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	from torchvision.ops.boxes import box_area


	def box_cxcywh_to_xyxy(x):
	x_c, y_c, w, h = x.unbind(-1)
	b = [(x_c - 0.5 * w), (y_c - 0.5 * h),
	(x_c + 0.5 * w), (y_c + 0.5 * h)]
	return torch.stack(b, dim=-1)


	def box_xyxy_to_cxcywh(x):
	x0, y0, x1, y1 = x.unbind(-1)
	b = [(x0 + x1) / 2, (y0 + y1) / 2,
	(x1 - x0), (y1 - y0)]
	return torch.stack(b, dim=-1)


	# modified from torchvision to also return the union
	def box_iou_2(boxes1, boxes2):
	area1 = box_area(boxes1)
	area2 = box_area(boxes2)

	lt = torch.max(boxes1[:, None, :2], boxes2[:, :2]) # [N,M,2]
	rb = torch.min(boxes1[:, None, 2:], boxes2[:, 2:]) # [N,M,2]

	wh = (rb - lt).clamp(min=0) # [N,M,2]
	inter = wh[:, :, 0] * wh[:, :, 1] # [N,M]

	union = area1[:, None] + area2 - inter

	iou = inter / union
	return iou , union


	def generalized_box_iou(boxes1, boxes2):
	"""
	Generalized IoU from https://giou.stanford.edu/

	The boxes should be in [x0, y0, x1, y1] format

	Returns a [N, M] pairwise matrix, where N = len(boxes1)
	and M = len(boxes2)
	"""
	# degenerate boxes gives inf / nan results
	# so do an early check
	assert (boxes1[:, 2:] >= boxes1[:, :2]).all()
	assert (boxes2[:, 2:] >= boxes2[:, :2]).all()
	iou, union = box_iou_2(boxes1, boxes2)

	lt = torch.min(boxes1[:, None, :2], boxes2[:, :2])
	rb = torch.max(boxes1[:, None, 2:], boxes2[:, 2:])

	wh = (rb - lt).clamp(min=0) # [N,M,2]
	area = wh[:, :, 0] * wh[:, :, 1]

	return iou - (area - union) / area


	def masks_to_boxes(masks):
	"""Compute the bounding boxes around the provided masks

	The masks should be in format [N, H, W] where N is the number of masks, (H, W) are the spatial dimensions.

	Returns a [N, 4] tensors, with the boxes in xyxy format
	"""
	if masks.numel() == 0:
	return torch.zeros((0, 4), device=masks.device)

	h, w = masks.shape[-2:]

	y = torch.arange(0, h, dtype=torch.float)
	x = torch.arange(0, w, dtype=torch.float)
	y, x = torch.meshgrid(y, x)

	x_mask = (masks * x.unsqueeze(0))
	x_max = x_mask.flatten(1).max(-1)[0]
	x_min = x_mask.masked_fill(~(masks.bool()), 1e8).flatten(1).min(-1)[0]

	y_mask = (masks * y.unsqueeze(0))
	y_max = y_mask.flatten(1).max(-1)[0]
	y_min = y_mask.masked_fill(~(masks.bool()), 1e8).flatten(1).min(-1)[0]

	return torch.stack([x_min, y_min, x_max, y_max], 1)
	"""
	Misc functions, including distributed helpers.

	Mostly copy-paste from torchvision references.
	"""
	import os
	import subprocess
	import time
	from collections import defaultdict, deque
	import datetime
	import pickle
	from packaging import version
	from typing import Optional, List

	import torch
	import torch.distributed as dist
	from torch import Tensor

	# needed due to empty tensor bug in pytorch and torchvision 0.5
	import torchvision
	if version.parse(torchvision.__version__) < version.parse('0.7'):
	from torchvision.ops import _new_empty_tensor
	from torchvision.ops.misc import _output_size


	class SmoothedValue(object):
	"""Track a series of values and provide access to smoothed values over a
	window or the global series average.
	"""

	def __init__(self, window_size=20, fmt=None):
	if fmt is None:
	fmt = "{median:.4f} ({global_avg:.4f})"
	self.deque = deque(maxlen=window_size)
	self.total = 0.0
	self.count = 0
	self.fmt = fmt

	def update(self, value, n=1):
	self.deque.append(value)
	self.count += n
	self.total += value * n

	def synchronize_between_processes(self):
	"""
	Warning: does not synchronize the deque!
	"""
	if not is_dist_avail_and_initialized():
	return
	t = torch.tensor([self.count, self.total], dtype=torch.float64, device='cuda')
	dist.barrier()
	dist.all_reduce(t)
	t = t.tolist()
	self.count = int(t[0])
	self.total = t[1]

