コード例 #1
0
ファイル: inference.py プロジェクト: akobiisr/wetectron
    def forward(self, anchors, objectness, box_regression, targets=None):
        """
        Arguments:
            anchors: list[list[BoxList]]
            objectness: list[tensor]
            box_regression: list[tensor]

        Returns:
            boxlists (list[BoxList]): the post-processed anchors, after
                applying box decoding and NMS
        """
        sampled_boxes = []
        num_levels = len(objectness)
        anchors = list(zip(*anchors))
        for a, o, b in zip(anchors, objectness, box_regression):
            sampled_boxes.append(self.forward_for_single_feature_map(a, o, b))

        boxlists = list(zip(*sampled_boxes))
        boxlists = [cat_boxlist(boxlist) for boxlist in boxlists]

        if num_levels > 1:
            boxlists = self.select_over_all_levels(boxlists)

        # append ground-truth bboxes to proposals
        if self.training and targets is not None:
            boxlists = self.add_gt_proposals(boxlists, targets)

        return boxlists
コード例 #2
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def cat_boxlist_with_keypoints(boxlists):
    assert all(boxlist.has_field("keypoints") for boxlist in boxlists)

    kp = [boxlist.get_field("keypoints").keypoints for boxlist in boxlists]
    kp = cat(kp, 0)

    fields = boxlists[0].get_fields()
    fields = [field for field in fields if field != "keypoints"]

    boxlists = [boxlist.copy_with_fields(fields) for boxlist in boxlists]
    boxlists = cat_boxlist(boxlists)
    boxlists.add_field("keypoints", kp)
    return boxlists
コード例 #3
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    def select_over_all_levels(self, boxlists):
        num_images = len(boxlists)
        results = []
        for i in range(num_images):
            scores = boxlists[i].get_field("scores")
            labels = boxlists[i].get_field("labels")
            boxes = boxlists[i].bbox
            boxlist = boxlists[i]
            result = []
            # skip the background
            for j in range(1, self.num_classes):
                inds = (labels == j).nonzero().view(-1)

                scores_j = scores[inds]
                boxes_j = boxes[inds, :].view(-1, 4)
                boxlist_for_class = BoxList(boxes_j, boxlist.size, mode="xyxy")
                boxlist_for_class.add_field("scores", scores_j)
                boxlist_for_class = boxlist_nms(boxlist_for_class,
                                                self.nms_thresh,
                                                score_field="scores")
                num_labels = len(boxlist_for_class)
                boxlist_for_class.add_field(
                    "labels",
                    torch.full((num_labels, ),
                               j,
                               dtype=torch.int64,
                               device=scores.device))
                result.append(boxlist_for_class)

            result = cat_boxlist(result)
            number_of_detections = len(result)

            # Limit to max_per_image detections **over all classes**
            if number_of_detections > self.fpn_post_nms_top_n > 0:
                cls_scores = result.get_field("scores")
                image_thresh, _ = torch.kthvalue(
                    cls_scores.cpu(),
                    number_of_detections - self.fpn_post_nms_top_n + 1)
                keep = cls_scores >= image_thresh.item()
                keep = torch.nonzero(keep).squeeze(1)
                result = result[keep]
            results.append(result)
        return results
コード例 #4
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    def filter_results(self, boxlist, num_classes):
        """Returns bounding-box detection results by thresholding on scores and
        applying non-maximum suppression (NMS).
        """
        # unwrap the boxlist to avoid additional overhead.
        # if we had multi-class NMS, we could perform this directly on the boxlist
        boxes = boxlist.bbox.reshape(-1, num_classes * 4)
        scores = boxlist.get_field("scores").reshape(-1, num_classes)

        device = scores.device
        result = []
        # Apply threshold on detection probabilities and apply NMS
        # Skip j = 0, because it's the background class
        inds_all = scores > self.score_thresh
        for j in range(1, num_classes):
            inds = inds_all[:, j].nonzero(as_tuple=False).squeeze(1)
            scores_j = scores[inds, j]
            boxes_j = boxes[inds, j * 4 : (j + 1) * 4]
            boxlist_for_class = BoxList(boxes_j, boxlist.size, mode="xyxy")
            boxlist_for_class.add_field("scores", scores_j)
            boxlist_for_class = boxlist_nms(
                boxlist_for_class, self.nms
            )
            num_labels = len(boxlist_for_class)
            boxlist_for_class.add_field(
                "labels", torch.full((num_labels,), j, dtype=torch.int64, device=device)
            )
            result.append(boxlist_for_class)

        result = cat_boxlist(result)
        number_of_detections = len(result)

