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"""
Module for creating Sankey diagrams using Matplotlib.
"""
import logging
from types import SimpleNamespace
import numpy as np
import matplotlib as mpl
from matplotlib.path import Path
from matplotlib.patches import PathPatch
from matplotlib.transforms import Affine2D
from matplotlib import _docstring
_log = logging.getLogger(__name__)
__author__ = "Kevin L. Davies"
__credits__ = ["Yannick Copin"]
__license__ = "BSD"
__version__ = "2011/09/16"
# Angles [deg/90]
RIGHT = 0
UP = 1
# LEFT = 2
DOWN = 3
class Sankey:
 """
 Sankey diagram.
 Sankey diagrams are a specific type of flow diagram, in which
 the width of the arrows is shown proportionally to the flow
 quantity. They are typically used to visualize energy or
 material or cost transfers between processes.
 `Wikipedia (6/1/2011) <https://en.wikipedia.org/wiki/Sankey_diagram>`_
 """
def __init__(self, ax=None, scale=1.0, unit='', format='%G', gap=0.25,
 radius=0.1, shoulder=0.03, offset=0.15, head_angle=100,
 margin=0.4, tolerance=1e-6, **kwargs):
 """
 Create a new Sankey instance.
 The optional arguments listed below are applied to all subdiagrams so
 that there is consistent alignment and formatting.
 In order to draw a complex Sankey diagram, create an instance of
 `Sankey` by calling it without any kwargs::
 sankey = Sankey()
 Then add simple Sankey sub-diagrams::
 sankey.add() # 1
 sankey.add() # 2
 #...
 sankey.add() # n
 Finally, create the full diagram::
 sankey.finish()
 Or, instead, simply daisy-chain those calls::
 Sankey().add().add... .add().finish()
 Other Parameters
 ----------------
 ax : `~matplotlib.axes.Axes`
 Axes onto which the data should be plotted. If *ax* isn't
 provided, new Axes will be created.
 scale : float
 Scaling factor for the flows. *scale* sizes the width of the paths
 in order to maintain proper layout. The same scale is applied to
 all subdiagrams. The value should be chosen such that the product
 of the scale and the sum of the inputs is approximately 1.0 (and
 the product of the scale and the sum of the outputs is
 approximately -1.0).
 unit : str
 The physical unit associated with the flow quantities. If *unit*
 is None, then none of the quantities are labeled.
 format : str or callable
 A Python number formatting string or callable used to label the
 flows with their quantities (i.e., a number times a unit, where the
 unit is given). If a format string is given, the label will be
 ``format % quantity``. If a callable is given, it will be called
 with ``quantity`` as an argument.
 gap : float
 Space between paths that break in/break away to/from the top or
 bottom.
 radius : float
 Inner radius of the vertical paths.
 shoulder : float
 Size of the shoulders of output arrows.
 offset : float
 Text offset (from the dip or tip of the arrow).
 head_angle : float
 Angle, in degrees, of the arrow heads (and negative of the angle of
 the tails).
 margin : float
 Minimum space between Sankey outlines and the edge of the plot
 area.
 tolerance : float
 Acceptable maximum of the magnitude of the sum of flows. The
 magnitude of the sum of connected flows cannot be greater than
 *tolerance*.
 **kwargs
 Any additional keyword arguments will be passed to `add`, which
 will create the first subdiagram.
 See Also
 --------
 Sankey.add
 Sankey.finish
 Examples
 --------
 .. plot:: gallery/specialty_plots/sankey_basics.py
 """
 # Check the arguments.
 if gap < 0:
 raise ValueError(
 "'gap' is negative, which is not allowed because it would "
 "cause the paths to overlap")
 if radius > gap:
 raise ValueError(
 "'radius' is greater than 'gap', which is not allowed because "
 "it would cause the paths to overlap")
 if head_angle < 0:
 raise ValueError(
 "'head_angle' is negative, which is not allowed because it "
 "would cause inputs to look like outputs and vice versa")
 if tolerance < 0:
 raise ValueError(
 "'tolerance' is negative, but it must be a magnitude")
# Create Axes if necessary.
 if ax is None:
 import matplotlib.pyplot as plt
 fig = plt.figure()
 ax = fig.add_subplot(1, 1, 1, xticks=[], yticks=[])
self.diagrams = []
# Store the inputs.
 self.ax = ax
 self.unit = unit
 self.format = format
 self.scale = scale
 self.gap = gap
 self.radius = radius
 self.shoulder = shoulder
 self.offset = offset
 self.margin = margin
 self.pitch = np.tan(np.pi * (1 - head_angle / 180.0) / 2.0)
 self.tolerance = tolerance
# Initialize the vertices of tight box around the diagram(s).
 self.extent = np.array((np.inf, -np.inf, np.inf, -np.inf))
# If there are any kwargs, create the first subdiagram.
 if len(kwargs):
 self.add(**kwargs)
def _arc(self, quadrant=0, cw=True, radius=1, center=(0, 0)):
 """
 Return the codes and vertices for a rotated, scaled, and translated
 90 degree arc.