	@property
	def median(self):
	d = torch.tensor(list(self.deque))
	return d.median().item()

	@property
	def avg(self):
	d = torch.tensor(list(self.deque), dtype=torch.float32)
	return d.mean().item()

	@property
	def global_avg(self):
	return self.total / self.count

	@property
	def max(self):
	return max(self.deque)

	@property
	def value(self):
	return self.deque[-1]

	def __str__(self):
	return self.fmt.format(
	median=self.median,
	avg=self.avg,
	global_avg=self.global_avg,
	max=self.max,
	value=self.value)


	def all_gather(data):
	"""
	Run all_gather on arbitrary picklable data (not necessarily tensors)
	Args:
	data: any picklable object
	Returns:
	list[data]: list of data gathered from each rank
	"""
	world_size = get_world_size()
	if world_size == 1:
	return [data]

	# serialized to a Tensor
	buffer = pickle.dumps(data)
	storage = torch.ByteStorage.from_buffer(buffer)
	tensor = torch.ByteTensor(storage).to("cuda")

	# obtain Tensor size of each rank
	local_size = torch.tensor([tensor.numel()], device="cuda")
	size_list = [torch.tensor([0], device="cuda") for _ in range(world_size)]
	dist.all_gather(size_list, local_size)
	size_list = [int(size.item()) for size in size_list]
	max_size = max(size_list)

	# receiving Tensor from all ranks
	# we pad the tensor because torch all_gather does not support
	# gathering tensors of different shapes
	tensor_list = []
	for _ in size_list:
	tensor_list.append(torch.empty((max_size,), dtype=torch.uint8, device="cuda"))
	if local_size != max_size:
	padding = torch.empty(size=(max_size - local_size,), dtype=torch.uint8, device="cuda")
	tensor = torch.cat((tensor, padding), dim=0)
	dist.all_gather(tensor_list, tensor)

	data_list = []
	for size, tensor in zip(size_list, tensor_list):
	buffer = tensor.cpu().numpy().tobytes()[:size]
	data_list.append(pickle.loads(buffer))

	return data_list


	def reduce_dict(input_dict, average=True):
	"""
	Args:
	input_dict (dict): all the values will be reduced
	average (bool): whether to do average or sum
	Reduce the values in the dictionary from all processes so that all processes
	have the averaged results. Returns a dict with the same fields as
	input_dict, after reduction.
	"""
	world_size = get_world_size()
	if world_size < 2:
	return input_dict
	with torch.no_grad():
	names = []
	values = []
	# sort the keys so that they are consistent across processes
	for k in sorted(input_dict.keys()):
	names.append(k)
	values.append(input_dict[k])
	values = torch.stack(values, dim=0)
	dist.all_reduce(values)
	if average:
	values /= world_size
	reduced_dict = {k: v for k, v in zip(names, values)}
	return reduced_dict


	class MetricLogger(object):
	def __init__(self, delimiter="\t"):
	self.meters = defaultdict(SmoothedValue)
	self.delimiter = delimiter

	def update(self, **kwargs):
	for k, v in kwargs.items():
	if isinstance(v, torch.Tensor):
	v = v.item()
	assert isinstance(v, (float, int))
	self.meters[k].update(v)

	def __getattr__(self, attr):
	if attr in self.meters:
	return self.meters[attr]
	if attr in self.__dict__:
	return self.__dict__[attr]
	raise AttributeError("'{}' object has no attribute '{}'".format(
	type(self).__name__, attr))

	def __str__(self):
	loss_str = []
	for name, meter in self.meters.items():
	loss_str.append(
	"{}: {}".format(name, str(meter))
	)
	return self.delimiter.join(loss_str)

	def synchronize_between_processes(self):
	for meter in self.meters.values():
	meter.synchronize_between_processes()