        # Limit to max_per_image detections **over all classes**
        if number_of_detections > self.detections_per_img > 0:
            cls_scores = result.get_field("scores")
            image_thresh, _ = torch.kthvalue(
                cls_scores.cpu(), number_of_detections - self.detections_per_img + 1
            )
            keep = cls_scores >= image_thresh.item()
            keep = torch.nonzero(keep, as_tuple=False).squeeze(1)
            result = result[keep]
        return result
コード例 #5
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 def testing_forward(self,
                     cls_score,
                     det_score,
                     proposals,
                     ref_scores=None,
                     ref_bbox_preds=None):
     if self.HEUR == "WSDDN":
         final_score = cls_score * det_score
         result = self.weak_post_processor(final_score, proposals)
     elif self.HEUR == "CLS-AVG":
         final_score = torch.mean(torch.stack(ref_scores), dim=0)
         result = self.weak_post_processor(final_score, proposals)
     elif self.HEUR == "AVG":  # AVG
         final_score = torch.mean(torch.stack(ref_scores), dim=0)
         final_regression = torch.mean(torch.stack(ref_bbox_preds), dim=0)
         result = self.strong_post_processor(
             (final_score, final_regression), proposals, softmax_on=False)
     elif self.HEUR == "UNION":  # UNION
         prop_list = [len(p) for p in proposals]
         ref_score_list = [rs.split(prop_list) for rs in ref_scores]
         ref_bbox_list = [rb.split(prop_list) for rb in ref_bbox_preds]
         final_score = [
             torch.cat((ref_score_list[0][i], ref_score_list[1][i],
                        ref_score_list[2][i]))
             for i in range(len(proposals))
         ]
         final_regression = [
             torch.cat((ref_bbox_list[0][i], ref_bbox_list[1][i],
                        ref_bbox_list[2][i])) for i in range(len(proposals))
         ]
         augmented_proposals = [
             cat_boxlist([p for _ in range(3)]) for p in proposals
         ]
         result = self.strong_post_processor(
             (cat(final_score), cat(final_regression)),
             augmented_proposals,
             softmax_on=False)
     else:
         raise ValueError
     return result
コード例 #6
0
ファイル: inference.py プロジェクト: akobiisr/wetectron
    def add_gt_proposals(self, proposals, targets):
        """
        Arguments:
            proposals: list[BoxList]
            targets: list[BoxList]
        """
        # Get the device we're operating on
        device = proposals[0].bbox.device

        gt_boxes = [target.copy_with_fields([]) for target in targets]

        # later cat of bbox requires all fields to be present for all bbox
        # so we need to add a dummy for objectness that's missing
        for gt_box in gt_boxes:
            gt_box.add_field("objectness", torch.ones(len(gt_box), device=device))

        proposals = [
            cat_boxlist((proposal, gt_box))
            for proposal, gt_box in zip(proposals, gt_boxes)
        ]

        return proposals
コード例 #7
0
ファイル: loss.py プロジェクト: akobiisr/wetectron
    def __call__(self, anchors, box_cls, box_regression, targets):
        """
        Arguments:
            anchors (list[BoxList])
            box_cls (list[Tensor])
            box_regression (list[Tensor])
            targets (list[BoxList])

        Returns:
            retinanet_cls_loss (Tensor)
            retinanet_regression_loss (Tensor
        """
        anchors = [
            cat_boxlist(anchors_per_image) for anchors_per_image in anchors
        ]
        labels, regression_targets = self.prepare_targets(anchors, targets)

        N = len(labels)
        box_cls, box_regression = \
                concat_box_prediction_layers(box_cls, box_regression)

        labels = torch.cat(labels, dim=0)
        regression_targets = torch.cat(regression_targets, dim=0)
        pos_inds = torch.nonzero(labels > 0).squeeze(1)

        retinanet_regression_loss = smooth_l1_loss(
            box_regression[pos_inds],
            regression_targets[pos_inds],
            beta=self.bbox_reg_beta,
            size_average=False,
        ) / (max(1,
                 pos_inds.numel() * self.regress_norm))

        labels = labels.int()

        retinanet_cls_loss = self.box_cls_loss_func(
            box_cls, labels) / (pos_inds.numel() + N)

        return retinanet_cls_loss, retinanet_regression_loss