820 lines
36 KiB
Python
820 lines
36 KiB
Python
"""
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Module for creating Sankey diagrams using Matplotlib.
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"""
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import logging
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from types import SimpleNamespace
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import numpy as np
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from matplotlib.path import Path
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from matplotlib.patches import PathPatch
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from matplotlib.transforms import Affine2D
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from matplotlib import docstring
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from matplotlib import rcParams
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_log = logging.getLogger(__name__)
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__author__ = "Kevin L. Davies"
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__credits__ = ["Yannick Copin"]
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__license__ = "BSD"
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__version__ = "2011/09/16"
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# Angles [deg/90]
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RIGHT = 0
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UP = 1
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# LEFT = 2
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DOWN = 3
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class Sankey(object):
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"""
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Sankey diagram.
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Sankey diagrams are a specific type of flow diagram, in which
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the width of the arrows is shown proportionally to the flow
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quantity. They are typically used to visualize energy or
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material or cost transfers between processes.
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`Wikipedia (6/1/2011) <https://en.wikipedia.org/wiki/Sankey_diagram>`_
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"""
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def __init__(self, ax=None, scale=1.0, unit='', format='%G', gap=0.25,
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radius=0.1, shoulder=0.03, offset=0.15, head_angle=100,
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margin=0.4, tolerance=1e-6, **kwargs):
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"""
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Create a new Sankey instance.
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Optional keyword arguments:
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=============== ===================================================
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Field Description
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=============== ===================================================
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*ax* axes onto which the data should be plotted
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If *ax* isn't provided, new axes will be created.
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*scale* scaling factor for the flows
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*scale* sizes the width of the paths in order to
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maintain proper layout. The same scale is applied
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to all subdiagrams. The value should be chosen
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such that the product of the scale and the sum of
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the inputs is approximately 1.0 (and the product of
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the scale and the sum of the outputs is
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approximately -1.0).
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*unit* string representing the physical unit associated
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with the flow quantities
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If *unit* is None, then none of the quantities are
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labeled.
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*format* a Python number formatting string to be used in
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labeling the flow as a quantity (i.e., a number
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times a unit, where the unit is given)
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*gap* space between paths that break in/break away
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to/from the top or bottom
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*radius* inner radius of the vertical paths
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*shoulder* size of the shoulders of output arrowS
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*offset* text offset (from the dip or tip of the arrow)
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*head_angle* angle of the arrow heads (and negative of the angle
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of the tails) [deg]
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*margin* minimum space between Sankey outlines and the edge
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of the plot area
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*tolerance* acceptable maximum of the magnitude of the sum of
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flows
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The magnitude of the sum of connected flows cannot
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be greater than *tolerance*.
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=============== ===================================================
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The optional arguments listed above are applied to all subdiagrams so
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that there is consistent alignment and formatting.
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If :class:`Sankey` is instantiated with any keyword arguments other
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than those explicitly listed above (``**kwargs``), they will be passed
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to :meth:`add`, which will create the first subdiagram.
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In order to draw a complex Sankey diagram, create an instance of
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:class:`Sankey` by calling it without any kwargs::
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sankey = Sankey()
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Then add simple Sankey sub-diagrams::
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sankey.add() # 1
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sankey.add() # 2
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#...
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sankey.add() # n
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Finally, create the full diagram::
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sankey.finish()
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Or, instead, simply daisy-chain those calls::
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Sankey().add().add... .add().finish()
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See Also
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--------
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Sankey.add
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Sankey.finish
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Examples
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--------
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.. plot:: gallery/specialty_plots/sankey_basics.py
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"""
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# Check the arguments.
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if gap < 0:
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raise ValueError(
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"'gap' is negative, which is not allowed because it would "
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"cause the paths to overlap")
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if radius > gap:
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raise ValueError(
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"'radius' is greater than 'gap', which is not allowed because "
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"it would cause the paths to overlap")
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if head_angle < 0:
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raise ValueError(
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"'head_angle' is negative, which is not allowed because it "
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"would cause inputs to look like outputs and vice versa")
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if tolerance < 0:
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raise ValueError(
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"'tolerance' is negative, but it must be a magnitude")
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# Create axes if necessary.
