train YOLOX-L on COCO

config/__init__.py

@@ -22,7 +22,6 @@ from .yolov4_config import yolov4_cfg
 from .yolov5_config import yolov5_cfg
 from .yolov7_config import yolov7_cfg
 from .yolox_config import yolox_cfg
-from .artdet_config import artdet_cfg
 
 
 def build_model_config(args):
@@ -49,9 +48,6 @@ def build_model_config(args):
     # YOLOX
     elif args.model in ['yolox_n', 'yolox_s', 'yolox_m', 'yolox_l', 'yolox_x']:
         cfg = yolox_cfg[args.model]
-    # ARTDet
-    elif args.model in ['artdet_n', 'artdet_s', 'artdet_m', 'artdet_l', 'artdet_x']:
-        cfg = artdet_cfg[args.model]
     return cfg
 
 

config/artdet_config.py

@@ -1,74 +0,0 @@
-# YOLOX-Plus Config
-
-
-artdet_cfg = {
-    'artdet_n':{
-        # ---------------- Model config ----------------
-        ## Backbone
-        'backbone': 'elannet',
-        'pretrained': True,
-        'bk_act': 'silu',
-        'bk_norm': 'BN',
-        'bk_dpw': False,
-        'width': 0.25,
-        'depth': 0.34,
-        'stride': [8, 16, 32],  # P3, P4, P5
-        'max_stride': 32,
-        ## Neck: SPP
-        'neck': 'sppf',
-        'neck_expand_ratio': 0.5,
-        'pooling_size': 5,
-        'neck_act': 'silu',
-        'neck_norm': 'BN',
-        'neck_depthwise': False,
-        ## Neck: PaFPN
-        'fpn': 'yolo_pafpn',
-        'fpn_reduce_layer': 'Conv',
-        'fpn_downsample_layer': 'Conv',
-        'fpn_core_block': 'ELANBlock',
-        'fpn_act': 'silu',
-        'fpn_norm': 'BN',
-        'fpn_depthwise': False,
-        ## Head
-        'head': 'decoupled_head',
-        'head_act': 'silu',
-        'head_norm': 'BN',
-        'num_cls_head': 2,
-        'num_reg_head': 2,
-        'head_depthwise': False,
-        'reg_max': 16,
-        # ---------------- Train config ----------------
-        ## input
-        'multi_scale': [0.5, 1.5],   # 320 -> 960
-        'trans_type': 'yolox_tiny',
-        # ---------------- Assignment config ----------------
-        ## matcher
-        'matcher': {'topk': 10,
-                    'alpha': 0.5,
-                    'beta': 6.0},
-        # ---------------- Loss config ----------------
-        ## loss weight
-        'cls_loss': 'vfl',
-        'loss_cls_weight': 1.0,
-        'loss_iou_weight': 2.0,
-        'loss_dfl_weight': 1.0,
-        # ---------------- Train config ----------------
-        ## close strong augmentation
-        'no_aug_epoch': 20,
-        ## optimizer
-        'optimizer': 'sgd',        # optional: sgd, AdamW
-        'momentum': 0.9,           # SGD: 0.9;    AdamW: None
-        'weight_decay': 5e-4,      # SGD: 5e-4;     AdamW: 5e-2
-        'clip_grad': 10,           # SGD: 10.0;     AdamW: -1
-        ## model EMA
-        'ema_decay': 0.9999,       # SGD: 0.9999;   AdamW: 0.9998
-        'ema_tau': 2000,
-        ## lr schedule
-        'scheduler': 'linear',
-        'lr0': 0.01,              # SGD: 0.01;     AdamW: 0.001
-        'lrf': 0.01,               # SGD: 0.01;     AdamW: 0.01
-        'warmup_momentum': 0.8,
-        'warmup_bias_lr': 0.1,
-    },
-
-}

models/detectors/__init__.py

@@ -9,7 +9,6 @@ from .yolov4.build import build_yolov4
 from .yolov5.build import build_yolov5
 from .yolov7.build import build_yolov7
 from .yolox.build import build_yolox
-from .artdet.build import build_artdet
 
 
 # build object detector
@@ -47,10 +46,6 @@ def build_model(args,
     elif args.model in ['yolox_n', 'yolox_s', 'yolox_m', 'yolox_l', 'yolox_x']:
         model, criterion = build_yolox(
             args, model_cfg, device, num_classes, trainable, deploy)
-    # ARTDet  
-    elif args.model in ['artdet_n', 'artdet_s', 'artdet_m', 'artdet_l', 'artdet_x']:
-        model, criterion = build_artdet(
-            args, model_cfg, device, num_classes, trainable, deploy)
 
