import annotator.uniformer.mmcv as mmcv import numpy as np from annotator.uniformer.mmcv.utils import deprecated_api_warning, is_tuple_of from numpy import random from ..builder import PIPELINES @PIPELINES.register_module() class Resize(object): """Resize images & seg. This transform resizes the input image to some scale. If the input dict contains the key "scale", then the scale in the input dict is used, otherwise the specified scale in the init method is used. ``img_scale`` can be None, a tuple (single-scale) or a list of tuple (multi-scale). There are 4 multiscale modes: - ``ratio_range is not None``: 1. When img_scale is None, img_scale is the shape of image in results (img_scale = results['img'].shape[:2]) and the image is resized based on the original size. (mode 1) 2. When img_scale is a tuple (single-scale), randomly sample a ratio from the ratio range and multiply it with the image scale. (mode 2) - ``ratio_range is None and multiscale_mode == "range"``: randomly sample a scale from the a range. (mode 3) - ``ratio_range is None and multiscale_mode == "value"``: randomly sample a scale from multiple scales. (mode 4) Args: img_scale (tuple or list[tuple]): Images scales for resizing. multiscale_mode (str): Either "range" or "value". ratio_range (tuple[float]): (min_ratio, max_ratio) keep_ratio (bool): Whether to keep the aspect ratio when resizing the image. """ def __init__(self, img_scale=None, multiscale_mode='range', ratio_range=None, keep_ratio=True): if img_scale is None: self.img_scale = None else: if isinstance(img_scale, list): self.img_scale = img_scale else: self.img_scale = [img_scale] assert mmcv.is_list_of(self.img_scale, tuple) if ratio_range is not None: # mode 1: given img_scale=None and a range of image ratio # mode 2: given a scale and a range of image ratio assert self.img_scale is None or len(self.img_scale) == 1 else: # mode 3 and 4: given multiple scales or a range of scales assert multiscale_mode in ['value', 'range'] self.multiscale_mode = multiscale_mode self.ratio_range = ratio_range self.keep_ratio = keep_ratio @staticmethod def random_select(img_scales): """Randomly select an img_scale from given candidates. Args: img_scales (list[tuple]): Images scales for selection. Returns: (tuple, int): Returns a tuple ``(img_scale, scale_dix)``, where ``img_scale`` is the selected image scale and ``scale_idx`` is the selected index in the given candidates. """ assert mmcv.is_list_of(img_scales, tuple) scale_idx = np.random.randint(len(img_scales)) img_scale = img_scales[scale_idx] return img_scale, scale_idx @staticmethod def random_sample(img_scales): """Randomly sample an img_scale when ``multiscale_mode=='range'``. Args: img_scales (list[tuple]): Images scale range for sampling. There must be two tuples in img_scales, which specify the lower and upper bound of image scales. Returns: (tuple, None): Returns a tuple ``(img_scale, None)``, where ``img_scale`` is sampled scale and None is just a placeholder to be consistent with :func:`random_select`. """ assert mmcv.is_list_of(img_scales, tuple) and len(img_scales) == 2 img_scale_long = [max(s) for s in img_scales] img_scale_short = [min(s) for s in img_scales] long_edge = np.random.randint( min(img_scale_long), max(img_scale_long) + 1) short_edge = np.random.randint( min(img_scale_short), max(img_scale_short) + 1) img_scale = (long_edge, short_edge) return img_scale, None @staticmethod def random_sample_ratio(img_scale, ratio_range): """Randomly sample an img_scale when ``ratio_range`` is specified. A ratio will be randomly sampled from the range specified by ``ratio_range``. Then it would be multiplied with ``img_scale`` to generate sampled scale. Args: img_scale (tuple): Images scale base to multiply with ratio. ratio_range (tuple[float]): The minimum and maximum ratio to scale the ``img_scale``. Returns: (tuple, None): Returns a tuple ``(scale, None)``, where ``scale`` is sampled ratio multiplied with ``img_scale`` and None is just a placeholder to be consistent with :func:`random_select`. """ assert isinstance(img_scale, tuple) and len(img_scale) == 2 min_ratio, max_ratio = ratio_range assert min_ratio <= max_ratio ratio = np.random.random_sample() * (max_ratio - min_ratio) + min_ratio scale = int(img_scale[0] * ratio), int(img_scale[1] * ratio) return scale, None def _random_scale(self, results): """Randomly sample an img_scale according to ``ratio_range`` and ``multiscale_mode``. If ``ratio_range`` is specified, a ratio will be sampled and be multiplied with ``img_scale``. If multiple scales are specified by ``img_scale``, a scale will be sampled according to ``multiscale_mode``. Otherwise, single scale will be used. Args: results (dict): Result dict from :obj:`dataset`. Returns: dict: Two new keys 'scale` and 'scale_idx` are added into ``results``, which would be used by subsequent pipelines. """ if self.ratio_range is not None: if self.img_scale is None: h, w = results['img'].shape[:2] scale, scale_idx = self.random_sample_ratio((w, h), self.ratio_range) else: scale, scale_idx = self.random_sample_ratio( self.img_scale[0], self.ratio_range) elif len(self.img_scale) == 1: scale, scale_idx = self.img_scale[0], 0 elif self.multiscale_mode == 'range': scale, scale_idx = self.random_sample(self.img_scale) elif self.multiscale_mode == 'value': scale, scale_idx = self.random_select(self.img_scale) else: raise NotImplementedError results['scale'] = scale results['scale_idx'] = scale_idx def _resize_img(self, results): """Resize images with ``results['scale']``.""" if self.keep_ratio: img, scale_factor = mmcv.imrescale( results['img'], results['scale'], return_scale=True) # the w_scale and h_scale has minor difference # a real fix should be done in the mmcv.imrescale in the future new_h, new_w = img.shape[:2] h, w = results['img'].shape[:2] w_scale = new_w / w h_scale = new_h / h else: img, w_scale, h_scale = mmcv.imresize( results['img'], results['scale'], return_scale=True) scale_factor = np.array([w_scale, h_scale, w_scale, h_scale], dtype=np.float32) results['img'] = img results['img_shape'] = img.shape results['pad_shape'] = img.shape # in case that there is no padding results['scale_factor'] = scale_factor results['keep_ratio'] = self.keep_ratio def _resize_seg(self, results): """Resize semantic segmentation map with ``results['scale']``.""" for key in results.get('seg_fields', []): if self.keep_ratio: gt_seg = mmcv.imrescale( results[key], results['scale'], interpolation='nearest') else: gt_seg = mmcv.imresize( results[key], results['scale'], interpolation='nearest') results[key] = gt_seg def __call__(self, results): """Call function to resize images, bounding boxes, masks, semantic segmentation map. Args: results (dict): Result dict from loading pipeline. Returns: dict: Resized results, 'img_shape', 'pad_shape', 'scale_factor', 'keep_ratio' keys are added into result dict. """ if 'scale' not in results: self._random_scale(results) self._resize_img(results) self._resize_seg(results) return results def __repr__(self): repr_str = self.__class__.__name__ repr_str += (f'(img_scale={self.img_scale}, ' f'multiscale_mode={self.multiscale_mode}, ' f'ratio_range={self.ratio_range}, ' f'keep_ratio={self.keep_ratio})') return repr_str @PIPELINES.register_module() class RandomFlip(object): """Flip the image & seg. If the input dict contains the key "flip", then the flag will be used, otherwise it will be randomly decided by a ratio specified in the init method. Args: prob (float, optional): The flipping probability. Default: None. direction(str, optional): The flipping direction. Options are 'horizontal' and 'vertical'. Default: 'horizontal'. """ @deprecated_api_warning({'flip_ratio': 'prob'}, cls_name='RandomFlip') def __init__(self, prob=None, direction='horizontal'): self.prob = prob self.direction = direction if prob is not None: assert prob >= 0 and prob <= 1 assert direction in ['horizontal', 'vertical'] def __call__(self, results): """Call function to flip bounding boxes, masks, semantic segmentation