torch_em.model.unetr

  1from collections import OrderedDict
  2from typing import Optional, Tuple, Union
  3
  4import torch
  5import torch.nn as nn
  6import torch.nn.functional as F
  7
  8from .unet import Decoder, ConvBlock2d, Upsampler2d
  9from .vit import get_vision_transformer
 10
 11try:
 12    from micro_sam.util import get_sam_model
 13except ImportError:
 14    get_sam_model = None
 15
 16
 17#
 18# UNETR IMPLEMENTATION [Vision Transformer (ViT from MAE / ViT from SAM) + UNet Decoder from `torch_em`]
 19#
 20
 21
 22class UNETR(nn.Module):
 23
 24    def _load_encoder_from_checkpoint(self, backbone, encoder, checkpoint):
 25
 26        if isinstance(checkpoint, str):
 27            if backbone == "sam" and isinstance(encoder, str):
 28                # If we have a SAM encoder, then we first try to load the full SAM Model
 29                # (using micro_sam) and otherwise fall back on directly loading the encoder state
 30                # from the checkpoint
 31                try:
 32                    _, model = get_sam_model(
 33                        model_type=encoder,
 34                        checkpoint_path=checkpoint,
 35                        return_sam=True
 36                    )
 37                    encoder_state = model.image_encoder.state_dict()
 38                except Exception:
 39                    # Try loading the encoder state directly from a checkpoint.
 40                    encoder_state = torch.load(checkpoint)
 41
 42            elif backbone == "mae":
 43                # vit initialization hints from:
 44                #     - https://github.com/facebookresearch/mae/blob/main/main_finetune.py#L233-L242
 45                encoder_state = torch.load(checkpoint)["model"]
 46                encoder_state = OrderedDict({
 47                    k: v for k, v in encoder_state.items()
 48                    if (k != "mask_token" and not k.startswith("decoder"))
 49                })
 50
 51                # let's remove the `head` from our current encoder (as the MAE pretrained don't expect it)
 52                current_encoder_state = self.encoder.state_dict()
 53                if ("head.weight" in current_encoder_state) and ("head.bias" in current_encoder_state):
 54                    del self.encoder.head
 55
 56        else:
 57            encoder_state = checkpoint
 58
 59        self.encoder.load_state_dict(encoder_state)
 60
 61    def __init__(
 62        self,
 63        img_size: int = 1024,
 64        backbone: str = "sam",
 65        encoder: Optional[Union[nn.Module, str]] = "vit_b",
 66        decoder: Optional[nn.Module] = None,
 67        out_channels: int = 1,
 68        use_sam_stats: bool = False,
 69        use_mae_stats: bool = False,
 70        resize_input: bool = True,
 71        encoder_checkpoint: Optional[Union[str, OrderedDict]] = None,
 72        final_activation: Optional[Union[str, nn.Module]] = None,
 73        use_skip_connection: bool = True,
 74        embed_dim: Optional[int] = None,
 75        use_conv_transpose=True,
 76    ) -> None:
 77        super().__init__()
 78
 79        self.use_sam_stats = use_sam_stats
 80        self.use_mae_stats = use_mae_stats
 81        self.use_skip_connection = use_skip_connection
 82        self.resize_input = resize_input
 83
 84        if isinstance(encoder, str):  # "vit_b" / "vit_l" / "vit_h"
 85            print(f"Using {encoder} from {backbone.upper()}")
 86            self.encoder = get_vision_transformer(img_size=img_size, backbone=backbone, model=encoder)
 87            if encoder_checkpoint is not None:
 88                self._load_encoder_from_checkpoint(backbone, encoder, encoder_checkpoint)
 89
 90            in_chans = self.encoder.in_chans
 91            if embed_dim is None:
 92                embed_dim = self.encoder.embed_dim
 93
 94        else:  # `nn.Module` ViT backbone
 95            self.encoder = encoder
 96
 97            have_neck = False
 98            for name, _ in self.encoder.named_parameters():
 99                if name.startswith("neck"):
