def test_prob_map_generator(self, name, size): # set up dataset dataset = TestDataset(name, size) data_loader = DataLoader(dataset, batch_size=1) # set up engine def inference(enging, batch): pass engine = Engine(inference) # add ProbMapGenerator() to evaluator output_dir = os.path.join(os.path.dirname(__file__), "testing_data") prob_map_gen = ProbMapProducer(output_dir=output_dir) evaluator = TestEvaluator(torch.device("cpu:0"), data_loader, size, val_handlers=[prob_map_gen]) # set up validation handler validation = ValidationHandler(evaluator, interval=1) validation.attach(engine) engine.run(data_loader) prob_map = np.load(os.path.join(output_dir, name + ".npy")) self.assertListEqual(np.diag(prob_map).astype(int).tolist(), list(range(1, size + 1)))
def train_handlers(self, context: Context): handlers: List[Any] = [] # LR Scheduler lr_scheduler = self.lr_scheduler_handler(context) if lr_scheduler: handlers.append(lr_scheduler) if context.local_rank == 0: handlers.extend([ StatsHandler(tag_name="train_loss", output_transform=from_engine(["loss"], first=True)), TensorBoardStatsHandler( log_dir=context.events_dir, tag_name="train_loss", output_transform=from_engine(["loss"], first=True), ), ]) if context.evaluator: logger.info( f"{context.local_rank} - Adding Validation to run every '{self._val_interval}' interval" ) handlers.append( ValidationHandler(self._val_interval, validator=context.evaluator, epoch_level=True)) return handlers
def test_content(self): data = [0] * 8 # set up engine def _train_func(engine, batch): pass engine = Engine(_train_func) # set up testing handler val_data_loader = torch.utils.data.DataLoader(Dataset(data)) evaluator = TestEvaluator(torch.device("cpu:0"), val_data_loader) saver = ValidationHandler(interval=2, validator=evaluator) saver.attach(engine) engine.run(data, max_epochs=5) self.assertEqual(evaluator.state.max_epochs, 4) self.assertEqual(evaluator.state.epoch_length, 8)
def train(args): # load hyper parameters task_id = args.task_id fold = args.fold val_output_dir = "./runs_{}_fold{}_{}/".format(task_id, fold, args.expr_name) log_filename = "nnunet_task{}_fold{}.log".format(task_id, fold) log_filename = os.path.join(val_output_dir, log_filename) interval = args.interval learning_rate = args.learning_rate max_epochs = args.max_epochs multi_gpu_flag = args.multi_gpu amp_flag = args.amp lr_decay_flag = args.lr_decay sw_batch_size = args.sw_batch_size tta_val = args.tta_val batch_dice = args.batch_dice window_mode = args.window_mode eval_overlap = args.eval_overlap local_rank = args.local_rank determinism_flag = args.determinism_flag determinism_seed = args.determinism_seed if determinism_flag: set_determinism(seed=determinism_seed) if local_rank == 0: print("Using deterministic training.") # transforms train_batch_size = data_loader_params[task_id]["batch_size"] if multi_gpu_flag: dist.init_process_group(backend="nccl", init_method="env://") device = torch.device(f"cuda:{local_rank}") torch.cuda.set_device(device) else: device = torch.device("cuda") properties, val_loader = get_data(args, mode="validation") _, train_loader = get_data(args, batch_size=train_batch_size, mode="train") # produce the network checkpoint = args.checkpoint net = get_network(properties, task_id, val_output_dir, checkpoint) net = net.to(device) if multi_gpu_flag: net = DistributedDataParallel(module=net, device_ids=[device], find_unused_parameters=True) optimizer = torch.optim.SGD( net.parameters(), lr=learning_rate, momentum=0.99, weight_decay=3e-5, nesterov=True, ) scheduler = torch.optim.lr_scheduler.LambdaLR( optimizer, lr_lambda=lambda epoch: (1 - epoch / max_epochs)**0.9) # produce evaluator val_handlers = [ StatsHandler(output_transform=lambda x: None), CheckpointSaver(save_dir=val_output_dir, save_dict={"net": net}, save_key_metric=True), ] evaluator = DynUNetEvaluator( device=device, val_data_loader=val_loader, network=net, n_classes=len(properties["labels"]), inferer=SlidingWindowInferer( roi_size=patch_size[task_id], sw_batch_size=sw_batch_size, overlap=eval_overlap, mode=window_mode, ), post_transform=None, key_val_metric={ "val_mean_dice": MeanDice( include_background=False, output_transform=lambda x: (x["pred"], x["label"]), ) }, val_handlers=val_handlers, amp=amp_flag, tta_val=tta_val, ) # produce trainer loss = DiceCELoss(to_onehot_y=True, softmax=True, batch=batch_dice) train_handlers = [] if lr_decay_flag: train_handlers += [ LrScheduleHandler(lr_scheduler=scheduler, print_lr=True) ] train_handlers += [ ValidationHandler(validator=evaluator, interval=interval, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), ] trainer = DynUNetTrainer( device=device, max_epochs=max_epochs, train_data_loader=train_loader, network=net, optimizer=optimizer, loss_function=loss, inferer=SimpleInferer(), post_transform=None, key_train_metric=None, train_handlers=train_handlers, amp=amp_flag, ) # run logger = logging.getLogger() formatter = logging.Formatter( "%(asctime)s - %(name)s - %(levelname)s - %(message)s") # Setup file handler fhandler = logging.FileHandler(log_filename) fhandler.setLevel(logging.INFO) fhandler.setFormatter(formatter) # Configure stream handler for the cells chandler = logging.StreamHandler() chandler.setLevel(logging.INFO) chandler.setFormatter(formatter) # Add both handlers if local_rank == 0: logger.addHandler(fhandler) logger.addHandler(chandler) logger.setLevel(logging.INFO) trainer.run()
def run_training_test(root_dir, device="cuda:0", amp=False): images = sorted(glob(os.path.join(root_dir, "img*.nii.gz"))) segs = sorted(glob(os.path.join(root_dir, "seg*.nii.gz"))) train_files = [{ "image": img, "label": seg } for img, seg in zip(images[:20], segs[:20])] val_files = [{ "image": img, "label": seg } for img, seg in zip(images[-20:], segs[-20:])] # define transforms for image and segmentation train_transforms = Compose([ LoadNiftid(keys=["image", "label"]), AsChannelFirstd(keys=["image", "label"], channel_dim=-1), ScaleIntensityd(keys=["image", "label"]), RandCropByPosNegLabeld(keys=["image", "label"], label_key="label", spatial_size=[96, 96, 96], pos=1, neg=1, num_samples=4), RandRotate90d(keys=["image", "label"], prob=0.5, spatial_axes=[0, 2]), ToTensord(keys=["image", "label"]), ]) val_transforms = Compose([ LoadNiftid(keys=["image", "label"]), AsChannelFirstd(keys=["image", "label"], channel_dim=-1), ScaleIntensityd(keys=["image", "label"]), ToTensord(keys=["image", "label"]), ]) # create a training data loader train_ds = monai.data.CacheDataset(data=train_files, transform=train_transforms, cache_rate=0.5) # use batch_size=2 to load images and use RandCropByPosNegLabeld to generate 2 x 4 images for network training train_loader = monai.data.DataLoader(train_ds, batch_size=2, shuffle=True, num_workers=4) # create a validation data loader val_ds = monai.data.CacheDataset(data=val_files, transform=val_transforms, cache_rate=1.0) val_loader = monai.data.DataLoader(val_ds, batch_size=1, num_workers=4) # create UNet, DiceLoss and Adam optimizer net = monai.networks.nets.UNet( dimensions=3, in_channels=1, out_channels=1, channels=(16, 32, 64, 128, 256), strides=(2, 2, 2, 2), num_res_units=2, ).to(device) loss = monai.losses.DiceLoss(sigmoid=True) opt = torch.optim.Adam(net.parameters(), 1e-3) lr_scheduler = torch.optim.lr_scheduler.StepLR(opt, step_size=2, gamma=0.1) val_post_transforms = Compose([ Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold_values=True), KeepLargestConnectedComponentd(keys="pred", applied_labels=[1]), ]) val_handlers = [ StatsHandler(output_transform=lambda x: None), TensorBoardStatsHandler(log_dir=root_dir, output_transform=lambda x: None), TensorBoardImageHandler(log_dir=root_dir, batch_transform=lambda x: (x["image"], x["label"]), output_transform=lambda x: x["pred"]), CheckpointSaver(save_dir=root_dir, save_dict={"net": net}, save_key_metric=True), ] evaluator = SupervisedEvaluator( device=device, val_data_loader=val_loader, network=net, inferer=SlidingWindowInferer(roi_size=(96, 96, 96), sw_batch_size=4, overlap=0.5), post_transform=val_post_transforms, key_val_metric={ "val_mean_dice": MeanDice(include_background=True, output_transform=lambda x: (x["pred"], x["label"])) }, additional_metrics={ "val_acc": Accuracy(output_transform=lambda x: (x["pred"], x["label"])) }, val_handlers=val_handlers, amp=True if amp else False, ) train_post_transforms = Compose([ Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold_values=True), KeepLargestConnectedComponentd(keys="pred", applied_labels=[1]), ]) train_handlers = [ LrScheduleHandler(lr_scheduler=lr_scheduler, print_lr=True), ValidationHandler(validator=evaluator, interval=2, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), TensorBoardStatsHandler(log_dir=root_dir, tag_name="train_loss", output_transform=lambda x: x["loss"]), CheckpointSaver(save_dir=root_dir, save_dict={ "net": net, "opt": opt }, save_interval=2, epoch_level=True), ] trainer = SupervisedTrainer( device=device, max_epochs=5, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=loss, inferer=SimpleInferer(), post_transform=train_post_transforms, key_train_metric={ "train_acc": Accuracy(output_transform=lambda x: (x["pred"], x["label"])) }, train_handlers=train_handlers, amp=True if amp else False, ) trainer.run() return evaluator.state.best_metric