maps. Args: results (dict): Result dict from loading pipeline. Returns: dict: Flipped results, 'flip', 'flip_direction' keys are added into result dict. """ if 'flip' not in results: flip = True if np.random.rand() < self.prob else False results['flip'] = flip if 'flip_direction' not in results: results['flip_direction'] = self.direction if results['flip']: # flip image results['img'] = mmcv.imflip( results['img'], direction=results['flip_direction']) # flip segs for key in results.get('seg_fields', []): # use copy() to make numpy stride positive results[key] = mmcv.imflip( results[key], direction=results['flip_direction']).copy() return results def __repr__(self): return self.__class__.__name__ + f'(prob={self.prob})' @PIPELINES.register_module() class Pad(object): """Pad the image & mask. There are two padding modes: (1) pad to a fixed size and (2) pad to the minimum size that is divisible by some number. Added keys are "pad_shape", "pad_fixed_size", "pad_size_divisor", Args: size (tuple, optional): Fixed padding size. size_divisor (int, optional): The divisor of padded size. pad_val (float, optional): Padding value. Default: 0. seg_pad_val (float, optional): Padding value of segmentation map. Default: 255. """ def __init__(self, size=None, size_divisor=None, pad_val=0, seg_pad_val=255): self.size = size self.size_divisor = size_divisor self.pad_val = pad_val self.seg_pad_val = seg_pad_val # only one of size and size_divisor should be valid assert size is not None or size_divisor is not None assert size is None or size_divisor is None def _pad_img(self, results): """Pad images according to ``self.size``.""" if self.size is not None: padded_img = mmcv.impad( results['img'], shape=self.size, pad_val=self.pad_val) elif self.size_divisor is not None: padded_img = mmcv.impad_to_multiple( results['img'], self.size_divisor, pad_val=self.pad_val) results['img'] = padded_img results['pad_shape'] = padded_img.shape results['pad_fixed_size'] = self.size results['pad_size_divisor'] = self.size_divisor def _pad_seg(self, results): """Pad masks according to ``results['pad_shape']``.""" for key in results.get('seg_fields', []): results[key] = mmcv.impad( results[key], shape=results['pad_shape'][:2], pad_val=self.seg_pad_val) def __call__(self, results): """Call function to pad images, masks, semantic segmentation maps. Args: results (dict): Result dict from loading pipeline. Returns: dict: Updated result dict. """ self._pad_img(results) self._pad_seg(results) return results def __repr__(self): repr_str = self.__class__.__name__ repr_str += f'(size={self.size}, size_divisor={self.size_divisor}, ' \ f'pad_val={self.pad_val})' return repr_str @PIPELINES.register_module() class Normalize(object): """Normalize the image. Added key is "img_norm_cfg". Args: mean (sequence): Mean values of 3 channels. std (sequence): Std values of 3 channels. to_rgb (bool): Whether to convert the image from BGR to RGB, default is true. """ def __init__(self, mean, std, to_rgb=True): self.mean = np.array(mean, dtype=np.float32) self.std = np.array(std, dtype=np.float32) self.to_rgb = to_rgb def __call__(self, results): """Call function to normalize images. Args: results (dict): Result dict from loading pipeline. Returns: dict: Normalized results, 'img_norm_cfg' key is added into result dict. """ results['img'] = mmcv.imnormalize(results['img'], self.mean, self.std, self.to_rgb) results['img_norm_cfg'] = dict( mean=self.mean, std=self.std, to_rgb=self.to_rgb) return results def __repr__(self): repr_str = self.__class__.