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# Copyright (c) Facebook, Inc. and its affiliates.
import itertools
import logging
import numpy as np
import operator
import pickle
from typing import Any, Callable, Dict, List, Optional, Union
import torch
import torch.utils.data as torchdata
from tabulate import tabulate
from termcolor import colored
from annotator.oneformer.detectron2.config import configurable
from annotator.oneformer.detectron2.structures import BoxMode
from annotator.oneformer.detectron2.utils.comm import get_world_size
from annotator.oneformer.detectron2.utils.env import seed_all_rng
from annotator.oneformer.detectron2.utils.file_io import PathManager
from annotator.oneformer.detectron2.utils.logger import _log_api_usage, log_first_n
from .catalog import DatasetCatalog, MetadataCatalog
from .common import AspectRatioGroupedDataset, DatasetFromList, MapDataset, ToIterableDataset
from .dataset_mapper import DatasetMapper
from .detection_utils import check_metadata_consistency
from .samplers import (
InferenceSampler,
RandomSubsetTrainingSampler,
RepeatFactorTrainingSampler,
TrainingSampler,
)
"""
This file contains the default logic to build a dataloader for training or testing.
"""
__all__ = [
"build_batch_data_loader",
"build_detection_train_loader",
"build_detection_test_loader",
"get_detection_dataset_dicts",
"load_proposals_into_dataset",
"print_instances_class_histogram",
]
def filter_images_with_only_crowd_annotations(dataset_dicts):
"""
Filter out images with none annotations or only crowd annotations
(i.e., images without non-crowd annotations).
A common training-time preprocessing on COCO dataset.
Args:
dataset_dicts (list[dict]): annotations in Detectron2 Dataset format.
Returns:
list[dict]: the same format, but filtered.
"""
num_before = len(dataset_dicts)
def valid(anns):
for ann in anns:
if ann.get("iscrowd", 0) == 0:
return True
return False
dataset_dicts = [x for x in dataset_dicts if valid(x["annotations"])]
num_after = len(dataset_dicts)
logger = logging.getLogger(__name__)
logger.info(
"Removed {} images with no usable annotations. {} images left.".format(
num_before - num_after, num_after
)
)
return dataset_dicts
def filter_images_with_few_keypoints(dataset_dicts, min_keypoints_per_image):
"""
Filter out images with too few number of keypoints.
Args:
dataset_dicts (list[dict]): annotations in Detectron2 Dataset format.
Returns:
list[dict]: the same format as dataset_dicts, but filtered.
"""
num_before = len(dataset_dicts)
def visible_keypoints_in_image(dic):
# Each keypoints field has the format [x1, y1, v1, ...], where v is visibility
annotations = dic["annotations"]
return sum(
(np.array(ann["keypoints"][2::3]) > 0).sum()
for ann in annotations
if "keypoints" in ann
)
dataset_dicts = [
x for x in dataset_dicts if visible_keypoints_in_image(x) >= min_keypoints_per_image
]
num_after = len(dataset_dicts)
logger = logging.getLogger(__name__)
logger.info(
"Removed {} images with fewer than {} keypoints.".format(
num_before - num_after, min_keypoints_per_image
)
)
return dataset_dicts
def load_proposals_into_dataset(dataset_dicts, proposal_file):
"""
Load precomputed object proposals into the dataset.
The proposal file should be a pickled dict with the following keys:
- "ids": list[int] or list[str], the image ids
- "boxes": list[np.ndarray], each is an Nx4 array of boxes corresponding to the image id
- "objectness_logits": list[np.ndarray], each is an N sized array of objectness scores
corresponding to the boxes.
- "bbox_mode": the BoxMode of the boxes array. Defaults to ``BoxMode.XYXY_ABS``.
Args:
dataset_dicts (list[dict]): annotations in Detectron2 Dataset format.
proposal_file (str): file path of pre-computed proposals, in pkl format.
Returns:
list[dict]: the same format as dataset_dicts, but added proposal field.
