feat: initial commit

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	import numbers
	import random
	import warnings
	from dataclasses import asdict, dataclass
	from typing import Any, Dict, List, Optional, Sequence, Tuple, Union

	import torch
	import torchvision.transforms.functional as F
	from torchvision.transforms import (
	CenterCrop,
	ColorJitter,
	Compose,
	Grayscale,
	InterpolationMode,
	Normalize,
	RandomResizedCrop,
	Resize,
	ToTensor,
	)
	from transformers.image_utils import OPENAI_CLIP_MEAN, OPENAI_CLIP_STD

	OPENAI_DATASET_MEAN = tuple(OPENAI_CLIP_MEAN)
	OPENAI_DATASET_STD = tuple(OPENAI_CLIP_STD)


	@dataclass
	class PreprocessCfg:
	size: Union[int, Tuple[int, int]] = 224
	mode: str = 'RGB'
	mean: Tuple[float, ...] = OPENAI_DATASET_MEAN
	std: Tuple[float, ...] = OPENAI_DATASET_STD
	interpolation: str = 'bicubic'
	resize_mode: str = 'shortest'
	fill_color: int = 0

	def __post_init__(self):
	assert self.mode in ('RGB',)

	@property
	def num_channels(self):
	return 3

	@property
	def input_size(self):
	return (self.num_channels,) + (self.size, self.size)


	_PREPROCESS_KEYS = set(asdict(PreprocessCfg()).keys())


	def merge_preprocess_dict(
	base: Union[PreprocessCfg, Dict],
	overlay: Dict,
	):
	"""Merge overlay key-value pairs on top of base preprocess cfg or dict.
	Input dicts are filtered based on PreprocessCfg fields.
	"""
	if isinstance(base, PreprocessCfg):
	base_clean = asdict(base)
	else:
	base_clean = {k: v for k, v in base.items() if k in _PREPROCESS_KEYS}
	if overlay:
	overlay_clean = {
	k: v for k, v in overlay.items() if k in _PREPROCESS_KEYS and v is not None
	}
	base_clean.update(overlay_clean)
	return base_clean


	def merge_preprocess_kwargs(base: Union[PreprocessCfg, Dict], **kwargs):
	return merge_preprocess_dict(base, kwargs)


	@dataclass
	class AugmentationCfg:
	scale: Tuple[float, float] = (0.9, 1.0)
	ratio: Optional[Tuple[float, float]] = None
	color_jitter: Optional[
	Union[float, Tuple[float, float, float], Tuple[float, float, float, float]]
	] = None
	re_prob: Optional[float] = None
	re_count: Optional[int] = None
	use_timm: bool = False

	# params for simclr_jitter_gray
	color_jitter_prob: float = None
	gray_scale_prob: float = None


	def _setup_size(size, error_msg):
	if isinstance(size, numbers.Number):
	return int(size), int(size)

	if isinstance(size, Sequence) and len(size) == 1:
	return size[0], size[0]

	if len(size) != 2:
	raise ValueError(error_msg)

	return size


	class ResizeKeepRatio:
	"""Resize and Keep Ratio

	Copy & paste from `timm`
	"""

	def __init__(
	self,
	size,
	longest=0.0,
	interpolation=InterpolationMode.BICUBIC,
	random_scale_prob=0.0,
	random_scale_range=(0.85, 1.05),
	random_aspect_prob=0.0,
	random_aspect_range=(0.9, 1.11),
	):
	if isinstance(size, (list, tuple)):
	self.size = tuple(size)
	else:
	self.size = (size, size)
	self.interpolation = interpolation
	self.longest = float(longest) # [0, 1] where 0 == shortest edge, 1 == longest
	self.random_scale_prob = random_scale_prob
	self.random_scale_range = random_scale_range
	self.random_aspect_prob = random_aspect_prob
	self.random_aspect_range = random_aspect_range

	@staticmethod
	def get_params(
	img,
	target_size,
	longest,
	random_scale_prob=0.0,
	random_scale_range=(0.85, 1.05),
	random_aspect_prob=0.0,
	random_aspect_range=(0.9, 1.11),
	):
	"""Get parameters"""
	source_size = img.size[::-1] # h, w
	h, w = source_size
	target_h, target_w = target_size
	ratio_h = h / target_h
	ratio_w = w / target_w
	ratio = max(ratio_h, ratio_w) * longest + min(ratio_h, ratio_w) * (
	1.0 - longest
	)
	if random_scale_prob > 0 and random.random() < random_scale_prob:
	ratio_factor = random.uniform(random_scale_range[0], random_scale_range[1])
	ratio_factor = (ratio_factor, ratio_factor)
	else:
	ratio_factor = (1.0, 1.0)
	if random_aspect_prob > 0 and random.random() < random_aspect_prob:
	aspect_factor = random.uniform(
	random_aspect_range[0], random_aspect_range[1]
	)
	ratio_factor = (
	ratio_factor[0] / aspect_factor,
	ratio_factor[1] * aspect_factor,
	)
	size = [round(x * f / ratio) for x, f in zip(source_size, ratio_factor)]
	return size

	def __call__(self, img):
	"""
	Args:
	img (PIL Image): Image to be cropped and resized.

