def main():
monai.config.print_config()
logging.basicConfig(stream=sys.stdout, level=logging.INFO)
set_determinism(12345)
device = torch.device("cuda:0")
# load generator
network_filepath = "./network_final.pth"
data = torch.load(network_filepath)
latent_size = 64
gen_net = Generator(latent_shape=latent_size,
start_shape=(latent_size, 8, 8),
channels=[32, 16, 8, 1],
strides=[2, 2, 2, 1])
gen_net.conv.add_module("activation", torch.nn.Sigmoid())
gen_net.load_state_dict(data["g_net"])
gen_net = gen_net.to(device)
# create fakes
output_dir = "./generated_images"
if not os.path.isdir(output_dir):
os.mkdir(output_dir)
num_fakes = 10
print("Generating %d fakes and saving in %s" % (num_fakes, output_dir))
fake_latents = make_latent(num_fakes, latent_size).to(device)
save_generator_fakes(output_dir, gen_net(fake_latents))
def test_script(self):
net = Generator(latent_shape=(64, ),
start_shape=(8, 8, 8),
channels=(8, 1),
strides=(2, 2),
num_res_units=2)
test_data = torch.rand(16, 64)
test_script_save(net, test_data)
def test_script(self):
net = Generator(latent_shape=(64, ),
start_shape=(8, 8, 8),
channels=(8, 1),
strides=(2, 2),
num_res_units=2)
test_data = torch.rand(16, 64)
out_orig, out_reloaded = test_script_save(net, test_data)
assert torch.allclose(out_orig, out_reloaded)
def run_training_test(root_dir, device="cuda:0"):
real_images = sorted(glob(os.path.join(root_dir, "img*.nii.gz")))
train_files = [{"reals": img} for img in zip(real_images)]
# prepare real data
train_transforms = Compose([
LoadNiftid(keys=["reals"]),
AsChannelFirstd(keys=["reals"]),
ScaleIntensityd(keys=["reals"]),
RandFlipd(keys=["reals"], prob=0.5),
ToTensord(keys=["reals"]),
])
train_ds = monai.data.CacheDataset(data=train_files,
transform=train_transforms,
cache_rate=0.5)
train_loader = monai.data.DataLoader(train_ds,
batch_size=2,
shuffle=True,
num_workers=4)
learning_rate = 2e-4
betas = (0.5, 0.999)
real_label = 1
fake_label = 0
# create discriminator
disc_net = Discriminator(in_shape=(1, 64, 64),
channels=(8, 16, 32, 64, 1),
strides=(2, 2, 2, 2, 1),
num_res_units=1,
kernel_size=5).to(device)
disc_net.apply(normal_init)
disc_opt = torch.optim.Adam(disc_net.parameters(),
learning_rate,
betas=betas)
disc_loss_criterion = torch.nn.BCELoss()
def discriminator_loss(gen_images, real_images):
real = real_images.new_full((real_images.shape[0], 1), real_label)
gen = gen_images.new_full((gen_images.shape[0], 1), fake_label)
realloss = disc_loss_criterion(disc_net(real_images), real)
genloss = disc_loss_criterion(disc_net(gen_images.detach()), gen)
return torch.div(torch.add(realloss, genloss), 2)
# create generator
latent_size = 64
gen_net = Generator(latent_shape=latent_size,
start_shape=(latent_size, 8, 8),
channels=[32, 16, 8, 1],
strides=[2, 2, 2, 1])
gen_net.apply(normal_init)
gen_net.conv.add_module("activation", torch.nn.Sigmoid())
gen_net = gen_net.to(device)
gen_opt = torch.optim.Adam(gen_net.parameters(),
learning_rate,
betas=betas)
gen_loss_criterion = torch.nn.BCELoss()
def generator_loss(gen_images):
output = disc_net(gen_images)
cats = output.new_full(output.shape, real_label)
return gen_loss_criterion(output, cats)
key_train_metric = None
train_handlers = [
StatsHandler(
name="training_loss",
output_transform=lambda x: {
Keys.GLOSS: x[Keys.GLOSS],
Keys.DLOSS: x[Keys.DLOSS]
},
),
TensorBoardStatsHandler(
log_dir=root_dir,
tag_name="training_loss",
output_transform=lambda x: {
Keys.GLOSS: x[Keys.GLOSS],
Keys.DLOSS: x[Keys.DLOSS]
},
),
CheckpointSaver(save_dir=root_dir,
save_dict={
"g_net": gen_net,
"d_net": disc_net
},
save_interval=2,
epoch_level=True),
]
disc_train_steps = 2
num_epochs = 5
trainer = GanTrainer(
device,
num_epochs,
train_loader,
gen_net,
gen_opt,
generator_loss,
disc_net,
disc_opt,
discriminator_loss,
d_train_steps=disc_train_steps,
latent_shape=latent_size,
key_train_metric=key_train_metric,
train_handlers=train_handlers,
)
trainer.run()
return trainer.state
def main():
monai.config.print_config()
logging.basicConfig(stream=sys.stdout, level=logging.INFO)
set_determinism(12345)
device = torch.device("cuda:0")
# load real data
mednist_url = "https://www.dropbox.com/s/5wwskxctvcxiuea/MedNIST.tar.gz?dl=1"
md5_value = "0bc7306e7427e00ad1c5526a6677552d"
extract_dir = "data"
tar_save_path = os.path.join(extract_dir, "MedNIST.tar.gz")