__name__ repr_str += f'(mean={self.mean}, std={self.std}, to_rgb=' \ f'{self.to_rgb})' return repr_str @PIPELINES.register_module() class Rerange(object): """Rerange the image pixel value. Args: min_value (float or int): Minimum value of the reranged image. Default: 0. max_value (float or int): Maximum value of the reranged image. Default: 255. """ def __init__(self, min_value=0, max_value=255): assert isinstance(min_value, float) or isinstance(min_value, int) assert isinstance(max_value, float) or isinstance(max_value, int) assert min_value < max_value self.min_value = min_value self.max_value = max_value def __call__(self, results): """Call function to rerange images. Args: results (dict): Result dict from loading pipeline. Returns: dict: Reranged results. """ img = results['img'] img_min_value = np.min(img) img_max_value = np.max(img) assert img_min_value < img_max_value # rerange to [0, 1] img = (img - img_min_value) / (img_max_value - img_min_value) # rerange to [min_value, max_value] img = img * (self.max_value - self.min_value) + self.min_value results['img'] = img return results def __repr__(self): repr_str = self.__class__.__name__ repr_str += f'(min_value={self.min_value}, max_value={self.max_value})' return repr_str @PIPELINES.register_module() class CLAHE(object): """Use CLAHE method to process the image. See `ZUIDERVELD,K. Contrast Limited Adaptive Histogram Equalization[J]. Graphics Gems, 1994:474-485.` for more information. Args: clip_limit (float): Threshold for contrast limiting. Default: 40.0. tile_grid_size (tuple[int]): Size of grid for histogram equalization. Input image will be divided into equally sized rectangular tiles. It defines the number of tiles in row and column. Default: (8, 8). """ def __init__(self, clip_limit=40.0, tile_grid_size=(8, 8)): assert isinstance(clip_limit, (float, int)) self.clip_limit = clip_limit assert is_tuple_of(tile_grid_size, int) assert len(tile_grid_size) == 2 self.tile_grid_size = tile_grid_size def __call__(self, results): """Call function to Use CLAHE method process images. Args: results (dict): Result dict from loading pipeline. Returns: dict: Processed results. """ for i in range(results['img'].shape[2]): results['img'][:, :, i] = mmcv.clahe( np.array(results['img'][:, :, i], dtype=np.uint8), self.clip_limit, self.tile_grid_size) return results def __repr__(self): repr_str = self.__class__.__name__ repr_str += f'(clip_limit={self.clip_limit}, '\ f'tile_grid_size={self.tile_grid_size})' return repr_str @PIPELINES.register_module() class RandomCrop(object): """Random crop the image & seg. Args: crop_size (tuple): Expected size after cropping, (h, w). cat_max_ratio (float): The maximum ratio that single category could occupy. """ def __init__(self, crop_size, cat_max_ratio=1., ignore_index=255): assert crop_size[0] > 0 and crop_size[1] > 0 self.crop_size = crop_size self.cat_max_ratio = cat_max_ratio self.ignore_index = ignore_index def get_crop_bbox(self, img): """Randomly get a crop bounding box.""" margin_h = max(img.shape[0] - self.crop_size[0], 0) margin_w = max(img.shape[1] - self.crop_size[1], 0) offset_h = np.random.randint(0, margin_h + 1) offset_w = np.random.randint(0, margin_w + 1) crop_y1, crop_y2 = offset_h, offset_h + self.crop_size[0] crop_x1, crop_x2 = offset_w, offset_w + self.crop_size[1] return crop_y1, crop_y2, crop_x1, crop_x2 def crop(self, img, crop_bbox): """Crop from ``img``""" crop_y1, crop_y2, crop_x1, crop_x2 = crop_bbox img = img[crop_y1:crop_y2, crop_x1:crop_x2, ...] return img def __call__(self, results): """Call function to randomly crop images, semantic segmentation maps. Args: results (dict): Result dict from loading pipeline. Returns: dict: Randomly cropped results, 'img_shape' key in result dict is updated according to crop size. """ img = results['img'] crop_bbox = self.get_crop_bbox(img) if self.cat_max_ratio < 1.: # Repeat 10 times for _ in range(10): seg_temp = self.crop(results['gt_semantic_seg'], crop_bbox) labels, cnt = np.unique(seg_temp, return_counts=True) cnt = cnt[labels != self.ignore_index] if len(cnt) > 1 and np.max(cnt) / np.sum( cnt) < self.cat_max_ratio: break crop_bbox = self.get_crop_bbox(img) # crop the image img = self.crop(img, crop_bbox) img_shape = img.shape results['img'] = img results['img_shape'] = img_shape # crop semantic seg for key in results.get('seg_fields', []): results[key] = self.crop(results[key], crop_bbox) return results def __repr__(self): return self.__class__.