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# Copyright (c) Facebook, Inc. and its affiliates. | |
import itertools | |
import logging | |
import math | |
from collections import defaultdict | |
from typing import Optional | |
import torch | |
from torch.utils.data.sampler import Sampler | |
from detectron2.utils import comm | |
logger = logging.getLogger(__name__) | |
class TrainingSampler(Sampler): | |
""" | |
In training, we only care about the "infinite stream" of training data. | |
So this sampler produces an infinite stream of indices and | |
all workers cooperate to correctly shuffle the indices and sample different indices. | |
The samplers in each worker effectively produces `indices[worker_id::num_workers]` | |
where `indices` is an infinite stream of indices consisting of | |
`shuffle(range(size)) + shuffle(range(size)) + ...` (if shuffle is True) | |
or `range(size) + range(size) + ...` (if shuffle is False) | |
Note that this sampler does not shard based on pytorch DataLoader worker id. | |
A sampler passed to pytorch DataLoader is used only with map-style dataset | |
and will not be executed inside workers. | |
But if this sampler is used in a way that it gets execute inside a dataloader | |
worker, then extra work needs to be done to shard its outputs based on worker id. | |
This is required so that workers don't produce identical data. | |
:class:`ToIterableDataset` implements this logic. | |
This note is true for all samplers in detectron2. | |
""" | |
def __init__(self, size: int, shuffle: bool = True, seed: Optional[int] = None): | |
""" | |
Args: | |
size (int): the total number of data of the underlying dataset to sample from | |
shuffle (bool): whether to shuffle the indices or not | |
seed (int): the initial seed of the shuffle. Must be the same | |
across all workers. If None, will use a random seed shared | |
among workers (require synchronization among all workers). | |
""" | |
if not isinstance(size, int): | |
raise TypeError(f"TrainingSampler(size=) expects an int. Got type {type(size)}.") | |
if size <= 0: | |
raise ValueError(f"TrainingSampler(size=) expects a positive int. Got {size}.") | |
self._size = size | |
self._shuffle = shuffle | |
if seed is None: | |
seed = comm.shared_random_seed() | |
self._seed = int(seed) | |
self._rank = comm.get_rank() | |
self._world_size = comm.get_world_size() | |
def __iter__(self): | |
start = self._rank | |
yield from itertools.islice(self._infinite_indices(), start, None, self._world_size) | |
def _infinite_indices(self): | |
g = torch.Generator() | |
g.manual_seed(self._seed) | |
while True: | |
if self._shuffle: | |
yield from torch.randperm(self._size, generator=g).tolist() | |
else: | |
yield from torch.arange(self._size).tolist() | |
class RandomSubsetTrainingSampler(TrainingSampler): | |
""" | |
Similar to TrainingSampler, but only sample a random subset of indices. | |
This is useful when you want to estimate the accuracy vs data-number curves by | |
training the model with different subset_ratio. | |
""" | |
def __init__( | |
self, | |
size: int, | |
subset_ratio: float, | |
shuffle: bool = True, | |
seed_shuffle: Optional[int] = None, | |
seed_subset: Optional[int] = None, | |
): | |
""" | |
Args: | |
size (int): the total number of data of the underlying dataset to sample from | |
subset_ratio (float): the ratio of subset data to sample from the underlying dataset | |
shuffle (bool): whether to shuffle the indices or not | |
seed_shuffle (int): the initial seed of the shuffle. Must be the same | |
across all workers. If None, will use a random seed shared | |
among workers (require synchronization among all workers). | |
seed_subset (int): the seed to randomize the subset to be sampled. | |
Must be the same across all workers. If None, will use a random seed shared | |
among workers (require synchronization among all workers). | |
""" | |
super().__init__(size=size, shuffle=shuffle, seed=seed_shuffle) | |
assert 0.0 < subset_ratio <= 1.0 | |
self._size_subset = int(size * subset_ratio) | |
assert self._size_subset > 0 | |
if seed_subset is None: | |
seed_subset = comm.shared_random_seed() | |
self._seed_subset = int(seed_subset) | |
# randomly generate the subset indexes to be sampled from | |
g = torch.Generator() | |
g.manual_seed(self._seed_subset) | |
indexes_randperm = torch.randperm(self._size, generator=g) | |
self._indexes_subset = indexes_randperm[: self._size_subset] | |
logger.info("Using RandomSubsetTrainingSampler......") | |
logger.info(f"Randomly sample {self._size_subset} data from the original {self._size} data") | |
def _infinite_indices(self): | |
g = torch.Generator() | |
g.manual_seed(self._seed) # self._seed equals seed_shuffle from __init__() | |
while True: | |
if self._shuffle: | |
# generate a random permutation to shuffle self._indexes_subset | |
randperm = torch.randperm(self._size_subset, generator=g) | |
yield from self._indexes_subset[randperm].tolist() | |
else: | |
yield from self._indexes_subset.tolist() | |
class RepeatFactorTrainingSampler(Sampler): | |
""" | |
Similar to TrainingSampler, but a sample may appear more times than others based | |
on its "repeat factor". This is suitable for training on class imbalanced datasets like LVIS. | |
""" | |
def __init__(self, repeat_factors, *, shuffle=True, seed=None): | |
""" | |
Args: | |
