Exemplo n.º 1
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def _convert_mmdet_result(result, shape: Tuple[int, int]) -> Instances:
    if isinstance(result, tuple):
        bbox_result, segm_result = result
        if isinstance(segm_result, tuple):
            segm_result = segm_result[0]
    else:
        bbox_result, segm_result = result, None

    bboxes = torch.from_numpy(np.vstack(bbox_result))  # Nx5
    bboxes, scores = bboxes[:, :4], bboxes[:, -1]
    labels = [
        torch.full((bbox.shape[0], ), i, dtype=torch.int32)
        for i, bbox in enumerate(bbox_result)
    ]
    labels = torch.cat(labels)
    inst = Instances(shape)
    inst.pred_boxes = Boxes(bboxes)
    inst.scores = scores
    inst.pred_classes = labels

    if segm_result is not None and len(labels) > 0:
        segm_result = list(itertools.chain(*segm_result))
        segm_result = [
            torch.from_numpy(x) if isinstance(x, np.ndarray) else x
            for x in segm_result
        ]
        segm_result = torch.stack(segm_result, dim=0)
        inst.pred_masks = segm_result
    return inst
Exemplo n.º 2
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    def label_and_sample_anchors(
        self, anchors: List[Boxes], gt_instances: List[Instances]
    ) -> Tuple[List[torch.Tensor], List[torch.Tensor]]:
        """
        Args:
            anchors (list[Boxes]): anchors for each feature map.
            gt_instances: the ground-truth instances for each image.

        Returns:
            list[Tensor]:
                List of #img tensors. i-th element is a vector of labels whose length is
                the total number of anchors across all feature maps R = sum(Hi * Wi * A).
                Label values are in {-1, 0, 1}, with meanings: -1 = ignore; 0 = negative
                class; 1 = positive class.
            list[Tensor]:
                i-th element is a Rx4 tensor. The values are the matched gt boxes for each
                anchor. Values are undefined for those anchors not labeled as 1.
        """
        anchors = Boxes.cat(anchors)

        gt_boxes = [x.gt_boxes for x in gt_instances]
        image_sizes = [x.image_size for x in gt_instances]
        del gt_instances

        gt_labels = []
        matched_gt_boxes = []
        for image_size_i, gt_boxes_i in zip(image_sizes, gt_boxes):
            """
            image_size_i: (h, w) for the i-th image
            gt_boxes_i: ground-truth boxes for i-th image
            """

            match_quality_matrix = retry_if_cuda_oom(pairwise_iou)(gt_boxes_i,
                                                                   anchors)
            matched_idxs, gt_labels_i = retry_if_cuda_oom(
                self.anchor_matcher)(match_quality_matrix)
            # Matching is memory-expensive and may result in CPU tensors. But the result is small
            gt_labels_i = gt_labels_i.to(device=gt_boxes_i.device)
            del match_quality_matrix

            if self.anchor_boundary_thresh >= 0:
                # Discard anchors that go out of the boundaries of the image
                # NOTE: This is legacy functionality that is turned off by default in Detectron2
                anchors_inside_image = anchors.inside_box(
                    image_size_i, self.anchor_boundary_thresh)
                gt_labels_i[~anchors_inside_image] = -1

            # A vector of labels (-1, 0, 1) for each anchor
            gt_labels_i = self._subsample_labels(gt_labels_i)

            if len(gt_boxes_i) == 0:
                # These values won't be used anyway since the anchor is labeled as background
                matched_gt_boxes_i = torch.zeros_like(anchors.tensor)
            else:
                # TODO wasted indexing computation for ignored boxes
                matched_gt_boxes_i = gt_boxes_i[matched_idxs].tensor

            gt_labels.append(gt_labels_i)  # N,AHW
            matched_gt_boxes.append(matched_gt_boxes_i)
        return gt_labels, matched_gt_boxes
Exemplo n.º 3
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def transform_proposals(dataset_dict,
                        image_shape,
                        transforms,
                        *,
                        proposal_topk,
                        min_box_size=0):
    """
    Apply transformations to the proposals in dataset_dict, if any.

    Args:
        dataset_dict (dict): a dict read from the dataset, possibly
            contains fields "proposal_boxes", "proposal_objectness_logits", "proposal_bbox_mode"
        image_shape (tuple): height, width
        transforms (TransformList):
        proposal_topk (int): only keep top-K scoring proposals
        min_box_size (int): proposals with either side smaller than this
            threshold are removed

