# Ultralytics 🚀 AGPL-3.0 License - https://ultralytics.com/license from __future__ import annotations import torch import torch.nn as nn from . import LOGGER from .metrics import bbox_iou, probiou from .ops import xywh2xyxy, xywhr2xyxyxyxy, xyxy2xywh from .torch_utils import TORCH_1_11 class TaskAlignedAssigner(nn.Module): """A task-aligned assigner for object detection. This class assigns ground-truth (gt) objects to anchors based on the task-aligned metric, which combines both classification and localization information. Attributes: topk (int): The number of top candidates to consider. topk2 (int): Secondary topk value for additional filtering. num_classes (int): The number of object classes. alpha (float): The alpha parameter for the classification component of the task-aligned metric. beta (float): The beta parameter for the localization component of the task-aligned metric. stride (list): List of stride values for different feature levels. stride_val (int): The stride value used for select_candidates_in_gts. eps (float): A small value to prevent division by zero. """ def __init__( self, topk: int = 13, num_classes: int = 80, alpha: float = 1.0, beta: float = 6.0, stride: list = [8, 16, 32], eps: float = 1e-9, topk2=None, ): """Initialize a TaskAlignedAssigner object with customizable hyperparameters. Args: topk (int, optional): The number of top candidates to consider. num_classes (int, optional): The number of object classes. alpha (float, optional): The alpha parameter for the classification component of the task-aligned metric. beta (float, optional): The beta parameter for the localization component of the task-aligned metric. stride (list, optional): List of stride values for different feature levels. eps (float, optional): A small value to prevent division by zero. topk2 (int, optional): Secondary topk value for additional filtering. """ super().__init__() self.topk = topk self.topk2 = topk2 or topk self.num_classes = num_classes self.alpha = alpha self.beta = beta self.stride = stride self.stride_val = self.stride[1] if len(self.stride) > 1 else self.stride[0] self.eps = eps @torch.no_grad() def forward(self, pd_scores, pd_bboxes, anc_points, gt_labels, gt_bboxes, mask_gt): """Compute the task-aligned assignment. Args: pd_scores (torch.Tensor): Predicted classification scores with shape (bs, num_total_anchors, num_classes). pd_bboxes (torch.Tensor): Predicted bounding boxes with shape (bs, num_total_anchors, 4). anc_points (torch.Tensor): Anchor points with shape (num_total_anchors, 2). gt_labels (torch.Tensor): Ground truth labels with shape (bs, n_max_boxes, 1). gt_bboxes (torch.Tensor): Ground truth boxes with shape (bs, n_max_boxes, 4). mask_gt (torch.Tensor): Mask for valid ground truth boxes with shape (bs, n_max_boxes, 1). Returns: target_labels (torch.Tensor): Target labels with shape (bs, num_total_anchors). target_bboxes (torch.Tensor): Target bounding boxes with shape (bs, num_total_anchors, 4). target_scores (torch.Tensor): Target scores with shape (bs, num_total_anchors, num_classes). fg_mask (torch.Tensor): Foreground mask with shape (bs, num_total_anchors). target_gt_idx (torch.Tensor): Target ground truth indices with shape (bs, num_total_anchors). References: https://github.com/Nioolek/PPYOLOE_pytorch/blob/master/ppyoloe/assigner/tal_assigner.py """ self.bs = pd_scores.shape[0] self.n_max_boxes = gt_bboxes.shape[1] device = gt_bboxes.device if self.n_max_boxes == 0: return ( torch.full_like(pd_scores[..., 