"""
logger = logging.getLogger(__name__)
logger.info("Loading proposals from: {}".format(proposal_file))
with PathManager.open(proposal_file, "rb") as f:
proposals = pickle.load(f, encoding="latin1")
# Rename the key names in D1 proposal files
rename_keys = {"indexes": "ids", "scores": "objectness_logits"}
for key in rename_keys:
if key in proposals:
proposals[rename_keys[key]] = proposals.pop(key)
# Fetch the indexes of all proposals that are in the dataset
# Convert image_id to str since they could be int.
img_ids = set({str(record["image_id"]) for record in dataset_dicts})
id_to_index = {str(id): i for i, id in enumerate(proposals["ids"]) if str(id) in img_ids}
# Assuming default bbox_mode of precomputed proposals are 'XYXY_ABS'
bbox_mode = BoxMode(proposals["bbox_mode"]) if "bbox_mode" in proposals else BoxMode.XYXY_ABS
for record in dataset_dicts:
# Get the index of the proposal
i = id_to_index[str(record["image_id"])]
boxes = proposals["boxes"][i]
objectness_logits = proposals["objectness_logits"][i]
# Sort the proposals in descending order of the scores
inds = objectness_logits.argsort()[::-1]
record["proposal_boxes"] = boxes[inds]
record["proposal_objectness_logits"] = objectness_logits[inds]
record["proposal_bbox_mode"] = bbox_mode
return dataset_dicts
def print_instances_class_histogram(dataset_dicts, class_names):
"""
Args:
dataset_dicts (list[dict]): list of dataset dicts.
class_names (list[str]): list of class names (zero-indexed).
"""
num_classes = len(class_names)
hist_bins = np.arange(num_classes + 1)
histogram = np.zeros((num_classes,), dtype=np.int)
for entry in dataset_dicts:
annos = entry["annotations"]
classes = np.asarray(
[x["category_id"] for x in annos if not x.get("iscrowd", 0)], dtype=np.int
)
if len(classes):
assert classes.min() >= 0, f"Got an invalid category_id={classes.min()}"
assert (
classes.max() < num_classes
), f"Got an invalid category_id={classes.max()} for a dataset of {num_classes} classes"
histogram += np.histogram(classes, bins=hist_bins)[0]
N_COLS = min(6, len(class_names) * 2)
def short_name(x):
# make long class names shorter. useful for lvis
if len(x) > 13:
return x[:11] + ".."
return x
data = list(
itertools.chain(*[[short_name(class_names[i]), int(v)] for i, v in enumerate(histogram)])
)
total_num_instances = sum(data[1::2])
data.extend([None] * (N_COLS - (len(data) % N_COLS)))
if num_classes > 1:
data.extend(["total", total_num_instances])
data = itertools.zip_longest(*[data[i::N_COLS] for i in range(N_COLS)])
table = tabulate(
data,
headers=["category", "#instances"] * (N_COLS // 2),
tablefmt="pipe",
numalign="left",
stralign="center",
)
log_first_n(
logging.INFO,
"Distribution of instances among all {} categories:\n".format(num_classes)
+ colored(table, "cyan"),
key="message",
)
def get_detection_dataset_dicts(
names,
filter_empty=True,
min_keypoints=0,
proposal_files=None,
check_consistency=True,
):
"""
Load and prepare dataset dicts for instance detection/segmentation and semantic segmentation.
Args:
names (str or list[str]): a dataset name or a list of dataset names
filter_empty (bool): whether to filter out images without instance annotations
min_keypoints (int): filter out images with fewer keypoints than
`min_keypoints`. Set to 0 to do nothing.
proposal_files (list[str]): if given, a list of object proposal files
that match each dataset in `names`.
check_consistency (bool): whether to check if datasets have consistent metadata.
Returns:
list[dict]: a list of dicts following the standard dataset dict format.