    The input dict is modified in-place, with abovementioned keys removed. A new
    key "proposals" will be added. Its value is an `Instances`
    object which contains the transformed proposals in its field
    "proposal_boxes" and "objectness_logits".
    """
    if "proposal_boxes" in dataset_dict:
        # Transform proposal boxes
        boxes = transforms.apply_box(
            BoxMode.convert(
                dataset_dict.pop("proposal_boxes"),
                dataset_dict.pop("proposal_bbox_mode"),
                BoxMode.XYXY_ABS,
            ))
        boxes = Boxes(boxes)
        objectness_logits = torch.as_tensor(
            dataset_dict.pop("proposal_objectness_logits").astype("float32"))

        boxes.clip(image_shape)
        keep = boxes.nonempty(threshold=min_box_size)
        boxes = boxes[keep]
        objectness_logits = objectness_logits[keep]

        proposals = Instances(image_shape)
        proposals.proposal_boxes = boxes[:proposal_topk]
        proposals.objectness_logits = objectness_logits[:proposal_topk]
        dataset_dict["proposals"] = proposals
Exemplo n.º 4
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def fast_rcnn_inference_single_image(
    boxes,
    scores,
    image_shape: Tuple[int, int],
    score_thresh: float,
    nms_thresh: float,
    topk_per_image: int,
):
    """
    Single-image inference. Return bounding-box detection results by thresholding
    on scores and applying non-maximum suppression (NMS).

    Args:
        Same as `fast_rcnn_inference`, but with boxes, scores, and image shapes
        per image.

    Returns:
        Same as `fast_rcnn_inference`, but for only one image.
    """
    valid_mask = torch.isfinite(boxes).all(dim=1) & torch.isfinite(scores).all(
        dim=1)
    if not valid_mask.all():
        boxes = boxes[valid_mask]
        scores = scores[valid_mask]

    scores = scores[:, :-1]
    num_bbox_reg_classes = boxes.shape[1] // 4
    # Convert to Boxes to use the `clip` function ...
    boxes = Boxes(boxes.reshape(-1, 4))
    boxes.clip(image_shape)
    boxes = boxes.tensor.view(-1, num_bbox_reg_classes, 4)  # R x C x 4

    # 1. Filter results based on detection scores. It can make NMS more efficient
    #    by filtering out low-confidence detections.
    filter_mask = scores > score_thresh  # R x K
    # R' x 2. First column contains indices of the R predictions;
    # Second column contains indices of classes.
    #filter_inds = filter_mask.nonzero()
    filter_inds = torch.nonzero(filter_mask)
    #print("filterzero")
    #filter_inds = torch.nonzero(filter_mask, as_tuple=True)

    if num_bbox_reg_classes == 1:
        boxes = boxes[filter_inds[:, 0], 0]
    else:
        boxes = boxes[filter_mask]
    scores = scores[filter_mask]

    # 2. Apply NMS for each class independently.
    keep = batched_nms(boxes, scores, filter_inds[:, 1], nms_thresh)
    if topk_per_image >= 0:
        keep = keep[:topk_per_image]
    boxes, scores, filter_inds = boxes[keep], scores[keep], filter_inds[keep]

    result = Instances(image_shape)
    result.pred_boxes = Boxes(boxes)
    result.scores = scores
    result.pred_classes = filter_inds[:, 1]
    return result, filter_inds[:, 0]
Exemplo n.º 5
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    def forward(self, features: List[torch.Tensor]):
        """
        Args:
            features (list[Tensor]): list of backbone feature maps on which to generate anchors.

        Returns:
            list[Boxes]: a list of Boxes containing all the anchors for each feature map
                (i.e. the cell anchors repeated over all locations in the feature map).
                The number of anchors of each feature map is Hi x Wi x num_cell_anchors,
                where Hi, Wi are resolution of the feature map divided by anchor stride.
        """
        grid_sizes = [feature_map.shape[-2:] for feature_map in features]
        anchors_over_all_feature_maps = self._grid_anchors(grid_sizes)
        return [Boxes(x) for x in anchors_over_all_feature_maps]
Exemplo n.º 6
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 def _uniform_sample_train_points(self, instances):
     assert self.training
     proposal_boxes = [x.proposal_boxes for x in instances]
     cat_boxes = Boxes.cat(proposal_boxes)
     # uniform sample
     point_coords = torch.rand(len(cat_boxes),
                               self.mask_point_train_num_points,
                               2,
                               device=cat_boxes.tensor.device)
     # sample point_labels
     point_coords_wrt_image = get_point_coords_wrt_image(
         cat_boxes.tensor, point_coords)
     point_labels = sample_point_labels(instances, point_coords_wrt_image)
     return point_coords, point_labels
Exemplo n.º 7
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    def _match_and_label_boxes(self, proposals, stage, targets):
        """
        Match proposals with groundtruth using the matcher at the given stage.
        Label the proposals as foreground or background based on the match.

