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import mmcv |
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import numpy as np |
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from mmcv.utils import deprecated_api_warning, is_tuple_of |
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from numpy import random |
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from mmseg.datasets.builder import PIPELINES |
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from IPython import embed |
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@PIPELINES.register_module() |
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class AlignResize(object): |
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"""Resize images & seg. Align |
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""" |
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def __init__(self, |
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img_scale=None, |
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multiscale_mode='range', |
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ratio_range=None, |
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keep_ratio=True, |
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size_divisor=32): |
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if img_scale is None: |
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self.img_scale = None |
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else: |
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if isinstance(img_scale, list): |
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self.img_scale = img_scale |
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else: |
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self.img_scale = [img_scale] |
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assert mmcv.is_list_of(self.img_scale, tuple) |
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if ratio_range is not None: |
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assert self.img_scale is None or len(self.img_scale) == 1 |
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else: |
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assert multiscale_mode in ['value', 'range'] |
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self.multiscale_mode = multiscale_mode |
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self.ratio_range = ratio_range |
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self.keep_ratio = keep_ratio |
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self.size_divisor = size_divisor |
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@staticmethod |
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def random_select(img_scales): |
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"""Randomly select an img_scale from given candidates. |
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Args: |
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img_scales (list[tuple]): Images scales for selection. |
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Returns: |
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(tuple, int): Returns a tuple ``(img_scale, scale_dix)``, |
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where ``img_scale`` is the selected image scale and |
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``scale_idx`` is the selected index in the given candidates. |
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""" |
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assert mmcv.is_list_of(img_scales, tuple) |
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scale_idx = np.random.randint(len(img_scales)) |
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img_scale = img_scales[scale_idx] |
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return img_scale, scale_idx |
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@staticmethod |
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def random_sample(img_scales): |
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"""Randomly sample an img_scale when ``multiscale_mode=='range'``. |
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Args: |
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img_scales (list[tuple]): Images scale range for sampling. |
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There must be two tuples in img_scales, which specify the lower |
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and uper bound of image scales. |
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Returns: |
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(tuple, None): Returns a tuple ``(img_scale, None)``, where |
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``img_scale`` is sampled scale and None is just a placeholder |
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to be consistent with :func:`random_select`. |
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""" |
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assert mmcv.is_list_of(img_scales, tuple) and len(img_scales) == 2 |
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img_scale_long = [max(s) for s in img_scales] |
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img_scale_short = [min(s) for s in img_scales] |
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long_edge = np.random.randint( |
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min(img_scale_long), |
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max(img_scale_long) + 1) |
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short_edge = np.random.randint( |
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min(img_scale_short), |
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max(img_scale_short) + 1) |
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img_scale = (long_edge, short_edge) |
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return img_scale, None |
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@staticmethod |
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def random_sample_ratio(img_scale, ratio_range): |
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"""Randomly sample an img_scale when ``ratio_range`` is specified. |
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A ratio will be randomly sampled from the range specified by |
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``ratio_range``. Then it would be multiplied with ``img_scale`` to |
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generate sampled scale. |
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Args: |
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img_scale (tuple): Images scale base to multiply with ratio. |
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ratio_range (tuple[float]): The minimum and maximum ratio to scale |
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the ``img_scale``. |
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Returns: |
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(tuple, None): Returns a tuple ``(scale, None)``, where |
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``scale`` is sampled ratio multiplied with ``img_scale`` and |
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None is just a placeholder to be consistent with |
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:func:`random_select`. |
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""" |
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assert isinstance(img_scale, tuple) and len(img_scale) == 2 |
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min_ratio, max_ratio = ratio_range |
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assert min_ratio <= max_ratio |
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ratio = np.random.random_sample() * (max_ratio - min_ratio) + min_ratio |
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scale = int(img_scale[0] * ratio), int(img_scale[1] * ratio) |
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return scale, None |
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def _random_scale(self, results): |
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"""Randomly sample an img_scale according to ``ratio_range`` and |
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``multiscale_mode``. |
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If ``ratio_range`` is specified, a ratio will be sampled and be |
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multiplied with ``img_scale``. |
