# Copyright (c) Facebook, Inc. and its affiliates. All Rights Reserved. import bisect import logging import torch.utils.data from maskrcnn_benchmark.utils.comm import get_world_size from maskrcnn_benchmark.utils.imports import import_file from . import datasets as D from . import samplers from .collate_batch import BatchCollator from .transforms import build_transforms def build_dataset(cfg, dataset_list, transforms, dataset_catalog, is_train=True): """ Arguments: dataset_list (list[str]): Contains the names of the datasets, i.e., coco_2014_trian, coco_2014_val, etc transforms (callable): transforms to apply to each (image, target) sample dataset_catalog (DatasetCatalog): contains the information on how to construct a dataset. is_train (bool): whether to setup the dataset for training or testing """ if not isinstance(dataset_list, (list, tuple)): raise RuntimeError( "dataset_list should be a list of strings, got {}".format(dataset_list)) datasets = [] for dataset_name in dataset_list: data = dataset_catalog.get(dataset_name) factory = getattr(D, data["factory"]) args = data["args"] # for COCODataset, we want to remove images without annotations # during training if data["factory"] == "COCODataset": args["remove_images_without_annotations"] = is_train args["transforms"] = transforms args["ignore_difficult"] = cfg.DATASETS.IGNORE_DIFFICULT # make dataset from factory dataset = factory(**args) datasets.append(dataset) # for testing, return a list of datasets if not is_train: return datasets # for training, concatenate all datasets into a single one dataset = datasets[0] if len(datasets) > 1: dataset = D.MixDataset(datasets, cfg.DATASETS.RATIOS) # dataset = D.ConcatDataset(datasets) return [dataset] def make_data_sampler(dataset, shuffle, distributed): if distributed: return samplers.DistributedSampler(dataset, shuffle=shuffle) if shuffle: sampler = torch.utils.data.sampler.RandomSampler(dataset) else: sampler = torch.utils.data.sampler.SequentialSampler(dataset) return sampler def _quantize(x, bins): bins = sorted(bins.copy()) quantized = list(map(lambda y: bisect.bisect_right(bins, y), x)) return quantized def _compute_aspect_ratios(dataset): aspect_ratios = [] for i in range(len(dataset)): img_info = dataset.get_img_info(i) aspect_ratio = float(img_info["height"]) / float(img_info["width"]) aspect_ratios.append(aspect_ratio) return aspect_ratios def make_batch_data_sampler( dataset, sampler, aspect_grouping, images_per_batch, num_iters=None, start_iter=0 ): if aspect_grouping: if not isinstance(aspect_grouping, (list, tuple)): aspect_grouping = [aspect_grouping] aspect_ratios = _compute_aspect_ratios(dataset) group_ids = _quantize(aspect_ratios, aspect_grouping) batch_sampler = samplers.GroupedBatchSampler( sampler, group_ids, images_per_batch, drop_uneven=False ) else: batch_sampler = torch.utils.data.sampler.BatchSampler( sampler, images_per_batch, drop_last=False ) if num_iters is not None: batch_sampler = samplers.IterationBasedBatchSampler(batch_sampler, num_iters, start_iter) return batch_sampler def make_data_loader(cfg, is_train=True, is_distributed=False, start_iter=0): num_gpus = get_world_size() if is_train: images_per_batch = cfg.SOLVER.IMS_PER_BATCH assert ( images_per_batch % num_gpus == 0 ), "SOLVER.IMS_PER_BATCH ({}) must be divisible by the number " "of GPUs ({}) used.".format(images_per_batch, num_gpus) images_per_gpu = images_per_batch // num_gpus shuffle = True num_iters = cfg.SOLVER.MAX_ITER else: images_per_batch = cfg.TEST.IMS_PER_BATCH assert ( images_per_batch % num_gpus == 0 ), "TEST.IMS_PER_BATCH ({}) must be divisible by the number " "of GPUs ({}) used.".format(images_per_batch, num_gpus) images_per_gpu = images_per_batch // num_gpus shuffle = False if not is_distributed else True num_iters = None start_iter = 0 if images_per_gpu > 1: logger = logging.getLogger(__name__) logger.warning( "When using more than one image per GPU you may encounter " "an out-of-memory (OOM) error if your GPU does not have " "sufficient memory. If this happens, you can reduce " "SOLVER.IMS_PER_BATCH (for training) or " "TEST.IMS_PER_BATCH (for inference). For training, you must " "also adjust the learning rate and schedule length according " "to the linear scaling rule. See for example: " "https://github.com/facebookresearch/Detectron/blob/master/configs/getting_started/tutorial_1gpu_e2e_faster_rcnn_R-50-FPN.yaml#L14" ) # group images which have similar aspect ratio. In this case, we only # group in two cases: those with width / height > 1, and the other way around, # but the code supports more general grouping strategy aspect_grouping = [1] if cfg.DATALOADER.ASPECT_RATIO_GROUPING else [] paths_catalog = import_file( "maskrcnn_benchmark.config.paths_catalog", cfg.PATHS_CATALOG, True ) DatasetCatalog = paths_catalog.DatasetCatalog dataset_list = cfg.DATASETS.TRAIN if is_train else cfg.DATASETS.TEST transforms = build_transforms(cfg, is_train) datasets = build_dataset(cfg,dataset_list, transforms, DatasetCatalog, is_train) data_loaders = [] for dataset in datasets: ''' for i in range(20): a=dataset[i] ipdb.set_trace() ''' sampler = make_data_sampler(dataset, shuffle, is_distributed) batch_sampler = make_batch_data_sampler( dataset, sampler, aspect_grouping, images_per_gpu, num_iters, start_iter ) collator = BatchCollator(cfg.DATALOADER.SIZE_DIVISIBILITY) num_workers = cfg.DATALOADER.NUM_WORKERS data_loader = torch.utils.data.DataLoader( dataset, num_workers=num_workers, batch_sampler=batch_sampler, collate_fn=collator, ) data_loaders.append(data_loader) if is_train: # during training, a single (possibly concatenated) data_loader is returned assert len(data_loaders) == 1 return data_loaders[0] return data_loaders