        Args:
            proposals (list[Instances]): One Instances for each image, with
                the field "proposal_boxes".
            stage (int): the current stage
            targets (list[Instances]): the ground truth instances

        Returns:
            list[Instances]: the same proposals, but with fields "gt_classes" and "gt_boxes"
        """
        num_fg_samples, num_bg_samples = [], []
        for proposals_per_image, targets_per_image in zip(proposals, targets):
            match_quality_matrix = pairwise_iou(
                targets_per_image.gt_boxes, proposals_per_image.proposal_boxes)
            # proposal_labels are 0 or 1
            matched_idxs, proposal_labels = self.proposal_matchers[stage](
                match_quality_matrix)
            if len(targets_per_image) > 0:
                gt_classes = targets_per_image.gt_classes[matched_idxs]
                # Label unmatched proposals (0 label from matcher) as background (label=num_classes)
                gt_classes[proposal_labels == 0] = self.num_classes
                gt_boxes = targets_per_image.gt_boxes[matched_idxs]
            else:
                gt_classes = torch.zeros_like(matched_idxs) + self.num_classes
                gt_boxes = Boxes(
                    targets_per_image.gt_boxes.tensor.new_zeros(
                        (len(proposals_per_image), 4)))
            proposals_per_image.gt_classes = gt_classes
            proposals_per_image.gt_boxes = gt_boxes

            num_fg_samples.append((proposal_labels == 1).sum().item())
            num_bg_samples.append(proposal_labels.numel() - num_fg_samples[-1])

        # Log the number of fg/bg samples in each stage
        storage = get_event_storage()
        storage.put_scalar(
            "stage{}/roi_head/num_fg_samples".format(stage),
            sum(num_fg_samples) / len(num_fg_samples),
        )
        storage.put_scalar(
            "stage{}/roi_head/num_bg_samples".format(stage),
            sum(num_bg_samples) / len(num_bg_samples),
        )
        return proposals
Exemplo n.º 8
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    def _rescale_detected_boxes(self, augmented_inputs, merged_instances,
                                tfms):
        augmented_instances = []
        for input, tfm in zip(augmented_inputs, tfms):
            # Transform the target box to the augmented image's coordinate space
            pred_boxes = merged_instances.pred_boxes.tensor.cpu().numpy()
            pred_boxes = torch.from_numpy(tfm.apply_box(pred_boxes))

            aug_instances = Instances(
                image_size=input["image"].shape[1:3],
                pred_boxes=Boxes(pred_boxes),
                pred_classes=merged_instances.pred_classes,
                scores=merged_instances.scores,
            )
            augmented_instances.append(aug_instances)
        return augmented_instances
Exemplo n.º 9
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def point_sample_fine_grained_features(features_list, feature_scales, boxes,
                                       point_coords):
    """
    Get features from feature maps in `features_list` that correspond to specific point coordinates
        inside each bounding box from `boxes`.

    Args:
        features_list (list[Tensor]): A list of feature map tensors to get features from.
        feature_scales (list[float]): A list of scales for tensors in `features_list`.
        boxes (list[Boxes]): A list of I Boxes  objects that contain R_1 + ... + R_I = R boxes all
            together.
        point_coords (Tensor): A tensor of shape (R, P, 2) that contains
            [0, 1] x [0, 1] box-normalized coordinates of the P sampled points.

    Returns:
        point_features (Tensor): A tensor of shape (R, C, P) that contains features sampled
            from all features maps in feature_list for P sampled points for all R boxes in `boxes`.
        point_coords_wrt_image (Tensor): A tensor of shape (R, P, 2) that contains image-level
            coordinates of P points.
    """
    cat_boxes = Boxes.cat(boxes)
    num_boxes = [b.tensor.size(0) for b in boxes]

    point_coords_wrt_image = get_point_coords_wrt_image(
        cat_boxes.tensor, point_coords)
    split_point_coords_wrt_image = torch.split(point_coords_wrt_image,
                                               num_boxes)

    point_features = []
    for idx_img, point_coords_wrt_image_per_image in enumerate(
            split_point_coords_wrt_image):
        point_features_per_image = []
        for idx_feature, feature_map in enumerate(features_list):
            h, w = feature_map.shape[-2:]
            scale = _as_tensor([w, h]) / feature_scales[idx_feature]
            point_coords_scaled = point_coords_wrt_image_per_image / scale.to(
                feature_map.device)
            point_features_per_image.append(
                point_sample(
                    feature_map[idx_img].unsqueeze(0),
                    point_coords_scaled.unsqueeze(0),
                    align_corners=False,
                ).squeeze(0).transpose(1, 0))
        point_features.append(cat(point_features_per_image, dim=1))