__name__ + f'(crop_size={self.crop_size})' @PIPELINES.register_module() class RandomRotate(object): """Rotate the image & seg. Args: prob (float): The rotation probability. degree (float, tuple[float]): Range of degrees to select from. If degree is a number instead of tuple like (min, max), the range of degree will be (``-degree``, ``+degree``) pad_val (float, optional): Padding value of image. Default: 0. seg_pad_val (float, optional): Padding value of segmentation map. Default: 255. center (tuple[float], optional): Center point (w, h) of the rotation in the source image. If not specified, the center of the image will be used. Default: None. auto_bound (bool): Whether to adjust the image size to cover the whole rotated image. Default: False """ def __init__(self, prob, degree, pad_val=0, seg_pad_val=255, center=None, auto_bound=False): self.prob = prob assert prob >= 0 and prob <= 1 if isinstance(degree, (float, int)): assert degree > 0, f'degree {degree} should be positive' self.degree = (-degree, degree) else: self.degree = degree assert len(self.degree) == 2, f'degree {self.degree} should be a ' \ f'tuple of (min, max)' self.pal_val = pad_val self.seg_pad_val = seg_pad_val self.center = center self.auto_bound = auto_bound def __call__(self, results): """Call function to rotate image, semantic segmentation maps. Args: results (dict): Result dict from loading pipeline. Returns: dict: Rotated results. """ rotate = True if np.random.rand() < self.prob else False degree = np.random.uniform(min(*self.degree), max(*self.degree)) if rotate: # rotate image results['img'] = mmcv.imrotate( results['img'], angle=degree, border_value=self.pal_val, center=self.center, auto_bound=self.auto_bound) # rotate segs for key in results.get('seg_fields', []): results[key] = mmcv.imrotate( results[key], angle=degree, border_value=self.seg_pad_val, center=self.center, auto_bound=self.auto_bound, interpolation='nearest') return results def __repr__(self): repr_str = self.__class__.__name__ repr_str += f'(prob={self.prob}, ' \ f'degree={self.degree}, ' \ f'pad_val={self.pal_val}, ' \ f'seg_pad_val={self.seg_pad_val}, ' \ f'center={self.center}, ' \ f'auto_bound={self.auto_bound})' return repr_str @PIPELINES.register_module() class RGB2Gray(object): """Convert RGB image to grayscale image. This transform calculate the weighted mean of input image channels with ``weights`` and then expand the channels to ``out_channels``. When ``out_channels`` is None, the number of output channels is the same as input channels. Args: out_channels (int): Expected number of output channels after transforming. Default: None. weights (tuple[float]): The weights to calculate the weighted mean. Default: (0.299, 0.587, 0.114). """ def __init__(self, out_channels=None, weights=(0.299, 0.587, 0.114)): assert out_channels is None or out_channels > 0 self.out_channels = out_channels assert isinstance(weights, tuple) for item in weights: assert isinstance(item, (float, int)) self.weights = weights def __call__(self, results): """Call function to convert RGB image to grayscale image. Args: results (dict): Result dict from loading pipeline. Returns: dict: Result dict with grayscale image. """ img = results['img'] assert len(img.shape) == 3 assert img.shape[2] == len(self.weights) weights = np.array(self.weights).reshape((1, 1, -1)) img = (img * weights).sum(2, keepdims=True) if self.out_channels is None: img = img.repeat(weights.shape[2], axis=2) else: img = img.repeat(self.out_channels, axis=2) results['img'] = img results['img_shape'] = img.shape return results def __repr__(self): repr_str = self.__class__.