0], self.num_classes), torch.zeros_like(pd_bboxes), torch.zeros_like(pd_scores), torch.zeros_like(pd_scores[..., 0]), torch.zeros_like(pd_scores[..., 0]), ) try: return self._forward(pd_scores, pd_bboxes, anc_points, gt_labels, gt_bboxes, mask_gt) except RuntimeError as e: if "out of memory" in str(e).lower(): # Move tensors to CPU, compute, then move back to original device LOGGER.warning("CUDA OutOfMemoryError in TaskAlignedAssigner, using CPU") cpu_tensors = [t.cpu() for t in (pd_scores, pd_bboxes, anc_points, gt_labels, gt_bboxes, mask_gt)] result = self._forward(*cpu_tensors) return tuple(t.to(device) for t in result) raise def _forward(self, pd_scores, pd_bboxes, anc_points, gt_labels, gt_bboxes, mask_gt): """Compute the task-aligned assignment. Args: pd_scores (torch.Tensor): Predicted classification scores with shape (bs, num_total_anchors, num_classes). pd_bboxes (torch.Tensor): Predicted bounding boxes with shape (bs, num_total_anchors, 4). anc_points (torch.Tensor): Anchor points with shape (num_total_anchors, 2). gt_labels (torch.Tensor): Ground truth labels with shape (bs, n_max_boxes, 1). gt_bboxes (torch.Tensor): Ground truth boxes with shape (bs, n_max_boxes, 4). mask_gt (torch.Tensor): Mask for valid ground truth boxes with shape (bs, n_max_boxes, 1). Returns: target_labels (torch.Tensor): Target labels with shape (bs, num_total_anchors). target_bboxes (torch.Tensor): Target bounding boxes with shape (bs, num_total_anchors, 4). target_scores (torch.Tensor): Target scores with shape (bs, num_total_anchors, num_classes). fg_mask (torch.Tensor): Foreground mask with shape (bs, num_total_anchors). target_gt_idx (torch.Tensor): Target ground truth indices with shape (bs, num_total_anchors). """ mask_pos, align_metric, overlaps = self.get_pos_mask( pd_scores, pd_bboxes, gt_labels, gt_bboxes, anc_points, mask_gt ) target_gt_idx, fg_mask, mask_pos = self.select_highest_overlaps( mask_pos, overlaps, self.n_max_boxes, align_metric ) # Assigned target target_labels, target_bboxes, target_scores = self.get_targets(gt_labels, gt_bboxes, target_gt_idx, fg_mask) # Normalize align_metric *= mask_pos pos_align_metrics = align_metric.amax(dim=-1, keepdim=True) # b, max_num_obj pos_overlaps = (overlaps * mask_pos).amax(dim=-1, keepdim=True) # b, max_num_obj norm_align_metric = (align_metric * pos_overlaps / (pos_align_metrics + self.eps)).amax(-2).unsqueeze(-1) target_scores = target_scores * norm_align_metric return target_labels, target_bboxes, target_scores, fg_mask.bool(), target_gt_idx def get_pos_mask(self, pd_scores, pd_bboxes, gt_labels, gt_bboxes, anc_points, mask_gt): """Get positive mask for each ground truth box. Args: pd_scores (torch.Tensor): Predicted classification scores with shape (bs, num_total_anchors, num_classes). pd_bboxes (torch.Tensor): Predicted bounding boxes with shape (bs, num_total_anchors, 4). gt_labels (torch.Tensor): Ground truth labels with shape (bs, n_max_boxes, 1). gt_bboxes (torch.Tensor): Ground truth boxes with shape (bs, n_max_boxes, 4). anc_points (torch.Tensor): Anchor points with shape (num_total_anchors, 2). mask_gt (torch.Tensor): Mask for valid ground truth boxes with shape (bs, n_max_boxes, 1). Returns: mask_pos (torch.Tensor): Positive mask with shape (bs, max_num_obj, h*w). align_metric (torch.Tensor): Alignment metric with shape (bs, max_num_obj, h*w). overlaps (torch.Tensor): Overlaps between predicted vs ground truth boxes with shape (bs, max_num_obj, h*w). """ mask_in_gts = self.select_candidates_in_gts(anc_points, gt_bboxes, mask_gt) # Get anchor_align metric, (b, max_num_obj, h*w) align_metric, overlaps = self.get_box_metrics(pd_scores, pd_bboxes, gt_labels, gt_bboxes, mask_in_gts * mask_gt) # Get topk_metric mask, (b, max_num_obj, h*w) mask_topk = self.select_topk_candidates(align_metric, topk_mask=mask_gt.expand(-1, -1, self.topk).bool()) # Merge all mask to a final mask, (b, max_num_obj, h*w) mask_pos = mask_topk * mask_in_gts * mask_gt return mask_pos, align_metric, overlaps def get_box_metrics(self, pd_scores, pd_bboxes, gt_labels, gt_bboxes, mask_gt): """Compute alignment metric given predicted and ground truth bounding boxes. Args: pd_scores (torch.Tensor): Predicted classification scores with shape (bs, num_total_anchors, num_classes). pd_bboxes (torch.Tensor): Predicted bounding boxes with shape (bs, num_total_anchors, 4). gt_labels (torch.Tensor): Ground truth labels with shape (bs, n_max_boxes, 1). gt_bboxes (torch.Tensor): Ground truth boxes with shape (bs, n_max_boxes, 4). mask_gt (torch.Tensor): Mask for valid ground truth boxes with shape (bs, n_max_boxes, h*w). Returns: align_metric (torch.Tensor): Alignment metric combining classification and localization. overlaps (torch.Tensor): IoU overlaps between predicted and ground truth boxes. """ na = pd_bboxes.shape[-2] mask_gt = mask_gt.bool() # b, max_num_obj, h*w overlaps = torch.zeros([self.bs, self.n_max_boxes, na], dtype=pd_bboxes.dtype, device=pd_bboxes.device) bbox_scores = torch.zeros([self.bs, self.n_max_boxes, na], dtype=pd_scores.dtype, device=pd_scores.device) ind = torch.zeros([2, self.bs, self.n_max_boxes], dtype=torch.long) # 2, b, max_num_obj ind[0] = torch.arange(end=self.bs).view(-1, 1).expand(-1, self.n_max_boxes) # b, max_num_obj ind[1] = gt_labels.squeeze(-1) # b, max_num_obj # Get the scores of each grid for each gt cls bbox_scores[mask_gt] = pd_scores[ind[0], :, ind[1]][mask_gt] # b, max_num_obj, h*w # (b, max_num_obj, 1, 4), (b, 1, h*w, 4) pd_boxes = pd_bboxes.unsqueeze(1).expand(-1, self.n_max_boxes, -1, -1)[mask_gt] gt_boxes = gt_bboxes.unsqueeze(2).expand(-1, -1, na, -1)[mask_gt] overlaps[mask_gt] = self.iou_calculation(gt_boxes, pd_boxes) align_metric = bbox_scores.pow(self.alpha) * overlaps.pow(self.beta) return align_metric, overlaps def iou_calculation(self, gt_bboxes, pd_bboxes): """Calculate IoU for horizontal bounding boxes. Args: gt_bboxes (torch.Tensor): Ground truth boxes. pd_bboxes (torch.Tensor): Predicted boxes. Returns: (torch.Tensor): IoU values between each pair of boxes. """ return bbox_iou(gt_bboxes, pd_bboxes, xywh=False, CIoU=True).squeeze(-1).clamp_(0) def select_topk_candidates(self, metrics, topk_mask=None): """Select the top-k candidates based on the given metrics. Args: metrics (torch.Tensor): A tensor of shape (b, max_num_obj, h*w), where b is the batch size, max_num_obj is the maximum number of objects, and h*w represents the total number of anchor points. topk_mask (torch.Tensor, optional): An optional boolean tensor of shape (b, max_num_obj, topk), where topk is the number of top candidates to consider. If not provided, the top-k values are automatically computed based on the given metrics. Returns: (torch.Tensor): A tensor of shape (b, max_num_obj, h*w) containing the selected top-k candidates. """ # (b, max_num_obj, topk) topk_metrics, topk_idxs = torch.topk(metrics, self.topk, dim=-1, largest=True) if topk_mask is None: topk_mask = (topk_metrics.max(-1, keepdim=True)[0] > self.eps).expand_as(topk_idxs) # (b, max_num_obj, topk) topk_idxs.masked_fill_(~topk_mask, 