""" The :mod:`sklearn.feature_extraction.image` submodule gathers utilities to extract features from images. """ # Authors: Emmanuelle Gouillart # Gael Varoquaux # Olivier Grisel # Vlad Niculae # License: BSD 3 clause from itertools import product from numbers import Integral, Number, Real import numpy as np from numpy.lib.stride_tricks import as_strided from scipy import sparse from ..base import BaseEstimator, TransformerMixin, _fit_context from ..utils import check_array, check_random_state from ..utils._param_validation import Hidden, Interval, RealNotInt, validate_params __all__ = [ "PatchExtractor", "extract_patches_2d", "grid_to_graph", "img_to_graph", "reconstruct_from_patches_2d", ] ############################################################################### # From an image to a graph def _make_edges_3d(n_x, n_y, n_z=1): """Returns a list of edges for a 3D image. Parameters ---------- n_x : int The size of the grid in the x direction. n_y : int The size of the grid in the y direction. n_z : integer, default=1 The size of the grid in the z direction, defaults to 1 """ vertices = np.arange(n_x * n_y * n_z).reshape((n_x, n_y, n_z)) edges_deep = np.vstack((vertices[:, :, :-1].ravel(), vertices[:, :, 1:].ravel())) edges_right = np.vstack((vertices[:, :-1].ravel(), vertices[:, 1:].ravel())) edges_down = np.vstack((vertices[:-1].ravel(), vertices[1:].ravel())) edges = np.hstack((edges_deep, edges_right, edges_down)) return edges def _compute_gradient_3d(edges, img): _, n_y, n_z = img.shape gradient = np.abs( img[ edges[0] // (n_y * n_z), (edges[0] % (n_y * n_z)) // n_z, (edges[0] % (n_y * n_z)) % n_z, ] - img[ edges[1] // (n_y * n_z), (edges[1] % (n_y * n_z)) // n_z, (edges[1] % (n_y * n_z)) % n_z, ] ) return gradient # XXX: Why mask the image after computing the weights? def _mask_edges_weights(mask, edges, weights=None): """Apply a mask to edges (weighted or not)""" inds = np.arange(mask.size) inds = inds[mask.ravel()] ind_mask = np.logical_and(np.isin(edges[0], inds), np.isin(edges[1], inds)) edges = edges[:, ind_mask] if weights is not None: weights = weights[ind_mask] if len(edges.ravel()): maxval = edges.max() else: maxval = 0 order = np.searchsorted(np.flatnonzero(mask), np.arange(maxval + 1)) edges = order[edges] if weights is None: return edges else: return edges, weights def _to_graph( n_x, n_y, n_z, mask=None, img=None, return_as=sparse.coo_matrix, dtype=None ): """Auxiliary function for img_to_graph and grid_to_graph""" edges = _make_edges_3d(n_x, n_y, n_z) if dtype is None: # To not overwrite input dtype if img is None: dtype = int else: dtype = img.dtype if img is not None: img = np.atleast_3d(img) weights = _compute_gradient_3d(edges, img) if mask is not None: edges, weights = _mask_edges_weights(mask, edges, weights) diag = img.squeeze()[mask] else: diag = img.ravel() n_voxels = diag.size else: if mask is not None: mask = mask.astype(dtype=bool, copy=False) edges = _mask_edges_weights(mask, edges) n_voxels = np.sum(mask) else: n_voxels = n_x * n_y * n_z weights = np.ones(edges.shape[1], dtype=dtype) diag = np.ones(n_voxels, dtype=dtype) diag_idx = np.arange(n_voxels) i_idx = np.hstack((edges[0], edges[1])) j_idx = np.hstack((edges[1], edges[0])) graph = sparse.coo_matrix( ( np.hstack((weights, weights, diag)), (np.hstack((i_idx, diag_idx)), np.hstack((j_idx, diag_idx))), ), (n_voxels, n_voxels), dtype=dtype, ) if return_as is np.ndarray: return graph.toarray() return return_as(graph) @validate_params( { "img": ["array-like"], "mask": [None, np.ndarray], "return_as": [type], "dtype": "no_validation", # validation delegated to numpy }, prefer_skip_nested_validation=True, ) def img_to_graph(img, *, mask=None, return_as=sparse.coo_matrix, dtype=None): """Graph of the pixel-to-pixel gradient connections. Edges are weighted with the gradient values. Read