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# Ultralytics YOLO 🚀, AGPL-3.0 license
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"""
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Model head modules
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"""
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import math
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import torch
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import torch.nn as nn
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from torch.nn.init import constant_, xavier_uniform_
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from ultralytics.utils.tal import dist2bbox, make_anchors
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from .block import DFL, Proto
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from .conv import Conv
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from .transformer import MLP, DeformableTransformerDecoder, DeformableTransformerDecoderLayer
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from .utils import bias_init_with_prob, linear_init_
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__all__ = 'Detect', 'Segment', 'Pose', 'Classify', 'RTDETRDecoder'
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class Detect(nn.Module):
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"""YOLOv8 Detect head for detection models."""
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dynamic = False # force grid reconstruction
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export = False # export mode
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shape = None
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anchors = torch.empty(0) # init
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strides = torch.empty(0) # init
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def __init__(self, nc=80, ch=()): # detection layer
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super().__init__()
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self.nc = nc # number of classes
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self.nl = len(ch) # number of detection layers
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self.reg_max = 16 # DFL channels (ch[0] // 16 to scale 4/8/12/16/20 for n/s/m/l/x)
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self.no = nc + self.reg_max * 4 # number of outputs per anchor
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self.stride = torch.zeros(self.nl) # strides computed during build
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c2, c3 = max((16, ch[0] // 4, self.reg_max * 4)), max(ch[0], min(self.nc, 100)) # channels
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self.cv2 = nn.ModuleList(
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nn.Sequential(Conv(x, c2, 3), Conv(c2, c2, 3), nn.Conv2d(c2, 4 * self.reg_max, 1)) for x in ch)
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self.cv3 = nn.ModuleList(nn.Sequential(Conv(x, c3, 3), Conv(c3, c3, 3), nn.Conv2d(c3, self.nc, 1)) for x in ch)
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self.dfl = DFL(self.reg_max) if self.reg_max > 1 else nn.Identity()
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def forward(self, x):
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"""Concatenates and returns predicted bounding boxes and class probabilities."""
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shape = x[0].shape # BCHW
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for i in range(self.nl):
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x[i] = torch.cat((self.cv2[i](x[i]), self.cv3[i](x[i])), 1)
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if self.training:
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return x
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elif self.dynamic or self.shape != shape:
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self.anchors, self.strides = (x.transpose(0, 1) for x in make_anchors(x, self.stride, 0.5))
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self.shape = shape
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x_cat = torch.cat([xi.view(shape[0], self.no, -1) for xi in x], 2)
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if self.export and self.format in ('saved_model', 'pb', 'tflite', 'edgetpu', 'tfjs'): # avoid TF FlexSplitV ops
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box = x_cat[:, :self.reg_max * 4]
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cls = x_cat[:, self.reg_max * 4:]
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else:
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box, cls = x_cat.split((self.reg_max * 4, self.nc), 1)
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dbox = dist2bbox(self.dfl(box), self.anchors.unsqueeze(0), xywh=True, dim=1) * self.strides
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if self.export and self.format in ('tflite', 'edgetpu'):
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# Normalize xywh with image size to mitigate quantization error of TFLite integer models as done in YOLOv5:
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# https://github.com/ultralytics/yolov5/blob/0c8de3fca4a702f8ff5c435e67f378d1fce70243/models/tf.py#L307-L309
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# See this PR for details: https://github.com/ultralytics/ultralytics/pull/1695
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img_h = shape[2] * self.stride[0]
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img_w = shape[3] * self.stride[0]
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img_size = torch.tensor([img_w, img_h, img_w, img_h], device=dbox.device).reshape(1, 4, 1)
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dbox /= img_size
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y = torch.cat((dbox, cls.sigmoid()), 1)
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return y if self.export else (y, x)
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def bias_init(self):
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"""Initialize Detect() biases, WARNING: requires stride availability."""
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m = self # self.model[-1] # Detect() module
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# cf = torch.bincount(torch.tensor(np.concatenate(dataset.labels, 0)[:, 0]).long(), minlength=nc) + 1
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# ncf = math.log(0.6 / (m.nc - 0.999999)) if cf is None else torch.log(cf / cf.sum()) # nominal class frequency
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for a, b, s in zip(m.cv2, m.cv3, m.stride): # from
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a[-1].bias.data[:] = 1.0 # box
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b[-1].bias.data[:m.nc] = math.log(5 / m.nc / (640 / s) ** 2) # cls (.01 objects, 80 classes, 640 img)
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class Segment(Detect):
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"""YOLOv8 Segment head for segmentation models."""
