117 lines
3.9 KiB
Python
117 lines
3.9 KiB
Python
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import numpy as np
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def regular_grid(ar_shape, n_points):
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"""Find `n_points` regularly spaced along `ar_shape`.
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The returned points (as slices) should be as close to cubically-spaced as
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possible. Essentially, the points are spaced by the Nth root of the input
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array size, where N is the number of dimensions. However, if an array
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dimension cannot fit a full step size, it is "discarded", and the
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computation is done for only the remaining dimensions.
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Parameters
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----------
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ar_shape : array-like of ints
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The shape of the space embedding the grid. ``len(ar_shape)`` is the
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number of dimensions.
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n_points : int
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The (approximate) number of points to embed in the space.
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Returns
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-------
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slices : tuple of slice objects
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A slice along each dimension of `ar_shape`, such that the intersection
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of all the slices give the coordinates of regularly spaced points.
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.. versionchanged:: 0.14.1
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In scikit-image 0.14.1 and 0.15, the return type was changed from a
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list to a tuple to ensure `compatibility with Numpy 1.15`_ and
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higher. If your code requires the returned result to be a list, you
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may convert the output of this function to a list with:
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>>> result = list(regular_grid(ar_shape=(3, 20, 40), n_points=8))
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.. _compatibility with NumPy 1.15: https://github.com/numpy/numpy/blob/master/doc/release/1.15.0-notes.rst#deprecations
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Examples
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--------
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>>> ar = np.zeros((20, 40))
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>>> g = regular_grid(ar.shape, 8)
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>>> g
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(slice(5, None, 10), slice(5, None, 10))
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>>> ar[g] = 1
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>>> ar.sum()
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8.0
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>>> ar = np.zeros((20, 40))
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>>> g = regular_grid(ar.shape, 32)
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>>> g
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(slice(2, None, 5), slice(2, None, 5))
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>>> ar[g] = 1
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>>> ar.sum()
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32.0
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>>> ar = np.zeros((3, 20, 40))
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>>> g = regular_grid(ar.shape, 8)
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>>> g
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(slice(1, None, 3), slice(5, None, 10), slice(5, None, 10))
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>>> ar[g] = 1
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>>> ar.sum()
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8.0
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"""
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ar_shape = np.asanyarray(ar_shape)
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ndim = len(ar_shape)
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unsort_dim_idxs = np.argsort(np.argsort(ar_shape))
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sorted_dims = np.sort(ar_shape)
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space_size = float(np.prod(ar_shape))
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if space_size <= n_points:
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return (slice(None), ) * ndim
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stepsizes = np.full(ndim, (space_size / n_points) ** (1.0 / ndim),
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dtype='float64')
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if (sorted_dims < stepsizes).any():
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for dim in range(ndim):
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stepsizes[dim] = sorted_dims[dim]
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space_size = float(np.prod(sorted_dims[dim + 1:]))
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stepsizes[dim + 1:] = ((space_size / n_points) **
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(1.0 / (ndim - dim - 1)))
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if (sorted_dims >= stepsizes).all():
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break
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starts = (stepsizes // 2).astype(int)
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stepsizes = np.round(stepsizes).astype(int)
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slices = [slice(start, None, step) for
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start, step in zip(starts, stepsizes)]
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slices = tuple(slices[i] for i in unsort_dim_idxs)
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return slices
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def regular_seeds(ar_shape, n_points, dtype=int):
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"""Return an image with ~`n_points` regularly-spaced nonzero pixels.
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Parameters
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----------
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ar_shape : tuple of int
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The shape of the desired output image.
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n_points : int
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The desired number of nonzero points.
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dtype : numpy data type, optional
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The desired data type of the output.
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Returns
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-------
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seed_img : array of int or bool
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The desired image.
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Examples
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--------
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>>> regular_seeds((5, 5), 4)
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array([[0, 0, 0, 0, 0],
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[0, 1, 0, 2, 0],
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[0, 0, 0, 0, 0],
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[0, 3, 0, 4, 0],
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[0, 0, 0, 0, 0]])
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"""
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grid = regular_grid(ar_shape, n_points)
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seed_img = np.zeros(ar_shape, dtype=dtype)
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seed_img[grid] = 1 + np.reshape(np.arange(seed_img[grid].size),
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seed_img[grid].shape)
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return seed_img
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