# Copyright (c) 2022 PaddlePaddle Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import copy import cv2 import numpy as np import shapely.ops from shapely.geometry import Polygon, MultiPolygon, GeometryCollection from sklearn.linear_model import LinearRegression from skimage import exposure from joblib import load from PIL import Image def normalize(im, mean, std, min_value=[0, 0, 0], max_value=[255, 255, 255]): # Rescaling (min-max normalization) range_value = np.asarray( [1. / (max_value[i] - min_value[i]) for i in range(len(max_value))], dtype=np.float32) im = (im - np.asarray(min_value, dtype=np.float32)) * range_value # Standardization (Z-score Normalization) im -= mean im /= std return im def permute(im, to_bgr=False): im = np.swapaxes(im, 1, 2) im = np.swapaxes(im, 1, 0) if to_bgr: im = im[[2, 1, 0], :, :] return im def center_crop(im, crop_size=224): height, width = im.shape[:2] w_start = (width - crop_size) // 2 h_start = (height - crop_size) // 2 w_end = w_start + crop_size h_end = h_start + crop_size im = im[h_start:h_end, w_start:w_end, ...] return im def img_flip(im, method=0): """ Flip an image. This function provides 5 flipping methods and can be applied to 2D or 3D numpy arrays. Args: im (np.ndarray): Input image. method (int|string): Flipping method. Must be one of [ 0, 1, 2, 3, 4, 'h', 'v', 'hv', 'rt2lb', 'lt2rb', 'dia', 'adia']. 0 or 'h': flip the image in horizontal direction, which is the most frequently used method; 1 or 'v': flip the image in vertical direction; 2 or 'hv': flip the image in both horizontal diction and vertical direction; 3 or 'rt2lb' or 'dia': flip the image across the diagonal; 4 or 'lt2rb' or 'adia': flip the image across the anti-diagonal. Returns: np.ndarray: Flipped image. Raises: ValueError: Invalid shape of images. Examples: Assume an image is like this: img: / + + - / * - * / We can flip it with following code: img_h = img_flip(img, 'h') img_v = img_flip(img, 'v') img_vh = img_flip(img, 2) img_rt2lb = img_flip(img, 3) img_lt2rb = img_flip(img, 4) Then we get the flipped images: img_h, flipped in horizontal direction: + + \ * \ - \ * - img_v, flipped in vertical direction: - * \ - \ * \ + + img_vh, flipped in both horizontal diction and vertical direction: / * - * / - + + / img_rt2lb, mirrored on the diagonal: / | | + / * + * / img_lt2rb, mirrored on the anti-diagonal: / * + * / + | | / """ if not len(im.shape) >= 2: raise ValueError("The number of image dimensions is less than 2.") if method == 0 or method == 'h': return horizontal_flip(im) elif method == 1 or method == 'v': return vertical_flip(im) elif method == 2 or method == 'hv': return hv_flip(im) elif method == 3 or method == 'rt2lb' or method == 'dia': return rt2lb_flip(im) elif method == 4 or method == 'lt2rb' or method == 'adia': return lt2rb_flip(im) else: return im def horizontal_flip(im): im = im[:, ::-1, ...] return im def vertical_flip(im): im = im[::-1, :, ...] return im def hv_flip(im): im = im[::-1, ::-1, ...] return im def rt2lb_flip(im): axs_list = list(range(len(im.shape))) axs_list[:2] = [1, 0] im = im.transpose(axs_list) return im def lt2rb_flip(im): axs_list = list(range(len(im.shape))) axs_list[:2] = [1, 0] im = im[::-1, ::-1, ...].transpose(axs_list) return im def img_simple_rotate(im, method=0): """ Rotate an image. This function provides 3 rotating methods and can be applied to 2D or 3D numpy arrays. Args: im (np.ndarray): Input image. method (int|string): Rotating method, which must be one of [ 0, 1, 2, 90, 180, 270 ]. 