Exemplo n.º 1
0
def create_pipeline_from_checkpoint_paths(
        config: ModelConfigBase,
        checkpoint_paths: List[Path]) -> Optional[InferencePipelineBase]:
    """
    Attempt to create a pipeline from the provided checkpoint paths. If the files referred to by the paths
    do not exist, or if there are no paths, None will be returned.
    """
    if len(checkpoint_paths) > 1:
        if config.is_segmentation_model:
            assert isinstance(config, SegmentationModelBase)
            return EnsemblePipeline.create_from_checkpoints(
                path_to_checkpoints=checkpoint_paths, model_config=config)
        elif config.is_scalar_model:
            assert isinstance(config, ScalarModelBase)
            return ScalarEnsemblePipeline.create_from_checkpoint(
                paths_to_checkpoint=checkpoint_paths, config=config)
        else:
            raise NotImplementedError(
                "Cannot create inference pipeline for unknown model type")
    if len(checkpoint_paths) == 1:
        if config.is_segmentation_model:
            assert isinstance(config, SegmentationModelBase)
            return InferencePipeline.create_from_checkpoint(
                path_to_checkpoint=checkpoint_paths[0], model_config=config)
        elif config.is_scalar_model:
            assert isinstance(config, ScalarModelBase)
            return ScalarInferencePipeline.create_from_checkpoint(
                path_to_checkpoint=checkpoint_paths[0], config=config)
        else:
            raise NotImplementedError(
                "Cannot create ensemble pipeline for unknown model type")
    return None
Exemplo n.º 2
0
def create_inference_pipeline(model_config: SegmentationModelBase,
                              full_path_to_checkpoints: List[Path],
                              use_gpu: bool = True) \
        -> Tuple[FullImageInferencePipelineBase, SegmentationModelBase]:
    """
    Create pipeline for inference, this can be a single model inference pipeline or an ensemble, if multiple
    checkpoints provided.
    :param model_config: Model config to use to create the pipeline.
    :param full_path_to_checkpoints: Checkpoints to use for model inference.
    :param use_gpu: If GPU should be used or not.
    """
    model_config.use_gpu = use_gpu
    logging.info('test_config: ' + model_config.model_name)

    inference_pipeline: Optional[FullImageInferencePipelineBase]
    if len(full_path_to_checkpoints) == 1:
        inference_pipeline = InferencePipeline.create_from_checkpoint(
            path_to_checkpoint=full_path_to_checkpoints[0],
            model_config=model_config)
    else:
        inference_pipeline = EnsemblePipeline.create_from_checkpoints(
            path_to_checkpoints=full_path_to_checkpoints,
            model_config=model_config)
    if inference_pipeline is None:
        raise ValueError("Cannot create inference pipeline")

    return inference_pipeline, model_config
def create_inference_pipeline(config: ModelConfigBase,
                              checkpoint_paths: List[Path]) -> Optional[InferencePipelineBase]:
    """
    If multiple checkpoints are found in run_recovery then create EnsemblePipeline otherwise InferencePipeline.
    If no checkpoint files exist in the run recovery or current run checkpoint folder, None will be returned.
    :param config: Model related configs.
    :param epoch: The epoch for which to create pipeline for.
    :param run_recovery: RunRecovery data if applicable
    :return: FullImageInferencePipelineBase or ScalarInferencePipelineBase
    """
    if not checkpoint_paths:
        return None

    if len(checkpoint_paths) > 1:
        if config.is_segmentation_model:
            assert isinstance(config, SegmentationModelBase)
            return EnsemblePipeline.create_from_checkpoints(path_to_checkpoints=checkpoint_paths, model_config=config)
        elif config.is_scalar_model:
            assert isinstance(config, ScalarModelBase)
            return ScalarEnsemblePipeline.create_from_checkpoint(paths_to_checkpoint=checkpoint_paths, config=config)
        else:
            raise NotImplementedError("Cannot create inference pipeline for unknown model type")
    if len(checkpoint_paths) == 1:
        if config.is_segmentation_model:
            assert isinstance(config, SegmentationModelBase)
            return InferencePipeline.create_from_checkpoint(path_to_checkpoint=checkpoint_paths[0],
                                                            model_config=config)
        elif config.is_scalar_model:
            assert isinstance(config, ScalarModelBase)
            return ScalarInferencePipeline.create_from_checkpoint(path_to_checkpoint=checkpoint_paths[0],
                                                                  config=config)
        else:
            raise NotImplementedError("Cannot create ensemble pipeline for unknown model type")
    return None
Exemplo n.º 4
0
def test_aggregate_results() -> None:
    """
    Test to make sure inference results are aggregated as expected
    """
    torch.manual_seed(1)
    num_models = 3
    # set expected posteriors
    model_results = []
    # create results for each model
    for x in range(num_models):
        posteriors = torch.nn.functional.softmax(torch.rand(3, 3, 3, 3),
                                                 dim=0).numpy()
        model_results.append(
            InferencePipeline.Result(
                epoch=0,
                patient_id=0,
                posteriors=posteriors,
                segmentation=posteriors_to_segmentation(posteriors),
                voxel_spacing_mm=(1, 1, 1)))