    return cat(point_features, dim=0), point_coords_wrt_image
Exemplo n.º 10
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 def _sample_train_points(self, coarse_mask, instances):
     assert self.training
     gt_classes = cat([x.gt_classes for x in instances])
     with torch.no_grad():
         # sample point_coords
         point_coords = get_uncertain_point_coords_with_randomness(
             coarse_mask,
             lambda logits: calculate_uncertainty(logits, gt_classes),
             self.mask_point_train_num_points,
             self.mask_point_oversample_ratio,
             self.mask_point_importance_sample_ratio,
         )
         # sample point_labels
         proposal_boxes = [x.proposal_boxes for x in instances]
         cat_boxes = Boxes.cat(proposal_boxes)
         point_coords_wrt_image = get_point_coords_wrt_image(
             cat_boxes.tensor, point_coords)
         point_labels = sample_point_labels(instances,
                                            point_coords_wrt_image)
     return point_coords, point_labels
Exemplo n.º 11
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    def _forward_box(self, features: Dict[str, torch.Tensor],
                     proposals: List[Instances]):
        """
        Forward logic of the box prediction branch. If `self.train_on_pred_boxes is True`,
            the function puts predicted boxes in the `proposal_boxes` field of `proposals` argument.

        Args:
            features (dict[str, Tensor]): mapping from feature map names to tensor.
                Same as in :meth:`ROIHeads.forward`.
            proposals (list[Instances]): the per-image object proposals with
                their matching ground truth.
                Each has fields "proposal_boxes", and "objectness_logits",
                "gt_classes", "gt_boxes".

        Returns:
            In training, a dict of losses.
            In inference, a list of `Instances`, the predicted instances.
        """
        features = [features[f] for f in self.box_in_features]
        box_features = self.box_pooler(features,
                                       [x.proposal_boxes for x in proposals])
        box_features = self.box_head(box_features)
        predictions = self.box_predictor(box_features)
        del box_features

        if self.training:
            losses = self.box_predictor.losses(predictions, proposals)
            # proposals is modified in-place below, so losses must be computed first.
            if self.train_on_pred_boxes:
                with torch.no_grad():
                    pred_boxes = self.box_predictor.predict_boxes_for_gt_classes(
                        predictions, proposals)
                    for proposals_per_image, pred_boxes_per_image in zip(
                            proposals, pred_boxes):
                        proposals_per_image.proposal_boxes = Boxes(
                            pred_boxes_per_image)
            return losses
        else:
            pred_instances, _ = self.box_predictor.inference(
                predictions, proposals)
            return pred_instances
Exemplo n.º 12
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    def _create_proposals_from_boxes(self, boxes, image_sizes):
        """
        Args:
            boxes (list[Tensor]): per-image predicted boxes, each of shape Ri x 4
            image_sizes (list[tuple]): list of image shapes in (h, w)

        Returns:
            list[Instances]: per-image proposals with the given boxes.
        """
        # Just like RPN, the proposals should not have gradients
        boxes = [Boxes(b.detach()) for b in boxes]
        proposals = []
        for boxes_per_image, image_size in zip(boxes, image_sizes):
            boxes_per_image.clip(image_size)
            if self.training:
                # do not filter empty boxes at inference time,
                # because the scores from each stage need to be aligned and added later
                boxes_per_image = boxes_per_image[boxes_per_image.nonempty()]
            prop = Instances(image_size)
            prop.proposal_boxes = boxes_per_image
            proposals.append(prop)
        return proposals
Exemplo n.º 13
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def convert_to_coco_dict(dataset_name):
    """
    Convert an instance detection/segmentation or keypoint detection dataset
    in detectron2's standard format into COCO json format.

    Generic dataset description can be found here:
    https://detectron2.readthedocs.io/tutorials/datasets.html#register-a-dataset

    COCO data format description can be found here:
    http://cocodataset.org/#format-data

    Args:
        dataset_name (str):
            name of the source dataset
            Must be registered in DatastCatalog and in detectron2's standard format.
            Must have corresponding metadata "thing_classes"
    Returns:
        coco_dict: serializable dict in COCO json format
    """

    dataset_dicts = DatasetCatalog.get(dataset_name)
    metadata = MetadataCatalog.get(dataset_name)

    # unmap the category mapping ids for COCO
    if hasattr(metadata, "thing_dataset_id_to_contiguous_id"):
        reverse_id_mapping = {
            v: k
            for k, v in metadata.thing_dataset_id_to_contiguous_id.items()
        }
        reverse_id_mapper = lambda contiguous_id: reverse_id_mapping[
            contiguous_id]  # noqa
    else:
        reverse_id_mapper = lambda contiguous_id: contiguous_id  # noqa

    categories = [{
        "id": reverse_id_mapper(id),
        "name": name
    } for id, name in enumerate(metadata.thing_classes)]

    logger.info("Converting dataset dicts into COCO format")
    coco_images = []
    coco_annotations = []

    for image_id, image_dict in enumerate(dataset_dicts):
        coco_image = {
            "id": image_dict.get("image_id", image_id),
            "width": int(image_dict["width"]),
            "height": int(image_dict["height"]),
            "file_name": str(image_dict["file_name"]),
        }
        coco_images.append(coco_image)

        anns_per_image = image_dict.get("annotations", [])
        for annotation in anns_per_image:
            # create a new dict with only COCO fields
            coco_annotation = {}

