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apdrawing / APDrawingGAN2 /models /networks.py
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import torch
import torch.nn as nn
from torch.nn import init
import functools
from torch.optim import lr_scheduler
###############################################################################
# Helper Functions
###############################################################################
def get_norm_layer(norm_type='instance'):
 if norm_type == 'batch':
 norm_layer = functools.partial(nn.BatchNorm2d, affine=True)
 elif norm_type == 'instance':
 norm_layer = functools.partial(nn.InstanceNorm2d, affine=False, track_running_stats=True)
 elif norm_type == 'none':
 norm_layer = None
 else:
 raise NotImplementedError('normalization layer [%s] is not found' % norm_type)
 return norm_layer
def get_scheduler(optimizer, opt):
 if opt.lr_policy == 'lambda':
 def lambda_rule(epoch):
 lr_l = 1.0 - max(0, epoch + 1 + opt.epoch_count - opt.niter) / float(opt.niter_decay + 1)
 return lr_l
 scheduler = lr_scheduler.LambdaLR(optimizer, lr_lambda=lambda_rule)
 elif opt.lr_policy == 'step':
 scheduler = lr_scheduler.StepLR(optimizer, step_size=opt.lr_decay_iters, gamma=0.1)
 elif opt.lr_policy == 'plateau':
 scheduler = lr_scheduler.ReduceLROnPlateau(optimizer, mode='min', factor=0.2, threshold=0.01, patience=5)
 elif opt.lr_policy == 'cosine':
 scheduler = lr_scheduler.CosineAnnealingLR(optimizer, T_max=opt.niter, eta_min=0)
 else:
 return NotImplementedError('learning rate policy [%s] is not implemented', opt.lr_policy)
 return scheduler
def init_weights(net, init_type='normal', gain=0.02):
 def init_func(m):
 classname = m.__class__.__name__
 if hasattr(m, 'weight') and (classname.find('Conv') != -1 or classname.find('Linear') != -1):
 if init_type == 'normal':
 init.normal_(m.weight.data, 0.0, gain)
 elif init_type == 'xavier':
 init.xavier_normal_(m.weight.data, gain=gain)
 elif init_type == 'kaiming':
 init.kaiming_normal_(m.weight.data, a=0, mode='fan_in')
 elif init_type == 'orthogonal':
 init.orthogonal_(m.weight.data, gain=gain)
 else:
 raise NotImplementedError('initialization method [%s] is not implemented' % init_type)
 if hasattr(m, 'bias') and m.bias is not None:
 init.constant_(m.bias.data, 0.0)
 elif classname.find('BatchNorm2d') != -1:
 init.normal_(m.weight.data, 1.0, gain)
 init.constant_(m.bias.data, 0.0)
print('initialize network with %s' % init_type)
 net.apply(init_func)
def init_net(net, init_type='normal', init_gain=0.02, gpu_ids=[]):
 if len(gpu_ids) > 0:
 assert(torch.cuda.is_available())
 net.to(gpu_ids[0])
 net = torch.nn.DataParallel(net, gpu_ids)
 init_weights(net, init_type, gain=init_gain)
 return net
def define_G(input_nc, output_nc, ngf, netG, norm='batch', use_dropout=False, init_type='normal', init_gain=0.02, gpu_ids=[], nnG=9, multiple=2, latent_dim=1024, ae_h=96, ae_w=96, extra_channel=2, nres=1):
 net = None
 norm_layer = get_norm_layer(norm_type=norm)
if netG == 'autoencoder':
 net = AutoEncoder(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout)
 elif netG == 'autoencoderfc':
 net = AutoEncoderWithFC(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout,
 multiple=multiple, latent_dim=latent_dim, h=ae_h, w=ae_w)
 elif netG == 'autoencoderfc2':
 net = AutoEncoderWithFC2(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout,
 multiple=multiple, latent_dim=latent_dim, h=ae_h, w=ae_w)
 elif netG == 'vae':
 net = VAE(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout,
 multiple=multiple, latent_dim=latent_dim, h=ae_h, w=ae_w)
 elif netG == 'classifier':
 net = Classifier(input_nc, output_nc, ngf, num_downs=nnG, norm_layer=norm_layer, use_dropout=use_dropout, h=ae_h, w=ae_w)
 elif netG == 'regressor':
 net = Regressor(input_nc, ngf, norm_layer=norm_layer, arch=nnG)
 elif netG == 'resnet_9blocks':#default for cyclegan
 net = ResnetGenerator(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout, n_blocks=9)
 elif netG == 'resnet_6blocks':
 net = ResnetGenerator(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout, n_blocks=6)
 elif netG == 'resnet_nblocks':
 net = ResnetGenerator(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout, n_blocks=nnG)
 elif netG == 'resnet_style2_9blocks':
 net = ResnetStyle2Generator(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout, n_blocks=9, model0_res=0, extra_channel=extra_channel)
 elif netG == 'resnet_style2_6blocks':
 net = ResnetStyle2Generator(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout, n_blocks=6, model0_res=0, extra_channel=extra_channel)
 elif netG == 'resnet_style2_nblocks':
 net = ResnetStyle2Generator(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout, n_blocks=nnG, model0_res=0, extra_channel=extra_channel)
 elif netG == 'unet_128':
 net = UnetGenerator(input_nc, output_nc, 7, ngf, norm_layer=norm_layer, use_dropout=use_dropout)
 elif netG == 'unet_256':#default for pix2pix
 net = UnetGenerator(input_nc, output_nc, 8, ngf, norm_layer=norm_layer, use_dropout=use_dropout)
 elif netG == 'unet_512':
 net = UnetGenerator(input_nc, output_nc, 9, ngf, norm_layer=norm_layer, use_dropout=use_dropout)
 elif netG == 'unet_ndown':
