Exemplo n.º 1
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 def build_evaluator(cls, cfg, dataset_name, output_folder=None):
     """
     Create evaluator(s) for a given dataset.
     This uses the special metadata "evaluator_type" associated with each builtin dataset.
     For your own dataset, you can simply create an evaluator manually in your
     script and do not have to worry about the hacky if-else logic here.
     """
     if output_folder is None:
         output_folder = os.path.join(cfg.OUTPUT_DIR, "inference")
     evaluator_list = []
     evaluator_type = MetadataCatalog.get(dataset_name).evaluator_type
     if evaluator_type == "lvis":
         return LVISEvaluator(dataset_name, cfg, True, output_folder)
     if evaluator_type == "coco":
         return COCOEvaluator(dataset_name, cfg, True, output_folder)
     if evaluator_type == "cityscapes":
         assert (
             torch.cuda.device_count() >= comm.get_rank()
         ), "CityscapesEvaluator currently do not work with multiple machines."
         return CityscapesEvaluator(dataset_name)
     if len(evaluator_list) == 0:
         raise NotImplementedError(
             "no Evaluator for the dataset {} with the type {}".format(
                 dataset_name, evaluator_type))
     if len(evaluator_list) == 1:
         return evaluator_list[0]
     return DatasetEvaluators(evaluator_list)
Exemplo n.º 2
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def setup(args):
    cfg = get_cfg()
    cfg.merge_from_file(args.config_file)
    cfg.SOLVER.BASE_LR = 0.001  # Avoid NaNs. Not useful in this script anyway.
    cfg.merge_from_list(args.opts)
    cfg.freeze()
    setup_logger(distributed_rank=comm.get_rank())
    return cfg
Exemplo n.º 3
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def setup(args):
    cfg = get_cfg()
    add_densepose_config(cfg)
    cfg.merge_from_file(args.config_file)
    cfg.merge_from_list(args.opts)
    cfg.freeze()
    default_setup(cfg, args)
    # Setup logger for "densepose" module
    setup_logger(output=cfg.OUTPUT_DIR,
                 distributed_rank=comm.get_rank(),
                 name="densepose")
    return cfg
Exemplo n.º 4
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    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()

        shard_size = (self._size - 1) // self._world_size + 1
        begin = shard_size * self._rank
        end = min(shard_size * (self._rank + 1), self._size)
        self._local_indices = range(begin, end)
Exemplo n.º 5
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def default_setup(cfg, args):
    """
    Perform some basic common setups at the beginning of a job, including:

    1. Set up the mydl logger
    2. Log basic information about environment, cmdline arguments, and config
    3. Backup the config to the output directory

    Args:
        cfg (CfgNode): the full config to be used
        args (argparse.NameSpace): the command line arguments to be logged
    """
    output_dir = cfg.OUTPUT_DIR
    if comm.is_main_process() and output_dir:
        PathManager.mkdirs(output_dir)

    rank = comm.get_rank()
    setup_logger(output_dir, distributed_rank=rank, name="fvcore")
    logger = setup_logger(output_dir, distributed_rank=rank)

    logger.info("Rank of current process: {}. World size: {}".format(
        rank, comm.get_world_size()))
    logger.info("Environment info:\n" + collect_env_info())

    logger.info("Command line arguments: " + str(args))
    if hasattr(args, "config_file") and args.config_file != "":
        logger.info("Contents of args.config_file={}:\n{}".format(
            args.config_file,
            PathManager.open(args.config_file, "r").read()))

    logger.info("Running with full config:\n{}".format(cfg))
    if comm.is_main_process() and output_dir:
        # Note: some of our scripts may expect the existence of
        # config.yaml in output directory
        path = os.path.join(output_dir, "config.yaml")
        with PathManager.open(path, "w") as f:
            f.write(cfg.dump())
        logger.info("Full config saved to {}".format(os.path.abspath(path)))

    if cfg.VERSION == 2:
        # make sure each worker has a different, yet deterministic seed if specified
        seed_all_rng(None if cfg.SEED < 0 else cfg.SEED + rank)