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if ax is None:
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import matplotlib.pyplot as plt
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fig = plt.figure()
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ax = fig.add_subplot(1, 1, 1, xticks=[], yticks=[])
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self.diagrams = []
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# Store the inputs.
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self.ax = ax
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self.unit = unit
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self.format = format
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self.scale = scale
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self.gap = gap
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self.radius = radius
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self.shoulder = shoulder
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self.offset = offset
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self.margin = margin
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self.pitch = np.tan(np.pi * (1 - head_angle / 180.0) / 2.0)
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self.tolerance = tolerance
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# Initialize the vertices of tight box around the diagram(s).
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self.extent = np.array((np.inf, -np.inf, np.inf, -np.inf))
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# If there are any kwargs, create the first subdiagram.
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if len(kwargs):
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self.add(**kwargs)
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def _arc(self, quadrant=0, cw=True, radius=1, center=(0, 0)):
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"""
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Return the codes and vertices for a rotated, scaled, and translated
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90 degree arc.
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Optional keyword arguments:
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=============== ==========================================
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Keyword Description
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=============== ==========================================
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*quadrant* uses 0-based indexing (0, 1, 2, or 3)
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*cw* if True, clockwise
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*center* (x, y) tuple of the arc's center
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=============== ==========================================
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"""
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# Note: It would be possible to use matplotlib's transforms to rotate,
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# scale, and translate the arc, but since the angles are discrete,
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# it's just as easy and maybe more efficient to do it here.
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ARC_CODES = [Path.LINETO,
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Path.CURVE4,
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Path.CURVE4,
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Path.CURVE4,
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Path.CURVE4,
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Path.CURVE4,
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Path.CURVE4]
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# Vertices of a cubic Bezier curve approximating a 90 deg arc
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# These can be determined by Path.arc(0,90).
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ARC_VERTICES = np.array([[1.00000000e+00, 0.00000000e+00],
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[1.00000000e+00, 2.65114773e-01],
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[8.94571235e-01, 5.19642327e-01],
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[7.07106781e-01, 7.07106781e-01],
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[5.19642327e-01, 8.94571235e-01],
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[2.65114773e-01, 1.00000000e+00],
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# Insignificant
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# [6.12303177e-17, 1.00000000e+00]])
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[0.00000000e+00, 1.00000000e+00]])
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if quadrant == 0 or quadrant == 2:
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if cw:
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vertices = ARC_VERTICES
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else:
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vertices = ARC_VERTICES[:, ::-1] # Swap x and y.
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elif quadrant == 1 or quadrant == 3:
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# Negate x.
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if cw:
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# Swap x and y.
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vertices = np.column_stack((-ARC_VERTICES[:, 1],
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ARC_VERTICES[:, 0]))
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else:
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vertices = np.column_stack((-ARC_VERTICES[:, 0],
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ARC_VERTICES[:, 1]))
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if quadrant > 1:
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radius = -radius # Rotate 180 deg.
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return list(zip(ARC_CODES, radius * vertices +
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np.tile(center, (ARC_VERTICES.shape[0], 1))))
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def _add_input(self, path, angle, flow, length):
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"""
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Add an input to a path and return its tip and label locations.
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"""
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if angle is None:
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return [0, 0], [0, 0]
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else:
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x, y = path[-1][1] # Use the last point as a reference.