 net = UnetGenerator(input_nc, output_nc, nnG, ngf, norm_layer=norm_layer, use_dropout=use_dropout)
 elif netG == 'unetres_ndown':
 net = UnetResGenerator(input_nc, output_nc, nnG, ngf, norm_layer=norm_layer, use_dropout=use_dropout, nres=nres)
 elif netG == 'partunet':
 net = PartUnet(input_nc, output_nc, nnG, ngf, norm_layer=norm_layer, use_dropout=use_dropout)
 elif netG == 'partunet2':
 net = PartUnet2(input_nc, output_nc, nnG, ngf, norm_layer=norm_layer, use_dropout=use_dropout)
 elif netG == 'partunetres':
 net = PartUnetRes(input_nc, output_nc, nnG, ngf, norm_layer=norm_layer, use_dropout=use_dropout,nres=nres)
 elif netG == 'partunet2res':
 net = PartUnet2Res(input_nc, output_nc, nnG, ngf, norm_layer=norm_layer, use_dropout=use_dropout,nres=nres)
 elif netG == 'partunet2style':
 net = PartUnet2Style(input_nc, output_nc, nnG, ngf, extra_channel=extra_channel, norm_layer=norm_layer, use_dropout=use_dropout)
 elif netG == 'partunet2resstyle':
 net = PartUnet2ResStyle(input_nc, output_nc, nnG, ngf, extra_channel=extra_channel, norm_layer=norm_layer, use_dropout=use_dropout,nres=nres)
 elif netG == 'combiner':
 net = Combiner(input_nc, output_nc, ngf, norm_layer=norm_layer, use_dropout=use_dropout, n_blocks=2)
 elif netG == 'combiner2':
 net = Combiner2(input_nc, output_nc, nnG, ngf, norm_layer=norm_layer, use_dropout=use_dropout)
 else:
 raise NotImplementedError('Generator model name [%s] is not recognized' % netG)
 return init_net(net, init_type, init_gain, gpu_ids)
def define_D(input_nc, ndf, netD,
 n_layers_D=3, norm='batch', use_sigmoid=False, init_type='normal', init_gain=0.02, gpu_ids=[]):
 net = None
 norm_layer = get_norm_layer(norm_type=norm)
if netD == 'basic':
 net = NLayerDiscriminator(input_nc, ndf, n_layers=3, norm_layer=norm_layer, use_sigmoid=use_sigmoid)
 elif netD == 'n_layers':
 net = NLayerDiscriminator(input_nc, ndf, n_layers_D, norm_layer=norm_layer, use_sigmoid=use_sigmoid)
 elif netD == 'pixel':
 net = PixelDiscriminator(input_nc, ndf, norm_layer=norm_layer, use_sigmoid=use_sigmoid)
 else:
 raise NotImplementedError('Discriminator model name [%s] is not recognized' % net)
 return init_net(net, init_type, init_gain, gpu_ids)
##############################################################################
# Classes
##############################################################################
# Defines the GAN loss which uses either LSGAN or the regular GAN.
# When LSGAN is used, it is basically same as MSELoss,
# but it abstracts away the need to create the target label tensor
# that has the same size as the input
class GANLoss(nn.Module):
 def __init__(self, use_lsgan=True, target_real_label=1.0, target_fake_label=0.0):
 super(GANLoss, self).__init__()
 self.register_buffer('real_label', torch.tensor(target_real_label))
 self.register_buffer('fake_label', torch.tensor(target_fake_label))
 if use_lsgan:
 self.loss = nn.MSELoss()
 else:#no_lsgan
 self.loss = nn.BCELoss()
def get_target_tensor(self, input, target_is_real):
 if target_is_real:
 target_tensor = self.real_label
 else:
 target_tensor = self.fake_label
 return target_tensor.expand_as(input)
def __call__(self, input, target_is_real):
 target_tensor = self.get_target_tensor(input, target_is_real)
 return self.loss(input, target_tensor)
class AutoEncoderMNIST(nn.Module):
 def __init__(self):
 super(AutoEncoderMNIST, self).__init__()
 self.encoder = nn.Sequential(
 nn.Conv2d(1, 16, 3, stride=3, padding=1), # b, 16, 10, 10
 nn.ReLU(True),
 nn.MaxPool2d(2, stride=2), # b, 16, 5, 5
 nn.Conv2d(16, 8, 3, stride=2, padding=1), # b, 8, 3, 3
 nn.ReLU(True),
 nn.MaxPool2d(2, stride=1) # b, 8, 2, 2
 )
 self.decoder = nn.Sequential(
 nn.ConvTranspose2d(8, 16, 3, stride=2), # b, 16, 5, 5
 nn.ReLU(True),
 nn.ConvTranspose2d(16, 8, 5, stride=3, padding=1), # b, 8, 15, 15
 nn.ReLU(True),
 nn.ConvTranspose2d(8, 1, 2, stride=2, padding=1), # b, 1, 28, 28
 nn.Tanh()
 )
def forward(self, x):
 x = self.encoder(x)
 x = self.decoder(x)
 return x
class AutoEncoder(nn.Module):
 def __init__(self, input_nc, output_nc, ngf=64, norm_layer=nn.BatchNorm2d, use_dropout=False, padding_type='reflect'):
 super(AutoEncoder, self).__init__()
 self.input_nc = input_nc
 self.output_nc = output_nc
 self.ngf = ngf
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
model = [nn.Conv2d(input_nc, ngf, kernel_size=4, stride=2, padding=1, bias=use_bias)]
 n_downsampling = 3
 for i in range(n_downsampling):
 mult = 2**i
 model += [nn.LeakyReLU(0.2),
 nn.Conv2d(ngf * mult, ngf * mult * 2, kernel_size=4,
 stride=2, padding=1, bias=use_bias),
 norm_layer(ngf * mult * 2)]
 self.encoder = nn.Sequential(*model)
model2 = []
 for i in range(n_downsampling):
 mult = 2**(n_downsampling - i)
 model2 += [nn.ReLU(),
 nn.ConvTranspose2d(ngf * mult, int(ngf * mult / 2),
 kernel_size=4, stride=2,
 padding=1, bias=use_bias),
 norm_layer(int(ngf * mult / 2))]
 model2 += [nn.ReLU()]
 model2 += [nn.ConvTranspose2d(ngf, output_nc, kernel_size=4, stride=2, padding=1, bias=use_bias)]
 model2 += [nn.Tanh()]
 self.decoder = nn.Sequential(*model2)
def forward(self, x):
 ax = self.encoder(x) # b, 512, 6, 6
 y = self.decoder(ax)
 return y, ax
class AutoEncoderWithFC(nn.Module):