        # cudnn benchmark has large overhead. It shouldn't be used considering the small size of
        # typical validation set.
        if not (hasattr(args, "eval_only") and args.eval_only):
            torch.backends.cudnn.benchmark = cfg.CUDNN_BENCHMARK
Exemplo n.º 6
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    def evaluate(self):
        """
        Returns:
            dict: has a key "segm", whose value is a dict of "AP" and "AP50".
        """
        comm.synchronize()
        if comm.get_rank() > 0:
            return
        os.environ["CITYSCAPES_DATASET"] = os.path.abspath(
            os.path.join(self._metadata.gt_dir, "..", "..")
        )
        # Load the Cityscapes eval script *after* setting the required env var,
        # since the script reads CITYSCAPES_DATASET into global variables at load time.
        import cityscapesscripts.evaluation.evalInstanceLevelSemanticLabeling as cityscapes_eval

        self._logger.info("Evaluating results under {} ...".format(self._temp_dir))

        # set some global states in cityscapes evaluation API, before evaluating
        cityscapes_eval.args.predictionPath = os.path.abspath(self._temp_dir)
        cityscapes_eval.args.predictionWalk = None
        cityscapes_eval.args.JSONOutput = False
        cityscapes_eval.args.colorized = False
        cityscapes_eval.args.gtInstancesFile = os.path.join(self._temp_dir, "gtInstances.json")

        # These lines are adopted from
        # https://github.com/mcordts/cityscapesScripts/blob/master/cityscapesscripts/evaluation/evalInstanceLevelSemanticLabeling.py # noqa
        groundTruthImgList = glob.glob(cityscapes_eval.args.groundTruthSearch)
        assert len(
            groundTruthImgList
        ), "Cannot find any ground truth images to use for evaluation. Searched for: {}".format(
            cityscapes_eval.args.groundTruthSearch
        )
        predictionImgList = []
        for gt in groundTruthImgList:
            predictionImgList.append(cityscapes_eval.getPrediction(gt, cityscapes_eval.args))
        results = cityscapes_eval.evaluateImgLists(
            predictionImgList, groundTruthImgList, cityscapes_eval.args
        )["averages"]

        ret = OrderedDict()
        ret["segm"] = {"AP": results["allAp"] * 100, "AP50": results["allAp50%"] * 100}
        self._working_dir.cleanup()
        return ret
Exemplo n.º 7
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 def build_evaluator(cls, cfg, dataset_name, output_folder=None):
     """
     Create evaluator(s) for a given dataset.
     This uses the special metadata "evaluator_type" associated with each builtin dataset.
     For your own dataset, you can simply create an evaluator manually in your
     script and do not have to worry about the hacky if-else logic here.
     """
     if output_folder is None:
         output_folder = os.path.join(cfg.OUTPUT_DIR, "inference")
     evaluator_list = []
     evaluator_type = MetadataCatalog.get(dataset_name).evaluator_type
     if evaluator_type in ["sem_seg", "coco_panoptic_seg"]:
         evaluator_list.append(
             SemSegEvaluator(
                 dataset_name,
                 distributed=True,
                 num_classes=cfg.MODEL.SEM_SEG_HEAD.NUM_CLASSES,
                 ignore_label=cfg.MODEL.SEM_SEG_HEAD.IGNORE_VALUE,
                 output_dir=output_folder,
             ))
     if evaluator_type in ["coco", "coco_panoptic_seg"]:
         evaluator_list.append(
             COCOEvaluator(dataset_name, cfg, True, output_folder))
     if evaluator_type == "coco_panoptic_seg":
         evaluator_list.append(
             COCOPanopticEvaluator(dataset_name, output_folder))
     elif evaluator_type == "cityscapes":
         assert (
             torch.cuda.device_count() >= comm.get_rank()
         ), "CityscapesEvaluator currently do not work with multiple machines."
         return CityscapesEvaluator(dataset_name)
     elif evaluator_type == "pascal_voc":
         return PascalVOCDetectionEvaluator(dataset_name)
     elif evaluator_type == "lvis":
         return LVISEvaluator(dataset_name, cfg, True, output_folder)
     if len(evaluator_list) == 0:
         raise NotImplementedError(
             "no Evaluator for the dataset {} with the type {}".format(
                 dataset_name, evaluator_type))
     elif len(evaluator_list) == 1:
         return evaluator_list[0]
     return DatasetEvaluators(evaluator_list)
Exemplo n.º 8
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    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).
        """
        self._size = size
        assert size > 0
        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()
Exemplo n.º 9
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    def __init__(self, dataset_dicts, repeat_thresh, shuffle=True, seed=None):
        """
        Args:
            dataset_dicts (list[dict]): annotations in mydl dataset format.
            repeat_thresh (float): frequency threshold below which data is repeated.
            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()