     if trainable:
         # Load pretrained weight

models/detectors/artdet/artdet.py

@@ -1,209 +0,0 @@
-# --------------- Torch components ---------------
-import torch
-import torch.nn as nn
-import torch.nn.functional as F
-
-# --------------- Model components ---------------
-from .artdet_backbone import build_backbone
-from .artdet_neck import build_neck
-from .artdet_pafpn import build_fpn
-from .artdet_head import build_head
-
-# --------------- External components ---------------
-from utils.misc import multiclass_nms
-
-
-# Anchor-free Real-Time Detection
-class ARTDet(nn.Module):
-    def __init__(self, 
-                 cfg,
-                 device, 
-                 num_classes = 20, 
-                 conf_thresh = 0.05,
-                 nms_thresh = 0.6,
-                 trainable = False, 
-                 topk = 1000,
-                 deploy = False):
-        super(ARTDet, self).__init__()
-        # ---------------------- Basic Parameters ----------------------
-        self.cfg = cfg
-        self.device = device
-        self.stride = cfg['stride']
-        self.reg_max = cfg['reg_max']
-        self.num_classes = num_classes
-        self.trainable = trainable
-        self.conf_thresh = conf_thresh
-        self.nms_thresh = nms_thresh
-        self.topk = topk
-        self.deploy = deploy
-        
-        # ---------------------- Network Parameters ----------------------
-        ## ----------- Backbone -----------
-        self.backbone, feats_dim = build_backbone(cfg, trainable&cfg['pretrained'])
-
-        ## ----------- Neck: SPP -----------
-        self.neck = build_neck(cfg=cfg, in_dim=feats_dim[-1], out_dim=feats_dim[-1])
-        feats_dim[-1] = self.neck.out_dim
-        
-        ## ----------- Neck: FPN -----------
-        self.fpn = build_fpn(cfg=cfg, in_dims=feats_dim, out_dim=round(256*cfg['width']))
-        self.head_dim = self.fpn.out_dim
-
-        ## ----------- Heads -----------
-        self.det_heads = nn.ModuleList(
-            [build_head(cfg, head_dim, head_dim, num_classes) 
-            for head_dim in self.head_dim
-            ])
-
-
-    # ---------------------- Basic Functions ----------------------
-    ## generate anchor points
-    def generate_anchors(self, level, fmp_size):
-        """
-            fmp_size: (List) [H, W]
-        """
-        # generate grid cells
-        fmp_h, fmp_w = fmp_size
-        anchor_y, anchor_x = torch.meshgrid([torch.arange(fmp_h), torch.arange(fmp_w)])
-        # [H, W, 2] -> [HW, 2]
-        anchor_xy = torch.stack([anchor_x, anchor_y], dim=-1).float().view(-1, 2)
-        anchor_xy += 0.5  # add center offset
-        anchor_xy *= self.stride[level]
-        anchors = anchor_xy.to(self.device)
-
-        return anchors
-        
-    ## post-process
-    def post_process(self, cls_preds, box_preds):
-        """
-        Input:
-            cls_preds: List(Tensor) [[H x W, C], ...]
-            box_preds: List(Tensor) [[H x W, 4], ...]
-        """
-        all_scores = []
-        all_labels = []
-        all_bboxes = []
-        
-        for cls_pred_i, box_pred_i in zip(cls_preds, box_preds):
-            # (H x W x C,)
-            scores_i = cls_pred_i.sigmoid().flatten()
-
-            # Keep top k top scoring indices only.
-            num_topk = min(self.topk, box_pred_i.size(0))
-
-            # torch.sort is actually faster than .topk (at least on GPUs)
-            predicted_prob, topk_idxs = scores_i.sort(descending=True)
-            topk_scores = predicted_prob[:num_topk]
-            topk_idxs = topk_idxs[:num_topk]
-
-            # filter out the proposals with low confidence score
-            keep_idxs = topk_scores > self.conf_thresh
-            topk_scores = topk_scores[keep_idxs]
-            topk_idxs = topk_idxs[keep_idxs]
-
-            anchor_idxs = torch.div(topk_idxs, self.num_classes, rounding_mode='floor')
-            topk_labels = topk_idxs % self.num_classes
-            topk_bboxes = box_pred_i[anchor_idxs]
-
-            all_scores.append(topk_scores)
-            all_labels.append(topk_labels)
-            all_bboxes.append(topk_bboxes)
-
-        scores = torch.cat(all_scores)
-        labels = torch.cat(all_labels)
-        bboxes = torch.cat(all_bboxes)
-
-        # to cpu & numpy
-        scores = scores.cpu().numpy()
-        labels = labels.cpu().numpy()
-        bboxes = bboxes.cpu().numpy()
-
-        # nms
-        scores, labels, bboxes = multiclass_nms(
-            scores, labels, bboxes, self.nms_thresh, self.num_classes, False)
-
-        return bboxes, scores, labels
-    
-    
-    # ---------------------- Main Process for Inference ----------------------
-    @torch.no_grad()
-    def inference_single_image(self, x):
-        # ---------------- Backbone ----------------
-        pyramid_feats = self.backbone(x)
-        pyramid_feats[-1] = self.neck(pyramid_feats[-1])
-        pyramid_feats = self.fpn(pyramid_feats)
-
-        # ---------------- Heads ----------------
-        all_cls_preds = []
-        all_box_preds = []
-        for level, (feat, head) in enumerate(zip(pyramid_feats, self.det_heads)):
-            # anchors: [M, 2]
-            fmp_size = feat.shape[-2:]
-            anchors = self.generate_anchors(level, fmp_size)
-
-            # pred
-            cls_pred, reg_pred, box_pred = head(feat, anchors, self.stride[level])
-
-            # collect preds
-            all_cls_preds.append(cls_pred[0])
-            all_box_preds.append(box_pred[0])
-
-        if self.deploy:
-            # no post process
-            cls_preds = torch.cat(all_cls_preds, dim=0)
-            box_pred = torch.cat(all_box_preds, dim=0)
-            # [n_anchors_all, 4 + C]
-            outputs = torch.cat([box_pred, cls_preds.sigmoid()], dim=-1)
-
-            return outputs
-
-        else:
-            # post process
-            bboxes, scores, labels = self.post_process(all_cls_preds, all_box_preds)
-            
-            return bboxes, scores, labels
-
-
-    # ---------------------- Main Process for Training ----------------------
-    def forward(self, x):
-        if not self.trainable:
-            return self.inference_single_image(x)
-        else:
-            # ---------------- Backbone ----------------
-            pyramid_feats = self.backbone(x)
-            pyramid_feats[-1] = self.neck(pyramid_feats[-1])
-            pyramid_feats = self.fpn(pyramid_feats)
-
-            # ---------------- Heads ----------------
-            all_anchors = []
-            all_cls_preds = []
-            all_reg_preds = []
-            all_box_preds = []
-            all_strides = []
-            for level, (feat, head) in enumerate(zip(pyramid_feats, self.det_heads)):
-                # anchors: [M, 2]
-                fmp_size = feat.shape[-2:]
-                anchors = self.generate_anchors(level, fmp_size)
-                # stride tensor: [M, 1]
-                stride_tensor = torch.ones_like(anchors[..., :1]) * self.stride[level]
-
-                # pred
-                cls_pred, reg_pred, box_pred = head(feat, anchors, self.stride[level])
-
-                # collect preds
-                all_cls_preds.append(cls_pred)
-                all_reg_preds.append(reg_pred)
-                all_box_preds.append(box_pred)
-                all_anchors.append(anchors)
-                all_strides.append(stride_tensor)
-            
-            # output dict
-            outputs = {"pred_cls": all_cls_preds,        # List(Tensor) [B, M, C]
-                       "pred_reg": all_reg_preds,        # List(Tensor) [B, M, 4*(reg_max)]
-                       "pred_box": all_box_preds,        # List(Tensor) [B, M, 4]
-                       "anchors": all_anchors,           # List(Tensor) [M, 2]
-                       "strides": self.stride,           # List(Int) = [8, 16, 32]
-                       "stride_tensor": all_strides      # List(Tensor) [M, 1]
-                       }
-            
-            return outputs 

models/detectors/artdet/artdet_backbone.py

@@ -1,154 +0,0 @@
-import torch
-import torch.nn as nn
-try:
-    from .artdet_basic import Conv, ELANBlock, DownSample
-except:
-    from artdet_basic import Conv, ELANBlock, DownSample
-
-
-
-model_urls = {
-    'elannet_pico': "https://github.com/yjh0410/image_classification_pytorch/releases/download/weight/elannet_pico.pth",
-    'elannet_nano': "https://github.com/yjh0410/image_classification_pytorch/releases/download/weight/elannet_nano.pth",
-    'elannet_small': "https://github.com/yjh0410/image_classification_pytorch/releases/download/weight/elannet_small.pth",
-    'elannet_medium': "https://github.com/yjh0410/image_classification_pytorch/releases/download/weight/elannet_medium.pth",
-    'elannet_large': "https://github.com/yjh0410/image_classification_pytorch/releases/download/weight/elannet_large.pth",
-    'elannet_huge': "https://github.com/yjh0410/image_classification_pytorch/releases/download/weight/elannet_huge.pth",
-}
-
-
-# ---------------------------- Backbones ----------------------------
-# ELANNet-P5
-class ELANNet(nn.Module):
-    def __init__(self, width=1.0, depth=1.0, act_type='silu', norm_type='BN', depthwise=False):
-        super(ELANNet, self).__init__()
-        self.feat_dims = [int(512 * width), int(1024 * width), int(1024 * width)]
-        
-        # P1/2
-        self.layer_1 = nn.Sequential(
-            Conv(3, int(64*width), k=3, p=1, s=2, act_type=act_type, norm_type=norm_type),
-            Conv(int(64*width), int(64*width), k=3, p=1, act_type=act_type, norm_type=norm_type, depthwise=depthwise)
-        )
-        # P2/4
-        self.layer_2 = nn.Sequential(   
-            Conv(int(64*width), int(128*width), k=3, p=1, s=2, act_type=act_type, norm_type=norm_type, depthwise=depthwise),             
-            ELANBlock(in_dim=int(128*width), out_dim=int(256*width), expand_ratio=0.5, depth=depth,
-                      act_type=act_type, norm_type=norm_type, depthwise=depthwise)
-        )
-        # P3/8
-        self.layer_3 = nn.Sequential(
-            DownSample(in_dim=int(256*width), out_dim=int(256*width), act_type=act_type, norm_type=norm_type),             
-            ELANBlock(in_dim=int(256*width), out_dim=int(512*width), expand_ratio=0.5, depth=depth,
-                      act_type=act_type, norm_type=norm_type, depthwise=depthwise)
-        )
-        # P4/16
-        self.layer_4 = nn.Sequential(
-            DownSample(in_dim=int(512*width), out_dim=int(512*width), act_type=act_type, norm_type=norm_type),             
-            ELANBlock(in_dim=int(512*width), out_dim=int(1024*width), expand_ratio=0.5, depth=depth,
-                      act_type=act_type, norm_type=norm_type, depthwise=depthwise)
-        )
-        # P5/32
-        self.layer_5 = nn.Sequential(
-            DownSample(in_dim=int(1024*width), out_dim=int(1024*width), act_type=act_type, norm_type=norm_type),             
-            ELANBlock(in_dim=int(1024*width), out_dim=int(1024*width), expand_ratio=0.25, depth=depth,
-                    act_type=act_type, norm_type=norm_type, depthwise=depthwise)
-        )
-
-
-    def forward(self, x):
-        c1 = self.layer_1(x)
-        c2 = self.layer_2(c1)
-        c3 = self.layer_3(c2)
-        c4 = self.layer_4(c3)
-        c5 = self.layer_5(c4)
-
-        outputs = [c3, c4, c5]
-
-        return outputs
-
-
-# ---------------------------- Functions ----------------------------
-## load pretrained weight
-def load_weight(model, model_name):
-    # load weight
-    print('Loading pretrained weight ...')
-    url = model_urls[model_name]
-    if url is not None:
-        checkpoint = torch.hub.load_state_dict_from_url(
-            url=url, map_location="cpu", check_hash=True)
-        # checkpoint state dict
-        checkpoint_state_dict = checkpoint.pop("model")
-        # model state dict
-        model_state_dict = model.state_dict()
-        # check
-        for k in list(checkpoint_state_dict.keys()):
-            if k in model_state_dict:
-                shape_model = tuple(model_state_dict[k].shape)
-                shape_checkpoint = tuple(checkpoint_state_dict[k].shape)
-                if shape_model != shape_checkpoint:
-                    checkpoint_state_dict.pop(k)
-            else:
-                checkpoint_state_dict.pop(k)
-                print(k)
-
-        model.load_state_dict(checkpoint_state_dict)
-    else:
-        print('No pretrained for {}'.format(model_name))
-
-    return model
-
-
-## build ELAN-Net
-def build_backbone(cfg, pretrained=False): 
-    # model
-    backbone = ELANNet(
-        width=cfg['width'],
-        depth=cfg['depth'],
-        act_type=cfg['bk_act'],
-        norm_type=cfg['bk_norm'],
-        depthwise=cfg['bk_dpw']
-        )
-    # check whether to load imagenet pretrained weight
-    if pretrained:
-        if cfg['width'] == 0.25 and cfg['depth'] == 0.34 and cfg['bk_dpw']:
-            backbone = load_weight(backbone, model_name='elannet_pico')
-        elif cfg['width'] == 0.25 and cfg['depth'] == 0.34:
-            backbone = load_weight(backbone, model_name='elannet_nano')
-        elif cfg['width'] == 0.5 and cfg['depth'] == 0.34:
-            backbone = load_weight(backbone, model_name='elannet_small')
-        elif cfg['width'] == 0.75 and cfg['depth'] == 0.67:
-            backbone = load_weight(backbone, model_name='elannet_medium')
-        elif cfg['width'] == 1.0 and cfg['depth'] == 1.0:
-            backbone = load_weight(backbone, model_name='elannet_large')
-        elif cfg['width'] == 1.25 and cfg['depth'] == 1.34:
-            backbone = load_weight(backbone, model_name='elannet_huge')
-    feat_dims = backbone.feat_dims
-
-    return backbone, feat_dims
-
-
-if __name__ == '__main__':
-    import time
-    from thop import profile
-    cfg = {
-        'pretrained': True,
-        'bk_act': 'silu',
-        'bk_norm': 'BN',
-        'bk_dpw': True,
-        'width': 0.25,
-        'depth': 0.34,
-    }
-    model, feats = build_backbone(cfg)
-    x = torch.randn(1, 3, 640, 640)
-    t0 = time.time()
-    outputs = model(x)
-    t1 = time.time()
-    print('Time: ', t1 - t0)
-    for out in outputs:
-        print(out.shape)
-
-    print('==============================')
-    flops, params = profile(model, inputs=(x, ), verbose=False)
-    print('==============================')
-    print('GFLOPs : {:.2f}'.format(flops / 1e9 * 2))
-    print('Params : {:.2f} M'.format(params / 1e6))