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dipdepth = (flow / 2) * self.pitch
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if angle == RIGHT:
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x -= length
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dip = [x + dipdepth, y + flow / 2.0]
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path.extend([(Path.LINETO, [x, y]),
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(Path.LINETO, dip),
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(Path.LINETO, [x, y + flow]),
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(Path.LINETO, [x + self.gap, y + flow])])
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label_location = [dip[0] - self.offset, dip[1]]
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else: # Vertical
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x -= self.gap
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if angle == UP:
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sign = 1
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else:
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sign = -1
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dip = [x - flow / 2, y - sign * (length - dipdepth)]
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if angle == DOWN:
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quadrant = 2
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else:
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quadrant = 1
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# Inner arc isn't needed if inner radius is zero
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if self.radius:
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path.extend(self._arc(quadrant=quadrant,
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cw=angle == UP,
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radius=self.radius,
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center=(x + self.radius,
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y - sign * self.radius)))
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else:
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path.append((Path.LINETO, [x, y]))
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path.extend([(Path.LINETO, [x, y - sign * length]),
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(Path.LINETO, dip),
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(Path.LINETO, [x - flow, y - sign * length])])
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path.extend(self._arc(quadrant=quadrant,
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cw=angle == DOWN,
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radius=flow + self.radius,
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center=(x + self.radius,
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y - sign * self.radius)))
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path.append((Path.LINETO, [x - flow, y + sign * flow]))
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label_location = [dip[0], dip[1] - sign * self.offset]
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return dip, label_location
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def _add_output(self, path, angle, flow, length):
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"""
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Append an output to a path and return its tip and label locations.
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.. note:: *flow* is negative for an output.
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"""
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if angle is None:
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return [0, 0], [0, 0]
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else:
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x, y = path[-1][1] # Use the last point as a reference.
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tipheight = (self.shoulder - flow / 2) * self.pitch
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if angle == RIGHT:
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x += length
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tip = [x + tipheight, y + flow / 2.0]
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path.extend([(Path.LINETO, [x, y]),
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(Path.LINETO, [x, y + self.shoulder]),
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(Path.LINETO, tip),
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(Path.LINETO, [x, y - self.shoulder + flow]),
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(Path.LINETO, [x, y + flow]),
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(Path.LINETO, [x - self.gap, y + flow])])
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label_location = [tip[0] + self.offset, tip[1]]
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else: # Vertical
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x += self.gap
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if angle == UP:
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sign = 1
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else:
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sign = -1
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tip = [x - flow / 2.0, y + sign * (length + tipheight)]
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if angle == UP:
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quadrant = 3
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else:
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quadrant = 0
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# Inner arc isn't needed if inner radius is zero
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if self.radius:
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path.extend(self._arc(quadrant=quadrant,
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cw=angle == UP,
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radius=self.radius,
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center=(x - self.radius,
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y + sign * self.radius)))
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else:
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path.append((Path.LINETO, [x, y]))
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path.extend([(Path.LINETO, [x, y + sign * length]),
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(Path.LINETO, [x - self.shoulder,
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y + sign * length]),
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(Path.LINETO, tip),
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(Path.LINETO, [x + self.shoulder - flow,
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y + sign * length]),
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(Path.LINETO, [x - flow, y + sign * length])])
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path.extend(self._arc(quadrant=quadrant,
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cw=angle == DOWN,
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radius=self.radius - flow,
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center=(x - self.radius,
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y + sign * self.radius)))
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path.append((Path.LINETO, [x - flow, y + sign * flow]))
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label_location = [tip[0], tip[1] + sign * self.offset]
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return tip, label_location
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def _revert(self, path, first_action=Path.LINETO):
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"""
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A path is not simply reversible by path[::-1] since the code
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specifies an action to take from the **previous** point.
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"""
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reverse_path = []
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next_code = first_action
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for code, position in path[::-1]:
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reverse_path.append((next_code, position))
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next_code = code
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return reverse_path
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# This might be more efficient, but it fails because 'tuple' object
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# doesn't support item assignment:
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# path[1] = path[1][-1:0:-1]
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# path[1][0] = first_action
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# path[2] = path[2][::-1]
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# return path
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@docstring.dedent_interpd
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def add(self, patchlabel='', flows=None, orientations=None, labels='',
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trunklength=1.0, pathlengths=0.25, prior=None, connect=(0, 0),
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rotation=0, **kwargs):
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"""
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Add a simple Sankey diagram with flows at the same hierarchical level.
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Parameters
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----------
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patchlabel : str
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Label to be placed at the center of the diagram.
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Note that *label* (not *patchlabel*) can be passed as keyword
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argument to create an entry in the legend.