100                    have_neck = True
101
102            if embed_dim is None:
103                if have_neck:
104                    embed_dim = self.encoder.neck[2].out_channels  # the value is 256
105                else:
106                    embed_dim = self.encoder.patch_embed.proj.out_channels
107
108            try:
109                in_chans = self.encoder.patch_embed.proj.in_channels
110            except AttributeError:  # for getting the input channels while using vit_t from MobileSam
111                in_chans = self.encoder.patch_embed.seq[0].c.in_channels
112
113        # parameters for the decoder network
114        depth = 3
115        initial_features = 64
116        gain = 2
117        features_decoder = [initial_features * gain ** i for i in range(depth + 1)][::-1]
118        scale_factors = depth * [2]
119        self.out_channels = out_channels
120
121        # choice of upsampler - to use (bilinear interpolation + conv) or conv transpose
122        _upsampler = SingleDeconv2DBlock if use_conv_transpose else Upsampler2d
123
124        if decoder is None:
125            self.decoder = Decoder(
126                features=features_decoder,
127                scale_factors=scale_factors[::-1],
128                conv_block_impl=ConvBlock2d,
129                sampler_impl=_upsampler,
130                norm="OldDefault",
131            )
132        else:
133            self.decoder = decoder
134
135        if use_skip_connection:
136            self.deconv1 = Deconv2DBlock(embed_dim, features_decoder[0])
137            self.deconv2 = nn.Sequential(
138                Deconv2DBlock(embed_dim, features_decoder[0]),
139                Deconv2DBlock(features_decoder[0], features_decoder[1])
140            )
141            self.deconv3 = nn.Sequential(
142                Deconv2DBlock(embed_dim, features_decoder[0]),
143                Deconv2DBlock(features_decoder[0], features_decoder[1]),
144                Deconv2DBlock(features_decoder[1], features_decoder[2])
145            )
146            self.deconv4 = ConvBlock2d(in_chans, features_decoder[-1], norm="OldDefault")
147        else:
148            self.deconv1 = Deconv2DBlock(embed_dim, features_decoder[0])
149            self.deconv2 = Deconv2DBlock(features_decoder[0], features_decoder[1])
150            self.deconv3 = Deconv2DBlock(features_decoder[1], features_decoder[2])
151            self.deconv4 = Deconv2DBlock(features_decoder[2], features_decoder[3])
152
153        self.base = ConvBlock2d(embed_dim, features_decoder[0], norm="OldDefault")
154
155        self.out_conv = nn.Conv2d(features_decoder[-1], out_channels, 1)
156
157        self.deconv_out = _upsampler(
158            scale_factor=2, in_channels=features_decoder[-1], out_channels=features_decoder[-1]
159        )
160
161        self.decoder_head = ConvBlock2d(2 * features_decoder[-1], features_decoder[-1], norm="OldDefault")
162
163        self.final_activation = self._get_activation(final_activation)
164
165    def _get_activation(self, activation):
166        return_activation = None
167        if activation is None:
168            return None
169        if isinstance(activation, nn.Module):
170            return activation
171        if isinstance(activation, str):
172            return_activation = getattr(nn, activation, None)
173        if return_activation is None:
174            raise ValueError(f"Invalid activation: {activation}")
175        return return_activation()
176
177    @staticmethod
178    def get_preprocess_shape(oldh: int, oldw: int, long_side_length: int) -> Tuple[int, int]:
179        """Compute the output size given input size and target long side length.
180        """
181        scale = long_side_length * 1.0 / max(oldh, oldw)
182        newh, neww = oldh * scale, oldw * scale
183        neww = int(neww + 0.5)
184        newh = int(newh + 0.5)
185        return (newh, neww)
186
187    def resize_longest_side(self, image: torch.Tensor) -> torch.Tensor:
188        """Resizes the image so that the longest side has the correct length.