0) # (b, max_num_obj, topk, h*w) -> (b, max_num_obj, h*w) count_tensor = torch.zeros(metrics.shape, dtype=torch.int8, device=topk_idxs.device) ones = torch.ones_like(topk_idxs[:, :, :1], dtype=torch.int8, device=topk_idxs.device) for k in range(self.topk): # Expand topk_idxs for each value of k and add 1 at the specified positions count_tensor.scatter_add_(-1, topk_idxs[:, :, k : k + 1], ones) # Filter invalid bboxes count_tensor.masked_fill_(count_tensor > 1, 0) return count_tensor.to(metrics.dtype) def get_targets(self, gt_labels, gt_bboxes, target_gt_idx, fg_mask): """Compute target labels, target bounding boxes, and target scores for the positive anchor points. Args: gt_labels (torch.Tensor): Ground truth labels of shape (b, max_num_obj, 1), where b is the batch size and max_num_obj is the maximum number of objects. gt_bboxes (torch.Tensor): Ground truth bounding boxes of shape (b, max_num_obj, 4). target_gt_idx (torch.Tensor): Indices of the assigned ground truth objects for positive anchor points, with shape (b, h*w), where h*w is the total number of anchor points. fg_mask (torch.Tensor): A boolean tensor of shape (b, h*w) indicating the positive (foreground) anchor points. Returns: target_labels (torch.Tensor): Target labels for positive anchor points with shape (b, h*w). target_bboxes (torch.Tensor): Target bounding boxes for positive anchor points with shape (b, h*w, 4). target_scores (torch.Tensor): Target scores for positive anchor points with shape (b, h*w, num_classes). """ # Assigned target labels, (b, 1) batch_ind = torch.arange(end=self.bs, dtype=torch.int64, device=gt_labels.device)[..., None] target_gt_idx = target_gt_idx + batch_ind * self.n_max_boxes # (b, h*w) target_labels = gt_labels.long().flatten()[target_gt_idx] # (b, h*w) # Assigned target boxes, (b, max_num_obj, 4) -> (b, h*w, 4) target_bboxes = gt_bboxes.view(-1, gt_bboxes.shape[-1])[target_gt_idx] # Assigned target scores target_labels.clamp_(0) # 10x faster than F.one_hot() target_scores = torch.zeros( (target_labels.shape[0], target_labels.shape[1], self.num_classes), dtype=torch.int64, device=target_labels.device, ) # (b, h*w, 80) target_scores.scatter_(2, target_labels.unsqueeze(-1), 1) fg_scores_mask = fg_mask[:, :, None].repeat(1, 1, self.num_classes) # (b, h*w, 80) target_scores = torch.where(fg_scores_mask > 0, target_scores, 0) return target_labels, target_bboxes, target_scores def select_candidates_in_gts(self, xy_centers, gt_bboxes, mask_gt, eps=1e-9): """Select positive anchor centers within ground truth bounding boxes. Args: xy_centers (torch.Tensor): Anchor center coordinates, shape (h*w, 2). gt_bboxes (torch.Tensor): Ground truth bounding boxes, shape (b, n_boxes, 4). mask_gt (torch.Tensor): Mask for valid ground truth boxes, shape (b, n_boxes, 1). eps (float, optional): Small value for numerical stability. Returns: (torch.Tensor): Boolean mask of positive anchors, shape (b, n_boxes, h*w). Notes: - b: batch size, n_boxes: number of ground truth boxes, h: height, w: width. - Bounding box format: [x_min, y_min, x_max, y_max]. """ gt_bboxes_xywh = xyxy2xywh(gt_bboxes) wh_mask = gt_bboxes_xywh[..., 2:] < self.stride[0] # the smallest stride gt_bboxes_xywh[..., 2:] = torch.where( (wh_mask * mask_gt).bool(), torch.tensor(self.stride_val, dtype=gt_bboxes_xywh.dtype, device=gt_bboxes_xywh.device), gt_bboxes_xywh[..., 2:], ) gt_bboxes = xywh2xyxy(gt_bboxes_xywh) n_anchors = xy_centers.shape[0] bs, n_boxes, _ = gt_bboxes.shape lt, rb = gt_bboxes.view(-1, 1, 4).chunk(2, 2) # left-top, right-bottom bbox_deltas = torch.cat((xy_centers[None] - lt, rb - xy_centers[None]), dim=2).view(bs, n_boxes, n_anchors, -1) return bbox_deltas.amin(3).gt_(eps) def select_highest_overlaps(self, mask_pos, overlaps, n_max_boxes, align_metric): """Select anchor boxes with highest IoU when assigned to multiple ground truths. Args: mask_pos (torch.Tensor): Positive mask, shape (b, n_max_boxes, h*w). overlaps (torch.Tensor): IoU overlaps, shape (b, n_max_boxes, h*w). n_max_boxes (int): Maximum number of ground truth boxes. align_metric (torch.Tensor): Alignment metric for selecting best matches. Returns: target_gt_idx (torch.Tensor): Indices of assigned ground truths, shape (b, h*w). fg_mask (torch.Tensor): Foreground mask, shape (b, h*w). mask_pos (torch.Tensor): Updated positive mask, shape (b, n_max_boxes, h*w). """ # Convert (b, n_max_boxes, h*w) -> (b, h*w) fg_mask = mask_pos.sum(-2) if fg_mask.max() > 1: # one anchor is assigned to multiple gt_bboxes mask_multi_gts = (fg_mask.unsqueeze(1) > 1).expand(-1, n_max_boxes, -1) # (b, n_max_boxes, h*w) max_overlaps_idx = overlaps.argmax(1) # (b, h*w) is_max_overlaps = torch.zeros(mask_pos.shape, dtype=mask_pos.dtype, device=mask_pos.device) is_max_overlaps.scatter_(1, max_overlaps_idx.unsqueeze(1), 1) mask_pos = torch.where(mask_multi_gts, is_max_overlaps, mask_pos).float() # (b, n_max_boxes, h*w) fg_mask = mask_pos.sum(-2) if self.topk2 != self.topk: align_metric = align_metric * mask_pos # update overlaps max_overlaps_idx = torch.topk(align_metric, self.topk2, dim=-1, largest=True).indices # (b, n_max_boxes) topk_idx = torch.zeros(mask_pos.shape, dtype=mask_pos.dtype, device=mask_pos.device) # update mask_pos topk_idx.scatter_(-1, max_overlaps_idx, 1.0) mask_pos *= topk_idx fg_mask = mask_pos.sum(-2) # Find each grid serve which gt(index) target_gt_idx = mask_pos.argmax(-2) # (b, h*w) return target_gt_idx, fg_mask, mask_pos class RotatedTaskAlignedAssigner(TaskAlignedAssigner): """Assigns ground-truth objects to rotated bounding boxes using a task-aligned metric.""" def iou_calculation(self, gt_bboxes, pd_bboxes): """Calculate IoU for rotated bounding boxes.""" return probiou(gt_bboxes, pd_bboxes).squeeze(-1).clamp_(0) def select_candidates_in_gts(self, xy_centers, gt_bboxes, mask_gt): """Select the positive anchor center in gt for rotated bounding boxes. Args: xy_centers (torch.Tensor): Anchor center coordinates with shape (h*w, 2). gt_bboxes (torch.Tensor): Ground truth bounding boxes with shape (b, n_boxes, 5). mask_gt (torch.Tensor): Mask for valid ground truth boxes with shape (b, n_boxes, 1). Returns: (torch.Tensor): Boolean mask of positive anchors with shape (b, n_boxes, h*w). """ wh_mask = gt_bboxes[..., 2:4] < self.stride[0] gt_bboxes[..., 2:4] = torch.where( (wh_mask * mask_gt).bool(), torch.tensor(self.stride_val, dtype=gt_bboxes.dtype, device=gt_bboxes.device), gt_bboxes[..., 2:4], ) # (b, n_boxes, 5) --> (b, n_boxes, 4, 2) corners = xywhr2xyxyxyxy(gt_bboxes) # (b, n_boxes, 1, 2) a, b, _, d = corners.split(1, dim=-2) ab = b - a ad = d - a # (b, n_boxes, h*w, 2) ap = xy_centers - a norm_ab = (ab * ab).sum(dim=-1) norm_ad = (ad * ad).sum(dim=-1) ap_dot_ab = (ap * ab).sum(dim=-1) ap_dot_ad = (ap * ad).sum(dim=-1) return (ap_dot_ab >= 0) & (ap_dot_ab <= norm_ab) & (ap_dot_ad >= 0) & (ap_dot_ad <= norm_ad) # is_in_box def make_anchors(feats, strides, grid_cell_offset=0.5): """Generate