def configure(self): self.set_device() network = UNet( dimensions=3, in_channels=1, out_channels=2, channels=(16, 32, 64, 128, 256), strides=(2, 2, 2, 2), num_res_units=2, norm=Norm.BATCH, ).to(self.device) if self.multi_gpu: network = DistributedDataParallel( module=network, device_ids=[self.device], find_unused_parameters=False, ) train_transforms = Compose([ LoadImaged(keys=("image", "label")), EnsureChannelFirstd(keys=("image", "label")), Spacingd(keys=("image", "label"), pixdim=[1.0, 1.0, 1.0], mode=["bilinear", "nearest"]), ScaleIntensityRanged( keys="image", a_min=-57, a_max=164, b_min=0.0, b_max=1.0, clip=True, ), CropForegroundd(keys=("image", "label"), source_key="image"), RandCropByPosNegLabeld( keys=("image", "label"), label_key="label", spatial_size=(96, 96, 96), pos=1, neg=1, num_samples=4, image_key="image", image_threshold=0, ), RandShiftIntensityd(keys="image", offsets=0.1, prob=0.5), ToTensord(keys=("image", "label")), ]) train_datalist = load_decathlon_datalist(self.data_list_file_path, True, "training") if self.multi_gpu: train_datalist = partition_dataset( data=train_datalist, shuffle=True, num_partitions=dist.get_world_size(), even_divisible=True, )[dist.get_rank()] train_ds = CacheDataset( data=train_datalist, transform=train_transforms, cache_num=32, cache_rate=1.0, num_workers=4, ) train_data_loader = DataLoader( train_ds, batch_size=2, shuffle=True, num_workers=4, ) val_transforms = Compose([ LoadImaged(keys=("image", "label")), EnsureChannelFirstd(keys=("image", "label")), ScaleIntensityRanged( keys="image", a_min=-57, a_max=164, b_min=0.0, b_max=1.0, clip=True, ), CropForegroundd(keys=("image", "label"), source_key="image"), ToTensord(keys=("image", "label")), ]) val_datalist = load_decathlon_datalist(self.data_list_file_path, True, "validation") val_ds = CacheDataset(val_datalist, val_transforms, 9, 0.0, 4) val_data_loader = DataLoader( val_ds, batch_size=1, shuffle=False, num_workers=4, ) post_transform = Compose([ Activationsd(keys="pred", softmax=True), AsDiscreted( keys=["pred", "label"], argmax=[True, False], to_onehot=True, n_classes=2, ), ]) # metric key_val_metric = { "val_mean_dice": MeanDice( include_background=False, output_transform=lambda x: (x["pred"], x["label"]), device=self.device, ) } val_handlers = [ StatsHandler(output_transform=lambda x: None), CheckpointSaver( save_dir=self.ckpt_dir, save_dict={"model": network}, save_key_metric=True, ), TensorBoardStatsHandler(log_dir=self.ckpt_dir, output_transform=lambda x: None), ] self.eval_engine = SupervisedEvaluator( device=self.device, val_data_loader=val_data_loader, network=network, inferer=SlidingWindowInferer( roi_size=[160, 160, 160], sw_batch_size=4, overlap=0.5, ), post_transform=post_transform, key_val_metric=key_val_metric, val_handlers=val_handlers, amp=self.amp, ) optimizer = torch.optim.Adam(network.parameters(), self.learning_rate) loss_function = DiceLoss(to_onehot_y=True, softmax=True) lr_scheduler = torch.optim.lr_scheduler.StepLR(optimizer, step_size=5000, gamma=0.1) train_handlers = [ LrScheduleHandler(lr_scheduler=lr_scheduler, print_lr=True), ValidationHandler(validator=self.eval_engine, interval=self.val_interval, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), TensorBoardStatsHandler( log_dir=self.ckpt_dir, tag_name="train_loss", output_transform=lambda x: x["loss"], ), ] self.train_engine = SupervisedTrainer( device=self.device, max_epochs=self.max_epochs, train_data_loader=train_data_loader, network=network, optimizer=optimizer, loss_function=loss_function, inferer=SimpleInferer(), post_transform=post_transform, key_train_metric=None, train_handlers=train_handlers, amp=self.amp, ) if self.local_rank > 0: self.train_engine.logger.setLevel(logging.WARNING) self.eval_engine.logger.setLevel(logging.WARNING)
network=net, inferer=get_inferer(), post_transform=val_post_transform, key_val_metric={ "val_mean_dice": MeanDice(include_background=False, output_transform=lambda x: (x["pred"], x["label"])) }, val_handlers=val_handlers, amp=amp, ) # %% # evaluator as an event handler of the trainer train_handlers = [ ValidationHandler(validator=evaluator, interval=1, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), MetricsSaver(save_dir=model_folder, metrics='*') ] trainer = monai.engines.SupervisedTrainer( device=device, max_epochs=max_epochs, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=DiceCELoss(), inferer=get_inferer(), key_train_metric=None, # key_train_metric={ # "train_mean_dice": MeanDice(include_background=False, output_transform=lambda x: (x["pred"], x["label"])) # },