 def __init__(self, input_nc, output_nc, ngf=64, norm_layer=nn.BatchNorm2d, use_dropout=False, multiple=2,latent_dim=1024, h=96, w=96):
 super(AutoEncoderWithFC, self).__init__()
 self.input_nc = input_nc
 self.output_nc = output_nc
 self.ngf = ngf
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
model = [nn.Conv2d(input_nc, ngf, kernel_size=4, stride=2, padding=1, bias=use_bias)]
 n_downsampling = 3
 #multiple = 2
 for i in range(n_downsampling):
 mult = multiple**i
 model += [nn.LeakyReLU(0.2),
 nn.Conv2d(int(ngf * mult), int(ngf * mult * multiple), kernel_size=4,
 stride=2, padding=1, bias=use_bias),
 norm_layer(int(ngf * mult * multiple))]
 self.encoder = nn.Sequential(*model)
 self.fc1 = nn.Linear(int(ngf*(multiple**n_downsampling)*h/16*w/16),latent_dim)
 self.relu = nn.ReLU(latent_dim)
 self.fc2 = nn.Linear(latent_dim,int(ngf*(multiple**n_downsampling)*h/16*w/16))
 self.rh = int(h/16)
 self.rw = int(w/16)
 model2 = []
 for i in range(n_downsampling):
 mult = multiple**(n_downsampling - i)
 model2 += [nn.ReLU(),
 nn.ConvTranspose2d(int(ngf * mult), int(ngf * mult / multiple),
 kernel_size=4, stride=2,
 padding=1, bias=use_bias),
 norm_layer(int(ngf * mult / multiple))]
 model2 += [nn.ReLU()]
 model2 += [nn.ConvTranspose2d(ngf, output_nc, kernel_size=4, stride=2, padding=1, bias=use_bias)]
 model2 += [nn.Tanh()]
 self.decoder = nn.Sequential(*model2)
def forward(self, x):
 ax = self.encoder(x) # b, 512, 6, 6
 ax = ax.view(ax.size(0), -1) # view -- reshape
 ax = self.relu(self.fc1(ax))
 ax = self.fc2(ax)
 ax = ax.view(ax.size(0),-1,self.rh,self.rw)
 y = self.decoder(ax)
 return y, ax
class AutoEncoderWithFC2(nn.Module):
 def __init__(self, input_nc, output_nc, ngf=64, norm_layer=nn.BatchNorm2d, use_dropout=False, multiple=2,latent_dim=1024, h=96, w=96):
 super(AutoEncoderWithFC2, self).__init__()
 self.input_nc = input_nc
 self.output_nc = output_nc
 self.ngf = ngf
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
model = [nn.Conv2d(input_nc, ngf, kernel_size=4, stride=2, padding=1, bias=use_bias)]
 n_downsampling = 2
 #multiple = 2
 for i in range(n_downsampling):
 mult = multiple**i
 model += [nn.LeakyReLU(0.2),
 nn.Conv2d(int(ngf * mult), int(ngf * mult * multiple), kernel_size=4,
 stride=2, padding=1, bias=use_bias),
 norm_layer(int(ngf * mult * multiple))]
 self.encoder = nn.Sequential(*model)
 self.fc1 = nn.Linear(int(ngf*(multiple**n_downsampling)*h/8*w/8),latent_dim)
 self.relu = nn.ReLU(latent_dim)
 self.fc2 = nn.Linear(latent_dim,int(ngf*(multiple**n_downsampling)*h/8*w/8))
 self.rh = h/8
 self.rw = w/8
 model2 = []
 for i in range(n_downsampling):
 mult = multiple**(n_downsampling - i)
 model2 += [nn.ReLU(),
 nn.ConvTranspose2d(int(ngf * mult), int(ngf * mult / multiple),
 kernel_size=4, stride=2,
 padding=1, bias=use_bias),
 norm_layer(int(ngf * mult / multiple))]
 model2 += [nn.ReLU()]
 model2 += [nn.ConvTranspose2d(ngf, output_nc, kernel_size=4, stride=2, padding=1, bias=use_bias)]
 model2 += [nn.Tanh()]
 self.decoder = nn.Sequential(*model2)
def forward(self, x):
 ax = self.encoder(x) # b, 256, 12, 12
 ax = ax.view(ax.size(0), -1) # view -- reshape
 ax = self.relu(self.fc1(ax))
 ax = self.fc2(ax)
 ax = ax.view(ax.size(0),-1,self.rh,self.rw)
 y = self.decoder(ax)
 return y, ax
class VAE(nn.Module):
 def __init__(self, input_nc, output_nc, ngf=64, norm_layer=nn.BatchNorm2d, use_dropout=False, multiple=2,latent_dim=1024, h=96, w=96):
 super(VAE, self).__init__()
 self.input_nc = input_nc
 self.output_nc = output_nc
 self.ngf = ngf
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
model = [nn.Conv2d(input_nc, ngf, kernel_size=4, stride=2, padding=1, bias=use_bias)]
 n_downsampling = 3
 for i in range(n_downsampling):
 mult = multiple**i
 model += [nn.LeakyReLU(0.2),
 nn.Conv2d(int(ngf * mult), int(ngf * mult * multiple), kernel_size=4,
 stride=2, padding=1, bias=use_bias),
 norm_layer(int(ngf * mult * multiple))]
 self.encoder_cnn = nn.Sequential(*model)
self.c_dim = int(ngf*(multiple**n_downsampling)*h/16*w/16)
 self.rh = h/16
 self.rw = w/16
 self.fc1 = nn.Linear(self.c_dim,latent_dim)
 self.fc2 = nn.Linear(self.c_dim,latent_dim)
 self.fc3 = nn.Linear(latent_dim,self.c_dim)
 self.relu = nn.ReLU()
model2 = []
 for i in range(n_downsampling):
 mult = multiple**(n_downsampling - i)
 model2 += [nn.ReLU(),
 nn.ConvTranspose2d(int(ngf * mult), int(ngf * mult / multiple),
 kernel_size=4, stride=2,
 padding=1, bias=use_bias),
 norm_layer(int(ngf * mult / multiple))]
 model2 += [nn.ReLU()]
 model2 += [nn.ConvTranspose2d(ngf, output_nc, kernel_size=4, stride=2, padding=1, bias=use_bias)]
 model2 += [nn.Tanh()]#[-1,1]
 self.decoder_cnn = nn.Sequential(*model2)
def encode(self, x):
 h1 = self.encoder_cnn(x)
 r1 = h1.view(h1.size(0), -1)
 return self.fc1(r1), self.fc2(r1)
def reparameterize(self, mu, logvar):# not deterministic for test mode
 std = torch.exp(0.5*logvar)
 eps = torch.randn_like(std)# torch.rand_like returns a tensor with the same size as input,
 # that is filled with random numbers from a normal distribution N(0,1)
 return eps.mul(std).add_(mu)
def decode(self, z):
 h4 = self.relu(self.fc3(z))
 r3 = h4.view(h4.size(0),-1,self.rh,self.rw)
 return self.decoder_cnn(r3)
def forward(self, x):
 mu, logvar = self.encode(x)