__name__ repr_str += f'(out_channels={self.out_channels}, ' \ f'weights={self.weights})' return repr_str @PIPELINES.register_module() class AdjustGamma(object): """Using gamma correction to process the image. Args: gamma (float or int): Gamma value used in gamma correction. Default: 1.0. """ def __init__(self, gamma=1.0): assert isinstance(gamma, float) or isinstance(gamma, int) assert gamma > 0 self.gamma = gamma inv_gamma = 1.0 / gamma self.table = np.array([(i / 255.0)**inv_gamma * 255 for i in np.arange(256)]).astype('uint8') def __call__(self, results): """Call function to process the image with gamma correction. Args: results (dict): Result dict from loading pipeline. Returns: dict: Processed results. """ results['img'] = mmcv.lut_transform( np.array(results['img'], dtype=np.uint8), self.table) return results def __repr__(self): return self.__class__.__name__ + f'(gamma={self.gamma})' @PIPELINES.register_module() class SegRescale(object): """Rescale semantic segmentation maps. Args: scale_factor (float): The scale factor of the final output. """ def __init__(self, scale_factor=1): self.scale_factor = scale_factor def __call__(self, results): """Call function to scale the semantic segmentation map. Args: results (dict): Result dict from loading pipeline. Returns: dict: Result dict with semantic segmentation map scaled. """ for key in results.get('seg_fields', []): if self.scale_factor != 1: results[key] = mmcv.imrescale( results[key], self.scale_factor, interpolation='nearest') return results def __repr__(self): return self.__class__.__name__ + f'(scale_factor={self.scale_factor})' @PIPELINES.register_module() class PhotoMetricDistortion(object): """Apply photometric distortion to image sequentially, every transformation is applied with a probability of 0.5. The position of random contrast is in second or second to last. 1. random brightness 2. random contrast (mode 0) 3. convert color from BGR to HSV 4. random saturation 5. random hue 6. convert color from HSV to BGR 7. random contrast (mode 1) Args: brightness_delta (int): delta of brightness. contrast_range (tuple): range of contrast. saturation_range (tuple): range of saturation. hue_delta (int): delta of hue. """ def __init__(self, brightness_delta=32, contrast_range=(0.5, 1.5), saturation_range=(0.5, 1.5), hue_delta=18): self.brightness_delta = brightness_delta self.contrast_lower, self.contrast_upper = contrast_range self.saturation_lower, self.saturation_upper = saturation_range self.hue_delta = hue_delta def convert(self, img, alpha=1, beta=0): """Multiple with alpha and add beat with clip.""" img = img.astype(np.float32) * alpha + beta img = np.clip(img, 0, 255) return img.astype(np.uint8) def brightness(self, img): """Brightness distortion.""" if random.randint(2): return self.convert( img, beta=random.uniform(-self.brightness_delta, self.brightness_delta)) return img def contrast(self, img): """Contrast distortion.""" if random.randint(2): return self.convert( img, alpha=random.uniform(self.contrast_lower, self.contrast_upper)) return img def saturation(self, img): """Saturation distortion.""" if random.randint(2): img = mmcv.bgr2hsv(img) img[:, :, 1] = self.convert( img[:, :, 1], alpha=random.uniform(self.saturation_lower, self.saturation_upper)) img = mmcv.hsv2bgr(img) return img def hue(self, img): """Hue distortion.""" if random.randint(2): img = mmcv.bgr2hsv(img) img[:, :, 0] = (img[:, :, 0].astype(int) + random.randint(-self.hue_delta, self.hue_delta)) % 180 img = mmcv.hsv2bgr(img) return img def __call__(self, results): """Call function to perform photometric distortion on images. Args: results (dict): Result dict from loading pipeline. Returns: dict: Result dict with images distorted. """ img = results['img'] # random brightness img = self.brightness(img) # mode == 0 --> do random contrast first # mode == 1 --> do random contrast last mode = random.randint(2) if mode == 1: img = self.contrast(img) # random saturation img = self.saturation(img) # random hue img = self.hue(img) # random contrast if mode == 0: img = self.contrast(img) results['img'] = img return results def __repr__(self): repr_str = self.__class__.__name__ repr_str += (f'(brightness_delta={self.brightness_delta}, ' f'contrast_range=({self.contrast_lower}, ' f'{self.contrast_upper}), ' f'saturation_range=({self.saturation_lower}, ' f'{self.saturation_upper}), ' f'hue_delta={self.hue_delta})') return repr_str