	Returns:
	PIL Image: Resized, padded to at least target size, possibly
	cropped to exactly target size
	"""
	size = self.get_params(
	img,
	self.size,
	self.longest,
	self.random_scale_prob,
	self.random_scale_range,
	self.random_aspect_prob,
	self.random_aspect_range,
	)
	img = F.resize(img, size, self.interpolation)
	return img

	def __repr__(self):
	format_string = self.__class__.__name__ + '(size={0}'.format(self.size)
	format_string += f', interpolation={self.interpolation})'
	format_string += f', longest={self.longest:.3f})'
	return format_string


	def center_crop_or_pad(
	img: torch.Tensor, output_size: List[int], fill=0
	) -> torch.Tensor:
	"""Center crops and/or pads the given image.
	If the image is torch Tensor, it is expected
	to have [..., H, W] shape, where ... means an arbitrary number of leading
	dimensions. If image size is smaller than output size along any edge, image is
	padded with 0 and then center cropped.

	Args:
	img (PIL Image or Tensor): Image to be cropped.
	output_size (sequence or int): (height, width) of the crop box. If int or
	sequence with single int, it is used for both directions.
	fill (int, Tuple[int]): Padding color

	Returns:
	PIL Image or Tensor: Cropped image.
	"""
	if isinstance(output_size, numbers.Number):
	output_size = (int(output_size), int(output_size))
	elif isinstance(output_size, (tuple, list)) and len(output_size) == 1:
	output_size = (output_size[0], output_size[0])

	_, image_height, image_width = F.get_dimensions(img)
	crop_height, crop_width = output_size

	if crop_width > image_width or crop_height > image_height:
	padding_ltrb = [
	(crop_width - image_width) // 2 if crop_width > image_width else 0,
	(crop_height - image_height) // 2 if crop_height > image_height else 0,
	(crop_width - image_width + 1) // 2 if crop_width > image_width else 0,
	(crop_height - image_height + 1) // 2 if crop_height > image_height else 0,
	]
	img = F.pad(img, padding_ltrb, fill=fill)
	_, image_height, image_width = F.get_dimensions(img)
	if crop_width == image_width and crop_height == image_height:
	return img

	crop_top = int(round((image_height - crop_height) / 2.0))
	crop_left = int(round((image_width - crop_width) / 2.0))
	return F.crop(img, crop_top, crop_left, crop_height, crop_width)


	class CenterCropOrPad(torch.nn.Module):
	"""Crops the given image at the center.
	If the image is torch Tensor, it is expected
	to have [..., H, W] shape, where ... means an arbitrary number of leading
	dimensions. If image size is smaller than output size along any edge, image is
	padded with 0 and then center cropped.

	Args:
	size (sequence or int): Desired output size of the crop. If size is an
	int instead of sequence like (h, w), a square crop (size, size) is
	made. If provided a sequence of length 1, it will be interpreted as
	(size[0], size[0]).
	"""

	def __init__(self, size, fill=0):
	super().__init__()
	self.size = _setup_size(
	size, error_msg='Please provide only two dimensions (h, w) for size.'
	)
	self.fill = fill

	def forward(self, img):
	"""
	Args:
	img (PIL Image or Tensor): Image to be cropped.

	Returns:
	PIL Image or Tensor: Cropped image.
	"""
	return center_crop_or_pad(img, self.size, fill=self.fill)

	def __repr__(self) -> str:
	return f'{self.__class__.__name__}(size={self.size})'


	def _convert_to_rgb(image):
	return image.convert('RGB')


	class _ColorJitter(object):
	"""
	Apply Color Jitter to the PIL image with a specified probability.
	"""

	def __init__(self, brightness=0.0, contrast=0.0, saturation=0.0, hue=0.0, p=0.8):
	assert 0.0 <= p <= 1.0
	self.p = p
	self.transf = ColorJitter(
	brightness=brightness, contrast=contrast, saturation=saturation, hue=hue
	)

	def __call__(self, img):
	if random.random() < self.p:
	return self.transf(img)
	else:
	return img


	class _GrayScale(object):
	"""
	Apply Gray Scale to the PIL image with a specified probability.
	"""

	def __init__(self, p=0.2):
	assert 0.0 <= p <= 1.0
	self.p = p
	self.transf = Grayscale(num_output_channels=3)

	def __call__(self, img):
	if random.random() < self.p:
	return self.transf(img)
	else:
	return img