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flows : list of float
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Array of flow values. By convention, inputs are positive and
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outputs are negative.
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Flows are placed along the top of the diagram from the inside out
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in order of their index within *flows*. They are placed along the
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sides of the diagram from the top down and along the bottom from
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the outside in.
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If the sum of the inputs and outputs is
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nonzero, the discrepancy will appear as a cubic Bezier curve along
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the top and bottom edges of the trunk.
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orientations : list of {-1, 0, 1}
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List of orientations of the flows (or a single orientation to be
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used for all flows). Valid values are 0 (inputs from
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the left, outputs to the right), 1 (from and to the top) or -1
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(from and to the bottom).
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labels : list of (str or None)
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List of labels for the flows (or a single label to be used for all
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flows). Each label may be *None* (no label), or a labeling string.
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If an entry is a (possibly empty) string, then the quantity for the
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corresponding flow will be shown below the string. However, if
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the *unit* of the main diagram is None, then quantities are never
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shown, regardless of the value of this argument.
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trunklength : float
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Length between the bases of the input and output groups (in
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data-space units).
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pathlengths : list of float
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List of lengths of the vertical arrows before break-in or after
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break-away. If a single value is given, then it will be applied to
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the first (inside) paths on the top and bottom, and the length of
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all other arrows will be justified accordingly. The *pathlengths*
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are not applied to the horizontal inputs and outputs.
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prior : int
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Index of the prior diagram to which this diagram should be
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connected.
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connect : (int, int)
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A (prior, this) tuple indexing the flow of the prior diagram and
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the flow of this diagram which should be connected. If this is the
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first diagram or *prior* is *None*, *connect* will be ignored.
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rotation : float
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Angle of rotation of the diagram in degrees. The interpretation of
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the *orientations* argument will be rotated accordingly (e.g., if
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*rotation* == 90, an *orientations* entry of 1 means to/from the
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left). *rotation* is ignored if this diagram is connected to an
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existing one (using *prior* and *connect*).
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Returns
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-------
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Sankey
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The current `.Sankey` instance.
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Other Parameters
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----------------
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**kwargs
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Additional keyword arguments set `matplotlib.patches.PathPatch`
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properties, listed below. For example, one may want to use
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``fill=False`` or ``label="A legend entry"``.
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%(Patch)s
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See Also
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--------
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Sankey.finish
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"""
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# Check and preprocess the arguments.
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if flows is None:
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flows = np.array([1.0, -1.0])
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else:
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flows = np.array(flows)
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n = flows.shape[0] # Number of flows
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if rotation is None:
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rotation = 0
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else:
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# In the code below, angles are expressed in deg/90.
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rotation /= 90.0
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if orientations is None:
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orientations = 0
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try:
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orientations = np.broadcast_to(orientations, n)
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except ValueError:
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raise ValueError(
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f"The shapes of 'flows' {np.shape(flows)} and 'orientations' "
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f"{np.shape(orientations)} are incompatible"
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) from None
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try:
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labels = np.broadcast_to(labels, n)
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except ValueError:
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raise ValueError(
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f"The shapes of 'flows' {np.shape(flows)} and 'labels' "
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f"{np.shape(labels)} are incompatible"
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) from None
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if trunklength < 0:
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raise ValueError(
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"'trunklength' is negative, which is not allowed because it "
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"would cause poor layout")
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if np.abs(np.sum(flows)) > self.tolerance:
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_log.info("The sum of the flows is nonzero (%f; patchlabel=%r); "
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"is the system not at steady state?",
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np.sum(flows), patchlabel)
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scaled_flows = self.scale * flows
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gain = sum(max(flow, 0) for flow in scaled_flows)
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loss = sum(min(flow, 0) for flow in scaled_flows)
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if prior is not None:
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if prior < 0:
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raise ValueError("The index of the prior diagram is negative")
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if min(connect) < 0:
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raise ValueError(
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"At least one of the connection indices is negative")
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if prior >= len(self.diagrams):
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raise ValueError(
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f"The index of the prior diagram is {prior}, but there "
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f"are only {len(self.diagrams)} other diagrams")
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if connect[0] >= len(self.diagrams[prior].flows):
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raise ValueError(
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"The connection index to the source diagram is {}, but "
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"that diagram has only {} flows".format(
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connect[0], len(self.diagrams[prior].flows)))
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if connect[1] >= n:
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raise ValueError(
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f"The connection index to this diagram is {connect[1]}, "
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f"but this diagram has only {n} flows")
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if self.diagrams[prior].angles[connect[0]] is None:
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raise ValueError(
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f"The connection cannot be made, which may occur if the "
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f"magnitude of flow {connect[0]} of diagram {prior} is "
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f"less than the specified tolerance")
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flow_error = (self.diagrams[prior].flows[connect[0]] +
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flows[connect[1]])
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if abs(flow_error) >= self.tolerance:
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raise ValueError(
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f"The scaled sum of the connected flows is {flow_error}, "
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f"which is not within the tolerance ({self.tolerance})")
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|
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# Determine if the flows are inputs.