            # COCO requirement: XYWH box format for axis-align and XYWHA for rotated
            bbox = annotation["bbox"]
            if isinstance(bbox, np.ndarray):
                if bbox.ndim != 1:
                    raise ValueError(
                        f"bbox has to be 1-dimensional. Got shape={bbox.shape}."
                    )
                bbox = bbox.tolist()
            if len(bbox) not in [4, 5]:
                raise ValueError(f"bbox has to has length 4 or 5. Got {bbox}.")
            from_bbox_mode = annotation["bbox_mode"]
            to_bbox_mode = BoxMode.XYWH_ABS if len(
                bbox) == 4 else BoxMode.XYWHA_ABS
            bbox = BoxMode.convert(bbox, from_bbox_mode, to_bbox_mode)

            # COCO requirement: instance area
            if "segmentation" in annotation:
                # Computing areas for instances by counting the pixels
                segmentation = annotation["segmentation"]
                # TODO: check segmentation type: RLE, BinaryMask or Polygon
                if isinstance(segmentation, list):
                    polygons = PolygonMasks([segmentation])
                    area = polygons.area()[0].item()
                elif isinstance(segmentation, dict):  # RLE
                    area = mask_util.area(segmentation).item()
                else:
                    raise TypeError(
                        f"Unknown segmentation type {type(segmentation)}!")
            else:
                # Computing areas using bounding boxes
                if to_bbox_mode == BoxMode.XYWH_ABS:
                    bbox_xy = BoxMode.convert(bbox, to_bbox_mode,
                                              BoxMode.XYXY_ABS)
                    area = Boxes([bbox_xy]).area()[0].item()
                else:
                    area = RotatedBoxes([bbox]).area()[0].item()

            if "keypoints" in annotation:
                keypoints = annotation["keypoints"]  # list[int]
                for idx, v in enumerate(keypoints):
                    if idx % 3 != 2:
                        # COCO's segmentation coordinates are floating points in [0, H or W],
                        # but keypoint coordinates are integers in [0, H-1 or W-1]
                        # For COCO format consistency we substract 0.5
                        # https://github.com/facebookresearch/detectron2/pull/175#issuecomment-551202163
                        keypoints[idx] = v - 0.5
                if "num_keypoints" in annotation:
                    num_keypoints = annotation["num_keypoints"]
                else:
                    num_keypoints = sum(kp > 0 for kp in keypoints[2::3])

            # COCO requirement:
            #   linking annotations to images
            #   "id" field must start with 1
            coco_annotation["id"] = len(coco_annotations) + 1
            coco_annotation["image_id"] = coco_image["id"]
            coco_annotation["bbox"] = [round(float(x), 3) for x in bbox]
            coco_annotation["area"] = float(area)
            coco_annotation["iscrowd"] = int(annotation.get("iscrowd", 0))
            coco_annotation["category_id"] = int(
                reverse_id_mapper(annotation["category_id"]))

            # Add optional fields
            if "keypoints" in annotation:
                coco_annotation["keypoints"] = keypoints
                coco_annotation["num_keypoints"] = num_keypoints

            if "segmentation" in annotation:
                seg = coco_annotation["segmentation"] = annotation[
                    "segmentation"]
                if isinstance(seg, dict):  # RLE
                    counts = seg["counts"]
                    if not isinstance(counts, str):
                        # make it json-serializable
                        seg["counts"] = counts.decode("ascii")

            coco_annotations.append(coco_annotation)

    logger.info(
        "Conversion finished, "
        f"#images: {len(coco_images)}, #annotations: {len(coco_annotations)}")

    info = {
        "date_created": str(datetime.datetime.now()),
        "description":
        "Automatically generated COCO json file for Detectron2.",
    }
    coco_dict = {
        "info": info,
        "images": coco_images,
        "categories": categories,
        "licenses": None
    }
    if len(coco_annotations) > 0:
        coco_dict["annotations"] = coco_annotations
    return coco_dict
Exemplo n.º 14
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def find_top_rpn_proposals(
    proposals: List[torch.Tensor],
    pred_objectness_logits: List[torch.Tensor],
    image_sizes: List[Tuple[int, int]],
    nms_thresh: float,
    pre_nms_topk: int,
    post_nms_topk: int,
    min_box_size: float,
    training: bool,
):
    """
    For each feature map, select the `pre_nms_topk` highest scoring proposals,
    apply NMS, clip proposals, and remove small boxes. Return the `post_nms_topk`
    highest scoring proposals among all the feature maps for each image.