    # We calculate expected_posteriors before aggregating, as aggregation modifies model_results.
    expected_posteriors = np.mean([x.posteriors for x in model_results],
                                  axis=0)
    ensemble_result = EnsemblePipeline.aggregate_results(
        model_results, aggregation_type=EnsembleAggregationType.Average)

    assert ensemble_result.epoch == model_results[0].epoch
    assert ensemble_result.patient_id == model_results[0].patient_id

    assert np.array_equal(ensemble_result.posteriors, expected_posteriors)
    assert np.array_equal(ensemble_result.segmentation,
                          posteriors_to_segmentation(expected_posteriors))
Exemplo n.º 5
0
def inference_identity(
        test_output_dirs: OutputFolderForTests,
        image_size: Any = (4, 5, 8),
        crop_size: Any = (5, 5, 5),
        shrink_by: Any = (0, 0, 0),
        num_classes: int = 5,
        create_mask: bool = True,
        extract_largest_foreground_connected_component: bool = False,
        is_ensemble: bool = False,
        posterior_smoothing_mm: Any = None) -> None:
    """
    Test to make sure inference pipeline is identity preserving, ie: we can recreate deterministic
    model output, ensuring the patching and stitching is robust.
    """
    # fix random seed
    np.random.seed(0)

    ground_truth_ids = list(map(str, range(num_classes)))
    # image to run inference on: The mock model passes the input image through, hence the input
    # image must have as many channels as we have classes (plus background), such that the output is
    # also a valid posterior.
    num_channels = num_classes + 1
    image_channels = np.random.randn(num_channels, *list(image_size))
    # create a random mask if required
    mask = np.round(np.random.uniform(
        size=image_size)).astype(np.int) if create_mask else None
    config = InferenceIdentityModel(shrink_by=shrink_by)
    config.crop_size = crop_size
    config.test_crop_size = crop_size
    config.image_channels = list(map(str, range(num_channels)))
    config.ground_truth_ids = ground_truth_ids
    config.posterior_smoothing_mm = posterior_smoothing_mm

    # We have to set largest_connected_component_foreground_classes after creating the model config,
    # because this parameter is not overridable and hence will not be set by GenericConfig's constructor.
    if extract_largest_foreground_connected_component:
        config.largest_connected_component_foreground_classes = [
            (c, None) for c in ground_truth_ids
        ]
    # set expected posteriors
    expected_posteriors = torch.nn.functional.softmax(
        torch.tensor(image_channels), dim=0).numpy()
    # apply the mask if required
    if mask is not None:
        expected_posteriors = image_util.apply_mask_to_posteriors(
            expected_posteriors, mask)
    if posterior_smoothing_mm is not None:
        expected_posteriors = image_util.gaussian_smooth_posteriors(
            posteriors=expected_posteriors,
            kernel_size_mm=posterior_smoothing_mm,
            voxel_spacing_mm=(1, 1, 1))
    # compute expected segmentation
    expected_segmentation = image_util.posteriors_to_segmentation(
        expected_posteriors)
    if extract_largest_foreground_connected_component:
        largest_component = image_util.extract_largest_foreground_connected_component(
            multi_label_array=expected_segmentation)
        # make sure the test data is accurate by checking if more than one component exists
        assert not np.array_equal(largest_component, expected_segmentation)
        expected_segmentation = largest_component

    # instantiate the model
    checkpoint = test_output_dirs.root_dir / "checkpoint.ckpt"
    create_model_and_store_checkpoint(config, checkpoint_path=checkpoint)

    # create single or ensemble inference pipeline
    inference_pipeline = InferencePipeline.create_from_checkpoint(
        path_to_checkpoint=checkpoint, model_config=config)
    assert inference_pipeline is not None
    full_image_inference_pipeline = EnsemblePipeline([inference_pipeline], config) \
        if is_ensemble else inference_pipeline

    # compute full image inference results
    inference_result = full_image_inference_pipeline \
        .predict_and_post_process_whole_image(image_channels=image_channels, mask=mask, voxel_spacing_mm=(1, 1, 1))

    # Segmentation must have same size as input image
    assert inference_result.segmentation.shape == image_size
    assert inference_result.posteriors.shape == (num_classes +
                                                 1, ) + image_size
    # check that the posteriors and segmentations are as expected. Flatten to a list so that the error
    # messages are more informative.
    assert np.allclose(inference_result.posteriors, expected_posteriors)
    assert np.array_equal(inference_result.segmentation, expected_segmentation)