|
|
are_inputs = [None] * n
|
|
for i, flow in enumerate(flows):
|
|
if flow >= self.tolerance:
|
|
are_inputs[i] = True
|
|
elif flow <= -self.tolerance:
|
|
are_inputs[i] = False
|
|
else:
|
|
_log.info(
|
|
"The magnitude of flow %d (%f) is below the tolerance "
|
|
"(%f).\nIt will not be shown, and it cannot be used in a "
|
|
"connection.", i, flow, self.tolerance)
|
|
|
|
# Determine the angles of the arrows (before rotation).
|
|
angles = [None] * n
|
|
for i, (orient, is_input) in enumerate(zip(orientations, are_inputs)):
|
|
if orient == 1:
|
|
if is_input:
|
|
angles[i] = DOWN
|
|
elif not is_input:
|
|
# Be specific since is_input can be None.
|
|
angles[i] = UP
|
|
elif orient == 0:
|
|
if is_input is not None:
|
|
angles[i] = RIGHT
|
|
else:
|
|
if orient != -1:
|
|
raise ValueError(
|
|
f"The value of orientations[{i}] is {orient}, "
|
|
f"but it must be -1, 0, or 1")
|
|
if is_input:
|
|
angles[i] = UP
|
|
elif not is_input:
|
|
angles[i] = DOWN
|
|
|
|
# Justify the lengths of the paths.
|
|
if np.iterable(pathlengths):
|
|
if len(pathlengths) != n:
|
|
raise ValueError(
|
|
f"The lengths of 'flows' ({n}) and 'pathlengths' "
|
|
f"({len(pathlengths)}) are incompatible")
|
|
else: # Make pathlengths into a list.
|
|
urlength = pathlengths
|
|
ullength = pathlengths
|
|
lrlength = pathlengths
|
|
lllength = pathlengths
|
|
d = dict(RIGHT=pathlengths)
|
|
pathlengths = [d.get(angle, 0) for angle in angles]
|
|
# Determine the lengths of the top-side arrows
|
|
# from the middle outwards.
|
|
for i, (angle, is_input, flow) in enumerate(zip(angles, are_inputs,
|
|
scaled_flows)):
|
|
if angle == DOWN and is_input:
|
|
pathlengths[i] = ullength
|
|
ullength += flow
|
|
elif angle == UP and not is_input:
|
|
pathlengths[i] = urlength
|
|
urlength -= flow # Flow is negative for outputs.
|
|
# Determine the lengths of the bottom-side arrows
|
|
# from the middle outwards.
|
|
for i, (angle, is_input, flow) in enumerate(reversed(list(zip(
|
|
angles, are_inputs, scaled_flows)))):
|
|
if angle == UP and is_input:
|
|
pathlengths[n - i - 1] = lllength
|
|
lllength += flow
|
|
elif angle == DOWN and not is_input:
|
|
pathlengths[n - i - 1] = lrlength
|
|
lrlength -= flow
|
|
# Determine the lengths of the left-side arrows
|
|
# from the bottom upwards.
|
|
has_left_input = False
|
|
for i, (angle, is_input, spec) in enumerate(reversed(list(zip(
|
|
angles, are_inputs, zip(scaled_flows, pathlengths))))):
|
|
if angle == RIGHT:
|
|
if is_input:
|
|
if has_left_input:
|
|
pathlengths[n - i - 1] = 0
|
|
else:
|
|
has_left_input = True
|
|
# Determine the lengths of the right-side arrows
|
|
# from the top downwards.
|
|
has_right_output = False
|
|
for i, (angle, is_input, spec) in enumerate(zip(
|
|
angles, are_inputs, list(zip(scaled_flows, pathlengths)))):
|
|
if angle == RIGHT:
|
|
if not is_input:
|
|
if has_right_output:
|
|
pathlengths[i] = 0
|
|
else:
|
|
has_right_output = True
|
|
|
|
# Begin the subpaths, and smooth the transition if the sum of the flows
|
|
# is nonzero.
|
|
urpath = [(Path.MOVETO, [(self.gap - trunklength / 2.0), # Upper right
|
|
gain / 2.0]),
|
|
(Path.LINETO, [(self.gap - trunklength / 2.0) / 2.0,
|
|
gain / 2.0]),
|
|
(Path.CURVE4, [(self.gap - trunklength / 2.0) / 8.0,
|
|
gain / 2.0]),
|
|
(Path.CURVE4, [(trunklength / 2.0 - self.gap) / 8.0,
|
|
-loss / 2.0]),
|
|
(Path.LINETO, [(trunklength / 2.0 - self.gap) / 2.0,
|
|
-loss / 2.0]),
|
|
(Path.LINETO, [(trunklength / 2.0 - self.gap),
|
|
-loss / 2.0])]
|
|
llpath = [(Path.LINETO, [(trunklength / 2.0 - self.gap), # Lower left
|
|
loss / 2.0]),
|
|
(Path.LINETO, [(trunklength / 2.0 - self.gap) / 2.0,
|
|
loss / 2.0]),
|
|
(Path.CURVE4, [(trunklength / 2.0 - self.gap) / 8.0,
|
|
loss / 2.0]),
|
|
(Path.CURVE4, [(self.gap - trunklength / 2.0) / 8.0,
|
|
-gain / 2.0]),
|
|
(Path.LINETO, [(self.gap - trunklength / 2.0) / 2.0,
|
|
-gain / 2.0]),
|
|
(Path.LINETO, [(self.gap - trunklength / 2.0),
|
|
-gain / 2.0])]
|
|
lrpath = [(Path.LINETO, [(trunklength / 2.0 - self.gap), # Lower right
|
|
loss / 2.0])]
|
|
ulpath = [(Path.LINETO, [self.gap - trunklength / 2.0, # Upper left
|
|
gain / 2.0])]
|
|
|
|
# Add the subpaths and assign the locations of the tips and labels.
|
|
tips = np.zeros((n, 2))
|
|
label_locations = np.zeros((n, 2))
|
|
# Add the top-side inputs and outputs from the middle outwards.
|
|
for i, (angle, is_input, spec) in enumerate(zip(
|
|
angles, are_inputs, list(zip(scaled_flows, pathlengths)))):
|
|
if angle == DOWN and is_input:
|
|
tips[i, :], label_locations[i, :] = self._add_input(
|
|
ulpath, angle, *spec)
|
|
elif angle == UP and not is_input:
|
|
tips[i, :], label_locations[i, :] = self._add_output(
|
|
urpath, angle, *spec)
|
|
# Add the bottom-side inputs and outputs from the middle outwards.
|
|
for i, (angle, is_input, spec) in enumerate(reversed(list(zip(
|
|
angles, are_inputs, list(zip(scaled_flows, pathlengths)))))):
|
|
if angle == UP and is_input:
|
|
tip, label_location = self._add_input(llpath, angle, *spec)
|
|
tips[n - i - 1, :] = tip
|
|
label_locations[n - i - 1, :] = label_location
|
|
elif angle == DOWN and not is_input:
|
|
tip, label_location = self._add_output(lrpath, angle, *spec)