 z = self.reparameterize(mu, logvar)
 reconx = self.decode(z)
 return reconx, mu, logvar
class Classifier(nn.Module):
 def __init__(self, input_nc, classes, ngf=64, num_downs=3, norm_layer=nn.BatchNorm2d, use_dropout=False,
 h=96, w=96):
 super(Classifier, self).__init__()
 self.input_nc = input_nc
 self.ngf = ngf
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
model = [nn.Conv2d(input_nc, ngf, kernel_size=4, stride=2, padding=1, bias=use_bias)]
 multiple = 2
 for i in range(num_downs):
 mult = multiple**i
 model += [nn.LeakyReLU(0.2),
 nn.Conv2d(int(ngf * mult), int(ngf * mult * multiple), kernel_size=4,
 stride=2, padding=1, bias=use_bias),
 norm_layer(int(ngf * mult * multiple))]
 self.encoder = nn.Sequential(*model)
 strides = 2**(num_downs+1)
 self.fc1 = nn.Linear(int(ngf*h*w/(strides*2)), classes)
def forward(self, x):
 ax = self.encoder(x) # b, 512, 6, 6
 ax = ax.view(ax.size(0), -1) # view -- reshape
 return self.fc1(ax)
class Regressor(nn.Module):
 def __init__(self, input_nc, ngf=64, norm_layer=nn.BatchNorm2d, arch=1):
 super(Regressor, self).__init__()
 # if use BatchNorm2d,
# no need to use bias as BatchNorm2d has affine parameters
self.arch = arch
if arch == 1:
 use_bias = True
 sequence = [
 nn.Conv2d(input_nc, ngf, kernel_size=3, stride=2, padding=0, bias=use_bias),#11->5
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ngf, 1, kernel_size=5, stride=1, padding=0, bias=use_bias),#5->1
 ]
 elif arch == 2:
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
 sequence = [
 nn.Conv2d(input_nc, ngf, kernel_size=3, stride=1, padding=0, bias=use_bias),#11->9
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ngf, ngf*2, kernel_size=3, stride=1, padding=0, bias=use_bias),#9->7
 norm_layer(ngf*2),
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ngf*2, ngf*4, kernel_size=3, stride=1, padding=0, bias=use_bias),#7->5
 norm_layer(ngf*4),
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ngf*4, 1, kernel_size=5, stride=1, padding=0, bias=use_bias),#5->1
 ]
 elif arch == 3:
 use_bias = True
 sequence = [
 nn.Conv2d(input_nc, ngf, kernel_size=3, stride=1, padding=1, bias=use_bias),#11->11
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ngf, 1, kernel_size=11, stride=1, padding=0, bias=use_bias),#11->1
 ]
 elif arch == 4:
 use_bias = True
 sequence = [
 nn.Conv2d(input_nc, ngf, kernel_size=3, stride=1, padding=1, bias=use_bias),#11->11
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ngf, ngf*2, kernel_size=3, stride=1, padding=1, bias=use_bias),#11->11
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ngf*2, ngf*4, kernel_size=3, stride=1, padding=1, bias=use_bias),#11->11
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ngf*4, 1, kernel_size=11, stride=1, padding=0, bias=use_bias),#11->1
 ]
 elif arch == 5:
 use_bias = True
 sequence = [
 nn.Conv2d(input_nc, ngf, kernel_size=3, stride=1, padding=1, bias=use_bias),#11->11
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ngf, ngf*2, kernel_size=3, stride=1, padding=1, bias=use_bias),#11->11
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ngf*2, ngf*4, kernel_size=3, stride=1, padding=1, bias=use_bias),#11->11
 nn.LeakyReLU(0.2, True),
 ]
 fc = [
 nn.Linear(ngf*4*11*11, 4096),
 nn.ReLU(True),
 nn.Dropout(),
 nn.Linear(4096, 1),
 ]
 self.fc = nn.Sequential(*fc)
self.model = nn.Sequential(*sequence)
def forward(self, x):
 if self.arch <= 4:
 return self.model(x)
 else:
 x = self.model(x)
 x = x.view(x.size(0), -1)
 x = self.fc(x)
 return x
# Defines the generator that consists of Resnet blocks between a few
# downsampling/upsampling operations.
# Code and idea originally from Justin Johnson's architecture.
# https://github.com/jcjohnson/fast-neural-style/
class ResnetGenerator(nn.Module):
 def __init__(self, input_nc, output_nc, ngf=64, norm_layer=nn.BatchNorm2d, use_dropout=False, n_blocks=6, padding_type='reflect'):
 assert(n_blocks >= 0)
 super(ResnetGenerator, self).__init__()
 self.input_nc = input_nc
 self.output_nc = output_nc
 self.ngf = ngf
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
model = [nn.ReflectionPad2d(3),
 nn.Conv2d(input_nc, ngf, kernel_size=7, padding=0,
 bias=use_bias),
 norm_layer(ngf),
 nn.ReLU(True)]
n_downsampling = 2
 for i in range(n_downsampling):
 mult = 2**i
 model += [nn.Conv2d(ngf * mult, ngf * mult * 2, kernel_size=3,
 stride=2, padding=1, bias=use_bias),
 norm_layer(ngf * mult * 2),
 nn.ReLU(True)]
mult = 2**n_downsampling
 for i in range(n_blocks):
 model += [ResnetBlock(ngf * mult, padding_type=padding_type, norm_layer=norm_layer, use_dropout=use_dropout, use_bias=use_bias)]
for i in range(n_downsampling):
 mult = 2**(n_downsampling - i)
 model += [nn.ConvTranspose2d(ngf * mult, int(ngf * mult / 2),
 kernel_size=3, stride=2,
 padding=1, output_padding=1,
 bias=use_bias),
 norm_layer(int(ngf * mult / 2)),
 nn.ReLU(True)]
 model += [nn.ReflectionPad2d(3)]
 model += [nn.Conv2d(ngf, output_nc, kernel_size=7, padding=0)]
 model += [nn.Tanh()]
self.model = nn.Sequential(*model)
def forward(self, input):
 return self.model(input)
class ResnetStyle2Generator(nn.Module):
 """Resnet-based generator that consists of Resnet blocks between a few downsampling/upsampling operations.