"""
if isinstance(names, str):
names = [names]
assert len(names), names
dataset_dicts = [DatasetCatalog.get(dataset_name) for dataset_name in names]
if isinstance(dataset_dicts[0], torchdata.Dataset):
if len(dataset_dicts) > 1:
# ConcatDataset does not work for iterable style dataset.
# We could support concat for iterable as well, but it's often
# not a good idea to concat iterables anyway.
return torchdata.ConcatDataset(dataset_dicts)
return dataset_dicts[0]
for dataset_name, dicts in zip(names, dataset_dicts):
assert len(dicts), "Dataset '{}' is empty!".format(dataset_name)
if proposal_files is not None:
assert len(names) == len(proposal_files)
# load precomputed proposals from proposal files
dataset_dicts = [
load_proposals_into_dataset(dataset_i_dicts, proposal_file)
for dataset_i_dicts, proposal_file in zip(dataset_dicts, proposal_files)
]
dataset_dicts = list(itertools.chain.from_iterable(dataset_dicts))
has_instances = "annotations" in dataset_dicts[0]
if filter_empty and has_instances:
dataset_dicts = filter_images_with_only_crowd_annotations(dataset_dicts)
if min_keypoints > 0 and has_instances:
dataset_dicts = filter_images_with_few_keypoints(dataset_dicts, min_keypoints)
if check_consistency and has_instances:
try:
class_names = MetadataCatalog.get(names[0]).thing_classes
check_metadata_consistency("thing_classes", names)
print_instances_class_histogram(dataset_dicts, class_names)
except AttributeError: # class names are not available for this dataset
pass
assert len(dataset_dicts), "No valid data found in {}.".format(",".join(names))
return dataset_dicts
def build_batch_data_loader(
dataset,
sampler,
total_batch_size,
*,
aspect_ratio_grouping=False,
num_workers=0,
collate_fn=None,
):
"""
Build a batched dataloader. The main differences from `torch.utils.data.DataLoader` are:
1. support aspect ratio grouping options
2. use no "batch collation", because this is common for detection training
Args:
dataset (torch.utils.data.Dataset): a pytorch map-style or iterable dataset.
sampler (torch.utils.data.sampler.Sampler or None): a sampler that produces indices.
Must be provided iff. ``dataset`` is a map-style dataset.
total_batch_size, aspect_ratio_grouping, num_workers, collate_fn: see
:func:`build_detection_train_loader`.
Returns:
iterable[list]. Length of each list is the batch size of the current
GPU. Each element in the list comes from the dataset.
"""
world_size = get_world_size()
assert (
total_batch_size > 0 and total_batch_size % world_size == 0
), "Total batch size ({}) must be divisible by the number of gpus ({}).".format(
total_batch_size, world_size
)
batch_size = total_batch_size // world_size
if isinstance(dataset, torchdata.IterableDataset):
assert sampler is None, "sampler must be None if dataset is IterableDataset"
else:
dataset = ToIterableDataset(dataset, sampler)
if aspect_ratio_grouping:
data_loader = torchdata.DataLoader(
dataset,
num_workers=num_workers,
collate_fn=operator.itemgetter(0), # don't batch, but yield individual elements
worker_init_fn=worker_init_reset_seed,
) # yield individual mapped dict
data_loader = AspectRatioGroupedDataset(data_loader, batch_size)
if collate_fn is None:
return data_loader
return MapDataset(data_loader, collate_fn)
else:
return torchdata.DataLoader(
dataset,
batch_size=batch_size,
drop_last=True,
num_workers=num_workers,
collate_fn=trivial_batch_collator if collate_fn is None else collate_fn,
worker_init_fn=worker_init_reset_seed,
)
def _train_loader_from_config(cfg, mapper=None, *, dataset=None, sampler=None):
if dataset is None:
dataset = get_detection_dataset_dicts(
cfg.DATASETS.TRAIN,
filter_empty=cfg.DATALOADER.FILTER_EMPTY_ANNOTATIONS,
min_keypoints=cfg.MODEL.ROI_KEYPOINT_HEAD.MIN_KEYPOINTS_PER_IMAGE
if cfg.MODEL.KEYPOINT_ON
else 0,
proposal_files=cfg.DATASETS.PROPOSAL_FILES_TRAIN if cfg.MODEL.LOAD_PROPOSALS else None,
)
_log_api_usage("dataset." + cfg.DATASETS.TRAIN[0])
if mapper is None:
mapper = DatasetMapper(cfg, True)
if sampler is None:
sampler_name = cfg.DATALOADER.SAMPLER_TRAIN
logger = logging.getLogger(__name__)
if isinstance(dataset, torchdata.IterableDataset):
logger.info("Not using any sampler since the dataset is IterableDataset.")
