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import torchvision |
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import random |
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from PIL import Image, ImageOps |
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import numpy as np |
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import numbers |
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import math |
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import torch |
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class GroupRandomCrop(object): |
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def __init__(self, size): |
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if isinstance(size, numbers.Number): |
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self.size = (int(size), int(size)) |
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else: |
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self.size = size |
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def __call__(self, img_group): |
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w, h = img_group[0].size |
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th, tw = self.size |
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out_images = list() |
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x1 = random.randint(0, w - tw) |
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y1 = random.randint(0, h - th) |
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for img in img_group: |
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assert(img.size[0] == w and img.size[1] == h) |
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if w == tw and h == th: |
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out_images.append(img) |
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else: |
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out_images.append(img.crop((x1, y1, x1 + tw, y1 + th))) |
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return out_images |
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class MultiGroupRandomCrop(object): |
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def __init__(self, size, groups=1): |
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if isinstance(size, numbers.Number): |
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self.size = (int(size), int(size)) |
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else: |
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self.size = size |
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self.groups = groups |
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def __call__(self, img_group): |
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w, h = img_group[0].size |
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th, tw = self.size |
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out_images = list() |
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for i in range(self.groups): |
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x1 = random.randint(0, w - tw) |
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y1 = random.randint(0, h - th) |
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for img in img_group: |
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assert(img.size[0] == w and img.size[1] == h) |
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if w == tw and h == th: |
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out_images.append(img) |
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else: |
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out_images.append(img.crop((x1, y1, x1 + tw, y1 + th))) |
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return out_images |
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class GroupCenterCrop(object): |
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def __init__(self, size): |
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self.worker = torchvision.transforms.CenterCrop(size) |
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def __call__(self, img_group): |
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return [self.worker(img) for img in img_group] |
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class GroupRandomHorizontalFlip(object): |
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"""Randomly horizontally flips the given PIL.Image with a probability of 0.5 |
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""" |
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def __init__(self, is_flow=False): |
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self.is_flow = is_flow |
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def __call__(self, img_group, is_flow=False): |
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v = random.random() |
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if v < 0.5: |
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ret = [img.transpose(Image.FLIP_LEFT_RIGHT) for img in img_group] |
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if self.is_flow: |
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for i in range(0, len(ret), 2): |
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ret[i] = ImageOps.invert(ret[i]) |
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return ret |
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else: |
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return img_group |
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class GroupNormalize(object): |
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def __init__(self, mean, std): |
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self.mean = mean |
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self.std = std |
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def __call__(self, tensor): |
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rep_mean = self.mean * (tensor.size()[0] // len(self.mean)) |
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rep_std = self.std * (tensor.size()[0] // len(self.std)) |
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for t, m, s in zip(tensor, rep_mean, rep_std): |
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t.sub_(m).div_(s) |
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return tensor |
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class GroupScale(object): |
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""" Rescales the input PIL.Image to the given 'size'. |
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'size' will be the size of the smaller edge. |
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For example, if height > width, then image will be |
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rescaled to (size * height / width, size) |
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size: size of the smaller edge |
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interpolation: Default: PIL.Image.BILINEAR |
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""" |
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def __init__(self, size, interpolation=Image.BILINEAR): |
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self.worker = torchvision.transforms.Resize(size, interpolation) |
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def __call__(self, img_group): |
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return [self.worker(img) for img in img_group] |
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class GroupOverSample(object): |
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def __init__(self, crop_size, scale_size=None, flip=True): |
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self.crop_size = crop_size if not isinstance( |
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crop_size, int) else (crop_size, crop_size) |
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if scale_size is not None: |
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self.scale_worker = GroupScale(scale_size) |
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else: |
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self.scale_worker = None |
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self.flip = flip |
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def __call__(self, img_group): |
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if self.scale_worker is not None: |
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img_group = self.scale_worker(img_group) |
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image_w, image_h = img_group[0].size |
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crop_w, crop_h = self.crop_size |
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offsets = GroupMultiScaleCrop.fill_fix_offset( |
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False, image_w, image_h, crop_w, crop_h) |
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oversample_group = list() |
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for o_w, o_h in offsets: |
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normal_group = list() |
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flip_group = list() |
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for i, img in enumerate(img_group): |
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crop = img.crop((o_w, o_h, o_w + crop_w, o_h + crop_h)) |
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normal_group.append(crop) |
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flip_crop = crop.copy().transpose(Image.FLIP_LEFT_RIGHT) |