models/detectors/artdet/artdet_basic.py

@@ -1,191 +0,0 @@
-import numpy as np
-import torch
-import torch.nn as nn
-
-
-# ---------------------------- 2D CNN ----------------------------
-class SiLU(nn.Module):
-    """export-friendly version of nn.SiLU()"""
-
-    @staticmethod
-    def forward(x):
-        return x * torch.sigmoid(x)
-
-
-def get_conv2d(c1, c2, k, p, s, d, g, bias=False):
-    conv = nn.Conv2d(c1, c2, k, stride=s, padding=p, dilation=d, groups=g, bias=bias)
-
-    return conv
-
-
-def get_activation(act_type=None):
-    if act_type == 'relu':
-        return nn.ReLU(inplace=True)
-    elif act_type == 'lrelu':
-        return nn.LeakyReLU(0.1, inplace=True)
-    elif act_type == 'mish':
-        return nn.Mish(inplace=True)
-    elif act_type == 'silu':
-        return nn.SiLU(inplace=True)
-    elif act_type is None:
-        return nn.Identity()
-
-
-def get_norm(norm_type, dim):
-    if norm_type == 'BN':
-        return nn.BatchNorm2d(dim)
-    elif norm_type == 'GN':
-        return nn.GroupNorm(num_groups=32, num_channels=dim)
-
-
-# Basic conv layer
-class Conv(nn.Module):
-    def __init__(self, 
-                 c1,                   # in channels
-                 c2,                   # out channels 
-                 k=1,                  # kernel size 
-                 p=0,                  # padding
-                 s=1,                  # padding
-                 d=1,                  # dilation
-                 act_type='lrelu',     # activation
-                 norm_type='BN',       # normalization
-                 depthwise=False):
-        super(Conv, self).__init__()
-        convs = []
-        add_bias = False if norm_type else True
-        p = p if d == 1 else d
-        if depthwise:
-            convs.append(get_conv2d(c1, c1, k=k, p=p, s=s, d=d, g=c1, bias=add_bias))
-            # depthwise conv
-            if norm_type:
-                convs.append(get_norm(norm_type, c1))
-            if act_type:
-                convs.append(get_activation(act_type))
-            # pointwise conv
-            convs.append(get_conv2d(c1, c2, k=1, p=0, s=1, d=d, g=1, bias=add_bias))
-            if norm_type:
-                convs.append(get_norm(norm_type, c2))
-            if act_type:
-                convs.append(get_activation(act_type))
-
-        else:
-            convs.append(get_conv2d(c1, c2, k=k, p=p, s=s, d=d, g=1, bias=add_bias))
-            if norm_type:
-                convs.append(get_norm(norm_type, c2))
-            if act_type:
-                convs.append(get_activation(act_type))
-            
-        self.convs = nn.Sequential(*convs)
-
-
-    def forward(self, x):
-        return self.convs(x)
-
-
-# ---------------------------- Modified YOLOv7's Modules ----------------------------
-## ELANBlock
-class ELANBlock(nn.Module):
-    def __init__(self, in_dim, out_dim, expand_ratio=0.5, depth=1.0, act_type='silu', norm_type='BN', depthwise=False):
-        super(ELANBlock, self).__init__()
-        if isinstance(expand_ratio, float):
-            inter_dim = int(in_dim * expand_ratio)
-            inter_dim2 = inter_dim
-        elif isinstance(expand_ratio, list):
-            assert len(expand_ratio) == 2
-            e1, e2 = expand_ratio
-            inter_dim = int(in_dim * e1)
-            inter_dim2 = int(inter_dim * e2)
-        # branch-1
-        self.cv1 = Conv(in_dim, inter_dim, k=1, act_type=act_type, norm_type=norm_type)
-        # branch-2
-        self.cv2 = Conv(in_dim, inter_dim, k=1, act_type=act_type, norm_type=norm_type)
-        # branch-3
-        for idx in range(round(3*depth)):
-            if idx == 0:
-                cv3 = [Conv(inter_dim, inter_dim2, k=3, p=1, act_type=act_type, norm_type=norm_type, depthwise=depthwise)]
-            else:
-                cv3.append(Conv(inter_dim2, inter_dim2, k=3, p=1, act_type=act_type, norm_type=norm_type, depthwise=depthwise))
-        self.cv3 = nn.Sequential(*cv3)
-        # branch-4
-        self.cv4 = nn.Sequential(*[
-            Conv(inter_dim2, inter_dim2, k=3, p=1, act_type=act_type, norm_type=norm_type, depthwise=depthwise)
-            for _ in range(round(3*depth))
-        ])
-        # output
-        self.out = Conv(inter_dim*2 + inter_dim2*2, out_dim, k=1, act_type=act_type, norm_type=norm_type)
-
-
-    def forward(self, x):
-        """
-        Input:
-            x: [B, C_in, H, W]
-        Output:
-            out: [B, C_out, H, W]
-        """
-        x1 = self.cv1(x)
-        x2 = self.cv2(x)
-        x3 = self.cv3(x2)
-        x4 = self.cv4(x3)
-
-        # [B, C, H, W] -> [B, 2C, H, W]
-        out = self.out(torch.cat([x1, x2, x3, x4], dim=1))
-
-        return out
-
-## DownSample
-class DownSample(nn.Module):
-    def __init__(self, in_dim, out_dim, act_type='silu', norm_type='BN', depthwise=False):
-        super().__init__()
-        inter_dim = out_dim // 2
-        self.mp = nn.MaxPool2d((2, 2), 2)
-        self.cv1 = Conv(in_dim, inter_dim, k=1, act_type=act_type, norm_type=norm_type)
-        self.cv2 = nn.Sequential(
-            Conv(in_dim, inter_dim, k=1, act_type=act_type, norm_type=norm_type),
-            Conv(inter_dim, inter_dim, k=3, p=1, s=2, act_type=act_type, norm_type=norm_type, depthwise=depthwise)
-        )
-
-    def forward(self, x):
-        """
-        Input:
-            x: [B, C, H, W]
-        Output:
-            out: [B, C, H//2, W//2]
-        """
-        # [B, C, H, W] -> [B, C//2, H//2, W//2]
-        x1 = self.cv1(self.mp(x))
-        x2 = self.cv2(x)
-
-        # [B, C, H//2, W//2]
-        out = torch.cat([x1, x2], dim=1)
-
-        return out
-
-
-# ---------------------------- FPN Modules ----------------------------
-## build fpn's core block
-def build_fpn_block(cfg, in_dim, out_dim):
-    if cfg['fpn_core_block'] == 'ELANBlock':
-        layer = ELANBlock(in_dim=in_dim,
-                          out_dim=out_dim,
-                          expand_ratio=[0.5, 0.5],
-                          depth=cfg['depth'],
-                          act_type=cfg['fpn_act'],
-                          norm_type=cfg['fpn_norm'],
-                          depthwise=cfg['fpn_depthwise']
-                          )
-        
-    return layer
-
-## build fpn's reduce layer
-def build_reduce_layer(cfg, in_dim, out_dim):
-    if cfg['fpn_reduce_layer'] == 'Conv':
-        layer = Conv(in_dim, out_dim, k=1, act_type=cfg['fpn_act'], norm_type=cfg['fpn_norm'])
-        
-    return layer
-
-## build fpn's downsample layer
-def build_downsample_layer(cfg, in_dim, out_dim):
-    if cfg['fpn_downsample_layer'] == 'Conv':
-        layer = Conv(in_dim, out_dim, k=3, s=2, p=1, act_type=cfg['fpn_act'], norm_type=cfg['fpn_norm'])
-        
-    return layer