sampler = None
else:
logger.info("Using training sampler {}".format(sampler_name))
if sampler_name == "TrainingSampler":
sampler = TrainingSampler(len(dataset))
elif sampler_name == "RepeatFactorTrainingSampler":
repeat_factors = RepeatFactorTrainingSampler.repeat_factors_from_category_frequency(
dataset, cfg.DATALOADER.REPEAT_THRESHOLD
)
sampler = RepeatFactorTrainingSampler(repeat_factors)
elif sampler_name == "RandomSubsetTrainingSampler":
sampler = RandomSubsetTrainingSampler(
len(dataset), cfg.DATALOADER.RANDOM_SUBSET_RATIO
)
else:
raise ValueError("Unknown training sampler: {}".format(sampler_name))
return {
"dataset": dataset,
"sampler": sampler,
"mapper": mapper,
"total_batch_size": cfg.SOLVER.IMS_PER_BATCH,
"aspect_ratio_grouping": cfg.DATALOADER.ASPECT_RATIO_GROUPING,
"num_workers": cfg.DATALOADER.NUM_WORKERS,
}
@configurable(from_config=_train_loader_from_config)
def build_detection_train_loader(
dataset,
*,
mapper,
sampler=None,
total_batch_size,
aspect_ratio_grouping=True,
num_workers=0,
collate_fn=None,
):
"""
Build a dataloader for object detection with some default features.
Args:
dataset (list or torch.utils.data.Dataset): a list of dataset dicts,
or a pytorch dataset (either map-style or iterable). It can be obtained
by using :func:`DatasetCatalog.get` or :func:`get_detection_dataset_dicts`.
mapper (callable): a callable which takes a sample (dict) from dataset and
returns the format to be consumed by the model.
When using cfg, the default choice is ``DatasetMapper(cfg, is_train=True)``.
sampler (torch.utils.data.sampler.Sampler or None): a sampler that produces
indices to be applied on ``dataset``.
If ``dataset`` is map-style, the default sampler is a :class:`TrainingSampler`,
which coordinates an infinite random shuffle sequence across all workers.
Sampler must be None if ``dataset`` is iterable.
total_batch_size (int): total batch size across all workers.
aspect_ratio_grouping (bool): whether to group images with similar
aspect ratio for efficiency. When enabled, it requires each
element in dataset be a dict with keys "width" and "height".
num_workers (int): number of parallel data loading workers
collate_fn: a function that determines how to do batching, same as the argument of
`torch.utils.data.DataLoader`. Defaults to do no collation and return a list of
data. No collation is OK for small batch size and simple data structures.
If your batch size is large and each sample contains too many small tensors,
it's more efficient to collate them in data loader.
Returns:
torch.utils.data.DataLoader:
a dataloader. Each output from it is a ``list[mapped_element]`` of length
``total_batch_size / num_workers``, where ``mapped_element`` is produced
by the ``mapper``.