repeat_factors (Tensor): a float vector, the repeat factor for each indice. When it's | |
full of ones, it is equivalent to ``TrainingSampler(len(repeat_factors), ...)``. | |
shuffle (bool): whether to shuffle the indices or not | |
seed (int): the initial seed of the shuffle. Must be the same | |
across all workers. If None, will use a random seed shared | |
among workers (require synchronization among all workers). | |
""" | |
self._shuffle = shuffle | |
if seed is None: | |
seed = comm.shared_random_seed() | |
self._seed = int(seed) | |
self._rank = comm.get_rank() | |
self._world_size = comm.get_world_size() | |
# Split into whole number (_int_part) and fractional (_frac_part) parts. | |
self._int_part = torch.trunc(repeat_factors) | |
self._frac_part = repeat_factors - self._int_part | |
def repeat_factors_from_category_frequency(dataset_dicts, repeat_thresh): | |
""" | |
Compute (fractional) per-image repeat factors based on category frequency. | |
The repeat factor for an image is a function of the frequency of the rarest | |
category labeled in that image. The "frequency of category c" in [0, 1] is defined | |
as the fraction of images in the training set (without repeats) in which category c | |
appears. | |
See :paper:`lvis` (>= v2) Appendix B.2. | |
Args: | |
dataset_dicts (list[dict]): annotations in Detectron2 dataset format. | |
repeat_thresh (float): frequency threshold below which data is repeated. | |
If the frequency is half of `repeat_thresh`, the image will be | |
repeated twice. | |
Returns: | |
torch.Tensor: | |
the i-th element is the repeat factor for the dataset image at index i. | |
""" | |
# 1. For each category c, compute the fraction of images that contain it: f(c) | |
category_freq = defaultdict(int) | |
for dataset_dict in dataset_dicts: # For each image (without repeats) | |
cat_ids = {ann["category_id"] for ann in dataset_dict["annotations"]} | |
for cat_id in cat_ids: | |
category_freq[cat_id] += 1 | |
num_images = len(dataset_dicts) | |
for k, v in category_freq.items(): | |
category_freq[k] = v / num_images | |
# 2. For each category c, compute the category-level repeat factor: | |
# r(c) = max(1, sqrt(t / f(c))) | |
category_rep = { | |
cat_id: max(1.0, math.sqrt(repeat_thresh / cat_freq)) | |
for cat_id, cat_freq in category_freq.items() | |
} | |
# 3. For each image I, compute the image-level repeat factor: | |
# r(I) = max_{c in I} r(c) | |
rep_factors = [] | |
for dataset_dict in dataset_dicts: | |
cat_ids = {ann["category_id"] for ann in dataset_dict["annotations"]} | |
rep_factor = max({category_rep[cat_id] for cat_id in cat_ids}, default=1.0) | |
rep_factors.append(rep_factor) | |
return torch.tensor(rep_factors, dtype=torch.float32) | |
def _get_epoch_indices(self, generator): | |
""" | |
Create a list of dataset indices (with repeats) to use for one epoch. | |
Args: | |
generator (torch.Generator): pseudo random number generator used for | |
stochastic rounding. | |
Returns: | |
torch.Tensor: list of dataset indices to use in one epoch. Each index | |
is repeated based on its calculated repeat factor. | |
""" | |
# Since repeat factors are fractional, we use stochastic rounding so | |
# that the target repeat factor is achieved in expectation over the | |
# course of training | |
rands = torch.rand(len(self._frac_part), generator=generator) | |
rep_factors = self._int_part + (rands < self._frac_part).float() | |
# Construct a list of indices in which we repeat images as specified | |
indices = [] | |
for dataset_index, rep_factor in enumerate(rep_factors): | |
indices.extend([dataset_index] * int(rep_factor.item())) | |
return torch.tensor(indices, dtype=torch.int64) | |
def __iter__(self): | |
start = self._rank | |
yield from itertools.islice(self._infinite_indices(), start, None, self._world_size) | |
def _infinite_indices(self): | |
g = torch.Generator() | |
g.manual_seed(self._seed) | |
while True: | |
# Sample indices with repeats determined by stochastic rounding; each | |
# "epoch" may have a slightly different size due to the rounding. | |
indices = self._get_epoch_indices(g) | |
if self._shuffle: | |
randperm = torch.randperm(len(indices), generator=g) | |
yield from indices[randperm].tolist() | |
else: | |
yield from indices.tolist() | |
class InferenceSampler(Sampler): | |
""" | |
Produce indices for inference across all workers. | |
Inference needs to run on the __exact__ set of samples, | |
therefore when the total number of samples is not divisible by the number of workers, | |
this sampler produces different number of samples on different workers. | |
""" | |
def __init__(self, size: int): | |
""" | |
Args: | |
size (int): the total number of data of the underlying dataset to sample from | |
""" | |
self._size = size | |
assert size > 0 | |
self._rank = comm.get_rank() | |
self._world_size = comm.get_world_size() | |
self._local_indices = self._get_local_indices(size, self._world_size, self._rank) | |
def _get_local_indices(total_size, world_size, rank): | |
shard_size = total_size // world_size | |
left = total_size % world_size | |
shard_sizes = [shard_size + int(r < left) for r in range(world_size)] | |
begin = sum(shard_sizes[:rank]) | |
end = min(sum(shard_sizes[: rank + 1]), total_size) | |
return range(begin, end) | |
def __iter__(self): | |
yield from self._local_indices | |
def __len__(self): | |
return len(self._local_indices) | |