|
|
tips[n - i - 1, :] = tip
|
|
label_locations[n - i - 1, :] = label_location
|
|
# Add the left-side inputs from the bottom upwards.
|
|
has_left_input = False
|
|
for i, (angle, is_input, spec) in enumerate(reversed(list(zip(
|
|
angles, are_inputs, list(zip(scaled_flows, pathlengths)))))):
|
|
if angle == RIGHT and is_input:
|
|
if not has_left_input:
|
|
# Make sure the lower path extends
|
|
# at least as far as the upper one.
|
|
if llpath[-1][1][0] > ulpath[-1][1][0]:
|
|
llpath.append((Path.LINETO, [ulpath[-1][1][0],
|
|
llpath[-1][1][1]]))
|
|
has_left_input = True
|
|
tip, label_location = self._add_input(llpath, angle, *spec)
|
|
tips[n - i - 1, :] = tip
|
|
label_locations[n - i - 1, :] = label_location
|
|
# Add the right-side outputs from the top downwards.
|
|
has_right_output = False
|
|
for i, (angle, is_input, spec) in enumerate(zip(
|
|
angles, are_inputs, list(zip(scaled_flows, pathlengths)))):
|
|
if angle == RIGHT and not is_input:
|
|
if not has_right_output:
|
|
# Make sure the upper path extends
|
|
# at least as far as the lower one.
|
|
if urpath[-1][1][0] < lrpath[-1][1][0]:
|
|
urpath.append((Path.LINETO, [lrpath[-1][1][0],
|
|
urpath[-1][1][1]]))
|
|
has_right_output = True
|
|
tips[i, :], label_locations[i, :] = self._add_output(
|
|
urpath, angle, *spec)
|
|
# Trim any hanging vertices.
|
|
if not has_left_input:
|
|
ulpath.pop()
|
|
llpath.pop()
|
|
if not has_right_output:
|
|
lrpath.pop()
|
|
urpath.pop()
|
|
|
|
# Concatenate the subpaths in the correct order (clockwise from top).
|
|
path = (urpath + self._revert(lrpath) + llpath + self._revert(ulpath) +
|
|
[(Path.CLOSEPOLY, urpath[0][1])])
|
|
|
|
# Create a patch with the Sankey outline.
|
|
codes, vertices = zip(*path)
|
|
vertices = np.array(vertices)
|
|
|
|
def _get_angle(a, r):
|
|
if a is None:
|
|
return None
|
|
else:
|
|
return a + r
|
|
|
|
if prior is None:
|
|
if rotation != 0: # By default, none of this is needed.
|
|
angles = [_get_angle(angle, rotation) for angle in angles]
|
|
rotate = Affine2D().rotate_deg(rotation * 90).transform_affine
|
|
tips = rotate(tips)
|
|
label_locations = rotate(label_locations)
|
|
vertices = rotate(vertices)
|
|
text = self.ax.text(0, 0, s=patchlabel, ha='center', va='center')
|
|
else:
|
|
rotation = (self.diagrams[prior].angles[connect[0]] -
|
|
angles[connect[1]])
|
|
angles = [_get_angle(angle, rotation) for angle in angles]
|
|
rotate = Affine2D().rotate_deg(rotation * 90).transform_affine
|
|
tips = rotate(tips)
|
|
offset = self.diagrams[prior].tips[connect[0]] - tips[connect[1]]
|
|
translate = Affine2D().translate(*offset).transform_affine
|
|
tips = translate(tips)
|
|
label_locations = translate(rotate(label_locations))
|
|
vertices = translate(rotate(vertices))
|
|
kwds = dict(s=patchlabel, ha='center', va='center')
|
|
text = self.ax.text(*offset, **kwds)
|
|
if rcParams['_internal.classic_mode']:
|
|
fc = kwargs.pop('fc', kwargs.pop('facecolor', '#bfd1d4'))
|
|
lw = kwargs.pop('lw', kwargs.pop('linewidth', 0.5))
|
|
else:
|
|
fc = kwargs.pop('fc', kwargs.pop('facecolor', None))
|
|
lw = kwargs.pop('lw', kwargs.pop('linewidth', None))
|
|
if fc is None:
|
|
fc = next(self.ax._get_patches_for_fill.prop_cycler)['color']
|
|
patch = PathPatch(Path(vertices, codes), fc=fc, lw=lw, **kwargs)
|
|
self.ax.add_patch(patch)