def main(): monai.config.print_config() logging.basicConfig(stream=sys.stdout, level=logging.INFO) # create a temporary directory and 40 random image, mask paris tempdir = tempfile.mkdtemp() print(f"generating synthetic data to {tempdir} (this may take a while)") for i in range(40): im, seg = create_test_image_3d(128, 128, 128, num_seg_classes=1, channel_dim=-1) n = nib.Nifti1Image(im, np.eye(4)) nib.save(n, os.path.join(tempdir, f"img{i:d}.nii.gz")) n = nib.Nifti1Image(seg, np.eye(4)) nib.save(n, os.path.join(tempdir, f"seg{i:d}.nii.gz")) images = sorted(glob(os.path.join(tempdir, "img*.nii.gz"))) segs = sorted(glob(os.path.join(tempdir, "seg*.nii.gz"))) train_files = [{ Keys.IMAGE: img, Keys.LABEL: seg } for img, seg in zip(images[:20], segs[:20])] val_files = [{ Keys.IMAGE: img, Keys.LABEL: seg } for img, seg in zip(images[-20:], segs[-20:])] # define transforms for image and segmentation train_transforms = Compose([ LoadNiftid(keys=[Keys.IMAGE, Keys.LABEL]), AsChannelFirstd(keys=[Keys.IMAGE, Keys.LABEL], channel_dim=-1), ScaleIntensityd(keys=[Keys.IMAGE, Keys.LABEL]), RandCropByPosNegLabeld(keys=[Keys.IMAGE, Keys.LABEL], label_key=Keys.LABEL, size=[96, 96, 96], pos=1, neg=1, num_samples=4), RandRotate90d(keys=[Keys.IMAGE, Keys.LABEL], prob=0.5, spatial_axes=[0, 2]), ToTensord(keys=[Keys.IMAGE, Keys.LABEL]), ]) val_transforms = Compose([ LoadNiftid(keys=[Keys.IMAGE, Keys.LABEL]), AsChannelFirstd(keys=[Keys.IMAGE, Keys.LABEL], channel_dim=-1), ScaleIntensityd(keys=[Keys.IMAGE, Keys.LABEL]), ToTensord(keys=[Keys.IMAGE, Keys.LABEL]), ]) # create a training data loader train_ds = monai.data.Dataset(data=train_files, transform=train_transforms) # use batch_size=2 to load images and use RandCropByPosNegLabeld to generate 2 x 4 images for network training train_loader = DataLoader(train_ds, batch_size=2, shuffle=True, num_workers=4, collate_fn=list_data_collate) # create a validation data loader val_ds = monai.data.Dataset(data=val_files, transform=val_transforms) val_loader = DataLoader(val_ds, batch_size=1, num_workers=4, collate_fn=list_data_collate) # create UNet, DiceLoss and Adam optimizer device = torch.device("cuda:0") net = monai.networks.nets.UNet( dimensions=3, in_channels=1, out_channels=1, channels=(16, 32, 64, 128, 256), strides=(2, 2, 2, 2), num_res_units=2, ).to(device) loss = monai.losses.DiceLoss(do_sigmoid=True) opt = torch.optim.Adam(net.parameters(), 1e-3) val_handlers = [StatsHandler(output_transform=lambda x: None)] evaluator = SupervisedEvaluator( device=device, val_data_loader=val_loader, network=net, inferer=SlidingWindowInferer(roi_size=(96, 96, 96), sw_batch_size=4, overlap=0.5), val_handlers=val_handlers, key_val_metric={ "val_mean_dice": MeanDice(include_background=True, add_sigmoid=True, output_transform=lambda x: (x[Keys.PRED], x[Keys.LABEL])) }, additional_metrics=None, ) train_handlers = [ ValidationHandler(validator=evaluator, interval=2, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x[Keys.INFO][Keys.LOSS]), ] trainer = SupervisedTrainer( device=device, max_epochs=5, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=loss, inferer=SimpleInferer(), train_handlers=train_handlers, amp=False, key_train_metric=None, ) trainer.run() shutil.rmtree(tempdir)
def train(index): # ---------- Build the nn-Unet network ------------ if opt.resolution is None: sizes, spacings = opt.patch_size, opt.spacing else: sizes, spacings = opt.patch_size, opt.resolution strides, kernels = [], [] while True: spacing_ratio = [sp / min(spacings) for sp in spacings] stride = [ 2 if ratio <= 2 and size >= 8 else 1 for (ratio, size) in zip(spacing_ratio, sizes) ] kernel = [3 if ratio <= 2 else 1 for ratio in spacing_ratio] if all(s == 1 for s in stride): break sizes = [i / j for i, j in zip(sizes, stride)] spacings = [i * j for i, j in zip(spacings, stride)] kernels.append(kernel) strides.append(stride) strides.insert(0, len(spacings) * [1]) kernels.append(len(spacings) * [3]) net = monai.networks.nets.DynUNet( spatial_dims=3, in_channels=opt.in_channels, out_channels=opt.out_channels, kernel_size=kernels, strides=strides, upsample_kernel_size=strides[1:], res_block=True, # act=act_type, # norm=Norm.BATCH, ).to(device) from torch.autograd import Variable from torchsummaryX import summary data = Variable( torch.randn(int(opt.batch_size), int(opt.in_channels), int(opt.patch_size[0]), int(opt.patch_size[1]), int(opt.patch_size[2]))).cuda() out = net(data) summary(net, data) print("out size: {}".format(out.size())) # if opt.preload is not None: # net.load_state_dict(torch.load(opt.preload)) # ---------- ------------------------ ------------ optim = torch.optim.Adam(net.parameters(), lr=opt.lr) lr_scheduler = torch.optim.lr_scheduler.LambdaLR( optim, lr_lambda=lambda epoch: (1 - epoch / opt.epochs)**0.9) loss_function = monai.losses.DiceCELoss(sigmoid=True) val_post_transforms = Compose([ Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold_values=True), # KeepLargestConnectedComponentd(keys="pred", applied_labels=[1]) ]) val_handlers = [ StatsHandler(output_transform=lambda x: None), CheckpointSaver(save_dir="./runs/", save_dict={"net": net}, save_key_metric=True), ] evaluator = SupervisedEvaluator( device=device, val_data_loader=val_loaders[index], network=net, inferer=SlidingWindowInferer(roi_size=opt.patch_size, sw_batch_size=opt.batch_size, overlap=0.5), post_transform=val_post_transforms, key_val_metric={ "val_mean_dice": MeanDice( include_background=True, output_transform=lambda x: (x["pred"], x["label"]), ) }, val_handlers=val_handlers) train_post_transforms = Compose([ Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold_values=True), # KeepLargestConnectedComponentd(keys="pred", applied_labels=[1]), ]) train_handlers = [ ValidationHandler(validator=evaluator, interval=5, epoch_level=True), LrScheduleHandler(lr_scheduler=lr_scheduler, print_lr=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), CheckpointSaver(save_dir="./runs/", save_dict={ "net": net, "opt": optim }, save_final=True, epoch_level=True), ] trainer = SupervisedTrainer( device=device, max_epochs=opt.epochs, train_data_loader=train_loaders[index], network=net, optimizer=optim, loss_function=loss_function, inferer=SimpleInferer(), post_transform=train_post_transforms, amp=False, train_handlers=train_handlers, ) trainer.run() return net
def train(gpu, args): """run a training pipeline.""" args.gpu = gpu if args.gpu is not None: print("Use GPU: {} for training".format(args.gpu)) if args.distributed: print('Setting up multiple GPUs') if args.dist_url == "env://" and args.rank == -1: args.rank = int(os.environ["RANK"]) if args.multiprocessing_distributed: # For multiprocessing distributed training, rank needs to be the # global rank among all the processes args.rank = args.rank * args.ngpus_per_node + gpu print(args.rank) dist.init_process_group( backend=args.dist_backend, init_method=args.dist_url, world_size=args.world_size, rank=args.rank, ) print('Done!') #======================================== images = sorted(glob.glob(os.path.join(args.data_folder, "*_ct.nii.gz"))) labels = sorted(glob.glob(os.path.join(args.data_folder, "*_seg.nii.gz"))) logging.info(f"training: image/label ({len(images)}) folder: {args.data_folder}") amp = True # auto. mixed precision keys = ("image", "label") #TODO is_one_hot = False # whether the label has multiple channels to represent multiple class train_frac, val_frac = 0.8, 0.2 n_train = int(train_frac * len(images)) + 1 n_val = min(len(images) - n_train, int(val_frac * len(images))) logging.info(f"training: train {n_train} val {n_val}, folder: {args.data_folder}") train_files = [{keys[0]: img, keys[1]: seg} for img, seg in zip(images[:n_train], labels[:n_train])] val_files = [{keys[0]: img, keys[1]: seg} for img, seg in zip(images[-n_val:], labels[-n_val:])] # create a training data loader logging.info(f"batch size {args.batch_size}") train_transforms = get_xforms("train", keys) train_ds = monai.data.CacheDataset(data=train_files, transform=train_transforms, cache_rate=args.cache_rate, num_workers=args.preprocessing_workers) if args.distributed: train_sampler = torch.utils.data.distributed.DistributedSampler(train_dataset, num_replicas=args.world_size, rank=args.rank ) train_loader = monai.data.DataLoader( train_ds, batch_size=args.batch_size, shuffle=True, num_workers=args.num_workers, pin_memory=torch.cuda.is_available(), sampler=train_sampler) # else: train_loader = monai.data.DataLoader( train_ds, batch_size=args.batch_size, shuffle=True, num_workers=args.num_workers, pin_memory=torch.cuda.is_available()) # create a validation data loader val_transforms = get_xforms("val", keys) val_ds = monai.data.CacheDataset(data=val_files, transform=val_transforms) val_loader = monai.data.DataLoader( val_ds, batch_size=1, # image-level batch to the sliding window method, not the window-level batch num_workers=args.num_workers, pin_memory=torch.cuda.is_available(), ) # create BasicUNet, DiceLoss and Adam optimizer if args.distributed: print('Setting Up ') torch.cuda.set_device(args.gpu) device = torch.device("cuda" if torch.cuda.is_available() else "cpu") net.cuda(args.gpu) args.batch_size = int(args.batch_size / ngpus_per_node) args.val_batch_size = int(args.val_batch_size / ngpus_per_node) args.num_workers = int( (args.num_workers + ngpus_per_node - 1) / ngpus_per_node ) net = torch.nn.parallel.DistributedDataParallel( net, device_ids=[args.gpu] ) else: device = torch.device("cuda" if