more in the :ref:`User Guide `. Parameters ---------- img : array-like of shape (height, width) or (height, width, channel) 2D or 3D image. mask : ndarray of shape (height, width) or \ (height, width, channel), dtype=bool, default=None An optional mask of the image, to consider only part of the pixels. return_as : np.ndarray or a sparse matrix class, \ default=sparse.coo_matrix The class to use to build the returned adjacency matrix. dtype : dtype, default=None The data of the returned sparse matrix. By default it is the dtype of img. Returns ------- graph : ndarray or a sparse matrix class The computed adjacency matrix. Notes ----- For scikit-learn versions 0.14.1 and prior, return_as=np.ndarray was handled by returning a dense np.matrix instance. Going forward, np.ndarray returns an np.ndarray, as expected. For compatibility, user code relying on this method should wrap its calls in ``np.asarray`` to avoid type issues. """ img = np.atleast_3d(img) n_x, n_y, n_z = img.shape return _to_graph(n_x, n_y, n_z, mask, img, return_as, dtype) @validate_params( { "n_x": [Interval(Integral, left=1, right=None, closed="left")], "n_y": [Interval(Integral, left=1, right=None, closed="left")], "n_z": [Interval(Integral, left=1, right=None, closed="left")], "mask": [None, np.ndarray], "return_as": [type], "dtype": "no_validation", # validation delegated to numpy }, prefer_skip_nested_validation=True, ) def grid_to_graph( n_x, n_y, n_z=1, *, mask=None, return_as=sparse.coo_matrix, dtype=int ): """Graph of the pixel-to-pixel connections. Edges exist if 2 voxels are connected. Parameters ---------- n_x : int Dimension in x axis. n_y : int Dimension in y axis. n_z : int, default=1 Dimension in z axis. mask : ndarray of shape (n_x, n_y, n_z), dtype=bool, default=None An optional mask of the image, to consider only part of the pixels. return_as : np.ndarray or a sparse matrix class, \ default=sparse.coo_matrix The class to use to build the returned adjacency matrix. dtype : dtype, default=int The data of the returned sparse matrix. By default it is int. Returns ------- graph : np.ndarray or a sparse matrix class The computed adjacency matrix. Notes ----- For scikit-learn versions 0.14.1 and prior, return_as=np.ndarray was handled by returning a dense np.matrix instance. Going forward, np.ndarray returns an np.ndarray, as expected. For compatibility, user code relying on this method should wrap its calls in ``np.asarray`` to avoid type issues. Examples -------- >>> import numpy as np >>> from sklearn.feature_extraction.image import grid_to_graph >>> shape_img = (4, 4, 1) >>> mask = np.zeros(shape=shape_img, dtype=bool) >>> mask[[1, 2], [1, 2], :] = True >>> graph = grid_to_graph(*shape_img, mask=mask) >>> print(graph) (0, 0) 1 (1, 1) 1 """ return _to_graph(n_x, n_y, n_z, mask=mask, return_as=return_as, dtype=dtype) ############################################################################### # From an image to a set of small image patches def _compute_n_patches(i_h, i_w, p_h, p_w, max_patches=None): """Compute the number of patches that will be extracted in an image. Read more in the :ref:`User Guide `. Parameters ---------- i_h : int The image height i_w : int The image with p_h : int The height of a patch p_w : int The width of a patch max_patches : int or float, default=None The maximum number of patches to extract. If `max_patches` is a float between 0 and 1, it is taken to be a proportion of the total number of patches. If `max_patches` is None, all possible patches are extracted. """ n_h = i_h - p_h + 1 n_w = i_w - p_w + 1 all_patches = n_h * n_w if max_patches: if isinstance(max_patches, (Integral)) and max_patches < all_patches: return max_patches elif isinstance(max_patches, (Integral)) and max_patches >= all_patches: return all_patches elif isinstance(max_patches, (Real)) and 0 < max_patches < 1: return int(max_patches * all_patches) else: raise ValueError("Invalid value for max_patches: %r" % max_patches) else: return all_patches def _extract_patches(arr, patch_shape=8, extraction_step=1): """Extracts patches of any n-dimensional array in place using strides. Given an n-dimensional array it will return a 2n-dimensional array with the first n dimensions indexing patch position and the last n indexing the patch content. This operation is immediate (O(1)). A reshape performed on the first n dimensions will cause numpy to copy data, leading to a list of extracted patches. Read more in the :ref:`User Guide `. Parameters ---------- arr : ndarray n-dimensional array of which patches are to be extracted patch_shape : int or tuple of length arr.ndim.default=8 Indicates the shape of the patches to be extracted. If an integer is given, the shape will be a hypercube of sidelength given by its value. extraction_step : int or tuple of length arr.ndim, default=1 Indicates step size at which extraction shall be performed. If integer is given, then the step is uniform in all dimensions. Returns ------- patches : strided ndarray 2n-dimensional array indexing patches on first n dimensions and containing patches on the last n dimensions. These dimensions are fake, but this way no data is copied. A simple reshape invokes a copying operation to obtain a list of patches: result.reshape([-1] + list(patch_shape)) """ arr_ndim = arr.ndim if isinstance(patch_shape, Number): patch_shape = tuple([patch_shape] * arr_ndim) if isinstance(extraction_step, Number): extraction_step = tuple([extraction_step] * arr_ndim) patch_strides = arr.strides slices = tuple(slice(None, None, st) for st in extraction_step) indexing_strides = arr[slices].strides patch_indices_shape = ( (np.array(arr.shape) - np.array(patch_shape)) // np.array(extraction_step) ) + 1 shape = tuple(list(patch_indices_shape) + list(patch_shape)) strides = tuple(list(indexing_strides) + list(patch_strides)) patches = as_strided(arr, shape=shape, strides=strides) return patches @validate_params( { "image": [np.ndarray], "patch_size": [tuple, list], "max_patches": [ Interval(RealNotInt, 0, 1, closed="neither"), Interval(Integral, 1, None, closed="left"), None, ], "random_state": ["random_state"], }, prefer_skip_nested_validation=True, ) def extract_patches_2d(image, patch_size, *, max_patches=None, random_state=None): """Reshape a 2D image into a collection of patches. The resulting patches are allocated in a dedicated array. Read more in the :ref:`User Guide `. Parameters ---------- image : ndarray of shape (image_height, image_width) or \ (image_height, image_width, n_channels) The original image data. For color images, the last dimension specifies the channel: a RGB image would have `n_channels=3`. patch_size : tuple of int (patch_height, patch_width) The dimensions of one patch. max_patches : int or float, default=None The maximum number of patches to extract. If `max_patches` is a float between 0 and 1, it is taken to be a proportion of the total number of patches. If `max_patches` is None it corresponds to the total number of patches that can be extracted. random_state : int, RandomState instance, default=None Determines the random number generator used for random sampling when `max_patches` is not None. Use an int to make the randomness deterministic. See :term:`Glossary `. Returns ------- patches : array of shape (n_patches, patch_height, patch_width) or \ (n_patches, patch_height, patch_width, n_channels) The collection of patches extracted from the image, where `n_patches` is either `max_patches` or the total number of patches that can be extracted. Examples -------- >>> from sklearn.datasets import load_sample_image >>> from sklearn.feature_extraction import image >>> # Use the array data from the first image