    Args:
        proposals (list[Tensor]): A list of L tensors. Tensor i has shape (N, Hi*Wi*A, 4).
            All proposal predictions on the feature maps.
        pred_objectness_logits (list[Tensor]): A list of L tensors. Tensor i has shape (N, Hi*Wi*A).
        image_sizes (list[tuple]): sizes (h, w) for each image
        nms_thresh (float): IoU threshold to use for NMS
        pre_nms_topk (int): number of top k scoring proposals to keep before applying NMS.
            When RPN is run on multiple feature maps (as in FPN) this number is per
            feature map.
        post_nms_topk (int): number of top k scoring proposals to keep after applying NMS.
            When RPN is run on multiple feature maps (as in FPN) this number is total,
            over all feature maps.
        min_box_size (float): minimum proposal box side length in pixels (absolute units
            wrt input images).
        training (bool): True if proposals are to be used in training, otherwise False.
            This arg exists only to support a legacy bug; look for the "NB: Legacy bug ..."
            comment.

    Returns:
        list[Instances]: list of N Instances. The i-th Instances
            stores post_nms_topk object proposals for image i, sorted by their
            objectness score in descending order.
    """
    num_images = len(image_sizes)
    device = proposals[0].device

    # 1. Select top-k anchor for every level and every image
    topk_scores = []  # #lvl Tensor, each of shape N x topk
    topk_proposals = []
    level_ids = []  # #lvl Tensor, each of shape (topk,)
    batch_idx = torch.arange(num_images, device=device)
    for level_id, (proposals_i, logits_i) in enumerate(
            zip(proposals, pred_objectness_logits)):
        Hi_Wi_A = logits_i.shape[1]
        if isinstance(Hi_Wi_A, torch.Tensor):  # it's a tensor in tracing
            num_proposals_i = torch.clamp(Hi_Wi_A, max=pre_nms_topk)
        else:
            num_proposals_i = min(Hi_Wi_A, pre_nms_topk)

        # sort is faster than topk: https://github.com/pytorch/pytorch/issues/22812
        # topk_scores_i, topk_idx = logits_i.topk(num_proposals_i, dim=1)
        logits_i, idx = logits_i.sort(descending=True, dim=1)
        topk_scores_i = logits_i.narrow(1, 0, num_proposals_i)
        topk_idx = idx.narrow(1, 0, num_proposals_i)

        # each is N x topk
        topk_proposals_i = proposals_i[batch_idx[:, None],
                                       topk_idx]  # N x topk x 4

        topk_proposals.append(topk_proposals_i)
        topk_scores.append(topk_scores_i)
        level_ids.append(
            torch.full((num_proposals_i, ),
                       level_id,
                       dtype=torch.int64,
                       device=device))

    # 2. Concat all levels together
    topk_scores = cat(topk_scores, dim=1)
    topk_proposals = cat(topk_proposals, dim=1)
    level_ids = cat(level_ids, dim=0)

    # 3. For each image, run a per-level NMS, and choose topk results.
    results: List[Instances] = []
    for n, image_size in enumerate(image_sizes):
        boxes = Boxes(topk_proposals[n])
        scores_per_img = topk_scores[n]
        lvl = level_ids

        valid_mask = torch.isfinite(
            boxes.tensor).all(dim=1) & torch.isfinite(scores_per_img)
        if not valid_mask.all():
            if training:
                raise FloatingPointError(
                    "Predicted boxes or scores contain Inf/NaN. Training has diverged."
                )
            boxes = boxes[valid_mask]
            scores_per_img = scores_per_img[valid_mask]
            lvl = lvl[valid_mask]
        boxes.clip(image_size)

        # filter empty boxes
        keep = boxes.nonempty(threshold=min_box_size)
        if _is_tracing() or keep.sum().item() != len(boxes):
            boxes, scores_per_img, lvl = boxes[keep], scores_per_img[
                keep], lvl[keep]

        keep = batched_nms(boxes.tensor, scores_per_img, lvl, nms_thresh)
        # In Detectron1, there was different behavior during training vs. testing.
        # (https://github.com/facebookresearch/Detectron/issues/459)
        # During training, topk is over the proposals from *all* images in the training batch.
        # During testing, it is over the proposals for each image separately.
        # As a result, the training behavior becomes batch-dependent,
        # and the configuration "POST_NMS_TOPK_TRAIN" end up relying on the batch size.
        # This bug is addressed in Detectron2 to make the behavior independent of batch size.
        keep = keep[:post_nms_topk]  # keep is already sorted