 We adapt Torch code and idea from Justin Johnson's neural style transfer project(https://github.com/jcjohnson/fast-neural-style)
 """
def __init__(self, input_nc, output_nc, ngf=64, norm_layer=nn.BatchNorm2d, use_dropout=False, n_blocks=6, padding_type='reflect', extra_channel=3, model0_res=0):
 """Construct a Resnet-based generator
 Parameters:
 input_nc (int) -- the number of channels in input images
 output_nc (int) -- the number of channels in output images
 ngf (int) -- the number of filters in the last conv layer
 norm_layer -- normalization layer
 use_dropout (bool) -- if use dropout layers
 n_blocks (int) -- the number of ResNet blocks
 padding_type (str) -- the name of padding layer in conv layers: reflect | replicate | zero
 """
 assert(n_blocks >= 0)
 super(ResnetStyle2Generator, self).__init__()
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
model0 = [nn.ReflectionPad2d(3),
 nn.Conv2d(input_nc, ngf, kernel_size=7, padding=0, bias=use_bias),
 norm_layer(ngf),
 nn.ReLU(True)]
n_downsampling = 2
 for i in range(n_downsampling): # add downsampling layers
 mult = 2 ** i
 model0 += [nn.Conv2d(ngf * mult, ngf * mult * 2, kernel_size=3, stride=2, padding=1, bias=use_bias),
 norm_layer(ngf * mult * 2),
 nn.ReLU(True)]
mult = 2 ** n_downsampling
 for i in range(model0_res): # add ResNet blocks
 model0 += [ResnetBlock(ngf * mult, padding_type=padding_type, norm_layer=norm_layer, use_dropout=use_dropout, use_bias=use_bias)]
model = []
 model += [nn.Conv2d(ngf * mult + extra_channel, ngf * mult, kernel_size=3, stride=1, padding=1, bias=use_bias),
 norm_layer(ngf * mult),
 nn.ReLU(True)]
for i in range(n_blocks-model0_res): # add ResNet blocks
 model += [ResnetBlock(ngf * mult, padding_type=padding_type, norm_layer=norm_layer, use_dropout=use_dropout, use_bias=use_bias)]
for i in range(n_downsampling): # add upsampling layers
 mult = 2 ** (n_downsampling - i)
 model += [nn.ConvTranspose2d(ngf * mult, int(ngf * mult / 2),
 kernel_size=3, stride=2,
 padding=1, output_padding=1,
 bias=use_bias),
 norm_layer(int(ngf * mult / 2)),
 nn.ReLU(True)]
 model += [nn.ReflectionPad2d(3)]
 model += [nn.Conv2d(ngf, output_nc, kernel_size=7, padding=0)]
 model += [nn.Tanh()]
self.model0 = nn.Sequential(*model0)
 self.model = nn.Sequential(*model)
 print(list(self.modules()))
def forward(self, input1, input2): # input2 [bs,c]
 """Standard forward"""
 f1 = self.model0(input1)
 [bs,c,h,w] = f1.shape
 input2 = input2.repeat(h,w,1,1).permute([2,3,0,1])
 y1 = torch.cat([f1, input2], 1)
 return self.model(y1)
class Combiner(nn.Module):
 def __init__(self, input_nc, output_nc, ngf=64, norm_layer=nn.BatchNorm2d, use_dropout=False, n_blocks=6, padding_type='reflect'):
 assert(n_blocks >= 0)
 super(Combiner, self).__init__()
 self.input_nc = input_nc
 self.output_nc = output_nc
 self.ngf = ngf
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
model = [nn.ReflectionPad2d(3),
 nn.Conv2d(input_nc, ngf, kernel_size=7, padding=0,
 bias=use_bias),
 norm_layer(ngf),
 nn.ReLU(True)]
for i in range(n_blocks):
 model += [ResnetBlock(ngf, padding_type=padding_type, norm_layer=norm_layer, use_dropout=use_dropout, use_bias=use_bias)]
model += [nn.ReflectionPad2d(3)]
 model += [nn.Conv2d(ngf, output_nc, kernel_size=7, padding=0)]
 model += [nn.Tanh()]
self.model = nn.Sequential(*model)
def forward(self, input):
 return self.model(input)
class Combiner2(nn.Module):
 def __init__(self, input_nc, output_nc, num_downs, ngf=64,
 norm_layer=nn.BatchNorm2d, use_dropout=False):
 super(Combiner2, self).__init__()
# construct unet structure
 unet_block = UnetSkipConnectionBlock(ngf, ngf * 2, input_nc=None, submodule=None, norm_layer=norm_layer, innermost=True)
 unet_block = UnetSkipConnectionBlock(output_nc, ngf, input_nc=input_nc, submodule=unet_block, outermost=True, norm_layer=norm_layer)
self.model = unet_block
def forward(self, input):
 return self.model(input)
# Define a resnet block
class ResnetBlock(nn.Module):
 def __init__(self, dim, padding_type, norm_layer, use_dropout, use_bias):
 super(ResnetBlock, self).__init__()
 self.conv_block = self.build_conv_block(dim, padding_type, norm_layer, use_dropout, use_bias)
def build_conv_block(self, dim, padding_type, norm_layer, use_dropout, use_bias):
 conv_block = []
 p = 0
 if padding_type == 'reflect':
 conv_block += [nn.ReflectionPad2d(1)]
 elif padding_type == 'replicate':
 conv_block += [nn.ReplicationPad2d(1)]
 elif padding_type == 'zero':
 p = 1
 else:
 raise NotImplementedError('padding [%s] is not implemented' % padding_type)
conv_block += [nn.Conv2d(dim, dim, kernel_size=3, padding=p, bias=use_bias),
 norm_layer(dim),
 nn.ReLU(True)]
 if use_dropout:
 conv_block += [nn.Dropout(0.5)]
p = 0
 if padding_type == 'reflect':
 conv_block += [nn.ReflectionPad2d(1)]
 elif padding_type == 'replicate':
 conv_block += [nn.ReplicationPad2d(1)]
 elif padding_type == 'zero':
 p = 1
 else:
 raise NotImplementedError('padding [%s] is not implemented' % padding_type)
 conv_block += [nn.Conv2d(dim, dim, kernel_size=3, padding=p, bias=use_bias),
 norm_layer(dim)]
return nn.Sequential(*conv_block)
def forward(self, x):
 out = x + self.conv_block(x)