torch.cuda.is_available() else "cpu") net = get_net().to(device) logging.info(f"epochs {args.max_epochs}, lr {args.lr}, momentum {args.momentum}") opt = torch.optim.Adam(net.parameters(), lr=args.lr) # create evaluator (to be used to measure model quality during training def pred_transform(y_pred): y_sigmoid = torch.sigmoid(y_pred) y_sigmoid = (y_sigmoid >= logit_thresh).float() return y_sigmoid logit_thresh = 0.5 train_metric = MeanDice( include_background=False, device = device, output_transform=lambda x: (pred_transform(x["pred"]), x["label"]), ) val_metric = MeanDice( include_background=False, device = device, output_transform=lambda x: (pred_transform(x["pred"]), x["label"]), ) val_handlers = [ ProgressBar(), CheckpointSaver(save_dir=args.model_folder, save_dict={'net': net, 'optimizer': opt}, save_key_metric=True, key_metric_n_saved=3), ] evaluator = monai.engines.SupervisedEvaluator( device=device, val_data_loader=val_loader, network=net, inferer=get_inferer(), key_val_metric={"val_mean_dice": val_metric}, val_handlers=val_handlers, amp=amp, ) # evaluator as an event handler of the trainer train_handlers = [ ValidationHandler(validator=evaluator, interval=1, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), LrScheduleHandler(BoundingExponentialLR(opt, gamma=args.gamma), print_lr=True, name='bounding_lr_scheduler', epoch_level=True,) ] trainer = monai.engines.SupervisedTrainer( device=device, max_epochs=args.max_epochs, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=DiceCELoss(), inferer=get_inferer(), key_train_metric={'train_mean_dice': train_metric}, train_handlers=train_handlers, amp=amp, ) trainer.run()
def train(args): """run a training pipeline.""" save_args_to_file(args, 'runs/') images = sorted(glob.glob(os.path.join(args.data_folder, "*_ct.nii.gz"))) labels = sorted(glob.glob(os.path.join(args.data_folder, "*_seg.nii.gz"))) logging.info( f"training: image/label ({len(images)}) folder: {args.data_folder}") amp = True # auto. mixed precision keys = ("image", "label") #TODO is_one_hot = False # whether the label has multiple channels to represent multiple class train_frac, val_frac = 0.8, 0.2 n_train = int(train_frac * len(images)) + 1 n_val = min(len(images) - n_train, int(val_frac * len(images))) logging.info( f"training: train {n_train} val {n_val}, folder: {args.data_folder}") train_files = [{ keys[0]: img, keys[1]: seg } for img, seg in zip(images[:n_train], labels[:n_train])] val_files = [{ keys[0]: img, keys[1]: seg } for img, seg in zip(images[-n_val:], labels[-n_val:])] # create a training data loader logging.info(f"batch size {args.batch_size}") train_transforms = get_xforms(args, "train", keys) train_ds = monai.data.CacheDataset(data=train_files, transform=train_transforms, cache_rate=args.cache_rate, num_workers=args.preprocessing_workers) train_loader = monai.data.DataLoader( train_ds, batch_size=args.batch_size, shuffle=True, num_workers=args.num_workers, pin_memory=torch.cuda.is_available(), ) # create a validation data loader val_transforms = get_xforms(args, "val", keys) val_ds = monai.data.CacheDataset(data=val_files, transform=val_transforms) val_loader = monai.data.DataLoader( val_ds, batch_size= 1, # image-level batch to the sliding window method, not the window-level batch num_workers=args.num_workers, pin_memory=torch.cuda.is_available(), ) # create BasicUNet, DiceLoss and Adam optimizer device = torch.device("cuda" if torch.cuda.is_available() else "cpu") net = get_net(args.n_classes).to(device) logging.info( f"epochs {args.max_epochs}, lr {args.lr}, momentum {args.momentum}") opt = torch.optim.Adam(net.parameters(), lr=args.lr) # create evaluator (to be used to measure model quality during training def pred_transform(y_pred): y_sigmoid = torch.sigmoid(y_pred) y_sigmoid = (y_sigmoid >= logit_thresh).float() return y_sigmoid logit_thresh = 0.5 train_metric = MeanDice( include_background=False, device=device, output_transform=lambda x: (pred_transform(x["pred"]), x["label"]), ) val_metric = MeanDice( include_background=False, device=device, output_transform=lambda x: (pred_transform(x["pred"]), x["label"]), ) val_handlers = [ ProgressBar(), CheckpointSaver(save_dir=args.model_folder, save_dict={ 'net': net, 'optimizer': opt }, save_key_metric=True, key_metric_n_saved=3), ] evaluator = monai.engines.SupervisedEvaluator( device=device, val_data_loader=val_loader, network=net, inferer=get_inferer(args), key_val_metric={"val_mean_dice": val_metric}, val_handlers=val_handlers, amp=amp, ) # evaluator as an event handler of the trainer train_handlers = [ ValidationHandler(validator=evaluator, interval=1, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), LrScheduleHandler( BoundingExponentialLR(opt, gamma=args.gamma, min_lr=args.min_lr, initial_lr=args.lr), print_lr=True, name='bounding_lr_scheduler', epoch_level=True, ) ] trainer = monai.engines.SupervisedTrainer( device=device, max_epochs=args.max_epochs, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=DiceCELoss(), inferer=get_inferer(args), key_train_metric={'train_mean_dice': train_metric}, train_handlers=train_handlers, amp=amp, ) trainer.run()