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def __init__(self, nc=80, nm=32, npr=256, ch=()):
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"""Initialize the YOLO model attributes such as the number of masks, prototypes, and the convolution layers."""
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super().__init__(nc, ch)
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self.nm = nm # number of masks
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self.npr = npr # number of protos
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self.proto = Proto(ch[0], self.npr, self.nm) # protos
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self.detect = Detect.forward
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c4 = max(ch[0] // 4, self.nm)
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self.cv4 = nn.ModuleList(nn.Sequential(Conv(x, c4, 3), Conv(c4, c4, 3), nn.Conv2d(c4, self.nm, 1)) for x in ch)
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def forward(self, x):
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"""Return model outputs and mask coefficients if training, otherwise return outputs and mask coefficients."""
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p = self.proto(x[0]) # mask protos
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bs = p.shape[0] # batch size
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mc = torch.cat([self.cv4[i](x[i]).view(bs, self.nm, -1) for i in range(self.nl)], 2) # mask coefficients
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x = self.detect(self, x)
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if self.training:
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return x, mc, p
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return (torch.cat([x, mc], 1), p) if self.export else (torch.cat([x[0], mc], 1), (x[1], mc, p))
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class Pose(Detect):
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"""YOLOv8 Pose head for keypoints models."""
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def __init__(self, nc=80, kpt_shape=(17, 3), ch=()):
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"""Initialize YOLO network with default parameters and Convolutional Layers."""
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super().__init__(nc, ch)
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self.kpt_shape = kpt_shape # number of keypoints, number of dims (2 for x,y or 3 for x,y,visible)
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self.nk = kpt_shape[0] * kpt_shape[1] # number of keypoints total
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self.detect = Detect.forward
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c4 = max(ch[0] // 4, self.nk)
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self.cv4 = nn.ModuleList(nn.Sequential(Conv(x, c4, 3), Conv(c4, c4, 3), nn.Conv2d(c4, self.nk, 1)) for x in ch)
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def forward(self, x):
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"""Perform forward pass through YOLO model and return predictions."""
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bs = x[0].shape[0] # batch size
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kpt = torch.cat([self.cv4[i](x[i]).view(bs, self.nk, -1) for i in range(self.nl)], -1) # (bs, 17*3, h*w)
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x = self.detect(self, x)
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if self.training:
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return x, kpt
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pred_kpt = self.kpts_decode(bs, kpt)
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return torch.cat([x, pred_kpt], 1) if self.export else (torch.cat([x[0], pred_kpt], 1), (x[1], kpt))
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def kpts_decode(self, bs, kpts):
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"""Decodes keypoints."""
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ndim = self.kpt_shape[1]
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if self.export: # required for TFLite export to avoid 'PLACEHOLDER_FOR_GREATER_OP_CODES' bug
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y = kpts.view(bs, *self.kpt_shape, -1)
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a = (y[:, :, :2] * 2.0 + (self.anchors - 0.5)) * self.strides
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if ndim == 3:
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a = torch.cat((a, y[:, :, 2:3].sigmoid()), 2)
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return a.view(bs, self.nk, -1)
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else:
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y = kpts.clone()
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if ndim == 3:
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y[:, 2::3].sigmoid_() # inplace sigmoid
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y[:, 0::ndim] = (y[:, 0::ndim] * 2.0 + (self.anchors[0] - 0.5)) * self.strides
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y[:, 1::ndim] = (y[:, 1::ndim] * 2.0 + (self.anchors[1] - 0.5)) * self.strides
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return y
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class Classify(nn.Module):
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"""YOLOv8 classification head, i.e. x(b,c1,20,20) to x(b,c2)."""
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def __init__(self, c1, c2, k=1, s=1, p=None, g=1): # ch_in, ch_out, kernel, stride, padding, groups
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super().__init__()
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c_ = 1280 # efficientnet_b0 size
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self.conv = Conv(c1, c_, k, s, p, g)
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self.pool = nn.AdaptiveAvgPool2d(1) # to x(b,c_,1,1)
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self.drop = nn.Dropout(p=0.0, inplace=True)
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self.linear = nn.Linear(c_, c2) # to x(b,c2)
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def forward(self, x):
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"""Performs a forward pass of the YOLO model on input image data."""