 return out
# Defines the Unet generator.
# |num_downs|: number of downsamplings in UNet. For example,
# if |num_downs| == 7, image of size 128x128 will become of size 1x1
# at the bottleneck
class UnetGenerator(nn.Module):
 def __init__(self, input_nc, output_nc, num_downs, ngf=64,
 norm_layer=nn.BatchNorm2d, use_dropout=False):
 super(UnetGenerator, self).__init__()
# construct unet structure
 unet_block = UnetSkipConnectionBlock(ngf * 8, ngf * 8, input_nc=None, submodule=None, norm_layer=norm_layer, innermost=True)
 for i in range(num_downs - 5):
 unet_block = UnetSkipConnectionBlock(ngf * 8, ngf * 8, input_nc=None, submodule=unet_block, norm_layer=norm_layer, use_dropout=use_dropout)
 unet_block = UnetSkipConnectionBlock(ngf * 4, ngf * 8, input_nc=None, submodule=unet_block, norm_layer=norm_layer)
 unet_block = UnetSkipConnectionBlock(ngf * 2, ngf * 4, input_nc=None, submodule=unet_block, norm_layer=norm_layer)
 unet_block = UnetSkipConnectionBlock(ngf, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer)
 unet_block = UnetSkipConnectionBlock(output_nc, ngf, input_nc=input_nc, submodule=unet_block, outermost=True, norm_layer=norm_layer)
self.model = unet_block
def forward(self, input):
 return self.model(input)
class UnetResGenerator(nn.Module):
 def __init__(self, input_nc, output_nc, num_downs, ngf=64,
 norm_layer=nn.BatchNorm2d, use_dropout=False, nres=1):
 super(UnetResGenerator, self).__init__()
# construct unet structure
 unet_block = UnetSkipConnectionResBlock(ngf * 8, ngf * 8, input_nc=None, submodule=None, norm_layer=norm_layer, innermost=True, nres=nres)
 for i in range(num_downs - 5):
 unet_block = UnetSkipConnectionBlock(ngf * 8, ngf * 8, input_nc=None, submodule=unet_block, norm_layer=norm_layer, use_dropout=use_dropout)
 unet_block = UnetSkipConnectionBlock(ngf * 4, ngf * 8, input_nc=None, submodule=unet_block, norm_layer=norm_layer)
 unet_block = UnetSkipConnectionBlock(ngf * 2, ngf * 4, input_nc=None, submodule=unet_block, norm_layer=norm_layer)
 unet_block = UnetSkipConnectionBlock(ngf, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer)
 unet_block = UnetSkipConnectionBlock(output_nc, ngf, input_nc=input_nc, submodule=unet_block, outermost=True, norm_layer=norm_layer)
self.model = unet_block
def forward(self, input):
 return self.model(input)
class PartUnet(nn.Module):
 def __init__(self, input_nc, output_nc, num_downs, ngf=64,
 norm_layer=nn.BatchNorm2d, use_dropout=False):
 super(PartUnet, self).__init__()
# construct unet structure
 # 3 downs
unet_block = UnetSkipConnectionBlock(ngf * 2, ngf * 4, input_nc=None, submodule=None, norm_layer=norm_layer, innermost=True)
 unet_block = UnetSkipConnectionBlock(ngf, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer)
 unet_block = UnetSkipConnectionBlock(output_nc, ngf, input_nc=input_nc, submodule=unet_block, outermost=True, norm_layer=norm_layer)
self.model = unet_block
def forward(self, input):
 return self.model(input)
class PartUnetRes(nn.Module):
 def __init__(self, input_nc, output_nc, num_downs, ngf=64,
 norm_layer=nn.BatchNorm2d, use_dropout=False, nres=1):
 super(PartUnetRes, self).__init__()
# construct unet structure
 # 3 downs
unet_block = UnetSkipConnectionResBlock(ngf * 2, ngf * 4, input_nc=None, submodule=None, norm_layer=norm_layer, innermost=True, nres=nres)
 unet_block = UnetSkipConnectionBlock(ngf, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer)
 unet_block = UnetSkipConnectionBlock(output_nc, ngf, input_nc=input_nc, submodule=unet_block, outermost=True, norm_layer=norm_layer)
self.model = unet_block
def forward(self, input):
 return self.model(input)
class PartUnet2(nn.Module):
 def __init__(self, input_nc, output_nc, num_downs, ngf=64,
 norm_layer=nn.BatchNorm2d, use_dropout=False):
 super(PartUnet2, self).__init__()
# construct unet structure
 unet_block = UnetSkipConnectionBlock(ngf * 2, ngf * 2, input_nc=None, submodule=None, norm_layer=norm_layer, innermost=True)
 for i in range(num_downs - 3):
 unet_block = UnetSkipConnectionBlock(ngf * 2, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer, use_dropout=use_dropout)
 unet_block = UnetSkipConnectionBlock(ngf, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer)
 unet_block = UnetSkipConnectionBlock(output_nc, ngf, input_nc=input_nc, submodule=unet_block, outermost=True, norm_layer=norm_layer)
self.model = unet_block
def forward(self, input):
 return self.model(input)
class PartUnet2Res(nn.Module):
 def __init__(self, input_nc, output_nc, num_downs, ngf=64,
 norm_layer=nn.BatchNorm2d, use_dropout=False, nres=1):
 super(PartUnet2Res, self).__init__()
# construct unet structure
 unet_block = UnetSkipConnectionResBlock(ngf * 2, ngf * 2, input_nc=None, submodule=None, norm_layer=norm_layer, innermost=True, nres=nres)
 for i in range(num_downs - 3):
 unet_block = UnetSkipConnectionBlock(ngf * 2, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer, use_dropout=use_dropout)
 unet_block = UnetSkipConnectionBlock(ngf, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer)
 unet_block = UnetSkipConnectionBlock(output_nc, ngf, input_nc=input_nc, submodule=unet_block, outermost=True, norm_layer=norm_layer)
self.model = unet_block
def forward(self, input):
 return self.model(input)
class PartUnet2Style(nn.Module):
 def __init__(self, input_nc, output_nc, num_downs, ngf=64, extra_channel=2,
 norm_layer=nn.BatchNorm2d, use_dropout=False):
 super(PartUnet2Style, self).__init__()
 # construct unet structure
 unet_block = UnetSkipConnectionStyleBlock(ngf * 2, ngf * 2, input_nc=None, submodule=None, norm_layer=norm_layer, innermost=True, extra_channel=extra_channel)
 for i in range(num_downs - 3):
 unet_block = UnetSkipConnectionStyleBlock(ngf * 2, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer, use_dropout=use_dropout, extra_channel=extra_channel)
 unet_block = UnetSkipConnectionStyleBlock(ngf, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer, extra_channel=extra_channel)
 unet_block = UnetSkipConnectionStyleBlock(output_nc, ngf, input_nc=input_nc, submodule=unet_block, outermost=True, norm_layer=norm_layer, extra_channel=extra_channel)
self.model = unet_block
def forward(self, input, cate):
 return self.model(input, cate)
class PartUnet2ResStyle(nn.Module):
 def __init__(self, input_nc, output_nc, num_downs, ngf=64, extra_channel=2,
 norm_layer=nn.BatchNorm2d, use_dropout=False, nres=1):
 super(PartUnet2ResStyle, self).__init__()
 # construct unet structure
 unet_block = UnetSkipConnectionResStyleBlock(ngf * 2, ngf * 2, input_nc=None, submodule=None, norm_layer=norm_layer, innermost=True, extra_channel=extra_channel, nres=nres)
 for i in range(num_downs - 3):
 unet_block = UnetSkipConnectionStyleBlock(ngf * 2, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer, use_dropout=use_dropout, extra_channel=extra_channel)
 unet_block = UnetSkipConnectionStyleBlock(ngf, ngf * 2, input_nc=None, submodule=unet_block, norm_layer=norm_layer, extra_channel=extra_channel)
 unet_block = UnetSkipConnectionStyleBlock(output_nc, ngf, input_nc=input_nc, submodule=unet_block, outermost=True, norm_layer=norm_layer, extra_channel=extra_channel)
self.model = unet_block
def forward(self, input, cate):
 return self.model(input, cate)