in this dataset: >>> one_image = load_sample_image("china.jpg") >>> print('Image shape: {}'.format(one_image.shape)) Image shape: (427, 640, 3) >>> patches = image.extract_patches_2d(one_image, (2, 2)) >>> print('Patches shape: {}'.format(patches.shape)) Patches shape: (272214, 2, 2, 3) >>> # Here are just two of these patches: >>> print(patches[1]) [[[174 201 231] [174 201 231]] [[173 200 230] [173 200 230]]] >>> print(patches[800]) [[[187 214 243] [188 215 244]] [[187 214 243] [188 215 244]]] """ i_h, i_w = image.shape[:2] p_h, p_w = patch_size if p_h > i_h: raise ValueError( "Height of the patch should be less than the height of the image." ) if p_w > i_w: raise ValueError( "Width of the patch should be less than the width of the image." ) image = check_array(image, allow_nd=True) image = image.reshape((i_h, i_w, -1)) n_colors = image.shape[-1] extracted_patches = _extract_patches( image, patch_shape=(p_h, p_w, n_colors), extraction_step=1 ) n_patches = _compute_n_patches(i_h, i_w, p_h, p_w, max_patches) if max_patches: rng = check_random_state(random_state) i_s = rng.randint(i_h - p_h + 1, size=n_patches) j_s = rng.randint(i_w - p_w + 1, size=n_patches) patches = extracted_patches[i_s, j_s, 0] else: patches = extracted_patches patches = patches.reshape(-1, p_h, p_w, n_colors) # remove the color dimension if useless if patches.shape[-1] == 1: return patches.reshape((n_patches, p_h, p_w)) else: return patches @validate_params( {"patches": [np.ndarray], "image_size": [tuple, Hidden(list)]}, prefer_skip_nested_validation=True, ) def reconstruct_from_patches_2d(patches, image_size): """Reconstruct the image from all of its patches. Patches are assumed to overlap and the image is constructed by filling in the patches from left to right, top to bottom, averaging the overlapping regions. Read more in the :ref:`User Guide `. Parameters ---------- patches : ndarray of shape (n_patches, patch_height, patch_width) or \ (n_patches, patch_height, patch_width, n_channels) The complete set of patches. If the patches contain colour information, channels are indexed along the last dimension: RGB patches would have `n_channels=3`. image_size : tuple of int (image_height, image_width) or \ (image_height, image_width, n_channels) The size of the image that will be reconstructed. Returns ------- image : ndarray of shape image_size The reconstructed image. """ i_h, i_w = image_size[:2] p_h, p_w = patches.shape[1:3] img = np.zeros(image_size) # compute the dimensions of the patches array n_h = i_h - p_h + 1 n_w = i_w - p_w + 1 for p, (i, j) in zip(patches, product(range(n_h), range(n_w))): img[i : i + p_h, j : j + p_w] += p for i in range(i_h): for j in range(i_w): # divide by the amount of overlap # XXX: is this the most efficient way? memory-wise yes, cpu wise? img[i, j] /= float(min(i + 1, p_h, i_h - i) * min(j + 1, p_w, i_w - j)) return img class PatchExtractor(TransformerMixin, BaseEstimator): """Extracts patches from a collection of images. Read more in the :ref:`User Guide `. .. versionadded:: 0.9 Parameters ---------- patch_size : tuple of int (patch_height, patch_width), default=None The dimensions of one patch. If set to None, the patch size will be automatically set to `(img_height // 10, img_width // 10)`, where `img_height` and `img_width` are the dimensions of the input images. max_patches : int or float, default=None The maximum number of patches per image to extract. If `max_patches` is a float in (0, 1), it is taken to mean a proportion of the total number of patches. If set to None, extract all possible patches. random_state : int, RandomState instance, default=None Determines the random number generator used for random sampling when `max_patches is not None`. Use an int to make the randomness deterministic. See :term:`Glossary `. See Also -------- reconstruct_from_patches_2d : Reconstruct image from all of its patches. Notes ----- This estimator is stateless and does not need to be fitted. However, we recommend to call :meth:`fit_transform` instead of :meth:`transform`, as parameter validation is only performed in :meth:`fit`. Examples -------- >>> from sklearn.datasets import load_sample_images >>> from sklearn.feature_extraction import image >>> # Use the array data from the second image in this dataset: >>> X = load_sample_images().images[1] >>> X = X[None, ...] >>> print(f"Image shape: {X.shape}") Image shape: (1, 427, 640, 3) >>> pe = image.PatchExtractor(patch_size=(10, 10)) >>> pe_trans = pe.transform(X) >>> print(f"Patches shape: {pe_trans.shape}") Patches shape: (263758, 10, 10, 3) >>> X_reconstructed = image.reconstruct_from_patches_2d(pe_trans, X.shape[1:]) >>> print(f"Reconstructed shape: {X_reconstructed.shape}") Reconstructed shape: (427, 640, 3) """ _parameter_constraints: dict = { "patch_size": [tuple, None], "max_patches": [ None, Interval(RealNotInt, 0, 1, closed="neither"), Interval(Integral, 1, None, closed="left"), ], "random_state": ["random_state"], } def __init__(self, *, patch_size=None, max_patches=None, random_state=None): self.patch_size = patch_size self.max_patches = max_patches self.random_state = random_state @_fit_context(prefer_skip_nested_validation=True) def fit(self, X, y=None): """Only validate the parameters of the estimator. This method allows to: (i) validate the parameters of the estimator and (ii) be consistent with the scikit-learn transformer API. Parameters ---------- X : ndarray of shape (n_samples, image_height, image_width) or \ (n_samples, image_height, image_width, n_channels) Array of images from which to extract patches. For color images, the last dimension specifies the channel: a RGB image would have `n_channels=3`. y : Ignored Not used, present for API consistency by convention. Returns ------- self : object Returns the instance itself. """ return self def transform(self, X): """Transform the image samples in `X` into a matrix of patch data. Parameters ---------- X : ndarray of shape (n_samples, image_height, image_width) or \ (n_samples, image_height, image_width, n_channels) Array of images from which to extract patches. For color images, the last dimension specifies the channel: a RGB image would have `n_channels=3`. Returns ------- patches : array of shape (n_patches, patch_height, patch_width) or \ (n_patches, patch_height, patch_width, n_channels) The collection of patches extracted from the images, where `n_patches` is either `n_samples * max_patches` or the total number of patches that can be extracted. """ X = self._validate_data( X=X, ensure_2d=False, allow_nd=True, ensure_min_samples=1, ensure_min_features=1, reset=False, ) random_state = check_random_state(self.random_state) n_imgs, img_height, img_width = X.shape[:3] if self.patch_size is None: patch_size = img_height // 10, img_width // 10 else: if len(self.patch_size) != 2: raise ValueError( "patch_size must be a tuple of two integers. Got" f" {self.patch_size} instead." ) patch_size = self.patch_size n_imgs, img_height, img_width = X.shape[:3] X = np.reshape(X, (n_imgs, img_height, img_width, -1)) n_channels = X.shape[-1] # compute the dimensions of the patches array patch_height, patch_width = patch_size n_patches = _compute_n_patches( img_height, img_width, patch_height, patch_width, self.max_patches ) patches_shape = (n_imgs * n_patches,) + patch_size if n_channels > 1: patches_shape += (n_channels,) # extract the patches patches = np.empty(patches_shape) for ii, image in enumerate(X): patches[ii * n_patches : (ii + 1) * n_patches] = extract_patches_2d( image, patch_size, max_patches=self.max_patches, random_state=random_state, ) return patches def _more_tags(self): return {"X_types": ["3darray"], "stateless": True}