 Other Parameters
 ----------------
 quadrant : {0, 1, 2, 3}, default: 0
 Uses 0-based indexing (0, 1, 2, or 3).
 cw : bool, default: True
 If True, the arc vertices are produced clockwise; counter-clockwise
 otherwise.
 radius : float, default: 1
 The radius of the arc.
 center : (float, float), default: (0, 0)
 (x, y) tuple of the arc's center.
 """
 # Note: It would be possible to use matplotlib's transforms to rotate,
 # scale, and translate the arc, but since the angles are discrete,
 # it's just as easy and maybe more efficient to do it here.
 ARC_CODES = [Path.LINETO,
 Path.CURVE4,
 Path.CURVE4,
 Path.CURVE4,
 Path.CURVE4,
 Path.CURVE4,
 Path.CURVE4]
 # Vertices of a cubic Bezier curve approximating a 90 deg arc
 # These can be determined by Path.arc(0, 90).
 ARC_VERTICES = np.array([[1.00000000e+00, 0.00000000e+00],
 [1.00000000e+00, 2.65114773e-01],
 [8.94571235e-01, 5.19642327e-01],
 [7.07106781e-01, 7.07106781e-01],
 [5.19642327e-01, 8.94571235e-01],
 [2.65114773e-01, 1.00000000e+00],
 # Insignificant
 # [6.12303177e-17, 1.00000000e+00]])
 [0.00000000e+00, 1.00000000e+00]])
 if quadrant in (0, 2):
 if cw:
 vertices = ARC_VERTICES
 else:
 vertices = ARC_VERTICES[:, ::-1] # Swap x and y.
 else: # 1, 3
 # Negate x.
 if cw:
 # Swap x and y.
 vertices = np.column_stack((-ARC_VERTICES[:, 1],
 ARC_VERTICES[:, 0]))
 else:
 vertices = np.column_stack((-ARC_VERTICES[:, 0],
 ARC_VERTICES[:, 1]))
 if quadrant > 1:
 radius = -radius # Rotate 180 deg.
 return list(zip(ARC_CODES, radius * vertices +
 np.tile(center, (ARC_VERTICES.shape[0], 1))))
def _add_input(self, path, angle, flow, length):
 """
 Add an input to a path and return its tip and label locations.
 """
 if angle is None:
 return [0, 0], [0, 0]
 else:
 x, y = path[-1][1] # Use the last point as a reference.
 dipdepth = (flow / 2) * self.pitch
 if angle == RIGHT:
 x -= length
 dip = [x + dipdepth, y + flow / 2.0]
 path.extend([(Path.LINETO, [x, y]),
 (Path.LINETO, dip),
 (Path.LINETO, [x, y + flow]),
 (Path.LINETO, [x + self.gap, y + flow])])
 label_location = [dip[0] - self.offset, dip[1]]
 else: # Vertical
 x -= self.gap
 if angle == UP:
 sign = 1
 else:
 sign = -1
dip = [x - flow / 2, y - sign * (length - dipdepth)]
 if angle == DOWN:
 quadrant = 2
 else:
 quadrant = 1
# Inner arc isn't needed if inner radius is zero
 if self.radius:
 path.extend(self._arc(quadrant=quadrant,
 cw=angle == UP,
 radius=self.radius,
 center=(x + self.radius,
 y - sign * self.radius)))
 else:
 path.append((Path.LINETO, [x, y]))
 path.extend([(Path.LINETO, [x, y - sign * length]),
 (Path.LINETO, dip),
 (Path.LINETO, [x - flow, y - sign * length])])
 path.extend(self._arc(quadrant=quadrant,
 cw=angle == DOWN,
 radius=flow + self.radius,
 center=(x + self.radius,
 y - sign * self.radius)))
 path.append((Path.LINETO, [x - flow, y + sign * flow]))
 label_location = [dip[0], dip[1] - sign * self.offset]
return dip, label_location
def _add_output(self, path, angle, flow, length):
 """
 Append an output to a path and return its tip and label locations.
 .. note:: *flow* is negative for an output.
