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TRELLIS2 / trellis2 /utils /data_utils.py

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	from typing import *
	import math
	import torch
	import numpy as np
	from torch.utils.data import Sampler, Dataset, DataLoader, DistributedSampler
	import torch.distributed as dist


	def recursive_to_device(
	data: Any,
	device: torch.device,
	non_blocking: bool = False,
	) -> Any:
	"""
	Recursively move all tensors in a data structure to a device.
	"""
	if hasattr(data, "to"):
	return data.to(device, non_blocking=non_blocking)
	elif isinstance(data, (list, tuple)):
	return type(data)(recursive_to_device(d, device, non_blocking) for d in data)
	elif isinstance(data, dict):
	return {k: recursive_to_device(v, device, non_blocking) for k, v in data.items()}
	else:
	return data


	def load_balanced_group_indices(
	load: List[int],
	num_groups: int,
	equal_size: bool = False,
	) -> List[List[int]]:
	"""
	Split indices into groups with balanced load.
	"""
	if equal_size:
	group_size = len(load) // num_groups
	indices = np.argsort(load)[::-1]
	groups = [[] for _ in range(num_groups)]
	group_load = np.zeros(num_groups)
	for idx in indices:
	min_group_idx = np.argmin(group_load)
	groups[min_group_idx].append(idx)
	if equal_size and len(groups[min_group_idx]) == group_size:
	group_load[min_group_idx] = float('inf')
	else:
	group_load[min_group_idx] += load[idx]
	return groups


	def cycle(data_loader: DataLoader) -> Iterator:
	while True:
	for data in data_loader:
	if isinstance(data_loader.sampler, ResumableSampler):
	data_loader.sampler.idx += data_loader.batch_size # type: ignore[attr-defined]
	yield data
	if isinstance(data_loader.sampler, DistributedSampler):
	data_loader.sampler.epoch += 1
	if isinstance(data_loader.sampler, ResumableSampler):
	data_loader.sampler.epoch += 1
	data_loader.sampler.idx = 0


	class ResumableSampler(Sampler):
	"""
	Distributed sampler that is resumable.

	Args:
	dataset: Dataset used for sampling.
	rank (int, optional): Rank of the current process within :attr:`num_replicas`.
	By default, :attr:`rank` is retrieved from the current distributed
	group.
	shuffle (bool, optional): If ``True`` (default), sampler will shuffle the
	indices.
	seed (int, optional): random seed used to shuffle the sampler if
	:attr:`shuffle=True`. This number should be identical across all
	processes in the distributed group. Default: ``0``.
	drop_last (bool, optional): if ``True``, then the sampler will drop the
	tail of the data to make it evenly divisible across the number of
	replicas. If ``False``, the sampler will add extra indices to make
	the data evenly divisible across the replicas. Default: ``False``.
	"""

	def __init__(
	self,
	dataset: Dataset,
	shuffle: bool = True,
	seed: int = 0,
	drop_last: bool = False,
	) -> None:
	self.dataset = dataset
	self.epoch = 0
	self.idx = 0
	self.drop_last = drop_last
	self.world_size = dist.get_world_size() if dist.is_initialized() else 1
	self.rank = dist.get_rank() if dist.is_initialized() else 0
	# If the dataset length is evenly divisible by # of replicas, then there
	# is no need to drop any data, since the dataset will be split equally.
	if self.drop_last and len(self.dataset) % self.world_size != 0: # type: ignore[arg-type]
	# Split to nearest available length that is evenly divisible.
	# This is to ensure each rank receives the same amount of data when
	# using this Sampler.
	self.num_samples = math.ceil(
	(len(self.dataset) - self.world_size) / self.world_size # type: ignore[arg-type]
	)
	else:
	self.num_samples = math.ceil(len(self.dataset) / self.world_size) # type: ignore[arg-type]
	self.total_size = self.num_samples * self.world_size
	self.shuffle = shuffle
	self.seed = seed