"""
if isinstance(dataset, list):
dataset = DatasetFromList(dataset, copy=False)
if mapper is not None:
dataset = MapDataset(dataset, mapper)
if isinstance(dataset, torchdata.IterableDataset):
assert sampler is None, "sampler must be None if dataset is IterableDataset"
else:
if sampler is None:
sampler = TrainingSampler(len(dataset))
assert isinstance(sampler, torchdata.Sampler), f"Expect a Sampler but got {type(sampler)}"
return build_batch_data_loader(
dataset,
sampler,
total_batch_size,
aspect_ratio_grouping=aspect_ratio_grouping,
num_workers=num_workers,
collate_fn=collate_fn,
)
def _test_loader_from_config(cfg, dataset_name, mapper=None):
"""
Uses the given `dataset_name` argument (instead of the names in cfg), because the
standard practice is to evaluate each test set individually (not combining them).
"""
if isinstance(dataset_name, str):
dataset_name = [dataset_name]
dataset = get_detection_dataset_dicts(
dataset_name,
filter_empty=False,
proposal_files=[
cfg.DATASETS.PROPOSAL_FILES_TEST[list(cfg.DATASETS.TEST).index(x)] for x in dataset_name
]
if cfg.MODEL.LOAD_PROPOSALS
else None,
)
if mapper is None:
mapper = DatasetMapper(cfg, False)
return {
"dataset": dataset,
"mapper": mapper,
"num_workers": cfg.DATALOADER.NUM_WORKERS,
"sampler": InferenceSampler(len(dataset))
if not isinstance(dataset, torchdata.IterableDataset)
else None,
}
@configurable(from_config=_test_loader_from_config)
def build_detection_test_loader(
dataset: Union[List[Any], torchdata.Dataset],
*,
mapper: Callable[[Dict[str, Any]], Any],
sampler: Optional[torchdata.Sampler] = None,
batch_size: int = 1,
num_workers: int = 0,
collate_fn: Optional[Callable[[List[Any]], Any]] = None,
) -> torchdata.DataLoader:
"""
Similar to `build_detection_train_loader`, with default batch size = 1,
and sampler = :class:`InferenceSampler`. This sampler coordinates all workers
to produce the exact set of all samples.
Args:
dataset: a list of dataset dicts,
or a pytorch dataset (either map-style or iterable). They can be obtained
by using :func:`DatasetCatalog.get` or :func:`get_detection_dataset_dicts`.
mapper: a callable which takes a sample (dict) from dataset
and returns the format to be consumed by the model.
When using cfg, the default choice is ``DatasetMapper(cfg, is_train=False)``.
sampler: a sampler that produces
indices to be applied on ``dataset``. Default to :class:`InferenceSampler`,
which splits the dataset across all workers. Sampler must be None
if `dataset` is iterable.
batch_size: the batch size of the data loader to be created.
Default to 1 image per worker since this is the standard when reporting
inference time in papers.
num_workers: number of parallel data loading workers
collate_fn: same as the argument of `torch.utils.data.DataLoader`.
Defaults to do no collation and return a list of data.
Returns:
DataLoader: a torch DataLoader, that loads the given detection
dataset, with test-time transformation and batching.
Examples:
::
data_loader = build_detection_test_loader(
DatasetRegistry.get("my_test"),
mapper=DatasetMapper(...))
# or, instantiate with a CfgNode:
data_loader = build_detection_test_loader(cfg, "my_test")
"""
if isinstance(dataset, list):
dataset = DatasetFromList(dataset, copy=False)
if mapper is not None:
dataset = MapDataset(dataset, mapper)
if isinstance(dataset, torchdata.IterableDataset):
assert sampler is None, "sampler must be None if dataset is IterableDataset"
else:
if sampler is None:
sampler = InferenceSampler(len(dataset))
return torchdata.DataLoader(
dataset,
batch_size=batch_size,
sampler=sampler,
drop_last=False,
num_workers=num_workers,
collate_fn=trivial_batch_collator if collate_fn is None else collate_fn,
)
def trivial_batch_collator(batch):
"""
A batch collator that does nothing.
"""
return batch
def worker_init_reset_seed(worker_id):
initial_seed = torch.initial_seed() % 2**31
seed_all_rng(initial_seed + worker_id)