        # Get fractional repeat factors and split into whole number (_int_part)
        # and fractional (_frac_part) parts.
        rep_factors = self._get_repeat_factors(dataset_dicts, repeat_thresh)
        self._int_part = torch.trunc(rep_factors)
        self._frac_part = rep_factors - self._int_part
Exemplo n.º 10
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def train(cfg, local_rank, distributed):
    model = build_detection_model(cfg)
    device = torch.device(cfg.MODEL.DEVICE)
    model.to(device)

    optimizer = make_optimizer(cfg, model)
    scheduler = make_lr_scheduler(cfg, optimizer)

    # Initialize mixed-precision training
    use_mixed_precision = cfg.DTYPE == "float16"
    amp_opt_level = 'O1' if use_mixed_precision else 'O0'
    model, optimizer = amp.initialize(model,
                                      optimizer,
                                      opt_level=amp_opt_level)

    if distributed:
        model = torch.nn.parallel.DistributedDataParallel(
            model,
            device_ids=[local_rank],
            output_device=local_rank,
            # this should be removed if we update BatchNorm stats
            broadcast_buffers=False,
        )

    arguments = {}
    arguments["iteration"] = 0

    output_dir = cfg.OUTPUT_DIR

    save_to_disk = get_rank() == 0
    checkpointer = DetectronCheckpointer(cfg, model, optimizer, scheduler,
                                         output_dir, save_to_disk)
    extra_checkpoint_data = checkpointer.load(cfg.MODEL.WEIGHT)
    arguments.update(extra_checkpoint_data)

    data_loader = make_data_loader(
        cfg,
        is_train=True,
        is_distributed=distributed,
        start_iter=arguments["iteration"],
    )

    test_period = cfg.SOLVER.TEST_PERIOD
    if test_period > 0:
        data_loader_val = make_data_loader(cfg,
                                           is_train=False,
                                           is_distributed=distributed,
                                           is_for_period=True)
    else:
        data_loader_val = None

    checkpoint_period = cfg.SOLVER.CHECKPOINT_PERIOD

    do_train(
        cfg,
        model,
        data_loader,
        data_loader_val,
        optimizer,
        scheduler,
        checkpointer,
        device,
        checkpoint_period,
        test_period,
        arguments,
    )

    return model
Exemplo n.º 11
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def main():
    parser = argparse.ArgumentParser(
        description="PyTorch Object Detection Training")
    parser.add_argument(
        "--config-file",
        default="",
        metavar="FILE",
        help="path to config file",
        type=str,
    )
    parser.add_argument("--local_rank", type=int, default=0)
    parser.add_argument(
        "--skip-test",
        dest="skip_test",
        help="Do not test the final model",
        action="store_true",
    )
    parser.add_argument(
        "opts",
        help="Modify config options using the command-line",
        default=None,
        nargs=argparse.REMAINDER,
    )

    args = parser.parse_args()

    num_gpus = int(
        os.environ["WORLD_SIZE"]) if "WORLD_SIZE" in os.environ else 1
    args.distributed = num_gpus > 1

    if args.distributed:
        torch.cuda.set_device(args.local_rank)
        torch.distributed.init_process_group(backend="nccl",
                                             init_method="env://")
        synchronize()

    cfg.merge_from_file(args.config_file)
    cfg.merge_from_list(args.opts)
    cfg.freeze()

    output_dir = cfg.OUTPUT_DIR
    if output_dir:
        mkdir(output_dir)

    logger = setup_logger("mydl", output_dir, get_rank())
    logger.info("Using {} GPUs".format(num_gpus))
    logger.info(args)

    logger.info("Collecting env info (might take some time)")
    logger.info("\n" + collect_env_info())