# Defines the submodule with skip connection.
# X -------------------identity---------------------- X
# |-- downsampling -- |submodule| -- upsampling --|
class UnetSkipConnectionBlock(nn.Module):
 def __init__(self, outer_nc, inner_nc, input_nc=None,
 submodule=None, outermost=False, innermost=False, norm_layer=nn.BatchNorm2d, use_dropout=False):
 super(UnetSkipConnectionBlock, self).__init__()
 self.outermost = outermost
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
 if input_nc is None:
 input_nc = outer_nc
 downconv = nn.Conv2d(input_nc, inner_nc, kernel_size=4,
 stride=2, padding=1, bias=use_bias)
 downrelu = nn.LeakyReLU(0.2, True)
 downnorm = norm_layer(inner_nc)
 uprelu = nn.ReLU(True)
 upnorm = norm_layer(outer_nc)
if outermost:
 upconv = nn.ConvTranspose2d(inner_nc * 2, outer_nc,
 kernel_size=4, stride=2,
 padding=1)
 down = [downconv]
 up = [uprelu, upconv, nn.Tanh()]
 model = down + [submodule] + up
 elif innermost:
 upconv = nn.ConvTranspose2d(inner_nc, outer_nc,
 kernel_size=4, stride=2,
 padding=1, bias=use_bias)
 down = [downrelu, downconv]
 up = [uprelu, upconv, upnorm]
 model = down + up
 else:
 upconv = nn.ConvTranspose2d(inner_nc * 2, outer_nc,
 kernel_size=4, stride=2,
 padding=1, bias=use_bias)
 down = [downrelu, downconv, downnorm]
 up = [uprelu, upconv, upnorm]
if use_dropout:
 model = down + [submodule] + up + [nn.Dropout(0.5)]
 else:
 model = down + [submodule] + up
self.model = nn.Sequential(*model)
def forward(self, x):
 if self.outermost:
 return self.model(x)
 else:
 return torch.cat([x, self.model(x)], 1)
class UnetSkipConnectionResBlock(nn.Module):
 def __init__(self, outer_nc, inner_nc, input_nc=None,
 submodule=None, outermost=False, innermost=False, norm_layer=nn.BatchNorm2d, use_dropout=False, nres=1):
 super(UnetSkipConnectionResBlock, self).__init__()
 self.outermost = outermost
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
 if input_nc is None:
 input_nc = outer_nc
 downconv = nn.Conv2d(input_nc, inner_nc, kernel_size=4,
 stride=2, padding=1, bias=use_bias)
 downrelu = nn.LeakyReLU(0.2, True)
 downnorm = norm_layer(inner_nc)
 uprelu = nn.ReLU(True)
 upnorm = norm_layer(outer_nc)
if outermost:
 upconv = nn.ConvTranspose2d(inner_nc * 2, outer_nc,
 kernel_size=4, stride=2,
 padding=1)
 down = [downconv]
 up = [uprelu, upconv, nn.Tanh()]
 model = down + [submodule] + up
 elif innermost:
 upconv = nn.ConvTranspose2d(inner_nc, outer_nc,
 kernel_size=4, stride=2,
 padding=1, bias=use_bias)
 down = [downrelu, downconv, downrelu]
 up = [upconv, upnorm]
 model = down
 # resblock: conv norm relu conv norm +
 for i in range(nres):
 model += [ResnetBlock(inner_nc, padding_type='reflect', norm_layer=norm_layer, use_dropout=use_dropout, use_bias=use_bias)]
 model += up
 #model = down + [submodule] + up
 print('UnetSkipConnectionResBlock','nres',nres,'inner_nc',inner_nc)
 else:
 upconv = nn.ConvTranspose2d(inner_nc * 2, outer_nc,
 kernel_size=4, stride=2,
 padding=1, bias=use_bias)
 down = [downrelu, downconv, downnorm]
 up = [uprelu, upconv, upnorm]
if use_dropout:
 model = down + [submodule] + up + [nn.Dropout(0.5)]
 else:
 model = down + [submodule] + up
self.model = nn.Sequential(*model)
def forward(self, x):
 if self.outermost:
 return self.model(x)
 else:
 return torch.cat([x, self.model(x)], 1)
class UnetSkipConnectionStyleBlock(nn.Module):
 def __init__(self, outer_nc, inner_nc, input_nc=None,
 submodule=None, outermost=False, innermost=False,
 extra_channel=2, norm_layer=nn.BatchNorm2d, use_dropout=False):
 super(UnetSkipConnectionStyleBlock, self).__init__()
 self.outermost = outermost
 self.innermost = innermost
 self.extra_channel = extra_channel
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
 if input_nc is None:
 input_nc = outer_nc
 downconv = nn.Conv2d(input_nc, inner_nc, kernel_size=4,
 stride=2, padding=1, bias=use_bias)
 downrelu = nn.LeakyReLU(0.2, True)
 downnorm = norm_layer(inner_nc)
 uprelu = nn.ReLU(True)
 upnorm = norm_layer(outer_nc)
if outermost:
 upconv = nn.ConvTranspose2d(inner_nc * 2, outer_nc,
 kernel_size=4, stride=2,
 padding=1)
 down = [downconv]
 up = [uprelu, upconv, nn.Tanh()]
 model = down + [submodule] + up
 elif innermost:
 upconv = nn.ConvTranspose2d(inner_nc+extra_channel, outer_nc,
 kernel_size=4, stride=2,
 padding=1, bias=use_bias)
 down = [downrelu, downconv]
 up = [uprelu, upconv, upnorm]
 model = down + up
 else:
 upconv = nn.ConvTranspose2d(inner_nc * 2, outer_nc,
 kernel_size=4, stride=2,
 padding=1, bias=use_bias)
 down = [downrelu, downconv, downnorm]
 up = [uprelu, upconv, upnorm]
if use_dropout:
 up = up + [nn.Dropout(0.5)]
 model = down + [submodule] + up
self.model = nn.Sequential(*model)
self.downmodel = nn.Sequential(*down)