	def image_transform(
	image_size: Union[int, Tuple[int, int]],
	is_train: bool,
	mean: Optional[Tuple[float, ...]] = None,
	std: Optional[Tuple[float, ...]] = None,
	resize_mode: Optional[str] = None,
	interpolation: Optional[str] = None,
	fill_color: int = 0,
	aug_cfg: Optional[Union[Dict[str, Any], AugmentationCfg]] = None,
	):
	mean = mean or OPENAI_DATASET_MEAN
	if not isinstance(mean, (list, tuple)):
	mean = (mean,) * 3

	std = std or OPENAI_DATASET_STD
	if not isinstance(std, (list, tuple)):
	std = (std,) * 3

	interpolation = interpolation or 'bicubic'
	assert interpolation in ['bicubic', 'bilinear', 'random']
	# NOTE random is ignored for interpolation_mode, so defaults to BICUBIC for
	# inference if set
	interpolation_mode = (
	InterpolationMode.BILINEAR
	if interpolation == 'bilinear'
	else InterpolationMode.BICUBIC
	)

	resize_mode = resize_mode or 'shortest'
	assert resize_mode in ('shortest', 'longest', 'squash')

	if isinstance(aug_cfg, dict):
	aug_cfg = AugmentationCfg(**aug_cfg)
	else:
	aug_cfg = aug_cfg or AugmentationCfg()

	normalize = Normalize(mean=mean, std=std)

	if is_train:
	aug_cfg_dict = {k: v for k, v in asdict(aug_cfg).items() if v is not None}
	use_timm = aug_cfg_dict.pop('use_timm', False)
	if use_timm:
	from timm.data import create_transform # timm can still be optional

	if isinstance(image_size, (tuple, list)):
	assert len(image_size) >= 2
	input_size = (3,) + image_size[-2:]
	else:
	input_size = (3, image_size, image_size)

	aug_cfg_dict.setdefault('color_jitter', None) # disable by default
	# drop extra non-timm items
	aug_cfg_dict.pop('color_jitter_prob', None)
	aug_cfg_dict.pop('gray_scale_prob', None)

	train_transform = create_transform(
	input_size=input_size,
	is_training=True,
	hflip=0.0,
	mean=mean,
	std=std,
	re_mode='pixel',
	interpolation=interpolation,
	**aug_cfg_dict,
	)
	else:
	train_transform = [
	RandomResizedCrop(
	image_size,
	scale=aug_cfg_dict.pop('scale'),
	interpolation=InterpolationMode.BICUBIC,
	),
	_convert_to_rgb,
	]
	if aug_cfg.color_jitter_prob:
	assert (
	aug_cfg.color_jitter is not None and len(aug_cfg.color_jitter) == 4
	)
	train_transform.extend(
	[_ColorJitter(*aug_cfg.color_jitter, p=aug_cfg.color_jitter_prob)]
	)
	if aug_cfg.gray_scale_prob:
	train_transform.extend([_GrayScale(aug_cfg.gray_scale_prob)])
	train_transform.extend(
	[
	ToTensor(),
	normalize,
	]
	)
	train_transform = Compose(train_transform)
	if aug_cfg_dict:
	warnings.warn(
	f'Unused augmentation cfg items, specify `use_timm` to use '
	f'({list(aug_cfg_dict.keys())}).'
	)
	return train_transform
	else:
	if resize_mode == 'longest':
	transforms = [
	ResizeKeepRatio(
	image_size, interpolation=interpolation_mode, longest=1
	),
	CenterCropOrPad(image_size, fill=fill_color),
	]
	elif resize_mode == 'squash':
	if isinstance(image_size, int):
	image_size = (image_size, image_size)
	transforms = [
	Resize(image_size, interpolation=interpolation_mode),
	]
	else:
	assert resize_mode == 'shortest'
	if not isinstance(image_size, (tuple, list)):
	image_size = (image_size, image_size)
	if image_size[0] == image_size[1]:
	# simple case, use torchvision built-in Resize w/ shortest edge mode
	# (scalar size arg)
	transforms = [Resize(image_size[0], interpolation=interpolation_mode)]
	else:
	# resize shortest edge to matching target dim for non-square target
	transforms = [ResizeKeepRatio(image_size)]
	transforms += [CenterCrop(image_size)]

	transforms.extend(
	[
	_convert_to_rgb,
	ToTensor(),
	normalize,
	]
	)
	return Compose(transforms)


	def image_transform_v2(
	cfg: PreprocessCfg,
	is_train: bool,
	aug_cfg: Optional[Union[Dict[str, Any], AugmentationCfg]] = None,
	):
	return image_transform(
	image_size=cfg.size,
	is_train=is_train,
	mean=cfg.mean,
	std=cfg.std,
	interpolation=cfg.interpolation,
	resize_mode=cfg.resize_mode,
	fill_color=cfg.fill_color,
	aug_cfg=aug_cfg,
	)