models/detectors/artdet/artdet_head.py

@@ -1,173 +0,0 @@
-import torch
-import torch.nn as nn
-import torch.nn.functional as F
-
-try:
-    from .artdet_basic import Conv
-except:
-    from artdet_basic import Conv
-
-
-class DecoupledHead(nn.Module):
-    def __init__(self, cfg, in_dim, out_dim, num_classes=80):
-        super().__init__()
-        print('==============================')
-        print('Head: Decoupled Head')
-        # --------- Basic Parameters ----------
-        self.in_dim = in_dim
-        self.num_classes = num_classes
-        self.reg_max = cfg['reg_max']
-        self.num_cls_head=cfg['num_cls_head']
-        self.num_reg_head=cfg['num_reg_head']
-
-        # --------- Network Parameters ----------
-        ## cls head
-        cls_feats = []
-        self.cls_out_dim = out_dim
-        for i in range(cfg['num_cls_head']):
-            if i == 0:
-                cls_feats.append(
-                    Conv(in_dim, self.cls_out_dim, k=3, p=1, s=1, 
-                        act_type=cfg['head_act'],
-                        norm_type=cfg['head_norm'],
-                        depthwise=cfg['head_depthwise'])
-                        )
-            else:
-                cls_feats.append(
-                    Conv(self.cls_out_dim, self.cls_out_dim, k=3, p=1, s=1, 
-                        act_type=cfg['head_act'],
-                        norm_type=cfg['head_norm'],
-                        depthwise=cfg['head_depthwise'])
-                        )      
-        ## reg head
-        reg_feats = []
-        self.reg_out_dim = out_dim
-        for i in range(cfg['num_reg_head']):
-            if i == 0:
-                reg_feats.append(
-                    Conv(in_dim, self.reg_out_dim, k=3, p=1, s=1, 
-                        act_type=cfg['head_act'],
-                        norm_type=cfg['head_norm'],
-                        depthwise=cfg['head_depthwise'])
-                        )
-            else:
-                reg_feats.append(
-                    Conv(self.reg_out_dim, self.reg_out_dim, k=3, p=1, s=1, 
-                        act_type=cfg['head_act'],
-                        norm_type=cfg['head_norm'],
-                        depthwise=cfg['head_depthwise'])
-                        )
-        self.cls_feats = nn.Sequential(*cls_feats)
-        self.reg_feats = nn.Sequential(*reg_feats)
-
-        ## Pred
-        self.cls_pred = nn.Conv2d(self.cls_out_dim, num_classes, kernel_size=1) 
-        self.reg_pred = nn.Conv2d(self.reg_out_dim, 4*cfg['reg_max'], kernel_size=1) 
-
-        ## ----------- proj_conv ------------
-        self.proj = nn.Parameter(torch.linspace(0, cfg['reg_max'], cfg['reg_max']), requires_grad=False)
-        self.proj_conv = nn.Conv2d(self.reg_max, 1, kernel_size=1, bias=False)
-        self.proj_conv.weight = nn.Parameter(self.proj.view([1, cfg['reg_max'], 1, 1]).clone().detach(), requires_grad=False)
-
-
-    def forward(self, x, anchors, stride):
-        """
-            in_feats: (Tensor) [B, C, H, W]
-        """
-        cls_feats = self.cls_feats(x)
-        reg_feats = self.reg_feats(x)
-
-        cls_pred = self.cls_pred(cls_feats)
-        reg_pred = self.reg_pred(reg_feats)
-
-        # process preds
-        B = x.shape[0]
-        cls_pred = cls_pred.permute(0, 2, 3, 1).contiguous().view(B, -1, self.num_classes)
-        reg_pred = reg_pred.permute(0, 2, 3, 1).contiguous().view(B, -1, 4*self.reg_max)
-
-        # ----------------------- Decode bbox -----------------------
-        M = reg_pred.shape[1]
-        # [B, M, 4*(reg_max)] -> [B, M, 4, reg_max] -> [B, 4, M, reg_max]
-        reg_pred_ = reg_pred.reshape([B, M, 4, self.reg_max])
-        # [B, M, 4, reg_max] -> [B, reg_max, 4, M]
-        reg_pred_ = reg_pred_.permute(0, 3, 2, 1).contiguous()
-        # [B, reg_max, 4, M] -> [B, 1, 4, M]
-        reg_pred_ = self.proj_conv(F.softmax(reg_pred_, dim=1))
-        # [B, 1, 4, M] -> [B, 4, M] -> [B, M, 4]
-        reg_pred_ = reg_pred_.view(B, 4, M).permute(0, 2, 1).contiguous()
-        ## tlbr -> xyxy
-        x1y1_pred = anchors[None] - reg_pred_[..., :2] * stride
-        x2y2_pred = anchors[None] + reg_pred_[..., 2:] * stride
-        box_pred = torch.cat([x1y1_pred, x2y2_pred], dim=-1)
-
-        return cls_pred, reg_pred, box_pred
-    
-
-# build detection head
-def build_head(cfg, in_dim, out_dim, num_classes=80):
-    if cfg['head'] == 'decoupled_head':
-        head = DecoupledHead(cfg, in_dim, out_dim, num_classes) 
-
-    return head
-
-
-if __name__ == '__main__':
-    import time
-    from thop import profile
-    cfg = {
-        'head': 'decoupled_head',
-        'num_cls_head': 2,
-        'num_reg_head': 2,
-        'head_act': 'silu',
-        'head_norm': 'BN',
-        'head_depthwise': False,
-        'reg_max': 16,
-    }
-    fpn_dims = [256, 512, 512]
-    # Head-1
-    model = build_head(cfg, 256, fpn_dims, num_classes=80)
-    x = torch.randn(1, 256, 80, 80)
-    t0 = time.time()
-    outputs = model(x)
-    t1 = time.time()
-    print('Time: ', t1 - t0)
-    # for out in outputs:
-    #     print(out.shape)
-
-    print('==============================')
-    flops, params = profile(model, inputs=(x, ), verbose=False)
-    print('==============================')
-    print('Head-1: GFLOPs : {:.2f}'.format(flops / 1e9 * 2))
-    print('Head-1: Params : {:.2f} M'.format(params / 1e6))
-
-    # Head-2
-    model = build_head(cfg, 512, fpn_dims, num_classes=80)
-    x = torch.randn(1, 512, 40, 40)
-    t0 = time.time()
-    outputs = model(x)
-    t1 = time.time()
-    print('Time: ', t1 - t0)
-    # for out in outputs:
-    #     print(out.shape)
-
-    print('==============================')
-    flops, params = profile(model, inputs=(x, ), verbose=False)
-    print('==============================')
-    print('Head-2: GFLOPs : {:.2f}'.format(flops / 1e9 * 2))
-    print('Head-2: Params : {:.2f} M'.format(params / 1e6))
-
-    # Head-3
-    model = build_head(cfg, 512, fpn_dims, num_classes=80)
-    x = torch.randn(1, 512, 20, 20)
-    t0 = time.time()
-    outputs = model(x)
-    t1 = time.time()
-    print('Time: ', t1 - t0)
-    # for out in outputs:
-    #     print(out.shape)
-
-    print('==============================')
-    flops, params = profile(model, inputs=(x, ), verbose=False)
-    print('==============================')
-    print('Head-3: GFLOPs : {:.2f}'.format(flops / 1e9 * 2))
-    print('Head-3: Params : {:.2f} M'.format(params / 1e6))