0 or 90 : rotate the image by 90 degrees, clockwise; 1 or 180: rotate the image by 180 degrees, clockwise; 2 or 270: rotate the image by 270 degrees, clockwise. Returns: np.ndarray: Rotated image. Raises: ValueError: Invalid shape of images. Examples: Assume an image is like this: img: / + + - / * - * / We can rotate it with following code: img_r90 = img_simple_rotate(img, 90) img_r180 = img_simple_rotate(img, 1) img_r270 = img_simple_rotate(img, 2) Then we get the following rotated images: img_r90, rotated by 90°: | | \ * \ + \ * + img_r180, rotated by 180°: / * - * / - + + / img_r270, rotated by 270°: + * \ + \ * \ | | """ if not len(im.shape) >= 2: raise ValueError("The number of image dimensions is less than 2.") if method == 0 or method == 90: return rot_90(im) elif method == 1 or method == 180: return rot_180(im) elif method == 2 or method == 270: return rot_270(im) else: return im def rot_90(im): axs_list = list(range(len(im.shape))) axs_list[:2] = [1, 0] im = im[::-1, :, ...].transpose(axs_list) return im def rot_180(im): im = im[::-1, ::-1, ...] return im def rot_270(im): axs_list = list(range(len(im.shape))) axs_list[:2] = [1, 0] im = im[:, ::-1, ...].transpose(axs_list) return im def rgb2bgr(im): return im[:, :, ::-1] def is_poly(poly): assert isinstance(poly, (list, dict)), \ "Invalid poly type: {}".format(type(poly)) return isinstance(poly, list) def horizontal_flip_poly(poly, width): flipped_poly = np.array(poly) flipped_poly[0::2] = width - np.array(poly[0::2]) return flipped_poly.tolist() def horizontal_flip_rle(rle, height, width): import pycocotools.mask as mask_util if 'counts' in rle and type(rle['counts']) == list: rle = mask_util.frPyObjects(rle, height, width) mask = mask_util.decode(rle) mask = mask[:, ::-1] rle = mask_util.encode(np.array(mask, order='F', dtype=np.uint8)) return rle def vertical_flip_poly(poly, height): flipped_poly = np.array(poly) flipped_poly[1::2] = height - np.array(poly[1::2]) return flipped_poly.tolist() def vertical_flip_rle(rle, height, width): import pycocotools.mask as mask_util if 'counts' in rle and type(rle['counts']) == list: rle = mask_util.frPyObjects(rle, height, width) mask = mask_util.decode(rle) mask = mask[::-1, :] rle = mask_util.encode(np.array(mask, order='F', dtype=np.uint8)) return rle def crop_poly(segm, crop): xmin, ymin, xmax, ymax = crop crop_coord = [xmin, ymin, xmin, ymax, xmax, ymax, xmax, ymin] crop_p = np.array(crop_coord).reshape(4, 2) crop_p = Polygon(crop_p) crop_segm = list() for poly in segm: poly = np.array(poly).reshape(len(poly) // 2, 2) polygon = Polygon(poly) if not polygon.is_valid: exterior = polygon.exterior multi_lines = exterior.intersection(exterior) polygons = shapely.ops.polygonize(multi_lines) polygon = MultiPolygon(polygons) multi_polygon = list() if isinstance(polygon, MultiPolygon): multi_polygon = copy.deepcopy(polygon) else: multi_polygon.append(copy.deepcopy(polygon)) for per_polygon in multi_polygon: inter = per_polygon.intersection(crop_p) if not inter: continue if isinstance(inter, (MultiPolygon, GeometryCollection)): for part in inter: if not isinstance(part, Polygon): continue part = np.squeeze( np.array(part.exterior.coords[:-1]).reshape(1, -1)) part[0::2] -= xmin part[1::2] -= ymin crop_segm.append(part.tolist()) elif isinstance(inter, Polygon): crop_poly = np.squeeze( np.array(inter.exterior.coords[:-1]).reshape(1, -1)) crop_poly[0::2] -= xmin crop_poly[1::2] -= ymin crop_segm.append(crop_poly.tolist()) else: continue return crop_segm def crop_rle(rle, crop, height, width): import pycocotools.mask as mask_util if 'counts' in rle and type(rle['counts']) == list: rle = mask_util.frPyObjects(rle, height, width) mask = mask_util.decode(rle) mask = mask[crop[1]:crop[3], crop[0]:crop[2]] rle = mask_util.encode(np.array(mask, order='F', dtype=np.uint8)) return rle def expand_poly(poly, x, y): expanded_poly = np.array(poly) expanded_poly[0::2] += x expanded_poly[1::2] += y return expanded_poly.tolist() def expand_rle(rle, x, y, height, width, h, w): import