	def add_meter(self, name, meter):
	self.meters[name] = meter

	def log_every(self, iterable, print_freq, header=None):
	i = 0
	if not header:
	header = ''
	start_time = time.time()
	end = time.time()
	iter_time = SmoothedValue(fmt='{avg:.4f}')
	data_time = SmoothedValue(fmt='{avg:.4f}')
	space_fmt = ':' + str(len(str(len(iterable)))) + 'd'
	if torch.cuda.is_available():
	log_msg = self.delimiter.join([
	header,
	'[{0' + space_fmt + '}/{1}]',
	'eta: {eta}',
	'{meters}',
	'time: {time}',
	'data: {data}',
	'max mem: {memory:.0f}'
	])
	else:
	log_msg = self.delimiter.join([
	header,
	'[{0' + space_fmt + '}/{1}]',
	'eta: {eta}',
	'{meters}',
	'time: {time}',
	'data: {data}'
	])
	MB = 1024.0 * 1024.0
	for obj in iterable:
	data_time.update(time.time() - end)
	yield obj
	iter_time.update(time.time() - end)
	if i % print_freq == 0 or i == len(iterable) - 1:
	eta_seconds = iter_time.global_avg * (len(iterable) - i)
	eta_string = str(datetime.timedelta(seconds=int(eta_seconds)))
	if torch.cuda.is_available():
	print(log_msg.format(
	i, len(iterable), eta=eta_string,
	meters=str(self),
	time=str(iter_time), data=str(data_time),
	memory=torch.cuda.max_memory_allocated() / MB))
	else:
	print(log_msg.format(
	i, len(iterable), eta=eta_string,
	meters=str(self),
	time=str(iter_time), data=str(data_time)))
	i += 1
	end = time.time()
	total_time = time.time() - start_time
	total_time_str = str(datetime.timedelta(seconds=int(total_time)))
	print('{} Total time: {} ({:.4f} s / it)'.format(
	header, total_time_str, total_time / len(iterable)))


	def get_sha():
	cwd = os.path.dirname(os.path.abspath(__file__))

	def _run(command):
	return subprocess.check_output(command, cwd=cwd).decode('ascii').strip()
	sha = 'N/A'
	diff = "clean"
	branch = 'N/A'
	try:
	sha = _run(['git', 'rev-parse', 'HEAD'])
	subprocess.check_output(['git', 'diff'], cwd=cwd)
	diff = _run(['git', 'diff-index', 'HEAD'])
	diff = "has uncommited changes" if diff else "clean"
	branch = _run(['git', 'rev-parse', '--abbrev-ref', 'HEAD'])
	except Exception:
	pass
	message = f"sha: {sha}, status: {diff}, branch: {branch}"
	return message


	def collate_fn(batch):
	batch = list(zip(*batch))
	batch[0] = nested_tensor_from_tensor_list(batch[0])
	return tuple(batch)


	def _max_by_axis(the_list):
	# type: (List[List[int]]) -> List[int]
	maxes = the_list[0]
	for sublist in the_list[1:]:
	for index, item in enumerate(sublist):
	maxes[index] = max(maxes[index], item)
	return maxes


	class NestedTensor(object):
	def __init__(self, tensors, mask: Optional[Tensor]):
	self.tensors = tensors
	self.mask = mask

	def to(self, device):
	# type: (Device) -> NestedTensor # noqa
	cast_tensor = self.tensors.to(device)
	mask = self.mask
	if mask is not None:
	assert mask is not None
	cast_mask = mask.to(device)
	else:
	cast_mask = None
	return NestedTensor(cast_tensor, cast_mask)

	def decompose(self):
	return self.tensors, self.mask

	def __repr__(self):
	return str(self.tensors)


	def nested_tensor_from_tensor_list(tensor_list: List[Tensor]):
	# TODO make this more general
	if tensor_list[0].ndim == 3:
	if torchvision._is_tracing():
	# nested_tensor_from_tensor_list() does not export well to ONNX
	# call _onnx_nested_tensor_from_tensor_list() instead
	return _onnx_nested_tensor_from_tensor_list(tensor_list)

	# TODO make it support different-sized images
	max_size = _max_by_axis([list(img.shape) for img in tensor_list])
	# min_size = tuple(min(s) for s in zip(*[img.shape for img in tensor_list]))
	batch_shape = [len(tensor_list)] + max_size
	b, c, h, w = batch_shape
	dtype = tensor_list[0].dtype
	device = tensor_list[0].device
	tensor = torch.zeros(batch_shape, dtype=dtype, device=device)
	mask = torch.ones((b, h, w), dtype=torch.bool, device=device)
	for img, pad_img, m in zip(tensor_list, tensor, mask):
	pad_img[: img.shape[0], : img.shape[1], : img.shape[2]].copy_(img)
	m[: img.shape[1], :img.shape[2]] = False
	else:
	raise ValueError('not supported')
	return NestedTensor(tensor, mask)


	# _onnx_nested_tensor_from_tensor_list() is an implementation of
	# nested_tensor_from_tensor_list() that is supported by ONNX tracing.
	@torch.jit.unused
	def _onnx_nested_tensor_from_tensor_list(tensor_list: List[Tensor]) -> NestedTensor:
	max_size = []
	for i in range(tensor_list[0].dim()):
	max_size_i = torch.max(torch.stack([img.shape[i] for img in tensor_list]).to(torch.float32)).to(torch.int64)
	max_size.append(max_size_i)
	max_size = tuple(max_size)