	def __iter__(self) -> Iterator:
	if self.shuffle:
	# deterministically shuffle based on epoch and seed
	g = torch.Generator()
	g.manual_seed(self.seed + self.epoch)
	indices = torch.randperm(len(self.dataset), generator=g).tolist() # type: ignore[arg-type]
	else:
	indices = list(range(len(self.dataset))) # type: ignore[arg-type]

	if not self.drop_last:
	# add extra samples to make it evenly divisible
	padding_size = self.total_size - len(indices)
	if padding_size <= len(indices):
	indices += indices[:padding_size]
	else:
	indices += (indices * math.ceil(padding_size / len(indices)))[
	:padding_size
	]
	else:
	# remove tail of data to make it evenly divisible.
	indices = indices[: self.total_size]
	assert len(indices) == self.total_size

	# subsample
	indices = indices[self.rank : self.total_size : self.world_size]

	# resume from previous state
	indices = indices[self.idx:]

	return iter(indices)

	def __len__(self) -> int:
	return self.num_samples

	def state_dict(self) -> dict[str, int]:
	return {
	'epoch': self.epoch,
	'idx': self.idx,
	}

	def load_state_dict(self, state_dict):
	self.epoch = state_dict['epoch']
	self.idx = state_dict['idx']


	class BalancedResumableSampler(ResumableSampler):
	"""
	Distributed sampler that is resumable and balances the load among the processes.

	Args:
	dataset: Dataset used for sampling.
	rank (int, optional): Rank of the current process within :attr:`num_replicas`.
	By default, :attr:`rank` is retrieved from the current distributed
	group.
	shuffle (bool, optional): If ``True`` (default), sampler will shuffle the
	indices.
	seed (int, optional): random seed used to shuffle the sampler if
	:attr:`shuffle=True`. This number should be identical across all
	processes in the distributed group. Default: ``0``.
	drop_last (bool, optional): if ``True``, then the sampler will drop the
	tail of the data to make it evenly divisible across the number of
	replicas. If ``False``, the sampler will add extra indices to make
	the data evenly divisible across the replicas. Default: ``False``.
	"""

	def __init__(
	self,
	dataset: Dataset,
	shuffle: bool = True,
	seed: int = 0,
	drop_last: bool = False,
	batch_size: int = 1,
	) -> None:
	assert hasattr(dataset, 'loads'), 'Dataset must have "loads" attribute to use BalancedResumableSampler'
	super().__init__(dataset, shuffle, seed, drop_last)
	self.batch_size = batch_size
	self.loads = dataset.loads

	def __iter__(self) -> Iterator:
	if self.shuffle:
	# deterministically shuffle based on epoch and seed
	g = torch.Generator()
	g.manual_seed(self.seed + self.epoch)
	indices = torch.randperm(len(self.dataset), generator=g).tolist() # type: ignore[arg-type]
	else:
	indices = list(range(len(self.dataset))) # type: ignore[arg-type]

	if not self.drop_last:
	# add extra samples to make it evenly divisible
	padding_size = self.total_size - len(indices)
	if padding_size <= len(indices):
	indices += indices[:padding_size]
	else:
	indices += (indices * math.ceil(padding_size / len(indices)))[
	:padding_size
	]
	else:
	# remove tail of data to make it evenly divisible.
	indices = indices[: self.total_size]
	assert len(indices) == self.total_size

	# balance load among processes
	num_batches = len(indices) // (self.batch_size * self.world_size)
	balanced_indices = []
	for i in range(num_batches):
	start_idx = i * self.batch_size * self.world_size
	end_idx = (i + 1) * self.batch_size * self.world_size
	batch_indices = indices[start_idx:end_idx]
	batch_loads = [self.loads[idx] for idx in batch_indices]
	groups = load_balanced_group_indices(batch_loads, self.world_size, equal_size=True)
	balanced_indices.extend([batch_indices[j] for j in groups[self.rank]])

	# resume from previous state
	indices = balanced_indices[self.idx:]

	return iter(indices)