download_and_extract(mednist_url, tar_save_path, extract_dir, md5_value)
hand_dir = os.path.join(extract_dir, "MedNIST", "Hand")
real_data = [{
"hand": os.path.join(hand_dir, filename)
} for filename in os.listdir(hand_dir)]
# define real data transforms
train_transforms = Compose([
LoadPNGD(keys=["hand"]),
AddChannelD(keys=["hand"]),
ScaleIntensityD(keys=["hand"]),
RandRotateD(keys=["hand"], range_x=15, prob=0.5, keep_size=True),
RandFlipD(keys=["hand"], spatial_axis=0, prob=0.5),
RandZoomD(keys=["hand"], min_zoom=0.9, max_zoom=1.1, prob=0.5),
ToTensorD(keys=["hand"]),
])
# create dataset and dataloader
real_dataset = CacheDataset(real_data, train_transforms)
batch_size = 300
real_dataloader = DataLoader(real_dataset,
batch_size=batch_size,
shuffle=True,
num_workers=10)
# define function to process batchdata for input into discriminator
def prepare_batch(batchdata):
"""
Process Dataloader batchdata dict object and return image tensors for D Inferer
"""
return batchdata["hand"]
# define networks
disc_net = Discriminator(in_shape=(1, 64, 64),
channels=(8, 16, 32, 64, 1),
strides=(2, 2, 2, 2, 1),
num_res_units=1,
kernel_size=5).to(device)
latent_size = 64
gen_net = Generator(latent_shape=latent_size,
start_shape=(latent_size, 8, 8),
channels=[32, 16, 8, 1],
strides=[2, 2, 2, 1])
# initialize both networks
disc_net.apply(normal_init)
gen_net.apply(normal_init)
# input images are scaled to [0,1] so enforce the same of generated outputs
gen_net.conv.add_module("activation", torch.nn.Sigmoid())
gen_net = gen_net.to(device)
# create optimizers and loss functions
learning_rate = 2e-4
betas = (0.5, 0.999)
disc_opt = torch.optim.Adam(disc_net.parameters(),
learning_rate,
betas=betas)
gen_opt = torch.optim.Adam(gen_net.parameters(),
learning_rate,
betas=betas)
disc_loss_criterion = torch.nn.BCELoss()
gen_loss_criterion = torch.nn.BCELoss()
real_label = 1
fake_label = 0
def discriminator_loss(gen_images, real_images):
"""
The discriminator loss is calculated by comparing D
prediction for real and generated images.
"""
real = real_images.new_full((real_images.shape[0], 1), real_label)
gen = gen_images.new_full((gen_images.shape[0], 1), fake_label)
realloss = disc_loss_criterion(disc_net(real_images), real)
genloss = disc_loss_criterion(disc_net(gen_images.detach()), gen)
return (genloss + realloss) / 2
def generator_loss(gen_images):
"""
The generator loss is calculated by determining how realistic
the discriminator classifies the generated images.
"""
output = disc_net(gen_images)
cats = output.new_full(output.shape, real_label)
return gen_loss_criterion(output, cats)
# initialize current run dir
run_dir = "model_out"
print("Saving model output to: %s " % run_dir)
# create workflow handlers
handlers = [
StatsHandler(
name="batch_training_loss",
output_transform=lambda x: {
Keys.GLOSS: x[Keys.GLOSS],
Keys.DLOSS: x[Keys.DLOSS]
},
),
CheckpointSaver(
save_dir=run_dir,
save_dict={
"g_net": gen_net,
"d_net": disc_net
},
save_interval=10,
save_final=True,
epoch_level=True,
),
]
# define key metric
key_train_metric = None
# create adversarial trainer
disc_train_steps = 5
num_epochs = 50
trainer = GanTrainer(
device,
num_epochs,
real_dataloader,
gen_net,
gen_opt,
generator_loss,
disc_net,
disc_opt,
discriminator_loss,
d_prepare_batch=prepare_batch,
d_train_steps=disc_train_steps,
latent_shape=latent_size,
key_train_metric=key_train_metric,
train_handlers=handlers,
)
# run GAN training
trainer.run()
# Training completed, save a few random generated images.
print("Saving trained generator sample output.")
test_img_count = 10
test_latents = make_latent(test_img_count, latent_size).to(device)
fakes = gen_net(test_latents)
for i, image in enumerate(fakes):
filename = "gen-fake-final-%d.png" % (i)
save_path = os.path.join(run_dir, filename)
img_array = image[0].cpu().data.numpy()
png_writer.write_png(img_array, save_path, scale=255)
def test_shape(self, input_param, input_data, expected_shape):
net = Generator(**input_param)
net.eval()
with torch.no_grad():
result = net.forward(input_data)
self.assertEqual(result.shape, expected_shape)
def test_shape(self, input_param, input_data, expected_shape):
net = Generator(**input_param)
with eval_mode(net):
result = net.forward(input_data)
self.assertEqual(result.shape, expected_shape)