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If multiple scales are specified by ``img_scale``, a scale will be |
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sampled according to ``multiscale_mode``. |
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Otherwise, single scale will be used. |
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Args: |
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results (dict): Result dict from :obj:`dataset`. |
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Returns: |
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dict: Two new keys 'scale` and 'scale_idx` are added into |
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``results``, which would be used by subsequent pipelines. |
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""" |
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if self.ratio_range is not None: |
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if self.img_scale is None: |
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h, w = results['img'].shape[:2] |
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scale, scale_idx = self.random_sample_ratio((w, h), |
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self.ratio_range) |
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else: |
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scale, scale_idx = self.random_sample_ratio( |
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self.img_scale[0], self.ratio_range) |
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elif len(self.img_scale) == 1: |
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scale, scale_idx = self.img_scale[0], 0 |
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elif self.multiscale_mode == 'range': |
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scale, scale_idx = self.random_sample(self.img_scale) |
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elif self.multiscale_mode == 'value': |
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scale, scale_idx = self.random_select(self.img_scale) |
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else: |
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raise NotImplementedError |
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results['scale'] = scale |
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results['scale_idx'] = scale_idx |
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def _align(self, img, size_divisor, interpolation=None): |
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align_h = int(np.ceil(img.shape[0] / size_divisor)) * size_divisor |
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align_w = int(np.ceil(img.shape[1] / size_divisor)) * size_divisor |
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if interpolation == None: |
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img = mmcv.imresize(img, (align_w, align_h)) |
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else: |
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img = mmcv.imresize(img, (align_w, align_h), interpolation=interpolation) |
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return img |
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def _resize_img(self, results): |
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"""Resize images with ``results['scale']``.""" |
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if self.keep_ratio: |
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img, scale_factor = mmcv.imrescale( |
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results['img'], results['scale'], return_scale=True) |
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img = self._align(img, self.size_divisor) |
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new_h, new_w = img.shape[:2] |
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h, w = results['img'].shape[:2] |
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w_scale = new_w / w |
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h_scale = new_h / h |
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else: |
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img, w_scale, h_scale = mmcv.imresize( |
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results['img'], results['scale'], return_scale=True) |
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h, w = img.shape[:2] |
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assert int(np.ceil(h / self.size_divisor)) * self.size_divisor == h and \ |
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int(np.ceil(w / self.size_divisor)) * self.size_divisor == w, \ |
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"img size not align. h:{} w:{}".format(h,w) |
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scale_factor = np.array([w_scale, h_scale, w_scale, h_scale], |
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dtype=np.float32) |
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results['img'] = img |
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results['img_shape'] = img.shape |
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results['pad_shape'] = img.shape |
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results['scale_factor'] = scale_factor |
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results['keep_ratio'] = self.keep_ratio |
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def _resize_seg(self, results): |
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"""Resize semantic segmentation map with ``results['scale']``.""" |
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for key in results.get('seg_fields', []): |
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if self.keep_ratio: |
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gt_seg = mmcv.imrescale( |
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results[key], results['scale'], interpolation='nearest') |
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gt_seg = self._align(gt_seg, self.size_divisor, interpolation='nearest') |
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else: |
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gt_seg = mmcv.imresize( |
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results[key], results['scale'], interpolation='nearest') |
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h, w = gt_seg.shape[:2] |
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assert int(np.ceil(h / self.size_divisor)) * self.size_divisor == h and \ |
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int(np.ceil(w / self.size_divisor)) * self.size_divisor == w, \ |
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"gt_seg size not align. h:{} w:{}".format(h, w) |
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results[key] = gt_seg |
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def __call__(self, results): |
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"""Call function to resize images, bounding boxes, masks, semantic |
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segmentation map. |
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Args: |
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results (dict): Result dict from loading pipeline. |
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Returns: |
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dict: Resized results, 'img_shape', 'pad_shape', 'scale_factor', |
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'keep_ratio' keys are added into result dict. |
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""" |
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if 'scale' not in results: |
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self._random_scale(results) |
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self._resize_img(results) |
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self._resize_seg(results) |
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return results |
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def __repr__(self): |
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repr_str = self.__class__.__name__ |
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repr_str += (f'(img_scale={self.img_scale}, ' |
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f'multiscale_mode={self.multiscale_mode}, ' |
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f'ratio_range={self.ratio_range}, ' |
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f'keep_ratio={self.keep_ratio})') |
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return repr_str |
