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import torch

from torch import nn

import numpy as np

import matplotlib.pyplot as plt

import pdb

from networks.resnet3d import resnet34

class ConvBlock(nn.Module):

def __init__(self, n_stages, n_filters_in, n_filters_out, normalization='none'):

super(ConvBlock, self).__init__()

ops = []

for i in range(n_stages):

if i == 0:

input_channel = n_filters_in

else:

input_channel = n_filters_out

ops.append(nn.Conv3d(input_channel, n_filters_out, 3, padding=1))

if normalization == 'batchnorm':

ops.append(nn.BatchNorm3d(n_filters_out))

elif normalization == 'groupnorm':

ops.append(nn.GroupNorm(num_groups=16, num_channels=n_filters_out))

elif normalization == 'instancenorm':

ops.append(nn.InstanceNorm3d(n_filters_out))

elif normalization != 'none':

assert False

ops.append(nn.ReLU(inplace=True))

self.conv = nn.Sequential(*ops)

def forward(self, x):

x = self.conv(x)

return x

class DownsamplingConvBlock(nn.Module):

def __init__(self, n_filters_in, n_filters_out, stride=2, normalization='none'):

super(DownsamplingConvBlock, self).__init__()

ops = []

if normalization != 'none':

ops.append(nn.Conv3d(n_filters_in, n_filters_out, stride, padding=0, stride=stride))

if normalization == 'batchnorm':

ops.append(nn.BatchNorm3d(n_filters_out))

elif normalization == 'groupnorm':

ops.append(nn.GroupNorm(num_groups=16, num_channels=n_filters_out))

elif normalization == 'instancenorm':

ops.append(nn.InstanceNorm3d(n_filters_out))

else:

assert False

else:

ops.append(nn.Conv3d(n_filters_in, n_filters_out, stride, padding=0, stride=stride))

ops.append(nn.ReLU(inplace=True))

self.conv = nn.Sequential(*ops)

def forward(self, x):

x = self.conv(x)

return x

class UpsamplingDeconvBlock(nn.Module):

def __init__(self, n_filters_in, n_filters_out, stride=2, normalization='none'):

super(UpsamplingDeconvBlock, self).__init__()

ops = []

if normalization != 'none':

ops.append(nn.ConvTranspose3d(n_filters_in, n_filters_out, stride, padding=0, stride=stride))

if normalization == 'batchnorm':

ops.append(nn.BatchNorm3d(n_filters_out))

elif normalization == 'groupnorm':

ops.append(nn.GroupNorm(num_groups=16, num_channels=n_filters_out))

elif normalization == 'instancenorm':

ops.append(nn.InstanceNorm3d(n_filters_out))

else:

assert False

else:

ops.append(nn.ConvTranspose3d(n_filters_in, n_filters_out, stride, padding=0, stride=stride))

ops.append(nn.ReLU(inplace=True))

self.conv = nn.Sequential(*ops)

def forward(self, x):

x = self.conv(x)

return x

class ResVNet(nn.Module):

def __init__(self, n_channels=1, n_classes=2, n_filters=16, normalization='instancenorm', has_dropout=False):

super(ResVNet, self).__init__()

print("new res")

self.resencoder = resnet34()

self.has_dropout = has_dropout

self.block_one = ConvBlock(1, n_channels, n_filters, normalization=normalization)

self.block_one_dw = DownsamplingConvBlock(n_filters, 2 * n_filters, normalization=normalization)

self.block_two = ConvBlock(2, n_filters * 2, n_filters * 2, normalization=normalization)

self.block_two_dw = DownsamplingConvBlock(n_filters * 2, n_filters * 4, normalization=normalization)

self.block_three = ConvBlock(3, n_filters * 4, n_filters * 4, normalization=normalization)

self.block_three_dw = DownsamplingConvBlock(n_filters * 4, n_filters * 8, normalization=normalization)

self.block_four = ConvBlock(3, n_filters * 8, n_filters * 8, normalization=normalization)

self.block_four_dw = DownsamplingConvBlock(n_filters * 8, n_filters * 16, normalization=normalization)

self.block_five = ConvBlock(3, n_filters * 16, n_filters * 16, normalization=normalization)

self.block_five_up = UpsamplingDeconvBlock(n_filters * 16, n_filters * 8, normalization=normalization)

self.block_six = ConvBlock(3, n_filters * 8, n_filters * 8, normalization=normalization)

self.block_six_up = UpsamplingDeconvBlock(n_filters * 8, n_filters * 4, normalization=normalization)

self.block_seven = ConvBlock(3, n_filters * 4, n_filters * 4, normalization=normalization)

self.block_seven_up = UpsamplingDeconvBlock(n_filters * 4, n_filters * 2, normalization=normalization)

self.block_eight = ConvBlock(2, n_filters * 2, n_filters * 2, normalization=normalization)

self.block_eight_up = UpsamplingDeconvBlock(n_filters * 2, n_filters, normalization=normalization)

if has_dropout:

self.dropout = nn.Dropout3d(p=0.5)

self.branchs = nn.ModuleList()

for i in range(1):

if has_dropout:

seq = nn.Sequential(

ConvBlock(1, n_filters, n_filters, normalization=normalization),

nn.Dropout3d(p=0.5),

nn.Conv3d(n_filters, n_classes, 1, padding=0)

)

else:

seq = nn.Sequential(

ConvBlock(1, n_filters, n_filters, normalization=normalization),

nn.Conv3d(n_filters, n_classes, 1, padding=0)

)

self.branchs.append(seq)

def encoder(self, input):

x1 = self.block_one(input)

x1_dw = self.block_one_dw(x1)

x2 = self.block_two(x1_dw)

x2_dw = self.block_two_dw(x2)

x3 = self.block_three(x2_dw)

x3_dw = self.block_three_dw(x3)

x4 = self.block_four(x3_dw)

x4_dw = self.block_four_dw(x4)

x5 = self.block_five(x4_dw)

if self.has_dropout:

x5 = self.dropout(x5)

res = [x1, x2, x3, x4, x5]

return res

def decoder(self, features):

x1 = features[0]

x2 = features[1]

x3 = features[2]

x4 = features[3]

x5 = features[4]

x5_up = self.block_five_up(x5)

x5_up = x5_up + x4

x6 = self.block_six(x5_up)

x6_up = self.block_six_up(x6)

x6_up = x6_up + x3

x7 = self.block_seven(x6_up)

x7_up = self.block_seven_up(x7)

x7_up = x7_up + x2

x8 = self.block_eight(x7_up)

x8_up = self.block_eight_up(x8)

x8_up = x8_up + x1

out = []

for branch in self.branchs:

o = branch(x8_up)

out.append(o)

out.append(x6)

return out

def forward(self, input, turnoff_drop=False):

if turnoff_drop:

has_dropout = self.has_dropout

self.has_dropout = False

features = self.resencoder(input)

out = self.decoder(features)

if turnoff_drop:

self.has_dropout = has_dropout

return out