models/detectors/artdet/artdet_neck.py

@@ -1,70 +0,0 @@
-import torch
-import torch.nn as nn
-from .artdet_basic import Conv
-
-
-# Spatial Pyramid Pooling - Fast (SPPF) layer for YOLOv5 by Glenn Jocher
-class SPPF(nn.Module):
-    """
-        This code referenced to https://github.com/ultralytics/yolov5
-    """
-    def __init__(self, cfg, in_dim, out_dim, expand_ratio=0.5):
-        super().__init__()
-        inter_dim = int(in_dim * expand_ratio)
-        self.out_dim = out_dim
-        self.cv1 = Conv(in_dim, inter_dim, k=1, act_type=cfg['neck_act'], norm_type=cfg['neck_norm'])
-        self.cv2 = Conv(inter_dim * 4, out_dim, k=1, act_type=cfg['neck_act'], norm_type=cfg['neck_norm'])
-        self.m = nn.MaxPool2d(kernel_size=cfg['pooling_size'], stride=1, padding=cfg['pooling_size'] // 2)
-
-    def forward(self, x):
-        x = self.cv1(x)
-        y1 = self.m(x)
-        y2 = self.m(y1)
-
-        return self.cv2(torch.cat((x, y1, y2, self.m(y2)), 1))
-
-
-# SPPF block with CSP module
-class SPPFBlockCSP(nn.Module):
-    """
-        CSP Spatial Pyramid Pooling Block
-    """
-    def __init__(self, cfg, in_dim, out_dim, expand_ratio):
-        super(SPPFBlockCSP, self).__init__()
-        inter_dim = int(in_dim * expand_ratio)
-        self.out_dim = out_dim
-        self.cv1 = Conv(in_dim, inter_dim, k=1, act_type=cfg['neck_act'], norm_type=cfg['neck_norm'])
-        self.cv2 = Conv(in_dim, inter_dim, k=1, act_type=cfg['neck_act'], norm_type=cfg['neck_norm'])
-        self.m = nn.Sequential(
-            Conv(inter_dim, inter_dim, k=3, p=1, 
-                 act_type=cfg['neck_act'], norm_type=cfg['neck_norm'], 
-                 depthwise=cfg['neck_depthwise']),
-            SPPF(cfg, inter_dim, inter_dim, expand_ratio=1.0),
-            Conv(inter_dim, inter_dim, k=3, p=1, 
-                 act_type=cfg['neck_act'], norm_type=cfg['neck_norm'], 
-                 depthwise=cfg['neck_depthwise'])
-        )
-        self.cv3 = Conv(inter_dim * 2, self.out_dim, k=1, act_type=cfg['neck_act'], norm_type=cfg['neck_norm'])
-
-        
-    def forward(self, x):
-        x1 = self.cv1(x)
-        x2 = self.cv2(x)
-        x3 = self.m(x2)
-        y = self.cv3(torch.cat([x1, x3], dim=1))
-
-        return y
-
-
-def build_neck(cfg, in_dim, out_dim):
-    model = cfg['neck']
-    print('==============================')
-    print('Neck: {}'.format(model))
-    # build neck
-    if model == 'sppf':
-        neck = SPPF(cfg, in_dim, out_dim, cfg['neck_expand_ratio'])
-    elif model == 'csp_sppf':
-        neck = SPPFBlockCSP(cfg, in_dim, out_dim, cfg['neck_expand_ratio'])
-
-    return neck
-        

models/detectors/artdet/artdet_pafpn.py

@@ -1,94 +0,0 @@
-import torch
-import torch.nn as nn
-import torch.nn.functional as F
-
-from .artdet_basic import (Conv, build_reduce_layer, build_downsample_layer, build_fpn_block)
-
-
-# YOLO-Style PaFPN
-class YoloPaFPN(nn.Module):
-    def __init__(self, cfg, in_dims=[256, 512, 1024], out_dim=None):
-        super(YoloPaFPN, self).__init__()
-        # --------------------------- Basic Parameters ---------------------------
-        self.in_dims = in_dims
-        c3, c4, c5 = in_dims
-        width = cfg['width']
-
-        # --------------------------- Network Parameters ---------------------------
-        ## top dwon
-        ### P5 -> P4
-        self.reduce_layer_1 = build_reduce_layer(cfg, c5, round(512*width))
-        self.reduce_layer_2 = build_reduce_layer(cfg, c4, round(512*width))
-        self.top_down_layer_1 = build_fpn_block(cfg, round(512*width) + round(512*width), round(512*width))
-
-        ### P4 -> P3
-        self.reduce_layer_3 = build_reduce_layer(cfg, round(512*width), round(256*width))
-        self.reduce_layer_4 = build_reduce_layer(cfg, c3, round(256*width))
-        self.top_down_layer_2 = build_fpn_block(cfg, round(256*width) + round(256*width), round(256*width))
-
-        ## bottom up
-        ### P3 -> P4
-        self.downsample_layer_1 = build_downsample_layer(cfg, round(256*width), round(256*width))
-        self.bottom_up_layer_1 = build_fpn_block(cfg, round(256*width) + round(256*width), round(512*width))
-
-        ### P4 -> P5
-        self.downsample_layer_2 = build_downsample_layer(cfg, round(512*width), round(512*width))
-        self.bottom_up_layer_2 = build_fpn_block(cfg, round(512*width) + round(512*width), round(1024*width))
-                
-        ## output proj layers
-        if out_dim is not None:
-            self.out_layers = nn.ModuleList([
-                Conv(in_dim, out_dim, k=1,
-                     act_type=cfg['fpn_act'], norm_type=cfg['fpn_norm'])
-                     for in_dim in [round(256*width), round(512*width), round(1024*width)]
-                     ])
-            self.out_dim = [out_dim] * 3
-        else:
-            self.out_layers = None
-            self.out_dim = [round(256*width), round(512*width), round(1024*width)]
-
-
-    def forward(self, features):
-        c3, c4, c5 = features
-
-        # Top down
-        ## P5 -> P4
-        c6 = self.reduce_layer_1(c5)
-        c7 = self.reduce_layer_2(c4)
-        c8 = torch.cat([F.interpolate(c6, scale_factor=2.0), c7], dim=1)
-        c9 = self.top_down_layer_1(c8)
-        ## P4 -> P3
-        c10 = self.reduce_layer_3(c9)
-        c11 = self.reduce_layer_4(c3)
-        c12 = torch.cat([F.interpolate(c10, scale_factor=2.0), c11], dim=1)
-        c13 = self.top_down_layer_2(c12)
-
-        # Bottom up
-        # p3 -> P4
-        c14 = self.downsample_layer_1(c13)
-        c15 = torch.cat([c14, c10], dim=1)
-        c16 = self.bottom_up_layer_1(c15)
-        # P4 -> P5
-        c17 = self.downsample_layer_2(c16)
-        c18 = torch.cat([c17, c6], dim=1)
-        c19 = self.bottom_up_layer_2(c18)
-
-        out_feats = [c13, c16, c19] # [P3, P4, P5]
-        
-        # output proj layers
-        if self.out_layers is not None:
-            out_feats_proj = []
-            for feat, layer in zip(out_feats, self.out_layers):
-                out_feats_proj.append(layer(feat))
-            return out_feats_proj
-
-        return out_feats
-
-
-def build_fpn(cfg, in_dims, out_dim=None):
-    model = cfg['fpn']
-    # build pafpn
-    if model == 'yolo_pafpn':
-        fpn_net = YoloPaFPN(cfg, in_dims, out_dim)
-
-    return fpn_net