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if isinstance(x, list):
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x = torch.cat(x, 1)
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x = self.linear(self.drop(self.pool(self.conv(x)).flatten(1)))
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return x if self.training else x.softmax(1)
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class RTDETRDecoder(nn.Module):
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export = False # export mode
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def __init__(
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self,
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nc=80,
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ch=(512, 1024, 2048),
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hd=256, # hidden dim
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nq=300, # num queries
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ndp=4, # num decoder points
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nh=8, # num head
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ndl=6, # num decoder layers
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d_ffn=1024, # dim of feedforward
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dropout=0.,
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act=nn.ReLU(),
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eval_idx=-1,
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# training args
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nd=100, # num denoising
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label_noise_ratio=0.5,
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box_noise_scale=1.0,
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learnt_init_query=False):
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super().__init__()
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self.hidden_dim = hd
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self.nhead = nh
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self.nl = len(ch) # num level
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self.nc = nc
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self.num_queries = nq
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self.num_decoder_layers = ndl
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# backbone feature projection
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self.input_proj = nn.ModuleList(nn.Sequential(nn.Conv2d(x, hd, 1, bias=False), nn.BatchNorm2d(hd)) for x in ch)
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# NOTE: simplified version but it's not consistent with .pt weights.
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# self.input_proj = nn.ModuleList(Conv(x, hd, act=False) for x in ch)
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# Transformer module
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decoder_layer = DeformableTransformerDecoderLayer(hd, nh, d_ffn, dropout, act, self.nl, ndp)
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self.decoder = DeformableTransformerDecoder(hd, decoder_layer, ndl, eval_idx)
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# denoising part
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self.denoising_class_embed = nn.Embedding(nc, hd)
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self.num_denoising = nd
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self.label_noise_ratio = label_noise_ratio
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self.box_noise_scale = box_noise_scale
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# decoder embedding
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self.learnt_init_query = learnt_init_query
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if learnt_init_query:
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self.tgt_embed = nn.Embedding(nq, hd)
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self.query_pos_head = MLP(4, 2 * hd, hd, num_layers=2)
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# encoder head
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self.enc_output = nn.Sequential(nn.Linear(hd, hd), nn.LayerNorm(hd))
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self.enc_score_head = nn.Linear(hd, nc)
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self.enc_bbox_head = MLP(hd, hd, 4, num_layers=3)
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# decoder head
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self.dec_score_head = nn.ModuleList([nn.Linear(hd, nc) for _ in range(ndl)])
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self.dec_bbox_head = nn.ModuleList([MLP(hd, hd, 4, num_layers=3) for _ in range(ndl)])
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self._reset_parameters()
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def forward(self, x, batch=None):
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from ultralytics.models.utils.ops import get_cdn_group
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# input projection and embedding
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feats, shapes = self._get_encoder_input(x)
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# prepare denoising training
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dn_embed, dn_bbox, attn_mask, dn_meta = \
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get_cdn_group(batch,
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self.nc,
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self.num_queries,
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self.denoising_class_embed.weight,
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self.num_denoising,
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self.label_noise_ratio,
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self.box_noise_scale,
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self.training)
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embed, refer_bbox, enc_bboxes, enc_scores = \
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self._get_decoder_input(feats, shapes, dn_embed, dn_bbox)
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# decoder
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dec_bboxes, dec_scores = self.decoder(embed,
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refer_bbox,
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feats,
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shapes,
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self.dec_bbox_head,
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self.dec_score_head,
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self.query_pos_head,
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attn_mask=attn_mask)
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x = dec_bboxes, dec_scores, enc_bboxes, enc_scores, dn_meta
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if self.training:
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return x
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# (bs, 300, 4+nc)
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y = torch.cat((dec_bboxes.squeeze(0), dec_scores.squeeze(0).sigmoid()), -1)
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return y if self.export else (y, x)
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def _generate_anchors(self, shapes, grid_size=0.05, dtype=torch.float32, device='cpu', eps=1e-2):
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anchors = []
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for i, (h, w) in enumerate(shapes):