189
190        Expects batched images with shape BxCxHxW and float format.
191        """
192        target_size = self.get_preprocess_shape(image.shape[2], image.shape[3], self.encoder.img_size)
193        return F.interpolate(
194            image, target_size, mode="bilinear", align_corners=False, antialias=True
195        )
196
197    def preprocess(self, x: torch.Tensor) -> torch.Tensor:
198        device = x.device
199
200        if self.use_sam_stats:
201            pixel_mean = torch.Tensor([123.675, 116.28, 103.53]).view(1, -1, 1, 1).to(device)
202            pixel_std = torch.Tensor([58.395, 57.12, 57.375]).view(1, -1, 1, 1).to(device)
203        elif self.use_mae_stats:
204            # TODO: add mean std from mae experiments (or open up arguments for this)
205            raise NotImplementedError
206        else:
207            pixel_mean = torch.Tensor([0.0, 0.0, 0.0]).view(1, -1, 1, 1).to(device)
208            pixel_std = torch.Tensor([1.0, 1.0, 1.0]).view(1, -1, 1, 1).to(device)
209
210        if self.resize_input:
211            x = self.resize_longest_side(x)
212        input_shape = x.shape[-2:]
213
214        x = (x - pixel_mean) / pixel_std
215        h, w = x.shape[-2:]
216        padh = self.encoder.img_size - h
217        padw = self.encoder.img_size - w
218        x = F.pad(x, (0, padw, 0, padh))
219        return x, input_shape
220
221    def postprocess_masks(
222        self,
223        masks: torch.Tensor,
224        input_size: Tuple[int, ...],
225        original_size: Tuple[int, ...],
226    ) -> torch.Tensor:
227        masks = F.interpolate(
228            masks,
229            (self.encoder.img_size, self.encoder.img_size),
230            mode="bilinear",
231            align_corners=False,
232        )
233        masks = masks[..., : input_size[0], : input_size[1]]
234        masks = F.interpolate(masks, original_size, mode="bilinear", align_corners=False)
235        return masks
236
237    def forward(self, x):
238        original_shape = x.shape[-2:]
239
240        # Reshape the inputs to the shape expected by the encoder
241        # and normalize the inputs if normalization is part of the model.
242        x, input_shape = self.preprocess(x)
243
244        use_skip_connection = getattr(self, "use_skip_connection", True)
245
246        encoder_outputs = self.encoder(x)
247
248        if isinstance(encoder_outputs[-1], list):
249            # `encoder_outputs` can be arranged in only two forms:
250            #   - either we only return the image embeddings
251            #   - or, we return the image embeddings and the "list" of global attention layers
252            z12, from_encoder = encoder_outputs
253        else:
254            z12 = encoder_outputs
255
256        if use_skip_connection:
257            from_encoder = from_encoder[::-1]
258            z9 = self.deconv1(from_encoder[0])
259            z6 = self.deconv2(from_encoder[1])
260            z3 = self.deconv3(from_encoder[2])
261            z0 = self.deconv4(x)
262
263        else:
264            z9 = self.deconv1(z12)
265            z6 = self.deconv2(z9)
266            z3 = self.deconv3(z6)
267            z0 = self.deconv4(z3)
268
269        updated_from_encoder = [z9, z6, z3]
270
271        x = self.base(z12)
272        x = self.decoder(x, encoder_inputs=updated_from_encoder)
273        x = self.deconv_out(x)
274
275        x = torch.cat([x, z0], dim=1)
276        x = self.decoder_head(x)
277
278        x = self.out_conv(x)
279        if self.final_activation is not None:
280            x = self.final_activation(x)
281
282        x = self.postprocess_masks(x, input_shape, original_shape)
283        return x
284
285
286#
287#  ADDITIONAL FUNCTIONALITIES
288#
289
290
291class SingleDeconv2DBlock(nn.Module):
292    def __init__(self, scale_factor, in_channels, out_channels):
293        super().__init__()
294        self.block = nn.ConvTranspose2d(in_channels, out_channels, kernel_size=2, stride=2, padding=0, output_padding=0)
295
296    def forward(self, x):
297        return self.block(x)
298
299
300class SingleConv2DBlock(nn.Module):
301    def __init__(self, in_channels, out_channels, kernel_size):
302        super().__init__()
303        self.block = nn.Conv2d(
304            in_channels, out_channels, kernel_size=kernel_size, stride=1, padding=((kernel_size - 1) // 2)
305        )
306
307    def forward(self, x):
308        return self.block(x)
309
310
311class Conv2DBlock(nn.Module):
312    def __init__(self, in_channels, out_channels, kernel_size=3):
313        super().__init__()
314        self.block = nn.Sequential(
315            SingleConv2DBlock(in_channels, out_channels, kernel_size),
316            nn.BatchNorm2d(out_channels),
317            nn.ReLU(True)
318        )
319
320    def forward(self, x):
321        return self.block(x)
322
323
324class Deconv2DBlock(nn.Module):
325    def __init__(self, in_channels, out_channels, kernel_size=3, use_conv_transpose=True):
326        super().__init__()
327        _upsampler = SingleDeconv2DBlock if use_conv_transpose else Upsampler2d
328        self.block = nn.Sequential(
329            _upsampler(scale_factor=2, in_channels=in_channels, out_channels=out_channels),
330            SingleConv2DBlock(out_channels, out_channels, kernel_size),
331            nn.BatchNorm2d(out_channels),
332            nn.ReLU(True)
333        )
334
335    def forward(self, x):
336        return self.block(x)