pycocotools.mask as mask_util if 'counts' in rle and type(rle['counts']) == list: rle = mask_util.frPyObjects(rle, height, width) mask = mask_util.decode(rle) expanded_mask = np.full((h, w), 0).astype(mask.dtype) expanded_mask[y:y + height, x:x + width] = mask rle = mask_util.encode(np.array(expanded_mask, order='F', dtype=np.uint8)) return rle def resize_poly(poly, im_scale_x, im_scale_y): resized_poly = np.array(poly, dtype=np.float32) resized_poly[0::2] *= im_scale_x resized_poly[1::2] *= im_scale_y return resized_poly.tolist() def resize_rle(rle, im_h, im_w, im_scale_x, im_scale_y, interp): import pycocotools.mask as mask_util if 'counts' in rle and type(rle['counts']) == list: rle = mask_util.frPyObjects(rle, im_h, im_w) mask = mask_util.decode(rle) mask = cv2.resize( mask, None, None, fx=im_scale_x, fy=im_scale_y, interpolation=interp) rle = mask_util.encode(np.array(mask, order='F', dtype=np.uint8)) return rle def to_uint8(im, is_linear=False): """ Convert raster data to uint8 type. Args: im (np.ndarray): Input raster image. is_linear (bool, optional): Use 2% linear stretch or not. Default is False. Returns: np.ndarray: Image data with unit8 type. """ # 2% linear stretch def _two_percent_linear(image, max_out=255, min_out=0): def _gray_process(gray, maxout=max_out, minout=min_out): # Get the corresponding gray level at 98% in the histogram. high_value = np.percentile(gray, 98) low_value = np.percentile(gray, 2) truncated_gray = np.clip(gray, a_min=low_value, a_max=high_value) processed_gray = ((truncated_gray - low_value) / (high_value - low_value)) * \ (maxout - minout) return np.uint8(processed_gray) if len(image.shape) == 3: processes = [] for b in range(image.shape[-1]): processes.append(_gray_process(image[:, :, b])) result = np.stack(processes, axis=2) else: # if len(image.shape) == 2 result = _gray_process(image) return np.uint8(result) # Simple image standardization def _sample_norm(image): stretches = [] if len(image.shape) == 3: for b in range(image.shape[-1]): stretched = exposure.equalize_hist(image[:, :, b]) stretched /= float(np.max(stretched)) stretches.append(stretched) stretched_img = np.stack(stretches, axis=2) else: # if len(image.shape) == 2 stretched_img = exposure.equalize_hist(image) return np.uint8(stretched_img * 255) dtype = im.dtype.name if dtype != "uint8": im = _sample_norm(im) if is_linear: im = _two_percent_linear(im) return im def to_intensity(im): """ Calculate the intensity of SAR data. Args: im (np.ndarray): SAR image. Returns: np.ndarray: Intensity image. """ if len(im.shape) != 2: raise ValueError("`len(im.shape) must be 2.") # If the type is complex, this is SAR data. if isinstance(type(im[0, 0]), complex): im = abs(im) return im def select_bands(im, band_list=[1, 2, 3]): """ Select bands of a multi-band image. Args: im (np.ndarray): Input image. band_list (list, optional): Bands to select (band index start from 1). Defaults to [1, 2, 3]. Returns: np.ndarray: Image with selected bands. """ if len(im.shape) == 2: # Image has only one channel return im if not isinstance(band_list, list) or len(band_list) == 0: raise TypeError("band_list must be non empty list.") total_band = im.shape[-1] result = [] for band in band_list: band = int(band - 1) if band < 0 or band >= total_band: raise ValueError("The element in band_list must > 1 and <= {}.". format(str(total_band))) result.append(im[:, :, band]) ima = np.stack(result, axis=-1) return ima def dehaze(im, gamma=False): """ Perform single image haze removal using dark channel prior. Args: im (np.ndarray): Input image. gamma (bool, optional): Use gamma correction or not. Defaults to False. Returns: np.ndarray: Output dehazed image. """ def _guided_filter(I, p, r, eps): m_I = cv2.boxFilter(I, -1, (r, r)) m_p = cv2.boxFilter(p, -1, (r, r)) m_Ip = cv2.boxFilter(I * p, -1, (r, r)) cov_Ip = m_Ip - m_I * m_p m_II = cv2.boxFilter(I * I, -1, (r, r)) var_I = m_II - m_I * m_I a = cov_Ip / (var_I + eps) b = m_p - a * m_I m_a = cv2.boxFilter(a, -1, (r, r)) m_b = cv2.boxFilter(b, -1, (r, r)) return m_a * I + m_b def _dehaze(im, r, w, maxatmo_mask, eps): # im is a RGB image and the value ranges in [0, 1]. atmo_mask = np.min(im, 2) dark_channel = cv2.erode(atmo_mask, np.ones((15, 15))) atmo_mask = _guided_filter(atmo_mask, dark_channel, r, eps) bins = 2000 ht = np.histogram(atmo_mask, bins) d = np.cumsum(ht[0]) / float(atmo_mask.size) for lmax in range(bins - 1, 0, -1): if d[lmax] <= 0.999: break atmo_illum = np.mean(im, 2)[atmo_mask >= ht[1][lmax]].max() atmo_mask = np.minimum(atmo_mask * w, maxatmo_mask) return atmo_mask, atmo_illum if np.max(im) > 1: im = im / 255. result = np.zeros(im.shape) mask_img, atmo_illum = _dehaze( im, r=81, w=0.95, maxatmo_mask=0.80, eps=1e-8) for k in range(3): result[:, :, k] = (im[:, :, k] - mask_img) / (1 - mask_img / atmo_illum) result = np.clip(result, 0, 1) if gamma: result = result**(np.log(0.5) / np.log(result.mean())) return (result * 255).astype("uint8") def match_histograms(im, ref): """ Match the cumulative histogram of one image to another. Args: im (np.ndarray): Input image. ref (np.ndarray): Reference image to match histogram of. `ref` must have the same number of channels as `im`. Returns: np.ndarray: Transformed input image. Raises: ValueError: When the number of channels of `ref` differs from that of im`. """ # TODO: Check the data types of the inputs to see if they are supported by skimage return exposure.match_histograms( im, ref, channel_axis=-1 if im.ndim > 2 else None) def match_by_regression(im, ref, pif_loc=None): """ Match the brightness values of two images using a linear regression method. Args: im (np.ndarray): Input image. ref (np.ndarray): Reference image to match. `ref` must have the same shape as `im`. pif_loc (tuple|None, optional): Spatial locations where pseudo-invariant features (PIFs) are obtained. If `pif_loc` is set to None, all pixels in the image will be used as training samples for the regression model. In other cases, `pif_loc` should be a tuple of np.ndarrays. Default: None. Returns: np.ndarray: Transformed input image. Raises: ValueError: When the shape of `ref` differs from that of `im`. """ def _linear_regress(im, ref, loc): regressor = LinearRegression() if loc is not None: x, y = im[loc], ref[loc] else: x, y = im, ref x, y = x.reshape(-1, 1), y.ravel() regressor.fit(x, y) matched = regressor.predict(im.reshape(-1, 1)) return matched.reshape(im.shape) if im.shape != ref.shape: raise ValueError("Image and Reference must have the same shape!") if im.ndim > 2: # Multiple channels matched = np.empty(im.shape, dtype=im.dtype) for ch in range(im.shape[-1]): matched[..., ch] = _linear_regress(im[..., ch], ref[..., ch], pif_loc) else: # Single channel matched = _linear_regress(im, ref, pif_loc).astype(im.dtype) return matched def inv_pca(im, joblib_path): """ Perform inverse PCA transformation. Args: im (np.ndarray): Input image after performing PCA. joblib_path (str): Path of *.joblib file that stores PCA information. Returns: np.ndarray: Reconstructed input image. """ pca = load(joblib_path) H, W, C = im.shape n_im = np.reshape(im, (-1, C)) r_im = pca.inverse_transform(n_im) r_im = np.reshape(r_im, (H, W, -1)) return r_im def decode_seg_mask(mask_path): """ Decode a segmentation mask image. Args: mask_path (str): Path of the mask image to decode. Returns: np.ndarray: Decoded mask image. """ mask = np.asarray(Image.open(mask_path)) mask = mask.astype('int64') return mask def calc_hr_shape(lr_shape, sr_factor): return tuple(int(s * sr_factor) for s in lr_shape)