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if img.mode == 'L' and i % 2 == 0: |
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flip_group.append(ImageOps.invert(flip_crop)) |
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else: |
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flip_group.append(flip_crop) |
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oversample_group.extend(normal_group) |
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if self.flip: |
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oversample_group.extend(flip_group) |
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return oversample_group |
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class GroupFullResSample(object): |
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def __init__(self, crop_size, scale_size=None, flip=True): |
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self.crop_size = crop_size if not isinstance( |
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crop_size, int) else (crop_size, crop_size) |
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if scale_size is not None: |
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self.scale_worker = GroupScale(scale_size) |
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else: |
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self.scale_worker = None |
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self.flip = flip |
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def __call__(self, img_group): |
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if self.scale_worker is not None: |
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img_group = self.scale_worker(img_group) |
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image_w, image_h = img_group[0].size |
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crop_w, crop_h = self.crop_size |
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w_step = (image_w - crop_w) // 4 |
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h_step = (image_h - crop_h) // 4 |
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offsets = list() |
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offsets.append((0 * w_step, 2 * h_step)) |
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offsets.append((4 * w_step, 2 * h_step)) |
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offsets.append((2 * w_step, 2 * h_step)) |
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oversample_group = list() |
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for o_w, o_h in offsets: |
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normal_group = list() |
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flip_group = list() |
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for i, img in enumerate(img_group): |
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crop = img.crop((o_w, o_h, o_w + crop_w, o_h + crop_h)) |
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normal_group.append(crop) |
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if self.flip: |
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flip_crop = crop.copy().transpose(Image.FLIP_LEFT_RIGHT) |
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if img.mode == 'L' and i % 2 == 0: |
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flip_group.append(ImageOps.invert(flip_crop)) |
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else: |
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flip_group.append(flip_crop) |
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oversample_group.extend(normal_group) |
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oversample_group.extend(flip_group) |
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return oversample_group |
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class GroupMultiScaleCrop(object): |
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def __init__(self, input_size, scales=None, max_distort=1, |
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fix_crop=True, more_fix_crop=True): |
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self.scales = scales if scales is not None else [1, .875, .75, .66] |
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self.max_distort = max_distort |
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self.fix_crop = fix_crop |
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self.more_fix_crop = more_fix_crop |
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self.input_size = input_size if not isinstance(input_size, int) else [ |
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input_size, input_size] |
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self.interpolation = Image.BILINEAR |
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def __call__(self, img_group): |
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im_size = img_group[0].size |
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crop_w, crop_h, offset_w, offset_h = self._sample_crop_size(im_size) |
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crop_img_group = [ |
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img.crop( |
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(offset_w, |
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offset_h, |
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offset_w + |
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crop_w, |
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offset_h + |
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crop_h)) for img in img_group] |
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ret_img_group = [img.resize((self.input_size[0], self.input_size[1]), self.interpolation) |
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for img in crop_img_group] |
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return ret_img_group |
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def _sample_crop_size(self, im_size): |
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image_w, image_h = im_size[0], im_size[1] |
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base_size = min(image_w, image_h) |
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crop_sizes = [int(base_size * x) for x in self.scales] |
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crop_h = [ |
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self.input_size[1] if abs( |
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x - self.input_size[1]) < 3 else x for x in crop_sizes] |
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crop_w = [ |
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self.input_size[0] if abs( |
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x - self.input_size[0]) < 3 else x for x in crop_sizes] |
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pairs = [] |
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for i, h in enumerate(crop_h): |
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for j, w in enumerate(crop_w): |
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if abs(i - j) <= self.max_distort: |
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pairs.append((w, h)) |
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crop_pair = random.choice(pairs) |
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if not self.fix_crop: |
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w_offset = random.randint(0, image_w - crop_pair[0]) |
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h_offset = random.randint(0, image_h - crop_pair[1]) |
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else: |
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w_offset, h_offset = self._sample_fix_offset( |
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image_w, image_h, crop_pair[0], crop_pair[1]) |
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return crop_pair[0], crop_pair[1], w_offset, h_offset |
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def _sample_fix_offset(self, image_w, image_h, crop_w, crop_h): |
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offsets = self.fill_fix_offset( |
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self.more_fix_crop, image_w, image_h, crop_w, crop_h) |
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return random.choice(offsets) |
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@staticmethod |
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def fill_fix_offset(more_fix_crop, image_w, image_h, crop_w, crop_h): |
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w_step = (image_w - crop_w) // 4 |
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h_step = (image_h - crop_h) // 4 |
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ret = list() |
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ret.append((0, 0)) |
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ret.append((4 * w_step, 0)) |
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ret.append((0, 4 * h_step)) |
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ret.append((4 * w_step, 4 * h_step)) |
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ret.append((2 * w_step, 2 * h_step)) |
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if more_fix_crop: |
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ret.append((0, 2 * h_step)) |
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ret.append((4 * w_step, 2 * h_step)) |
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ret.append((2 * w_step, 4 * h_step)) |
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ret.append((2 * w_step, 0 * h_step)) |