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grid_y, grid_x = torch.meshgrid(torch.arange(end=h, dtype=dtype, device=device),
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torch.arange(end=w, dtype=dtype, device=device),
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indexing='ij')
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grid_xy = torch.stack([grid_x, grid_y], -1) # (h, w, 2)
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valid_WH = torch.tensor([h, w], dtype=dtype, device=device)
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grid_xy = (grid_xy.unsqueeze(0) + 0.5) / valid_WH # (1, h, w, 2)
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wh = torch.ones_like(grid_xy, dtype=dtype, device=device) * grid_size * (2.0 ** i)
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anchors.append(torch.cat([grid_xy, wh], -1).view(-1, h * w, 4)) # (1, h*w, 4)
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anchors = torch.cat(anchors, 1) # (1, h*w*nl, 4)
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valid_mask = ((anchors > eps) * (anchors < 1 - eps)).all(-1, keepdim=True) # 1, h*w*nl, 1
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anchors = torch.log(anchors / (1 - anchors))
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anchors = anchors.masked_fill(~valid_mask, float('inf'))
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return anchors, valid_mask
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def _get_encoder_input(self, x):
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# get projection features
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x = [self.input_proj[i](feat) for i, feat in enumerate(x)]
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# get encoder inputs
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feats = []
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shapes = []
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for feat in x:
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h, w = feat.shape[2:]
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# [b, c, h, w] -> [b, h*w, c]
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feats.append(feat.flatten(2).permute(0, 2, 1))
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# [nl, 2]
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shapes.append([h, w])
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# [b, h*w, c]
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feats = torch.cat(feats, 1)
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return feats, shapes
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def _get_decoder_input(self, feats, shapes, dn_embed=None, dn_bbox=None):
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bs = len(feats)
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# prepare input for decoder
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anchors, valid_mask = self._generate_anchors(shapes, dtype=feats.dtype, device=feats.device)
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features = self.enc_output(valid_mask * feats) # bs, h*w, 256
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enc_outputs_scores = self.enc_score_head(features) # (bs, h*w, nc)
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# query selection
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# (bs, num_queries)
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topk_ind = torch.topk(enc_outputs_scores.max(-1).values, self.num_queries, dim=1).indices.view(-1)
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# (bs, num_queries)
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batch_ind = torch.arange(end=bs, dtype=topk_ind.dtype).unsqueeze(-1).repeat(1, self.num_queries).view(-1)
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# (bs, num_queries, 256)
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top_k_features = features[batch_ind, topk_ind].view(bs, self.num_queries, -1)
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# (bs, num_queries, 4)
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top_k_anchors = anchors[:, topk_ind].view(bs, self.num_queries, -1)
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# dynamic anchors + static content
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refer_bbox = self.enc_bbox_head(top_k_features) + top_k_anchors
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enc_bboxes = refer_bbox.sigmoid()
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if dn_bbox is not None:
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refer_bbox = torch.cat([dn_bbox, refer_bbox], 1)
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enc_scores = enc_outputs_scores[batch_ind, topk_ind].view(bs, self.num_queries, -1)
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embeddings = self.tgt_embed.weight.unsqueeze(0).repeat(bs, 1, 1) if self.learnt_init_query else top_k_features
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if self.training:
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refer_bbox = refer_bbox.detach()
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if not self.learnt_init_query:
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embeddings = embeddings.detach()
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if dn_embed is not None:
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embeddings = torch.cat([dn_embed, embeddings], 1)
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return embeddings, refer_bbox, enc_bboxes, enc_scores
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# TODO
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def _reset_parameters(self):
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# class and bbox head init
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bias_cls = bias_init_with_prob(0.01) / 80 * self.nc
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# NOTE: the weight initialization in `linear_init_` would cause NaN when training with custom datasets.
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# linear_init_(self.enc_score_head)
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constant_(self.enc_score_head.bias, bias_cls)
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constant_(self.enc_bbox_head.layers[-1].weight, 0.)
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constant_(self.enc_bbox_head.layers[-1].bias, 0.)
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for cls_, reg_ in zip(self.dec_score_head, self.dec_bbox_head):
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# linear_init_(cls_)
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constant_(cls_.bias, bias_cls)
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constant_(reg_.layers[-1].weight, 0.)
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constant_(reg_.layers[-1].bias, 0.)
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linear_init_(self.enc_output[0])
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xavier_uniform_(self.enc_output[0].weight)
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if self.learnt_init_query:
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xavier_uniform_(self.tgt_embed.weight)
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xavier_uniform_(self.query_pos_head.layers[0].weight)
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xavier_uniform_(self.query_pos_head.layers[1].weight)
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for layer in self.input_proj:
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xavier_uniform_(layer[0].weight)
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