|
|
|
|
# Add the path labels.
|
|
texts = []
|
|
for number, angle, label, location in zip(flows, angles, labels,
|
|
label_locations):
|
|
if label is None or angle is None:
|
|
label = ''
|
|
elif self.unit is not None:
|
|
quantity = self.format % abs(number) + self.unit
|
|
if label != '':
|
|
label += "\n"
|
|
label += quantity
|
|
texts.append(self.ax.text(x=location[0], y=location[1],
|
|
s=label,
|
|
ha='center', va='center'))
|
|
# Text objects are placed even they are empty (as long as the magnitude
|
|
# of the corresponding flow is larger than the tolerance) in case the
|
|
# user wants to provide labels later.
|
|
|
|
# Expand the size of the diagram if necessary.
|
|
self.extent = (min(np.min(vertices[:, 0]),
|
|
np.min(label_locations[:, 0]),
|
|
self.extent[0]),
|
|
max(np.max(vertices[:, 0]),
|
|
np.max(label_locations[:, 0]),
|
|
self.extent[1]),
|
|
min(np.min(vertices[:, 1]),
|
|
np.min(label_locations[:, 1]),
|
|
self.extent[2]),
|
|
max(np.max(vertices[:, 1]),
|
|
np.max(label_locations[:, 1]),
|
|
self.extent[3]))
|
|
# Include both vertices _and_ label locations in the extents; there are
|
|
# where either could determine the margins (e.g., arrow shoulders).
|
|
|
|
# Add this diagram as a subdiagram.
|
|
self.diagrams.append(
|
|
SimpleNamespace(patch=patch, flows=flows, angles=angles, tips=tips,
|
|
text=text, texts=texts))
|
|
|
|
# Allow a daisy-chained call structure (see docstring for the class).
|
|
return self
|
|
|
|
def finish(self):
|
|
"""
|
|
Adjust the axes and return a list of information about the Sankey
|
|
subdiagram(s).
|
|
|
|
Return value is a list of subdiagrams represented with the following
|
|
fields:
|
|
|
|
=============== ===================================================
|
|
Field Description
|
|
=============== ===================================================
|
|
*patch* Sankey outline (an instance of
|
|
:class:`~matplotlib.patches.PathPatch`)
|
|
*flows* values of the flows (positive for input, negative
|
|
for output)
|
|
*angles* list of angles of the arrows [deg/90]
|
|
For example, if the diagram has not been rotated,
|
|
an input to the top side will have an angle of 3
|
|
(DOWN), and an output from the top side will have
|
|
an angle of 1 (UP). If a flow has been skipped
|
|
(because its magnitude is less than *tolerance*),
|
|
then its angle will be *None*.
|
|
*tips* array in which each row is an [x, y] pair
|
|
indicating the positions of the tips (or "dips") of
|
|
the flow paths
|
|
If the magnitude of a flow is less the *tolerance*
|
|
for the instance of :class:`Sankey`, the flow is
|
|
skipped and its tip will be at the center of the
|
|
diagram.
|
|
*text* :class:`~matplotlib.text.Text` instance for the
|
|
label of the diagram
|
|
*texts* list of :class:`~matplotlib.text.Text` instances
|
|
for the labels of flows
|
|
=============== ===================================================
|
|
|
|
See Also
|
|
--------
|
|
Sankey.add
|
|
"""
|
|
self.ax.axis([self.extent[0] - self.margin,
|
|
self.extent[1] + self.margin,
|
|
self.extent[2] - self.margin,
|
|
self.extent[3] + self.margin])
|
|
self.ax.set_aspect('equal', adjustable='datalim')
|
|
return self.diagrams
|