"""Copyright(c) 2023 lyuwenyu. All Rights Reserved. Modifications Copyright (c) 2024 The DEIM Authors. All Rights Reserved. """ import torch from .utils import inverse_sigmoid from .box_ops import box_cxcywh_to_xyxy, box_xyxy_to_cxcywh def get_contrastive_denoising_training_group(targets, num_classes, num_queries, class_embed, num_denoising=100, label_noise_ratio=0.5, box_noise_scale=1.0,): """cnd""" if num_denoising <= 0: return None, None, None, None num_gts = [len(t['labels']) for t in targets] device = targets[0]['labels'].device max_gt_num = max(num_gts) if max_gt_num == 0: return None, None, None, None num_group = num_denoising // max_gt_num num_group = 1 if num_group == 0 else num_group # pad gt to max_num of a batch bs = len(num_gts) input_query_class = torch.full([bs, max_gt_num], num_classes, dtype=torch.int32, device=device) input_query_bbox = torch.zeros([bs, max_gt_num, 4], device=device) pad_gt_mask = torch.zeros([bs, max_gt_num], dtype=torch.bool, device=device) for i in range(bs): num_gt = num_gts[i] if num_gt > 0: input_query_class[i, :num_gt] = targets[i]['labels'] input_query_bbox[i, :num_gt] = targets[i]['boxes'] pad_gt_mask[i, :num_gt] = 1 # each group has positive and negative queries. input_query_class = input_query_class.tile([1, 2 * num_group]) input_query_bbox = input_query_bbox.tile([1, 2 * num_group, 1]) pad_gt_mask = pad_gt_mask.tile([1, 2 * num_group]) # positive and negative mask negative_gt_mask = torch.zeros([bs, max_gt_num * 2, 1], device=device) negative_gt_mask[:, max_gt_num:] = 1 negative_gt_mask = negative_gt_mask.tile([1, num_group, 1]) positive_gt_mask = 1 - negative_gt_mask # contrastive denoising training positive index positive_gt_mask = positive_gt_mask.squeeze(-1) * pad_gt_mask dn_positive_idx = torch.nonzero(positive_gt_mask)[:, 1] dn_positive_idx = torch.split(dn_positive_idx, [n * num_group for n in num_gts]) # total denoising queries num_denoising = int(max_gt_num * 2 * num_group) if label_noise_ratio > 0: mask = torch.rand_like(input_query_class, dtype=torch.float) < (label_noise_ratio * 0.5) # randomly put a new one here new_label = torch.randint_like(mask, 0, num_classes, dtype=input_query_class.dtype) input_query_class = torch.where(mask & pad_gt_mask, new_label, input_query_class) if box_noise_scale > 0: known_bbox = box_cxcywh_to_xyxy(input_query_bbox) diff = torch.tile(input_query_bbox[..., 2:] * 0.5, [1, 1, 2]) * box_noise_scale rand_sign = torch.randint_like(input_query_bbox, 0, 2) * 2.0 - 1.0 rand_part = torch.rand_like(input_query_bbox) rand_part = (rand_part + 1.0) * negative_gt_mask + rand_part * (1 - negative_gt_mask) known_bbox += (rand_sign * rand_part * diff) known_bbox = torch.clip(known_bbox, min=0.0, max=1.0) input_query_bbox = box_xyxy_to_cxcywh(known_bbox) input_query_bbox[input_query_bbox < 0] *= -1 input_query_bbox_unact = inverse_sigmoid(input_query_bbox) input_query_logits = class_embed(input_query_class) tgt_size = num_denoising + num_queries attn_mask = torch.full([tgt_size, tgt_size], False, dtype=torch.bool, device=device) # match query cannot see the reconstruction attn_mask[num_denoising:, :num_denoising] = True # reconstruct cannot see each other for i in range(num_group): if i == 0: attn_mask[max_gt_num * 2 * i: max_gt_num * 2 * (i + 1), max_gt_num * 2 * (i + 1): num_denoising] = True if i == num_group - 1: attn_mask[max_gt_num * 2 * i: max_gt_num * 2 * (i + 1), :max_gt_num * i * 2] = True else: attn_mask[max_gt_num * 2 * i: max_gt_num * 2 * (i + 1), max_gt_num * 2 * (i + 1): num_denoising] = True attn_mask[max_gt_num * 2 * i: max_gt_num * 2 * (i + 1), :max_gt_num * 2 * i] = True dn_meta = { "dn_positive_idx": dn_positive_idx, "dn_num_group": num_group, "dn_num_split": [num_denoising, num_queries] } # print(input_query_class.shape) # torch.Size([4, 196, 256]) # print(input_query_bbox.shape) # torch.Size([4, 196, 4]) # print(attn_mask.shape) # torch.Size([496, 496]) return input_query_logits, input_query_bbox_unact, attn_mask, dn_meta