anchors from features.""" anchor_points, stride_tensor = [], [] assert feats is not None dtype, device = feats[0].dtype, feats[0].device for i in range(len(feats)): # use len(feats) to avoid TracerWarning from iterating over strides tensor stride = strides[i] h, w = feats[i].shape[2:] if isinstance(feats, list) else (int(feats[i][0]), int(feats[i][1])) sx = torch.arange(end=w, device=device, dtype=dtype) + grid_cell_offset # shift x sy = torch.arange(end=h, device=device, dtype=dtype) + grid_cell_offset # shift y sy, sx = torch.meshgrid(sy, sx, indexing="ij") if TORCH_1_11 else torch.meshgrid(sy, sx) anchor_points.append(torch.stack((sx, sy), -1).view(-1, 2)) stride_tensor.append(torch.full((h * w, 1), stride, dtype=dtype, device=device)) return torch.cat(anchor_points), torch.cat(stride_tensor) def dist2bbox(distance, anchor_points, xywh=True, dim=-1): """Transform distance(ltrb) to box(xywh or xyxy).""" lt, rb = distance.chunk(2, dim) x1y1 = anchor_points - lt x2y2 = anchor_points + rb if xywh: c_xy = (x1y1 + x2y2) / 2 wh = x2y2 - x1y1 return torch.cat([c_xy, wh], dim) # xywh bbox return torch.cat((x1y1, x2y2), dim) # xyxy bbox def bbox2dist(anchor_points: torch.Tensor, bbox: torch.Tensor, reg_max: int | None = None) -> torch.Tensor: """Transform bbox(xyxy) to dist(ltrb).""" x1y1, x2y2 = bbox.chunk(2, -1) dist = torch.cat((anchor_points - x1y1, x2y2 - anchor_points), -1) if reg_max is not None: dist = dist.clamp_(0, reg_max - 0.01) # dist (lt, rb) return dist def dist2rbox(pred_dist, pred_angle, anchor_points, dim=-1): """Decode predicted rotated bounding box coordinates from anchor points and distribution. Args: pred_dist (torch.Tensor): Predicted rotated distance with shape (bs, h*w, 4). pred_angle (torch.Tensor): Predicted angle with shape (bs, h*w, 1). anchor_points (torch.Tensor): Anchor points with shape (h*w, 2). dim (int, optional): Dimension along which to split. Returns: (torch.Tensor): Predicted rotated bounding boxes with shape (bs, h*w, 4). """ lt, rb = pred_dist.split(2, dim=dim) cos, sin = torch.cos(pred_angle), torch.sin(pred_angle) # (bs, h*w, 1) xf, yf = ((rb - lt) / 2).split(1, dim=dim) x, y = xf * cos - yf * sin, xf * sin + yf * cos xy = torch.cat([x, y], dim=dim) + anchor_points return torch.cat([xy, lt + rb], dim=dim) def rbox2dist( target_bboxes: torch.Tensor, anchor_points: torch.Tensor, target_angle: torch.Tensor, dim: int = -1, reg_max: int | None = None, ): """Transform rotated bounding box (xywh) to distance (ltrb). This is the inverse of dist2rbox. Args: target_bboxes (torch.Tensor): Target rotated bounding boxes with shape (bs, h*w, 4), format [x, y, w, h]. anchor_points (torch.Tensor): Anchor points with shape (h*w, 2). target_angle (torch.Tensor): Target angle with shape (bs, h*w, 1). dim (int, optional): Dimension along which to split. reg_max (int, optional): Maximum regression value for clamping. Returns: (torch.Tensor): Rotated distance with shape (bs, h*w, 4), format [l, t, r, b]. """ xy, wh = target_bboxes.split(2, dim=dim) offset = xy - anchor_points # (bs, h*w, 2) offset_x, offset_y = offset.split(1, dim=dim) cos, sin = torch.cos(target_angle), torch.sin(target_angle) xf = offset_x * cos + offset_y * sin yf = -offset_x * sin + offset_y * cos w, h = wh.split(1, dim=dim) target_l = w / 2 - xf target_t = h / 2 - yf target_r = w / 2 + xf target_b = h / 2 + yf dist = torch.cat([target_l, target_t, target_r, target_b], dim=dim) if reg_max is not None: dist = dist.clamp_(0, reg_max - 0.01) return dist