    logger.info("Loaded configuration file {}".format(args.config_file))
    with open(args.config_file, "r") as cf:
        config_str = "\n" + cf.read()
        logger.info(config_str)
    logger.info("Running with config:\n{}".format(cfg))

    output_config_path = os.path.join(cfg.OUTPUT_DIR, 'config.yml')
    logger.info("Saving config into: {}".format(output_config_path))
    # save overloaded model config in the output directory
    save_config(cfg, output_config_path)

    model = train(cfg, args.local_rank, args.distributed)

    if not args.skip_test:
        run_test(cfg, model, args.distributed)
Exemplo n.º 12
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def main():
    parser = argparse.ArgumentParser(
        description="PyTorch Object Detection Inference")
    parser.add_argument(
        "--config-file",
        default=
        "/private/home/fmassa/github/detectron.pytorch_v2/configs/e2e_faster_rcnn_R_50_C4_1x_caffe2.yaml",
        metavar="FILE",
        help="path to config file",
    )
    parser.add_argument("--local_rank", type=int, default=0)
    parser.add_argument(
        "--ckpt",
        help=
        "The path to the checkpoint for test, default is the latest checkpoint.",
        default=None,
    )
    parser.add_argument(
        "opts",
        help="Modify config options using the command-line",
        default=None,
        nargs=argparse.REMAINDER,
    )

    args = parser.parse_args()

    num_gpus = int(
        os.environ["WORLD_SIZE"]) if "WORLD_SIZE" in os.environ else 1
    distributed = num_gpus > 1

    if distributed:
        torch.cuda.set_device(args.local_rank)
        torch.distributed.init_process_group(backend="nccl",
                                             init_method="env://")
        synchronize()

    cfg.merge_from_file(args.config_file)
    cfg.merge_from_list(args.opts)
    cfg.freeze()

    save_dir = ""
    logger = setup_logger("mydl", save_dir, get_rank())
    logger.info("Using {} GPUs".format(num_gpus))
    logger.info(cfg)

    logger.info("Collecting env info (might take some time)")
    logger.info("\n" + collect_env_info())

    model = build_detection_model(cfg)
    model.to(cfg.MODEL.DEVICE)

    # Initialize mixed-precision if necessary
    use_mixed_precision = cfg.DTYPE == 'float16'
    amp_handle = amp.init(enabled=use_mixed_precision, verbose=cfg.AMP_VERBOSE)

    output_dir = cfg.OUTPUT_DIR
    checkpointer = DetectronCheckpointer(cfg, model, save_dir=output_dir)
    ckpt = cfg.MODEL.WEIGHT if args.ckpt is None else args.ckpt
    _ = checkpointer.load(ckpt, use_latest=args.ckpt is None)

    iou_types = ("bbox", )
    if cfg.MODEL.MASK_ON:
        iou_types = iou_types + ("segm", )
    if cfg.MODEL.KEYPOINT_ON:
        iou_types = iou_types + ("keypoints", )
    output_folders = [None] * len(cfg.DATASETS.TEST)
    dataset_names = cfg.DATASETS.TEST
    if cfg.OUTPUT_DIR:
        for idx, dataset_name in enumerate(dataset_names):
            output_folder = os.path.join(cfg.OUTPUT_DIR, "inference",
                                         dataset_name)
            mkdir(output_folder)
            output_folders[idx] = output_folder
    data_loaders_val = make_data_loader(cfg,
                                        is_train=False,
                                        is_distributed=distributed)
    for output_folder, dataset_name, data_loader_val in zip(
            output_folders, dataset_names, data_loaders_val):
        inference(
            model,
            data_loader_val,
            dataset_name=dataset_name,
            iou_types=iou_types,
            box_only=False if cfg.MODEL.RETINANET_ON else cfg.MODEL.RPN_ONLY,
            bbox_aug=cfg.TEST.BBOX_AUG.ENABLED,
            device=cfg.MODEL.DEVICE,
            expected_results=cfg.TEST.EXPECTED_RESULTS,
            expected_results_sigma_tol=cfg.TEST.EXPECTED_RESULTS_SIGMA_TOL,
            output_folder=output_folder,
        )
        synchronize()