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ret.append((1 * w_step, 1 * h_step)) |
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ret.append((3 * w_step, 1 * h_step)) |
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ret.append((1 * w_step, 3 * h_step)) |
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ret.append((3 * w_step, 3 * h_step)) |
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return ret |
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class GroupRandomSizedCrop(object): |
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"""Random crop the given PIL.Image to a random size of (0.08 to 1.0) of the original size |
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and and a random aspect ratio of 3/4 to 4/3 of the original aspect ratio |
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This is popularly used to train the Inception networks |
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size: size of the smaller edge |
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interpolation: Default: PIL.Image.BILINEAR |
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""" |
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def __init__(self, size, interpolation=Image.BILINEAR): |
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self.size = size |
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self.interpolation = interpolation |
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def __call__(self, img_group): |
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for attempt in range(10): |
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area = img_group[0].size[0] * img_group[0].size[1] |
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target_area = random.uniform(0.08, 1.0) * area |
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aspect_ratio = random.uniform(3. / 4, 4. / 3) |
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w = int(round(math.sqrt(target_area * aspect_ratio))) |
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h = int(round(math.sqrt(target_area / aspect_ratio))) |
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if random.random() < 0.5: |
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w, h = h, w |
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if w <= img_group[0].size[0] and h <= img_group[0].size[1]: |
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x1 = random.randint(0, img_group[0].size[0] - w) |
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y1 = random.randint(0, img_group[0].size[1] - h) |
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found = True |
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break |
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else: |
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found = False |
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x1 = 0 |
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y1 = 0 |
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if found: |
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out_group = list() |
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for img in img_group: |
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img = img.crop((x1, y1, x1 + w, y1 + h)) |
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assert(img.size == (w, h)) |
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out_group.append( |
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img.resize( |
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(self.size, self.size), self.interpolation)) |
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return out_group |
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else: |
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scale = GroupScale(self.size, interpolation=self.interpolation) |
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crop = GroupRandomCrop(self.size) |
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return crop(scale(img_group)) |
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class ConvertDataFormat(object): |
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def __init__(self, model_type): |
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self.model_type = model_type |
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def __call__(self, images): |
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if self.model_type == '2D': |
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return images |
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tc, h, w = images.size() |
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t = tc // 3 |
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images = images.view(t, 3, h, w) |
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images = images.permute(1, 0, 2, 3) |
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return images |
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class Stack(object): |
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def __init__(self, roll=False): |
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self.roll = roll |
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def __call__(self, img_group): |
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if img_group[0].mode == 'L': |
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return np.concatenate([np.expand_dims(x, 2) |
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for x in img_group], axis=2) |
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elif img_group[0].mode == 'RGB': |
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if self.roll: |
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return np.concatenate([np.array(x)[:, :, ::-1] |
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for x in img_group], axis=2) |
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else: |
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return np.concatenate(img_group, axis=2) |
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class ToTorchFormatTensor(object): |
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""" Converts a PIL.Image (RGB) or numpy.ndarray (H x W x C) in the range [0, 255] |
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to a torch.FloatTensor of shape (C x H x W) in the range [0.0, 1.0] """ |
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def __init__(self, div=True): |
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self.div = div |
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def __call__(self, pic): |
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if isinstance(pic, np.ndarray): |
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img = torch.from_numpy(pic).permute(2, 0, 1).contiguous() |
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else: |
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img = torch.ByteTensor( |
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torch.ByteStorage.from_buffer( |
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pic.tobytes())) |
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img = img.view(pic.size[1], pic.size[0], len(pic.mode)) |
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img = img.transpose(0, 1).transpose(0, 2).contiguous() |
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return img.float().div(255) if self.div else img.float() |
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class IdentityTransform(object): |
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def __call__(self, data): |
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return data |
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if __name__ == "__main__": |
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trans = torchvision.transforms.Compose([ |
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GroupScale(256), |
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GroupRandomCrop(224), |
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Stack(), |
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ToTorchFormatTensor(), |
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GroupNormalize( |
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mean=[.485, .456, .406], |
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std=[.229, .224, .225] |
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)] |
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) |
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im = Image.open('../tensorflow-model-zoo.torch/lena_299.png') |
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color_group = [im] * 3 |
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rst = trans(color_group) |
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gray_group = [im.convert('L')] * 9 |
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gray_rst = trans(gray_group) |
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trans2 = torchvision.transforms.Compose([ |
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GroupRandomSizedCrop(256), |
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Stack(), |
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ToTorchFormatTensor(), |
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GroupNormalize( |
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mean=[.485, .456, .406], |
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std=[.229, .224, .225]) |
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]) |
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print(trans2(color_group)) |
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