 """
 if angle is None:
 return [0, 0], [0, 0]
 else:
 x, y = path[-1][1] # Use the last point as a reference.
 tipheight = (self.shoulder - flow / 2) * self.pitch
 if angle == RIGHT:
 x += length
 tip = [x + tipheight, y + flow / 2.0]
 path.extend([(Path.LINETO, [x, y]),
 (Path.LINETO, [x, y + self.shoulder]),
 (Path.LINETO, tip),
 (Path.LINETO, [x, y - self.shoulder + flow]),
 (Path.LINETO, [x, y + flow]),
 (Path.LINETO, [x - self.gap, y + flow])])
 label_location = [tip[0] + self.offset, tip[1]]
 else: # Vertical
 x += self.gap
 if angle == UP:
 sign, quadrant = 1, 3
 else:
 sign, quadrant = -1, 0
tip = [x - flow / 2.0, y + sign * (length + tipheight)]
 # Inner arc isn't needed if inner radius is zero
 if self.radius:
 path.extend(self._arc(quadrant=quadrant,
 cw=angle == UP,
 radius=self.radius,
 center=(x - self.radius,
 y + sign * self.radius)))
 else:
 path.append((Path.LINETO, [x, y]))
 path.extend([(Path.LINETO, [x, y + sign * length]),
 (Path.LINETO, [x - self.shoulder,
 y + sign * length]),
 (Path.LINETO, tip),
 (Path.LINETO, [x + self.shoulder - flow,
 y + sign * length]),
 (Path.LINETO, [x - flow, y + sign * length])])
 path.extend(self._arc(quadrant=quadrant,
 cw=angle == DOWN,
 radius=self.radius - flow,
 center=(x - self.radius,
 y + sign * self.radius)))
 path.append((Path.LINETO, [x - flow, y + sign * flow]))
 label_location = [tip[0], tip[1] + sign * self.offset]
 return tip, label_location
def _revert(self, path, first_action=Path.LINETO):
 """
 A path is not simply reversible by path[::-1] since the code
 specifies an action to take from the **previous** point.
 """
 reverse_path = []
 next_code = first_action
 for code, position in path[::-1]:
 reverse_path.append((next_code, position))
 next_code = code
 return reverse_path
 # This might be more efficient, but it fails because 'tuple' object
 # doesn't support item assignment:
 # path[1] = path[1][-1:0:-1]
 # path[1][0] = first_action
 # path[2] = path[2][::-1]
 # return path
@_docstring.dedent_interpd
 def add(self, patchlabel='', flows=None, orientations=None, labels='',
 trunklength=1.0, pathlengths=0.25, prior=None, connect=(0, 0),
 rotation=0, **kwargs):
 """
 Add a simple Sankey diagram with flows at the same hierarchical level.
 Parameters
 ----------
 patchlabel : str
 Label to be placed at the center of the diagram.
 Note that *label* (not *patchlabel*) can be passed as keyword
 argument to create an entry in the legend.
 flows : list of float
 Array of flow values. By convention, inputs are positive and
 outputs are negative.
 Flows are placed along the top of the diagram from the inside out
 in order of their index within *flows*. They are placed along the
 sides of the diagram from the top down and along the bottom from
 the outside in.
 If the sum of the inputs and outputs is
 nonzero, the discrepancy will appear as a cubic Bézier curve along
 the top and bottom edges of the trunk.
 orientations : list of {-1, 0, 1}
 List of orientations of the flows (or a single orientation to be
 used for all flows). Valid values are 0 (inputs from
 the left, outputs to the right), 1 (from and to the top) or -1
 (from and to the bottom).
 labels : list of (str or None)
 List of labels for the flows (or a single label to be used for all
 flows). Each label may be *None* (no label), or a labeling string.
 If an entry is a (possibly empty) string, then the quantity for the
 corresponding flow will be shown below the string. However, if
 the *unit* of the main diagram is None, then quantities are never
 shown, regardless of the value of this argument.
 trunklength : float
 Length between the bases of the input and output groups (in
 data-space units).
 pathlengths : list of float
 List of lengths of the vertical arrows before break-in or after
 break-away. If a single value is given, then it will be applied to
 the first (inside) paths on the top and bottom, and the length of
 all other arrows will be justified accordingly. The *pathlengths*
 are not applied to the horizontal inputs and outputs.
 prior : int
 Index of the prior diagram to which this diagram should be
 connected.
 connect : (int, int)
 A (prior, this) tuple indexing the flow of the prior diagram and
 the flow of this diagram which should be connected. If this is the
 first diagram or *prior* is *None*, *connect* will be ignored.
 rotation : float
 Angle of rotation of the diagram in degrees. The interpretation of
 the *orientations* argument will be rotated accordingly (e.g., if
 *rotation* == 90, an *orientations* entry of 1 means to/from the
 left). *rotation* is ignored if this diagram is connected to an
 existing one (using *prior* and *connect*).