        res = Instances(image_size)
        res.proposal_boxes = boxes[keep]
        res.objectness_logits = scores_per_img[keep]
        results.append(res)
    return results
Exemplo n.º 15
0
    def __init__(
        self,
        box2box_transform,
        pred_class_logits,
        pred_proposal_deltas,
        proposals,
        smooth_l1_beta=0.0,
        box_reg_loss_type="smooth_l1",
    ):
        """
        Args:
            box2box_transform (Box2BoxTransform/Box2BoxTransformRotated):
                box2box transform instance for proposal-to-detection transformations.
            pred_class_logits (Tensor): A tensor of shape (R, K + 1) storing the predicted class
                logits for all R predicted object instances.
                Each row corresponds to a predicted object instance.
            pred_proposal_deltas (Tensor): A tensor of shape (R, K * B) or (R, B) for
                class-specific or class-agnostic regression. It stores the predicted deltas that
                transform proposals into final box detections.
                B is the box dimension (4 or 5).
                When B is 4, each row is [dx, dy, dw, dh (, ....)].
                When B is 5, each row is [dx, dy, dw, dh, da (, ....)].
            proposals (list[Instances]): A list of N Instances, where Instances i stores the
                proposals for image i, in the field "proposal_boxes".
                When training, each Instances must have ground-truth labels
                stored in the field "gt_classes" and "gt_boxes".
                The total number of all instances must be equal to R.
            smooth_l1_beta (float): The transition point between L1 and L2 loss in
                the smooth L1 loss function. When set to 0, the loss becomes L1. When
                set to +inf, the loss becomes constant 0.
            box_reg_loss_type (str): Box regression loss type. One of: "smooth_l1", "giou"
        """
        self.box2box_transform = box2box_transform
        self.num_preds_per_image = [len(p) for p in proposals]
        self.pred_class_logits = pred_class_logits
        self.pred_proposal_deltas = pred_proposal_deltas
        self.smooth_l1_beta = smooth_l1_beta
        self.box_reg_loss_type = box_reg_loss_type

        self.image_shapes = [x.image_size for x in proposals]

        if len(proposals):
            box_type = type(proposals[0].proposal_boxes)
            # cat(..., dim=0) concatenates over all images in the batch
            self.proposals = box_type.cat(
                [p.proposal_boxes for p in proposals])
            assert (not self.proposals.tensor.requires_grad
                    ), "Proposals should not require gradients!"

            # "gt_classes" exists if and only if training. But other gt fields may
            # not necessarily exist in training for images that have no groundtruth.
            if proposals[0].has("gt_classes"):
                self.gt_classes = cat([p.gt_classes for p in proposals], dim=0)

                # If "gt_boxes" does not exist, the proposals must be all negative and
                # should not be included in regression loss computation.
                # Here we just use proposal_boxes as an arbitrary placeholder because its
                # value won't be used in self.box_reg_loss().
                gt_boxes = [
                    p.gt_boxes if p.has("gt_boxes") else p.proposal_boxes
                    for p in proposals
                ]
                self.gt_boxes = box_type.cat(gt_boxes)
        else:
            self.proposals = Boxes(
                torch.zeros(0, 4, device=self.pred_proposal_deltas.device))
        self._no_instances = len(self.proposals) == 0  # no instances found
Exemplo n.º 16
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def annotations_to_instances(annos, image_size, mask_format="polygon"):
    """
    Create an :class:`Instances` object used by the models,
    from instance annotations in the dataset dict.

    Args:
        annos (list[dict]): a list of instance annotations in one image, each
            element for one instance.
        image_size (tuple): height, width

    Returns:
        Instances:
            It will contain fields "gt_boxes", "gt_classes",
            "gt_masks", "gt_keypoints", if they can be obtained from `annos`.
            This is the format that builtin models expect.
    """
    boxes = [
        BoxMode.convert(obj["bbox"], obj["bbox_mode"], BoxMode.XYXY_ABS)
        for obj in annos
    ]
    target = Instances(image_size)
    target.gt_boxes = Boxes(boxes)

    classes = [int(obj["category_id"]) for obj in annos]
    classes = torch.tensor(classes, dtype=torch.int64)
    target.gt_classes = classes

    if len(annos) and "segmentation" in annos[0]:
        segms = [obj["segmentation"] for obj in annos]
        if mask_format == "polygon":
            try:
                masks = PolygonMasks(segms)
            except ValueError as e:
                raise ValueError(
                    "Failed to use mask_format=='polygon' from the given annotations!"
                ) from e
        else:
            assert mask_format == "bitmask", mask_format
            masks = []
            for segm in segms:
                if isinstance(segm, list):
                    # polygon
                    masks.append(polygons_to_bitmask(segm, *image_size))
                elif isinstance(segm, dict):
                    # COCO RLE
                    masks.append(mask_util.decode(segm))
                elif isinstance(segm, np.ndarray):
                    assert segm.ndim == 2, "Expect segmentation of 2 dimensions, got {}.".format(
                        segm.ndim)
                    # mask array
                    masks.append(segm)
                else:
                    raise ValueError(
                        "Cannot convert segmentation of type '{}' to BitMasks!"
                        "Supported types are: polygons as list[list[float] or ndarray],"
                        " COCO-style RLE as a dict, or a binary segmentation mask "
                        " in a 2D numpy array of shape HxW.".format(
                            type(segm)))
            # torch.from_numpy does not support array with negative stride.
            masks = BitMasks(
                torch.stack([
                    torch.from_numpy(np.ascontiguousarray(x)) for x in masks
                ]))
        target.gt_masks = masks

