forked from 170010011/fr
212 lines
8.9 KiB
Python
212 lines
8.9 KiB
Python
"""
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This morphological reconstruction routine was adapted from CellProfiler, code
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licensed under both GPL and BSD licenses.
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Website: http://www.cellprofiler.org
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Copyright (c) 2003-2009 Massachusetts Institute of Technology
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Copyright (c) 2009-2011 Broad Institute
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All rights reserved.
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Original author: Lee Kamentsky
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"""
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import numpy as np
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from ..filters._rank_order import rank_order
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def reconstruction(seed, mask, method='dilation', selem=None, offset=None):
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"""Perform a morphological reconstruction of an image.
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Morphological reconstruction by dilation is similar to basic morphological
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dilation: high-intensity values will replace nearby low-intensity values.
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The basic dilation operator, however, uses a structuring element to
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determine how far a value in the input image can spread. In contrast,
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reconstruction uses two images: a "seed" image, which specifies the values
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that spread, and a "mask" image, which gives the maximum allowed value at
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each pixel. The mask image, like the structuring element, limits the spread
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of high-intensity values. Reconstruction by erosion is simply the inverse:
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low-intensity values spread from the seed image and are limited by the mask
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image, which represents the minimum allowed value.
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Alternatively, you can think of reconstruction as a way to isolate the
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connected regions of an image. For dilation, reconstruction connects
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regions marked by local maxima in the seed image: neighboring pixels
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less-than-or-equal-to those seeds are connected to the seeded region.
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Local maxima with values larger than the seed image will get truncated to
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the seed value.
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Parameters
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----------
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seed : ndarray
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The seed image (a.k.a. marker image), which specifies the values that
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are dilated or eroded.
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mask : ndarray
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The maximum (dilation) / minimum (erosion) allowed value at each pixel.
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method : {'dilation'|'erosion'}, optional
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Perform reconstruction by dilation or erosion. In dilation (or
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erosion), the seed image is dilated (or eroded) until limited by the
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mask image. For dilation, each seed value must be less than or equal
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to the corresponding mask value; for erosion, the reverse is true.
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Default is 'dilation'.
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selem : ndarray, optional
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The neighborhood expressed as an n-D array of 1's and 0's.
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Default is the n-D square of radius equal to 1 (i.e. a 3x3 square
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for 2D images, a 3x3x3 cube for 3D images, etc.)
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offset : ndarray, optional
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The coordinates of the center of the structuring element.
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Default is located on the geometrical center of the selem, in that case
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selem dimensions must be odd.
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Returns
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-------
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reconstructed : ndarray
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The result of morphological reconstruction.
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Examples
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--------
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>>> import numpy as np
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>>> from skimage.morphology import reconstruction
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First, we create a sinusoidal mask image with peaks at middle and ends.
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>>> x = np.linspace(0, 4 * np.pi)
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>>> y_mask = np.cos(x)
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Then, we create a seed image initialized to the minimum mask value (for
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reconstruction by dilation, min-intensity values don't spread) and add
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"seeds" to the left and right peak, but at a fraction of peak value (1).
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>>> y_seed = y_mask.min() * np.ones_like(x)
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>>> y_seed[0] = 0.5
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>>> y_seed[-1] = 0
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>>> y_rec = reconstruction(y_seed, y_mask)
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The reconstructed image (or curve, in this case) is exactly the same as the
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mask image, except that the peaks are truncated to 0.5 and 0. The middle
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peak disappears completely: Since there were no seed values in this peak
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region, its reconstructed value is truncated to the surrounding value (-1).
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As a more practical example, we try to extract the bright features of an
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image by subtracting a background image created by reconstruction.
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>>> y, x = np.mgrid[:20:0.5, :20:0.5]
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>>> bumps = np.sin(x) + np.sin(y)
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To create the background image, set the mask image to the original image,
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and the seed image to the original image with an intensity offset, `h`.
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>>> h = 0.3
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>>> seed = bumps - h
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>>> background = reconstruction(seed, bumps)
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The resulting reconstructed image looks exactly like the original image,
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but with the peaks of the bumps cut off. Subtracting this reconstructed
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image from the original image leaves just the peaks of the bumps
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>>> hdome = bumps - background
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This operation is known as the h-dome of the image and leaves features
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of height `h` in the subtracted image.