models/detectors/artdet/build.py

@@ -1,55 +0,0 @@
-#!/usr/bin/env python3
-# -*- coding:utf-8 -*-
-
-import torch
-import torch.nn as nn
-
-from .loss import build_criterion
-from .artdet import ARTDet
-
-
-# build object detector
-def build_artdet(args, cfg, device, num_classes=80, trainable=False, deploy=False):
-    print('==============================')
-    print('Build {} ...'.format(args.model.upper()))
-        
-    # -------------- Build ARTDet --------------
-    model = ARTDet(
-        cfg=cfg,
-        device=device, 
-        num_classes=num_classes,
-        trainable=trainable,
-        conf_thresh=args.conf_thresh,
-        nms_thresh=args.nms_thresh,
-        topk=args.topk,
-        deploy=deploy
-        )
-
-    # -------------- Initialize ARTDet --------------
-    for m in model.modules():
-        if isinstance(m, nn.BatchNorm2d):
-            m.eps = 1e-3
-            m.momentum = 0.03    
-    # Init head
-    init_prob = 0.01
-    bias_value = -torch.log(torch.tensor((1. - init_prob) / init_prob))
-    for det_head in model.det_heads:
-        # cls pred
-        b = det_head.cls_pred.bias.view(1, -1)
-        b.data.fill_(bias_value.item())
-        det_head.cls_pred.bias = torch.nn.Parameter(b.view(-1), requires_grad=True)
-        # reg pred
-        b = det_head.reg_pred.bias.view(-1, )
-        b.data.fill_(1.0)
-        det_head.reg_pred.bias = torch.nn.Parameter(b.view(-1), requires_grad=True)
-        w = det_head.reg_pred.weight
-        w.data.fill_(0.)
-        det_head.reg_pred.weight = torch.nn.Parameter(w, requires_grad=True)
-
-
-    # -------------- Build criterion --------------
-    criterion = None
-    if trainable:
-        # build criterion for training
-        criterion = build_criterion(cfg, device, num_classes)
-    return model, criterion

