr.args:
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if isinstance(arg, BooleanFunction):
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arg_expand(arg)
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elif isinstance(arg, Relational):
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arg_list.append(arg)
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arg_list = []
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if isinstance(expr, BooleanFunction):
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arg_expand(expr)
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#Check whether there is an equality in the expression provided.
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if any(isinstance(e, (Equality, GreaterThan, LessThan))
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for e in arg_list):
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has_equality = True
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elif not isinstance(expr, Relational):
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expr = Eq(expr, 0)
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has_equality = True
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elif isinstance(expr, (Equality, GreaterThan, LessThan)):
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has_equality = True
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xyvar = [i for i in (x_var, y_var) if i is not None]
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free_symbols = expr.free_symbols
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range_symbols = Tuple(*flatten(xyvar)).free_symbols
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undeclared = free_symbols - range_symbols
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if len(free_symbols & range_symbols) > 2:
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raise NotImplementedError("Implicit plotting is not implemented for "
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"more than 2 variables")
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#Create default ranges if the range is not provided.
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default_range = Tuple(-5, 5)
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def _range_tuple(s):
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if isinstance(s, Symbol):
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return Tuple(s) + default_range
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if len(s) == 3:
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return Tuple(*s)
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raise ValueError('symbol or `(symbol, min, max)` expected but got %s' % s)
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if len(xyvar) == 0:
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xyvar = list(_sort_gens(free_symbols))
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var_start_end_x = _range_tuple(xyvar[0])
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x = var_start_end_x[0]
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if len(xyvar) != 2:
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if x in undeclared or not undeclared:
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xyvar.append(Dummy('f(%s)' % x.name))
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else:
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xyvar.append(undeclared.pop())
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var_start_end_y = _range_tuple(xyvar[1])
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#Check whether the depth is greater than 4 or less than 0.
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if depth > 4:
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depth = 4
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elif depth < 0:
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depth = 0
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series_argument = ImplicitSeries(expr, var_start_end_x, var_start_end_y,
|
||
|
has_equality, adaptive, depth,
|
||
|
points, line_color)
|
||
|
|
||
|
#set the x and y limits
|
||
|
kwargs['xlim'] = tuple(float(x) for x in var_start_end_x[1:])
|
||
|
kwargs['ylim'] = tuple(float(y) for y in var_start_end_y[1:])
|
||
|
# set the x and y labels
|
||
|
kwargs.setdefault('xlabel', var_start_end_x[0])
|
||
|
kwargs.setdefault('ylabel', var_start_end_y[0])
|
||
|
p = Plot(series_argument, **kwargs)
|
||
|
if show:
|
||
|
p.show()
|
||
|
return p
|