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Notes
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-----
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The algorithm is taken from [1]_. Applications for greyscale reconstruction
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are discussed in [2]_ and [3]_.
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References
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----------
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.. [1] Robinson, "Efficient morphological reconstruction: a downhill
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filter", Pattern Recognition Letters 25 (2004) 1759-1767.
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.. [2] Vincent, L., "Morphological Grayscale Reconstruction in Image
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Analysis: Applications and Efficient Algorithms", IEEE Transactions
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on Image Processing (1993)
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.. [3] Soille, P., "Morphological Image Analysis: Principles and
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Applications", Chapter 6, 2nd edition (2003), ISBN 3540429883.
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"""
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assert tuple(seed.shape) == tuple(mask.shape)
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if method == 'dilation' and np.any(seed > mask):
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raise ValueError("Intensity of seed image must be less than that "
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"of the mask image for reconstruction by dilation.")
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elif method == 'erosion' and np.any(seed < mask):
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raise ValueError("Intensity of seed image must be greater than that "
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"of the mask image for reconstruction by erosion.")
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try:
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from ._greyreconstruct import reconstruction_loop
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except ImportError:
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raise ImportError("_greyreconstruct extension not available.")
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if selem is None:
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selem = np.ones([3] * seed.ndim, dtype=bool)
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else:
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selem = selem.astype(bool)
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if offset is None:
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if not all([d % 2 == 1 for d in selem.shape]):
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raise ValueError("Footprint dimensions must all be odd")
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offset = np.array([d // 2 for d in selem.shape])
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else:
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if offset.ndim != selem.ndim:
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raise ValueError("Offset and selem ndims must be equal.")
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if not all([(0 <= o < d) for o, d in zip(offset, selem.shape)]):
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raise ValueError("Offset must be included inside selem")
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# Cross out the center of the selem
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selem[tuple(slice(d, d + 1) for d in offset)] = False
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# Make padding for edges of reconstructed image so we can ignore boundaries
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dims = np.zeros(seed.ndim + 1, dtype=int)
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dims[1:] = np.array(seed.shape) + (np.array(selem.shape) - 1)
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dims[0] = 2
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inside_slices = tuple(slice(o, o + s) for o, s in zip(offset, seed.shape))
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# Set padded region to minimum image intensity and mask along first axis so
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# we can interleave image and mask pixels when sorting.
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if method == 'dilation':
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pad_value = np.min(seed)
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elif method == 'erosion':
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pad_value = np.max(seed)
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else:
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raise ValueError("Reconstruction method can be one of 'erosion' "
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"or 'dilation'. Got '%s'." % method)
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images = np.full(dims, pad_value, dtype='float64')
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images[(0, *inside_slices)] = seed
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images[(1, *inside_slices)] = mask
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# Create a list of strides across the array to get the neighbors within
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# a flattened array
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value_stride = np.array(images.strides[1:]) // images.dtype.itemsize
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image_stride = images.strides[0] // images.dtype.itemsize
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selem_mgrid = np.mgrid[[slice(-o, d - o)
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for d, o in zip(selem.shape, offset)]]
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selem_offsets = selem_mgrid[:, selem].transpose()
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nb_strides = np.array([np.sum(value_stride * selem_offset)
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for selem_offset in selem_offsets], np.int32)
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images = images.flatten()
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# Erosion goes smallest to largest; dilation goes largest to smallest.
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index_sorted = np.argsort(images).astype(np.int32)
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if method == 'dilation':
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index_sorted = index_sorted[::-1]
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# Make a linked list of pixels sorted by value. -1 is the list terminator.
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prev = np.full(len(images), -1, np.int32)
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next = np.full(len(images), -1, np.int32)
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prev[index_sorted[1:]] = index_sorted[:-1]
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next[index_sorted[:-1]] = index_sorted[1:]
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# Cython inner-loop compares the rank of pixel values.
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if method == 'dilation':
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value_rank, value_map = rank_order(images)
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elif method == 'erosion':
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value_rank, value_map = rank_order(-images)
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value_map = -value_map
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start = index_sorted[0]
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reconstruction_loop(value_rank, prev, next, nb_strides, start,
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image_stride)
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# Reshape reconstructed image to original image shape and remove padding.
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rec_img = value_map[value_rank[:image_stride]]
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rec_img.shape = np.array(seed.shape) + (np.array(selem.shape) - 1)
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return rec_img[inside_slices]
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