models/detectors/artdet/loss.py

@@ -1,283 +0,0 @@
-import torch
-import torch.nn as nn
-import torch.nn.functional as F
-from .matcher import TaskAlignedAssigner
-from utils.box_ops import bbox2dist, bbox_iou
-
-
-
-class Criterion(object):
-    def __init__(self, 
-                 cfg, 
-                 device, 
-                 num_classes=80):
-        self.cfg = cfg
-        self.device = device
-        self.num_classes = num_classes
-        self.reg_max = cfg['reg_max']
-        self.use_dfl = cfg['reg_max'] > 1
-        # loss
-        self.cls_lossf = ClassificationLoss(cfg, reduction='none')
-        self.reg_lossf = RegressionLoss(num_classes, cfg['reg_max'] - 1, self.use_dfl)
-        # loss weight
-        self.loss_cls_weight = cfg['loss_cls_weight']
-        self.loss_iou_weight = cfg['loss_iou_weight']
-        self.loss_dfl_weight = cfg['loss_dfl_weight']
-        # matcher
-        matcher_config = cfg['matcher']
-        self.matcher = TaskAlignedAssigner(
-            topk=matcher_config['topk'],
-            num_classes=num_classes,
-            alpha=matcher_config['alpha'],
-            beta=matcher_config['beta']
-            )
-
-
-    def __call__(self, outputs, targets):        
-        """
-            outputs['pred_cls']: List(Tensor) [B, M, C]
-            outputs['pred_regs']: List(Tensor) [B, M, 4*(reg_max+1)]
-            outputs['pred_boxs']: List(Tensor) [B, M, 4]
-            outputs['anchors']: List(Tensor) [M, 2]
-            outputs['strides']: List(Int) [8, 16, 32] output stride
-            outputs['stride_tensor']: List(Tensor) [M, 1]
-            targets: (List) [dict{'boxes': [...], 
-                                 'labels': [...], 
-                                 'orig_size': ...}, ...]
-        """
-        bs = outputs['pred_cls'][0].shape[0]
-        device = outputs['pred_cls'][0].device
-        strides = outputs['stride_tensor']
-        anchors = outputs['anchors']
-        anchors = torch.cat(anchors, dim=0)
-        num_anchors = anchors.shape[0]
-
-        # preds: [B, M, C]
-        cls_preds = torch.cat(outputs['pred_cls'], dim=1)
-        reg_preds = torch.cat(outputs['pred_reg'], dim=1)
-        box_preds = torch.cat(outputs['pred_box'], dim=1)
-        
-        # label assignment
-        gt_label_targets = []
-        gt_score_targets = []
-        gt_bbox_targets = []
-        fg_masks = []
-
-        for batch_idx in range(bs):
-            tgt_labels = targets[batch_idx]["labels"].to(device)     # [Mp,]
-            tgt_boxs = targets[batch_idx]["boxes"].to(device)        # [Mp, 4]
-
-            # check target
-            if len(tgt_labels) == 0 or tgt_boxs.max().item() == 0.:
-                # There is no valid gt
-                fg_mask = cls_preds.new_zeros(1, num_anchors).bool()               #[1, M,]
-                gt_label = cls_preds.new_zeros((1, num_anchors,))                  #[1, M,]
-                gt_score = cls_preds.new_zeros((1, num_anchors, self.num_classes)) #[1, M, C]
-                gt_box = cls_preds.new_zeros((1, num_anchors, 4))                  #[1, M, 4]
-            else:
-                tgt_labels = tgt_labels[None, :, None]      # [1, Mp, 1]
-                tgt_boxs = tgt_boxs[None]                   # [1, Mp, 4]
-                (
-                    gt_label,   #[1, M]
-                    gt_box,     #[1, M, 4]
-                    gt_score,   #[1, M, C]
-                    fg_mask,    #[1, M,]
-                    _
-                ) = self.matcher(
-                    pd_scores = cls_preds[batch_idx:batch_idx+1].detach().sigmoid(), 
-                    pd_bboxes = box_preds[batch_idx:batch_idx+1].detach(),
-                    anc_points = anchors,
-                    gt_labels = tgt_labels,
-                    gt_bboxes = tgt_boxs
-                    )
-            gt_label_targets.append(gt_label)
-            gt_score_targets.append(gt_score)
-            gt_bbox_targets.append(gt_box)
-            fg_masks.append(fg_mask)
-
-        # List[B, 1, M, C] -> Tensor[B, M, C] -> Tensor[BM, C]
-        fg_masks = torch.cat(fg_masks, 0).view(-1)                                    # [BM,]
-        gt_label_targets = torch.cat(gt_label_targets, 0).view(-1)                    # [BM,]
-        gt_score_targets = torch.cat(gt_score_targets, 0).view(-1, self.num_classes)  # [BM, C]
-        gt_bbox_targets = torch.cat(gt_bbox_targets, 0).view(-1, 4)                   # [BM, 4]
-        
-        # cls loss
-        cls_preds = cls_preds.view(-1, self.num_classes)
-        gt_label_targets = torch.where(
-            fg_masks > 0,
-            gt_label_targets,
-            torch.full_like(gt_label_targets, self.num_classes)
-            )
-        gt_labels_one_hot = F.one_hot(gt_label_targets.long(), self.num_classes + 1)[..., :-1]
-        loss_cls = self.cls_lossf(cls_preds, gt_score_targets, gt_labels_one_hot)
-
-        # reg loss
-        anchors = anchors[None].repeat(bs, 1, 1).view(-1, 2)                           # [BM, 2]
-        strides = torch.cat(strides, dim=0).unsqueeze(0).repeat(bs, 1, 1).view(-1, 1)  # [BM, 1]
-        bbox_weight = gt_score_targets[fg_masks].sum(-1, keepdim=True)                 # [BM, 1]
-        reg_preds = reg_preds.view(-1, 4*self.reg_max)                                 # [BM, 4*(reg_max + 1)]
-        box_preds = box_preds.view(-1, 4)                                              # [BM, 4]
-        loss_iou, loss_dfl = self.reg_lossf(
-            pred_regs = reg_preds,
-            pred_boxs = box_preds,
-            anchors = anchors,
-            gt_boxs = gt_bbox_targets,
-            bbox_weight = bbox_weight,
-            fg_masks = fg_masks,
-            strides = strides,
-            )
-        
-        # normalize loss
-        gt_score_targets_sum = max(gt_score_targets.sum(), 1)
-        loss_cls = loss_cls.sum() / gt_score_targets_sum
-        loss_iou = loss_iou.sum() / gt_score_targets_sum
-        loss_dfl = loss_dfl.sum() / gt_score_targets_sum
-
-        # total loss
-        losses = loss_cls * self.loss_cls_weight + \
-                 loss_iou * self.loss_iou_weight
-        if self.use_dfl:
-            losses += loss_dfl * self.loss_dfl_weight
-            loss_dict = dict(
-                    loss_cls = loss_cls,
-                    loss_iou = loss_iou,
-                    loss_dfl = loss_dfl,
-                    losses = losses
-            )
-        else:
-            loss_dict = dict(
-                    loss_cls = loss_cls,
-                    loss_iou = loss_iou,
-                    losses = losses
-            )
-
-        return loss_dict
-    
-
-class ClassificationLoss(nn.Module):
-    def __init__(self, cfg, reduction='none'):
-        super(ClassificationLoss, self).__init__()
-        self.cfg = cfg
-        self.reduction = reduction
-        # For VFL
-        self.alpha = 0.75
-        self.gamma = 2.0
-
-    def varifocalloss(self, pred_logits, gt_score, gt_label, alpha=0.75, gamma=2.0):
-        focal_weight = alpha * pred_logits.sigmoid().pow(gamma) * (1 - gt_label) + gt_score * gt_label
-        with torch.cuda.amp.autocast(enabled=False):
-            bce_loss = F.binary_cross_entropy_with_logits(
-                pred_logits.float(), gt_score.float(), reduction='none')
-            loss = bce_loss * focal_weight
-
-            if self.reduction == 'sum':
-                loss = loss.sum()
-            elif self.reduction == 'mean':
-                loss = loss.mean()
-
-        return loss
-
-    def binary_cross_entropy(self, pred_logits, gt_score):
-        loss = F.binary_cross_entropy_with_logits(
-            pred_logits.float(), gt_score.float(), reduction='none')
-
-        if self.reduction == 'sum':
-            loss = loss.sum()
-        elif self.reduction == 'mean':
-            loss = loss.mean()
-
-        return loss
-
-
-    def forward(self, pred_logits, gt_score, gt_label):
-        if self.cfg['cls_loss'] == 'bce':
-            return self.binary_cross_entropy(pred_logits, gt_score)
-        elif self.cfg['cls_loss'] == 'vfl':
-            return self.varifocalloss(pred_logits, gt_score, gt_label, self.alpha, self.gamma)
-
-
-class RegressionLoss(nn.Module):
-    def __init__(self, num_classes, reg_max, use_dfl):
-        super(RegressionLoss, self).__init__()
-        self.num_classes = num_classes
-        self.reg_max = reg_max
-        self.use_dfl = use_dfl
-
-
-    def df_loss(self, pred_regs, target):
-        gt_left = target.to(torch.long)
-        gt_right = gt_left + 1
-        weight_left = gt_right.to(torch.float) - target
-        weight_right = 1 - weight_left
-        # loss left
-        loss_left = F.cross_entropy(
-            pred_regs.view(-1, self.reg_max + 1),
-            gt_left.view(-1),
-            reduction='none').view(gt_left.shape) * weight_left
-        # loss right
-        loss_right = F.cross_entropy(
-            pred_regs.view(-1, self.reg_max + 1),
-            gt_right.view(-1),
-            reduction='none').view(gt_left.shape) * weight_right
-
-        loss = (loss_left + loss_right).mean(-1, keepdim=True)
-        
-        return loss
-
-
-    def forward(self, pred_regs, pred_boxs, anchors, gt_boxs, bbox_weight, fg_masks, strides):
-        """
-        Input:
-            pred_regs: (Tensor) [BM, 4*(reg_max + 1)]
-            pred_boxs: (Tensor) [BM, 4]
-            anchors: (Tensor) [BM, 2]
-            gt_boxs: (Tensor) [BM, 4]
-            bbox_weight: (Tensor) [BM, 1]
-            fg_masks: (Tensor) [BM,]
-            strides: (Tensor) [BM, 1]
-        """
-        # select positive samples mask
-        num_pos = fg_masks.sum()
-
-        if num_pos > 0:
-            pred_boxs_pos = pred_boxs[fg_masks]
-            gt_boxs_pos = gt_boxs[fg_masks]
-
-            # iou loss
-            ious = bbox_iou(pred_boxs_pos,
-                            gt_boxs_pos,
-                            xywh=False,
-                            CIoU=True)
-            loss_iou = (1.0 - ious) * bbox_weight
-               
-            # dfl loss
-            if self.use_dfl:
-                pred_regs_pos = pred_regs[fg_masks]
-                gt_boxs_s = gt_boxs / strides
-                anchors_s = anchors / strides
-                gt_ltrb_s = bbox2dist(anchors_s, gt_boxs_s, self.reg_max)
-                gt_ltrb_s_pos = gt_ltrb_s[fg_masks]
-                loss_dfl = self.df_loss(pred_regs_pos, gt_ltrb_s_pos)
-                loss_dfl *= bbox_weight
-            else:
-                loss_dfl = pred_regs.sum() * 0.
-
-        else:
-            loss_iou = pred_regs.sum() * 0.
-            loss_dfl = pred_regs.sum() * 0.
-
-        return loss_iou, loss_dfl
-
-
-def build_criterion(cfg, device, num_classes):
-    criterion = Criterion(
-        cfg=cfg,
-        device=device,
-        num_classes=num_classes
-        )
-
-    return criterion
-
-
-if __name__ == "__main__":
-    pass