	# work around for
	# pad_img[: img.shape[0], : img.shape[1], : img.shape[2]].copy_(img)
	# m[: img.shape[1], :img.shape[2]] = False
	# which is not yet supported in onnx
	padded_imgs = []
	padded_masks = []
	for img in tensor_list:
	padding = [(s1 - s2) for s1, s2 in zip(max_size, tuple(img.shape))]
	padded_img = torch.nn.functional.pad(img, (0, padding[2], 0, padding[1], 0, padding[0]))
	padded_imgs.append(padded_img)

	m = torch.zeros_like(img[0], dtype=torch.int, device=img.device)
	padded_mask = torch.nn.functional.pad(m, (0, padding[2], 0, padding[1]), "constant", 1)
	padded_masks.append(padded_mask.to(torch.bool))

	tensor = torch.stack(padded_imgs)
	mask = torch.stack(padded_masks)

	return NestedTensor(tensor, mask=mask)


	def setup_for_distributed(is_master):
	"""
	This function disables printing when not in master process
	"""
	import builtins as __builtin__
	builtin_print = __builtin__.print

	def print(args, *kwargs):
	force = kwargs.pop('force', False)
	if is_master or force:
	builtin_print(args, *kwargs)

	__builtin__.print = print


	def is_dist_avail_and_initialized():
	if not dist.is_available():
	return False
	if not dist.is_initialized():
	return False
	return True


	def get_world_size():
	if not is_dist_avail_and_initialized():
	return 1
	return dist.get_world_size()


	def get_rank():
	if not is_dist_avail_and_initialized():
	return 0
	return dist.get_rank()


	def is_main_process():
	return get_rank() == 0


	def save_on_master(args, *kwargs):
	if is_main_process():
	torch.save(args, *kwargs)


	def init_distributed_mode(args):
	if 'RANK' in os.environ and 'WORLD_SIZE' in os.environ:
	args.rank = int(os.environ["RANK"])
	args.world_size = int(os.environ['WORLD_SIZE'])
	args.gpu = int(os.environ['LOCAL_RANK'])
	elif 'SLURM_PROCID' in os.environ:
	args.rank = int(os.environ['SLURM_PROCID'])
	args.gpu = args.rank % torch.cuda.device_count()
	else:
	print('Not using distributed mode')
	args.distributed = False
	return

	args.distributed = True

	torch.cuda.set_device(args.gpu)
	args.dist_backend = 'nccl'
	print('\| distributed init (rank {}): {}'.format(
	args.rank, args.dist_url), flush=True)
	torch.distributed.init_process_group(backend=args.dist_backend, init_method=args.dist_url,
	world_size=args.world_size, rank=args.rank)
	torch.distributed.barrier()
	setup_for_distributed(args.rank == 0)


	@torch.no_grad()
	def accuracy(output, target, topk=(1,)):
	if output.dim() == 1:
	output = output.unsqueeze(0)

	maxk = max(topk)
	batch_size = target.size(0)

	_, pred = output.topk(maxk, 1, True, True)
	pred = pred.t()
	correct = pred.eq(target.view(1, -1).expand_as(pred))

	res = []
	for k in topk:
	correct_k = correct[:k].view(-1).float().sum(0, keepdim=True)
	res.append(correct_k.mul_(100.0 / batch_size))
	return res


	'''
	def accuracy(output, target, topk=(1,)):
	"""Computes the precision@k for the specified values of k"""
	if target.numel() == 0:
	return [torch.zeros([], device=output.device)]
	maxk = max(topk)
	batch_size = target.size(0)

	_, pred = output.topk(maxk, 1, True, True)
	pred = pred.t()
	correct = pred.eq(target.view(1, -1).expand_as(pred))

	res = []
	for k in topk:
	correct_k = correct[:k].view(-1).float().sum(0)
	res.append(correct_k.mul_(100.0 / batch_size))
	return res
	'''

	def interpolate(input, size=None, scale_factor=None, mode="nearest", align_corners=None):
	# type: (Tensor, Optional[List[int]], Optional[float], str, Optional[bool]) -> Tensor
	"""
	Equivalent to nn.functional.interpolate, but with support for empty batch sizes.
	This will eventually be supported natively by PyTorch, and this
	class can go away.
	"""
	if version.parse(torchvision.__version__) < version.parse('0.7'):
	if input.numel() > 0:
	return torch.nn.functional.interpolate(
	input, size, scale_factor, mode, align_corners
	)

	output_shape = _output_size(2, input, size, scale_factor)
	output_shape = list(input.shape[:-2]) + list(output_shape)
	return _new_empty_tensor(input, output_shape)
	else:
	return torchvision.ops.misc.interpolate(input, size, scale_factor, mode, align_corners)