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from __future__ import annotations |
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from collections.abc import Sequence |
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import numpy as np |
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import torch |
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import torch.nn as nn |
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from monai.networks.blocks import Convolution, ResidualUnit |
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from monai.networks.layers.factories import Act, Norm |
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from monai.networks.layers.simplelayers import Reshape |
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from monai.utils import ensure_tuple, ensure_tuple_rep |
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class Generator(nn.Module): |
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""" |
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Defines a simple generator network accepting a latent vector and through a sequence of convolution layers |
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constructs an output tensor of greater size and high dimensionality. The method `_get_layer` is used to |
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create each of these layers, override this method to define layers beyond the default |
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:py:class:`monai.networks.blocks.Convolution` or :py:class:`monai.networks.blocks.ResidualUnit` layers. |
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The layers are constructed using the values in the `channels` and `strides` arguments, the number being defined by |
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the length of these (which must match). Input is first passed through a :py:class:`torch.nn.Linear` layer to |
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convert the input vector to an image tensor with dimensions `start_shape`. This passes through the convolution |
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layers and is progressively upsampled if the `strides` values are greater than 1 using transpose convolutions. The |
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size of the final output is defined by the `start_shape` dimension and the amount of upsampling done through |
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strides. In the default definition the size of the output's spatial dimensions will be that of `start_shape` |
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multiplied by the product of `strides`, thus the example network below upsamples an starting size of (64, 8, 8) |
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to (1, 64, 64) since its `strides` are (2, 2, 2). |
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Args: |
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latent_shape: tuple of integers stating the dimension of the input latent vector (minus batch dimension) |
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start_shape: tuple of integers stating the dimension of the tensor to pass to convolution subnetwork |
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channels: tuple of integers stating the output channels of each convolutional layer |
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strides: tuple of integers stating the stride (upscale factor) of each convolutional layer |
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kernel_size: integer or tuple of integers stating size of convolutional kernels |
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num_res_units: integer stating number of convolutions in residual units, 0 means no residual units |
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act: name or type defining activation layers |
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norm: name or type defining normalization layers |
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dropout: optional float value in range [0, 1] stating dropout probability for layers, None for no dropout |
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bias: boolean stating if convolution layers should have a bias component |
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Examples:: |
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# 3 layers, latent input vector of shape (42, 24), output volume of shape (1, 64, 64) |
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net = Generator((42, 24), (64, 8, 8), (32, 16, 1), (2, 2, 2)) |
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""" |
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def __init__( |
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self, |
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latent_shape: Sequence[int], |
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start_shape: Sequence[int], |
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channels: Sequence[int], |
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strides: Sequence[int], |
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kernel_size: Sequence[int] | int = 3, |
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num_res_units: int = 2, |
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act=Act.PRELU, |
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norm=Norm.INSTANCE, |
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dropout: float | None = None, |
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bias: bool = True, |
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) -> None: |
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super().__init__() |
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self.in_channels, *self.start_shape = ensure_tuple(start_shape) |
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self.dimensions = len(self.start_shape) |
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self.latent_shape = ensure_tuple(latent_shape) |
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self.channels = ensure_tuple(channels) |
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self.strides = ensure_tuple(strides) |
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self.kernel_size = ensure_tuple_rep(kernel_size, self.dimensions) |
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self.num_res_units = num_res_units |
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self.act = act |
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self.norm = norm |
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self.dropout = dropout |
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self.bias = bias |
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self.flatten = nn.Flatten() |
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self.linear = nn.Linear(int(np.prod(self.latent_shape)), int(np.prod(start_shape))) |
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self.reshape = Reshape(*start_shape) |
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self.conv = nn.Sequential() |
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echannel = self.in_channels |
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for i, (c, s) in enumerate(zip(channels, strides)): |
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is_last = i == len(channels) - 1 |
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layer = self._get_layer(echannel, c, s, is_last) |
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self.conv.add_module("layer_%i" % i, layer) |
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echannel = c |
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def _get_layer( |
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self, in_channels: int, out_channels: int, strides: int, is_last: bool |
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) -> Convolution | nn.Sequential: |
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""" |
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Returns a layer accepting inputs with `in_channels` number of channels and producing outputs of `out_channels` |
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number of channels. The `strides` indicates upsampling factor, ie. transpose convolutional stride. If `is_last` |
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is True this is the final layer and is not expected to include activation and normalization layers. |
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""" |
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layer: Convolution | nn.Sequential |
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layer = Convolution( |
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in_channels=in_channels, |
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strides=strides, |
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is_transposed=True, |
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conv_only=is_last or self.num_res_units > 0, |
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spatial_dims=self.dimensions, |
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out_channels=out_channels, |
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kernel_size=self.kernel_size, |
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act=self.act, |
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norm=self.norm, |
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dropout=self.dropout, |
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bias=self.bias, |
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) |
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if self.num_res_units > 0: |
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ru = ResidualUnit( |
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in_channels=out_channels, |
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subunits=self.num_res_units, |
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last_conv_only=is_last, |
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spatial_dims=self.dimensions, |
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out_channels=out_channels, |
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kernel_size=self.kernel_size, |
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act=self.act, |
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norm=self.norm, |
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dropout=self.dropout, |
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bias=self.bias, |
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) |
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layer = nn.Sequential(layer, ru) |
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return layer |
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def forward(self, x: torch.Tensor) -> torch.Tensor: |
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x = self.flatten(x) |
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x = self.linear(x) |
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x = self.reshape(x) |
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x = self.conv(x) |
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return x |
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