models/detectors/artdet/matcher.py

@@ -1,204 +0,0 @@
-import torch
-import torch.nn as nn
-import torch.nn.functional as F
-from utils.box_ops import bbox_iou
-
-
-# -------------------------- Task Aligned Assigner --------------------------
-class TaskAlignedAssigner(nn.Module):
-    def __init__(self,
-                 topk=10,
-                 num_classes=80,
-                 alpha=0.5,
-                 beta=6.0, 
-                 eps=1e-9):
-        super(TaskAlignedAssigner, self).__init__()
-        self.topk = topk
-        self.num_classes = num_classes
-        self.bg_idx = num_classes
-        self.alpha = alpha
-        self.beta = beta
-        self.eps = eps
-
-    @torch.no_grad()
-    def forward(self,
-                pd_scores,
-                pd_bboxes,
-                anc_points,
-                gt_labels,
-                gt_bboxes):
-        """This code referenced to
-           https://github.com/Nioolek/PPYOLOE_pytorch/blob/master/ppyoloe/assigner/tal_assigner.py
-        Args:
-            pd_scores (Tensor): shape(bs, num_total_anchors, num_classes)
-            pd_bboxes (Tensor): shape(bs, num_total_anchors, 4)
-            anc_points (Tensor): shape(num_total_anchors, 2)
-            gt_labels (Tensor): shape(bs, n_max_boxes, 1)
-            gt_bboxes (Tensor): shape(bs, n_max_boxes, 4)
-        Returns:
-            target_labels (Tensor): shape(bs, num_total_anchors)
-            target_bboxes (Tensor): shape(bs, num_total_anchors, 4)
-            target_scores (Tensor): shape(bs, num_total_anchors, num_classes)
-            fg_mask (Tensor): shape(bs, num_total_anchors)
-        """
-        self.bs = pd_scores.size(0)
-        self.n_max_boxes = gt_bboxes.size(1)
-
-        mask_pos, align_metric, overlaps = self.get_pos_mask(
-            pd_scores, pd_bboxes, gt_labels, gt_bboxes, anc_points)
-
-        target_gt_idx, fg_mask, mask_pos = select_highest_overlaps(
-            mask_pos, overlaps, self.n_max_boxes)
-
-        # 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(axis=-1, keepdim=True)  # b, max_num_obj
-        pos_overlaps = (overlaps * mask_pos).amax(axis=-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):
-        # 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)
-        # get in_gts mask, (b, max_num_obj, h*w)
-        mask_in_gts = select_candidates_in_gts(anc_points, gt_bboxes)
-        # get topk_metric mask, (b, max_num_obj, h*w)
-        mask_topk = self.select_topk_candidates(align_metric * mask_in_gts)
-        # merge all mask to a final mask, (b, max_num_obj, h*w)
-        mask_pos = mask_topk * mask_in_gts
-
-        return mask_pos, align_metric, overlaps
-
-
-    def get_box_metrics(self, pd_scores, pd_bboxes, gt_labels, gt_bboxes):
-        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).repeat(1, self.n_max_boxes)  # b, max_num_obj
-        ind[1] = gt_labels.long().squeeze(-1)  # b, max_num_obj
-        # get the scores of each grid for each gt cls
-        bbox_scores = pd_scores[ind[0], :, ind[1]]  # b, max_num_obj, h*w
-
-        overlaps = bbox_iou(gt_bboxes.unsqueeze(2), pd_bboxes.unsqueeze(1), xywh=False,
-                            CIoU=True).squeeze(3).clamp(0)
-        align_metric = bbox_scores.pow(self.alpha) * overlaps.pow(self.beta)
-
-        return align_metric, overlaps
-
-
-    def select_topk_candidates(self, metrics, largest=True):
-        """
-        Args:
-            metrics: (b, max_num_obj, h*w).
-            topk_mask: (b, max_num_obj, topk) or None
-        """
-
-        num_anchors = metrics.shape[-1]  # h*w
-        # (b, max_num_obj, topk)
-        topk_metrics, topk_idxs = torch.topk(metrics, self.topk, dim=-1, largest=largest)
-        topk_mask = (topk_metrics.max(-1, keepdim=True)[0] > self.eps).tile([1, 1, self.topk])
-        # (b, max_num_obj, topk)
-        topk_idxs[~topk_mask] = 0
-        # (b, max_num_obj, topk, h*w) -> (b, max_num_obj, h*w)
-        is_in_topk = F.one_hot(topk_idxs, num_anchors).sum(-2)
-        # filter invalid bboxes
-        is_in_topk = torch.where(is_in_topk > 1, 0, is_in_topk)
-        return is_in_topk.to(metrics.dtype)
-
-
-    def get_targets(self, gt_labels, gt_bboxes, target_gt_idx, fg_mask):
-        """
-        Args:
-            gt_labels: (b, max_num_obj, 1)
-            gt_bboxes: (b, max_num_obj, 4)
-            target_gt_idx: (b, h*w)
-            fg_mask: (b, h*w)
-        """
-
-        # 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)
-        target_bboxes = gt_bboxes.view(-1, 4)[target_gt_idx]
-
-        # assigned target scores
-        target_labels.clamp(0)
-        target_scores = F.one_hot(target_labels, self.num_classes)  # (b, h*w, 80)
-        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
-    
-
-# -------------------------- Basic Functions --------------------------
-def select_candidates_in_gts(xy_centers, gt_bboxes, eps=1e-9):
-    """select the positive anchors's center in gt
-    Args:
-        xy_centers (Tensor): shape(bs*n_max_boxes, num_total_anchors, 4)
-        gt_bboxes (Tensor): shape(bs, n_max_boxes, 4)
-    Return:
-        (Tensor): shape(bs, n_max_boxes, num_total_anchors)
-    """
-    n_anchors = xy_centers.size(0)
-    bs, n_max_boxes, _ = gt_bboxes.size()
-    _gt_bboxes = gt_bboxes.reshape([-1, 4])
-    xy_centers = xy_centers.unsqueeze(0).repeat(bs * n_max_boxes, 1, 1)
-    gt_bboxes_lt = _gt_bboxes[:, 0:2].unsqueeze(1).repeat(1, n_anchors, 1)
-    gt_bboxes_rb = _gt_bboxes[:, 2:4].unsqueeze(1).repeat(1, n_anchors, 1)
-    b_lt = xy_centers - gt_bboxes_lt
-    b_rb = gt_bboxes_rb - xy_centers
-    bbox_deltas = torch.cat([b_lt, b_rb], dim=-1)
-    bbox_deltas = bbox_deltas.reshape([bs, n_max_boxes, n_anchors, -1])
-    return (bbox_deltas.min(axis=-1)[0] > eps).to(gt_bboxes.dtype)
-
-
-def select_highest_overlaps(mask_pos, overlaps, n_max_boxes):
-    """if an anchor box is assigned to multiple gts,
-        the one with the highest iou will be selected.
-    Args:
-        mask_pos (Tensor): shape(bs, n_max_boxes, num_total_anchors)
-        overlaps (Tensor): shape(bs, n_max_boxes, num_total_anchors)
-    Return:
-        target_gt_idx (Tensor): shape(bs, num_total_anchors)
-        fg_mask (Tensor): shape(bs, num_total_anchors)
-        mask_pos (Tensor): shape(bs, n_max_boxes, num_total_anchors)
-    """
-    fg_mask = mask_pos.sum(axis=-2)
-    if fg_mask.max() > 1:
-        mask_multi_gts = (fg_mask.unsqueeze(1) > 1).repeat([1, n_max_boxes, 1])
-        max_overlaps_idx = overlaps.argmax(axis=1)
-        is_max_overlaps = F.one_hot(max_overlaps_idx, n_max_boxes)
-        is_max_overlaps = is_max_overlaps.permute(0, 2, 1).to(overlaps.dtype)
-        mask_pos = torch.where(mask_multi_gts, is_max_overlaps, mask_pos)
-        fg_mask = mask_pos.sum(axis=-2)
-    target_gt_idx = mask_pos.argmax(axis=-2)
-    return target_gt_idx, fg_mask , mask_pos
-
-
-def iou_calculator(box1, box2, eps=1e-9):
-    """Calculate iou for batch
-    Args:
-        box1 (Tensor): shape(bs, n_max_boxes, 1, 4)
-        box2 (Tensor): shape(bs, 1, num_total_anchors, 4)
-    Return:
-        (Tensor): shape(bs, n_max_boxes, num_total_anchors)
-    """
-    box1 = box1.unsqueeze(2)  # [N, M1, 4] -> [N, M1, 1, 4]
-    box2 = box2.unsqueeze(1)  # [N, M2, 4] -> [N, 1, M2, 4]
-    px1y1, px2y2 = box1[:, :, :, 0:2], box1[:, :, :, 2:4]
-    gx1y1, gx2y2 = box2[:, :, :, 0:2], box2[:, :, :, 2:4]
-    x1y1 = torch.maximum(px1y1, gx1y1)
-    x2y2 = torch.minimum(px2y2, gx2y2)
-    overlap = (x2y2 - x1y1).clip(0).prod(-1)
-    area1 = (px2y2 - px1y1).clip(0).prod(-1)
-    area2 = (gx2y2 - gx1y1).clip(0).prod(-1)
-    union = area1 + area2 - overlap + eps
-
-    return overlap / union

train.sh

@@ -3,7 +3,7 @@ python train.py \
         --cuda \
         -d coco \
         --root /mnt/share/ssd2/dataset/ \
-        -m artdet_n \
+        -m yolox_l \
         -bs 16 \
         -size 640 \
         --wp_epoch 3 \