 self.upmodel = nn.Sequential(*up)
 self.submodule = submodule
def forward(self, x, cate):# cate [bs,c]
 if self.innermost:
 y1 = self.downmodel(x)
 [bs,c,h,w] = y1.shape
 map = cate.repeat(h,w,1,1).permute([2,3,0,1])
 y2 = torch.cat([y1,map], 1)
 y3 = self.upmodel(y2)
 return torch.cat([x, y3], 1)
 else:
 y1 = self.downmodel(x)
 y2 = self.submodule(y1,cate)
 y3 = self.upmodel(y2)
 if self.outermost:
 return y3
 else:
 return torch.cat([x, y3], 1)
class UnetSkipConnectionResStyleBlock(nn.Module):
 def __init__(self, outer_nc, inner_nc, input_nc=None,
 submodule=None, outermost=False, innermost=False,
 extra_channel=2, norm_layer=nn.BatchNorm2d, use_dropout=False, nres=1):
 super(UnetSkipConnectionResStyleBlock, self).__init__()
 self.outermost = outermost
 self.innermost = innermost
 self.extra_channel = extra_channel
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
 if input_nc is None:
 input_nc = outer_nc
 downconv = nn.Conv2d(input_nc, inner_nc, kernel_size=4,
 stride=2, padding=1, bias=use_bias)
 downrelu = nn.LeakyReLU(0.2, True)
 downnorm = norm_layer(inner_nc)
 uprelu = nn.ReLU(True)
 upnorm = norm_layer(outer_nc)
if outermost:
 upconv = nn.ConvTranspose2d(inner_nc * 2, outer_nc,
 kernel_size=4, stride=2,
 padding=1)
 down = [downconv]
 up = [uprelu, upconv, nn.Tanh()]
 model = down + [submodule] + up
 elif innermost:
 upconv = nn.ConvTranspose2d(inner_nc, outer_nc,
 kernel_size=4, stride=2,
 padding=1, bias=use_bias)
 down = [downrelu, downconv, downrelu]
 up = [nn.Conv2d(inner_nc+extra_channel, inner_nc, kernel_size=3, stride=1, padding=1, bias=use_bias),
 norm_layer(inner_nc),
 nn.ReLU(True)]
 for i in range(nres):
 up += [ResnetBlock(inner_nc, padding_type='reflect', norm_layer=norm_layer, use_dropout=use_dropout, use_bias=use_bias)]
 up += [ upconv, upnorm]
 model = down + up
 print('UnetSkipConnectionResStyleBlock','nres',nres,'inner_nc',inner_nc)
 else:
 upconv = nn.ConvTranspose2d(inner_nc * 2, outer_nc,
 kernel_size=4, stride=2,
 padding=1, bias=use_bias)
 down = [downrelu, downconv, downnorm]
 up = [uprelu, upconv, upnorm]
if use_dropout:
 up = up + [nn.Dropout(0.5)]
 model = down + [submodule] + up
self.model = nn.Sequential(*model)
self.downmodel = nn.Sequential(*down)
 self.upmodel = nn.Sequential(*up)
 self.submodule = submodule
def forward(self, x, cate):# cate [bs,c]
 # concate in the innermost block
 if self.innermost:
 y1 = self.downmodel(x)
 [bs,c,h,w] = y1.shape
 map = cate.repeat(h,w,1,1).permute([2,3,0,1])
 y2 = torch.cat([y1,map], 1)
 y3 = self.upmodel(y2)
 return torch.cat([x, y3], 1)
 else:
 y1 = self.downmodel(x)
 y2 = self.submodule(y1,cate)
 y3 = self.upmodel(y2)
 if self.outermost:
 return y3
 else:
 return torch.cat([x, y3], 1)
# Defines the PatchGAN discriminator with the specified arguments.
class NLayerDiscriminator(nn.Module):
 def __init__(self, input_nc, ndf=64, n_layers=3, norm_layer=nn.BatchNorm2d, use_sigmoid=False):
 super(NLayerDiscriminator, self).__init__()
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
kw = 4
 padw = 1
 sequence = [
 nn.Conv2d(input_nc, ndf, kernel_size=kw, stride=2, padding=padw),
 nn.LeakyReLU(0.2, True)
 ]
nf_mult = 1
 nf_mult_prev = 1
 for n in range(1, n_layers):
 nf_mult_prev = nf_mult
 nf_mult = min(2**n, 8)
 sequence += [
 nn.Conv2d(ndf * nf_mult_prev, ndf * nf_mult,
 kernel_size=kw, stride=2, padding=padw, bias=use_bias),
 norm_layer(ndf * nf_mult),
 nn.LeakyReLU(0.2, True)
 ]
nf_mult_prev = nf_mult
 nf_mult = min(2**n_layers, 8)
 sequence += [
 nn.Conv2d(ndf * nf_mult_prev, ndf * nf_mult,
 kernel_size=kw, stride=1, padding=padw, bias=use_bias),
 norm_layer(ndf * nf_mult),
 nn.LeakyReLU(0.2, True)
 ]
sequence += [nn.Conv2d(ndf * nf_mult, 1, kernel_size=kw, stride=1, padding=padw)]
if use_sigmoid:#no_lsgan, use sigmoid before calculating bceloss(binary cross entropy)
 sequence += [nn.Sigmoid()]
self.model = nn.Sequential(*sequence)
def forward(self, input):
 return self.model(input)
class PixelDiscriminator(nn.Module):
 def __init__(self, input_nc, ndf=64, norm_layer=nn.BatchNorm2d, use_sigmoid=False):
 super(PixelDiscriminator, self).__init__()
 if type(norm_layer) == functools.partial:
 use_bias = norm_layer.func == nn.InstanceNorm2d
 else:
 use_bias = norm_layer == nn.InstanceNorm2d
self.net = [
 nn.Conv2d(input_nc, ndf, kernel_size=1, stride=1, padding=0),
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ndf, ndf * 2, kernel_size=1, stride=1, padding=0, bias=use_bias),
 norm_layer(ndf * 2),
 nn.LeakyReLU(0.2, True),
 nn.Conv2d(ndf * 2, 1, kernel_size=1, stride=1, padding=0, bias=use_bias)]
if use_sigmoid:
 self.net.append(nn.Sigmoid())
self.net = nn.Sequential(*self.net)
def forward(self, input):
 return self.net(input)