    if len(annos) and "keypoints" in annos[0]:
        kpts = [obj.get("keypoints", []) for obj in annos]
        target.gt_keypoints = Keypoints(kpts)

    return target
Exemplo n.º 17
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def _evaluate_box_proposals(dataset_predictions, coco_api, thresholds=None, area="all", limit=None):
    """
    Evaluate detection proposal recall metrics. This function is a much
    faster alternative to the official COCO API recall evaluation code. However,
    it produces slightly different results.
    """
    # Record max overlap value for each gt box
    # Return vector of overlap values
    areas = {
        "all": 0,
        "small": 1,
        "medium": 2,
        "large": 3,
        "96-128": 4,
        "128-256": 5,
        "256-512": 6,
        "512-inf": 7,
    }
    area_ranges = [
        [0 ** 2, 1e5 ** 2],  # all
        [0 ** 2, 32 ** 2],  # small
        [32 ** 2, 96 ** 2],  # medium
        [96 ** 2, 1e5 ** 2],  # large
        [96 ** 2, 128 ** 2],  # 96-128
        [128 ** 2, 256 ** 2],  # 128-256
        [256 ** 2, 512 ** 2],  # 256-512
        [512 ** 2, 1e5 ** 2],
    ]  # 512-inf
    assert area in areas, "Unknown area range: {}".format(area)
    area_range = area_ranges[areas[area]]
    gt_overlaps = []
    num_pos = 0

    for prediction_dict in dataset_predictions:
        predictions = prediction_dict["proposals"]

        # sort predictions in descending order
        # TODO maybe remove this and make it explicit in the documentation
        inds = predictions.objectness_logits.sort(descending=True)[1]
        predictions = predictions[inds]

        ann_ids = coco_api.getAnnIds(imgIds=prediction_dict["image_id"])
        anno = coco_api.loadAnns(ann_ids)
        gt_boxes = [
            BoxMode.convert(obj["bbox"], BoxMode.XYWH_ABS, BoxMode.XYXY_ABS)
            for obj in anno
            if obj["iscrowd"] == 0
        ]
        gt_boxes = torch.as_tensor(gt_boxes).reshape(-1, 4)  # guard against no boxes
        gt_boxes = Boxes(gt_boxes)
        gt_areas = torch.as_tensor([obj["area"] for obj in anno if obj["iscrowd"] == 0])

        if len(gt_boxes) == 0 or len(predictions) == 0:
            continue

        valid_gt_inds = (gt_areas >= area_range[0]) & (gt_areas <= area_range[1])
        gt_boxes = gt_boxes[valid_gt_inds]

        num_pos += len(gt_boxes)

        if len(gt_boxes) == 0:
            continue

        if limit is not None and len(predictions) > limit:
            predictions = predictions[:limit]

        overlaps = pairwise_iou(predictions.proposal_boxes, gt_boxes)

        _gt_overlaps = torch.zeros(len(gt_boxes))
        for j in range(min(len(predictions), len(gt_boxes))):
            # find which proposal box maximally covers each gt box
            # and get the iou amount of coverage for each gt box
            max_overlaps, argmax_overlaps = overlaps.max(dim=0)

            # find which gt box is 'best' covered (i.e. 'best' = most iou)
            gt_ovr, gt_ind = max_overlaps.max(dim=0)
            assert gt_ovr >= 0
            # find the proposal box that covers the best covered gt box
            box_ind = argmax_overlaps[gt_ind]
            # record the iou coverage of this gt box
            _gt_overlaps[j] = overlaps[box_ind, gt_ind]
            assert _gt_overlaps[j] == gt_ovr
            # mark the proposal box and the gt box as used
            overlaps[box_ind, :] = -1
            overlaps[:, gt_ind] = -1

        # append recorded iou coverage level
        gt_overlaps.append(_gt_overlaps)
    gt_overlaps = (
        torch.cat(gt_overlaps, dim=0) if len(gt_overlaps) else torch.zeros(0, dtype=torch.float32)
    )
    gt_overlaps, _ = torch.sort(gt_overlaps)

    if thresholds is None:
        step = 0.05
        thresholds = torch.arange(0.5, 0.95 + 1e-5, step, dtype=torch.float32)
    recalls = torch.zeros_like(thresholds)
    # compute recall for each iou threshold
    for i, t in enumerate(thresholds):
        recalls[i] = (gt_overlaps >= t).float().sum() / float(num_pos)
    # ar = 2 * np.trapz(recalls, thresholds)
    ar = recalls.mean()
    return {
        "ar": ar,
        "recalls": recalls,
        "thresholds": thresholds,
        "gt_overlaps": gt_overlaps,
        "num_pos": num_pos,
    }