 Returns
 -------
 Sankey
 The current `.Sankey` instance.
 Other Parameters
 ----------------
 **kwargs
 Additional keyword arguments set `matplotlib.patches.PathPatch`
 properties, listed below. For example, one may want to use
 ``fill=False`` or ``label="A legend entry"``.
 %(Patch:kwdoc)s
 See Also
 --------
 Sankey.finish
 """
 # Check and preprocess the arguments.
 flows = np.array([1.0, -1.0]) if flows is None else np.array(flows)
 n = flows.shape[0] # Number of flows
 if rotation is None:
 rotation = 0
 else:
 # In the code below, angles are expressed in deg/90.
 rotation /= 90.0
 if orientations is None:
 orientations = 0
 try:
 orientations = np.broadcast_to(orientations, n)
 except ValueError:
 raise ValueError(
 f"The shapes of 'flows' {np.shape(flows)} and 'orientations' "
 f"{np.shape(orientations)} are incompatible"
 ) from None
 try:
 labels = np.broadcast_to(labels, n)
 except ValueError:
 raise ValueError(
 f"The shapes of 'flows' {np.shape(flows)} and 'labels' "
 f"{np.shape(labels)} are incompatible"
 ) from None
 if trunklength < 0:
 raise ValueError(
 "'trunklength' is negative, which is not allowed because it "
 "would cause poor layout")
 if abs(np.sum(flows)) > self.tolerance:
 _log.info("The sum of the flows is nonzero (%f; patchlabel=%r); "
 "is the system not at steady state?",
 np.sum(flows), patchlabel)
 scaled_flows = self.scale * flows
 gain = sum(max(flow, 0) for flow in scaled_flows)
 loss = sum(min(flow, 0) for flow in scaled_flows)
 if prior is not None:
 if prior < 0:
 raise ValueError("The index of the prior diagram is negative")
 if min(connect) < 0:
 raise ValueError(
 "At least one of the connection indices is negative")
 if prior >= len(self.diagrams):
 raise ValueError(
 f"The index of the prior diagram is {prior}, but there "
 f"are only {len(self.diagrams)} other diagrams")
 if connect[0] >= len(self.diagrams[prior].flows):
 raise ValueError(
 "The connection index to the source diagram is {}, but "
 "that diagram has only {} flows".format(
 connect[0], len(self.diagrams[prior].flows)))
 if connect[1] >= n:
 raise ValueError(
 f"The connection index to this diagram is {connect[1]}, "
 f"but this diagram has only {n} flows")
 if self.diagrams[prior].angles[connect[0]] is None:
 raise ValueError(
 f"The connection cannot be made, which may occur if the "
 f"magnitude of flow {connect[0]} of diagram {prior} is "
 f"less than the specified tolerance")
 flow_error = (self.diagrams[prior].flows[connect[0]] +
 flows[connect[1]])
 if abs(flow_error) >= self.tolerance:
 raise ValueError(
 f"The scaled sum of the connected flows is {flow_error}, "
 f"which is not within the tolerance ({self.tolerance})")
# 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 is_input is False:
 # 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 is_input is False:
 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 is_input is False:
 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 is_input is False:
 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 is_input is False:
 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 is_input is False:
 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 is_input is False:
 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 is_input is False:
 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 mpl.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 = self.ax._get_patches_for_fill.get_next_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:
 if isinstance(self.format, str):
 quantity = self.format % abs(number) + self.unit
 elif callable(self.format):
 quantity = self.format(number)
 else:
 raise TypeError(
 'format must be callable or a format string')
 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).
 Returns a list of subdiagrams with the following fields:
 ======== =============================================================
 Field Description
 ======== =============================================================
 *patch* Sankey outline (a `~matplotlib.patches.PathPatch`).
 *flows* Flow values (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 has an angle of 3 (DOWN),
 and an output from the top side has 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* (N, 2)-array of the (x, y) positions of the tips (or "dips")
 of the flow paths.
 If the magnitude of a flow is less the *tolerance* of this
 `Sankey` instance, the flow is skipped and its tip will be at
 the center of the diagram.
 *text* `.Text` instance for the diagram label.
 *texts* List of `.Text` instances for the flow labels.
 ======== =============================================================
 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