forked from 170010011/fr
82 lines
3.4 KiB
Python
82 lines
3.4 KiB
Python
import numpy as np
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from . import _spath
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def shortest_path(arr, reach=1, axis=-1, output_indexlist=False):
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"""Find the shortest path through an n-d array from one side to another.
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Parameters
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----------
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arr : ndarray of float64
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reach : int, optional
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By default (``reach = 1``), the shortest path can only move
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one row up or down for every step it moves forward (i.e.,
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the path gradient is limited to 1). `reach` defines the
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number of elements that can be skipped along each non-axis
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dimension at each step.
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axis : int, optional
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The axis along which the path must always move forward (default -1)
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output_indexlist : bool, optional
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See return value `p` for explanation.
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Returns
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-------
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p : iterable of int
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For each step along `axis`, the coordinate of the shortest path.
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If `output_indexlist` is True, then the path is returned as a list of
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n-d tuples that index into `arr`. If False, then the path is returned
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as an array listing the coordinates of the path along the non-axis
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dimensions for each step along the axis dimension. That is,
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`p.shape == (arr.shape[axis], arr.ndim-1)` except that p is squeezed
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before returning so if `arr.ndim == 2`, then
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`p.shape == (arr.shape[axis],)`
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cost : float
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Cost of path. This is the absolute sum of all the
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differences along the path.
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"""
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# First: calculate the valid moves from any given position. Basically,
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# always move +1 along the given axis, and then can move anywhere within
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# a grid defined by the reach.
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if axis < 0:
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axis += arr.ndim
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offset_ind_shape = (2 * reach + 1,) * (arr.ndim - 1)
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offset_indices = np.indices(offset_ind_shape) - reach
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offset_indices = np.insert(offset_indices, axis,
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np.ones(offset_ind_shape), axis=0)
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offset_size = np.multiply.reduce(offset_ind_shape)
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offsets = np.reshape(offset_indices, (arr.ndim, offset_size), order='F').T
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# Valid starting positions are anywhere on the hyperplane defined by
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# position 0 on the given axis. Ending positions are anywhere on the
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# hyperplane at position -1 along the same.
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non_axis_shape = arr.shape[:axis] + arr.shape[axis + 1:]
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non_axis_indices = np.indices(non_axis_shape)
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non_axis_size = np.multiply.reduce(non_axis_shape)
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start_indices = np.insert(non_axis_indices, axis,
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np.zeros(non_axis_shape), axis=0)
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starts = np.reshape(start_indices, (arr.ndim, non_axis_size), order='F').T
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end_indices = np.insert(non_axis_indices, axis,
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np.full(non_axis_shape, -1,
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dtype=non_axis_indices.dtype), axis=0)
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ends = np.reshape(end_indices, (arr.ndim, non_axis_size), order='F').T
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# Find the minimum-cost path to one of the end-points
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m = _spath.MCP_Diff(arr, offsets=offsets)
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costs, traceback = m.find_costs(starts, ends, find_all_ends=False)
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# Figure out which end-point was found
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for end in ends:
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cost = costs[tuple(end)]
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if cost != np.inf:
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break
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traceback = m.traceback(end)
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if not output_indexlist:
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traceback = np.array(traceback)
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traceback = np.concatenate([traceback[:, :axis],
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traceback[:, axis + 1:]], axis=1)
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traceback = np.squeeze(traceback)
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return traceback, cost
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