def train(cfg): log_dir = create_log_dir(cfg) device = set_device(cfg) # -------------------------------------------------------------------------- # Data Loading and Preprocessing # -------------------------------------------------------------------------- # __________________________________________________________________________ # Build MONAI preprocessing train_preprocess = Compose([ ToTensorD(keys="image"), TorchVisionD(keys="image", name="ColorJitter", brightness=64.0 / 255.0, contrast=0.75, saturation=0.25, hue=0.04), ToNumpyD(keys="image"), RandFlipD(keys="image", prob=0.5), RandRotate90D(keys="image", prob=0.5), CastToTypeD(keys="image", dtype=np.float32), RandZoomD(keys="image", prob=0.5, min_zoom=0.9, max_zoom=1.1), ScaleIntensityRangeD(keys="image", a_min=0.0, a_max=255.0, b_min=-1.0, b_max=1.0), ToTensorD(keys=("image", "label")), ]) valid_preprocess = Compose([ CastToTypeD(keys="image", dtype=np.float32), ScaleIntensityRangeD(keys="image", a_min=0.0, a_max=255.0, b_min=-1.0, b_max=1.0), ToTensorD(keys=("image", "label")), ]) # __________________________________________________________________________ # Create MONAI dataset train_json_info_list = load_decathlon_datalist( data_list_file_path=cfg["dataset_json"], data_list_key="training", base_dir=cfg["data_root"], ) valid_json_info_list = load_decathlon_datalist( data_list_file_path=cfg["dataset_json"], data_list_key="validation", base_dir=cfg["data_root"], ) train_dataset = PatchWSIDataset( train_json_info_list, cfg["region_size"], cfg["grid_shape"], cfg["patch_size"], train_preprocess, image_reader_name="openslide" if cfg["use_openslide"] else "cuCIM", ) valid_dataset = PatchWSIDataset( valid_json_info_list, cfg["region_size"], cfg["grid_shape"], cfg["patch_size"], valid_preprocess, image_reader_name="openslide" if cfg["use_openslide"] else "cuCIM", ) # __________________________________________________________________________ # DataLoaders train_dataloader = DataLoader(train_dataset, num_workers=cfg["num_workers"], batch_size=cfg["batch_size"], pin_memory=True) valid_dataloader = DataLoader(valid_dataset, num_workers=cfg["num_workers"], batch_size=cfg["batch_size"], pin_memory=True) # __________________________________________________________________________ # Get sample batch and some info first_sample = first(train_dataloader) if first_sample is None: raise ValueError("Fist sample is None!") print("image: ") print(" shape", first_sample["image"].shape) print(" type: ", type(first_sample["image"])) print(" dtype: ", first_sample["image"].dtype) print("labels: ") print(" shape", first_sample["label"].shape) print(" type: ", type(first_sample["label"])) print(" dtype: ", first_sample["label"].dtype) print(f"batch size: {cfg['batch_size']}") print(f"train number of batches: {len(train_dataloader)}") print(f"valid number of batches: {len(valid_dataloader)}") # -------------------------------------------------------------------------- # Deep Learning Classification Model # -------------------------------------------------------------------------- # __________________________________________________________________________ # initialize model model = TorchVisionFCModel("resnet18", num_classes=1, use_conv=True, pretrained=cfg["pretrain"]) model = model.to(device) # loss function loss_func = torch.nn.BCEWithLogitsLoss() loss_func = loss_func.to(device) # optimizer if cfg["novograd"]: optimizer = Novograd(model.parameters(), cfg["lr"]) else: optimizer = SGD(model.parameters(), lr=cfg["lr"], momentum=0.9) # AMP scaler if cfg["amp"]: cfg["amp"] = True if monai.utils.get_torch_version_tuple() >= ( 1, 6) else False else: cfg["amp"] = False scheduler = lr_scheduler.CosineAnnealingLR(optimizer, T_max=cfg["n_epochs"]) # -------------------------------------------- # Ignite Trainer/Evaluator # -------------------------------------------- # Evaluator val_handlers = [ CheckpointSaver(save_dir=log_dir, save_dict={"net": model}, save_key_metric=True), StatsHandler(output_transform=lambda x: None), TensorBoardStatsHandler(log_dir=log_dir, output_transform=lambda x: None), ] val_postprocessing = Compose([ ActivationsD(keys="pred", sigmoid=True), AsDiscreteD(keys="pred", threshold=0.5) ]) evaluator = SupervisedEvaluator( device=device, val_data_loader=valid_dataloader, network=model, postprocessing=val_postprocessing, key_val_metric={ "val_acc": Accuracy(output_transform=from_engine(["pred", "label"])) }, val_handlers=val_handlers, amp=cfg["amp"], ) # Trainer train_handlers = [ LrScheduleHandler(lr_scheduler=scheduler, print_lr=True), CheckpointSaver(save_dir=cfg["logdir"], save_dict={ "net": model, "opt": optimizer }, save_interval=1, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=from_engine(["loss"], first=True)), ValidationHandler(validator=evaluator, interval=1, epoch_level=True), TensorBoardStatsHandler(log_dir=cfg["logdir"], tag_name="train_loss", output_transform=from_engine(["loss"], first=True)), ] train_postprocessing = Compose([ ActivationsD(keys="pred", sigmoid=True), AsDiscreteD(keys="pred", threshold=0.5) ]) trainer = SupervisedTrainer( device=device, max_epochs=cfg["n_epochs"], train_data_loader=train_dataloader, network=model, optimizer=optimizer, loss_function=loss_func, postprocessing=train_postprocessing, key_train_metric={ "train_acc": Accuracy(output_transform=from_engine(["pred", "label"])) }, train_handlers=train_handlers, amp=cfg["amp"], ) trainer.run()
def main(tempdir): monai.config.print_config() logging.basicConfig(stream=sys.stdout, level=logging.INFO) ################################ DATASET ################################ # get dataset train_ds = CacheDataset(data=train_files, transform=train_transforms, cache_rate=0.5) train_loader = DataLoader(train_ds, batch_size=2, shuffle=True, num_workers=4) val_ds = CacheDataset(data=val_files, transform=val_transforms, cache_rate=1.0) val_loader = DataLoader(val_ds, batch_size=1, num_workers=4) ################################ DATASET ################################ ################################ NETWORK ################################ # create UNet, DiceLoss and Adam optimizer device = torch.device("cuda" if torch.cuda.is_available() else "cpu") net = monai.networks.nets.UNet( dimensions=3, in_channels=1, out_channels=1, channels=(16, 32, 64, 128, 256), strides=(2, 2, 2, 2), num_res_units=2, ).to(device) ################################ NETWORK ################################ ################################ LOSS ################################ loss = monai.losses.DiceLoss(sigmoid=True) ################################ LOSS ################################ ################################ OPT ################################ opt = torch.optim.Adam(net.parameters(), 1e-3) ################################ OPT ################################ ################################ LR ################################ lr_scheduler = torch.optim.lr_scheduler.StepLR(opt, step_size=2, gamma=0.1) ################################ LR ################################ ################################ Evalutaion ################################ val_post_transforms = ... val_handlers = ... evaluator = ... train_post_transforms = Compose([ Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold_values=True), KeepLargestConnectedComponentd(keys="pred", applied_labels=[1]), ]) train_handlers = [ LrScheduleHandler(lr_scheduler=lr_scheduler, print_lr=True), ValidationHandler(validator=evaluator, interval=2, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), TensorBoardStatsHandler(log_dir="./runs/", tag_name="train_loss", output_transform=lambda x: x["loss"]), CheckpointSaver(save_dir="./runs/", save_dict={ "net": net, "opt": opt }, save_interval=2, epoch_level=True), ] trainer = SupervisedTrainer( device=device, max_epochs=5, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=loss, inferer=SimpleInferer(), post_transform=train_post_transforms, key_train_metric={ "train_acc": Accuracy(output_transform=lambda x: (x["pred"], x["label"])) }, train_handlers=train_handlers, # if no FP16 support in GPU or PyTorch version < 1.6, will not enable AMP training amp=True if monai.utils.get_torch_version_tuple() >= (1, 6) else False, ) trainer.run()
def run_training_test(root_dir, device="cuda:0", amp=False, num_workers=4): images = sorted(glob(os.path.join(root_dir, "img*.nii.gz"))) segs = sorted(glob(os.path.join(root_dir, "seg*.nii.gz"))) train_files = [{"image": img, "label": seg} for img, seg in zip(images[:20], segs[:20])] val_files = [{"image": img, "label": seg} for img, seg in zip(images[-20:], segs[-20:])] # define transforms for image and segmentation train_transforms = Compose( [ LoadImaged(keys=["image", "label"]), AsChannelFirstd(keys=["image", "label"], channel_dim=-1), ScaleIntensityd(keys=["image", "label"]), RandCropByPosNegLabeld( keys=["image", "label"], label_key="label", spatial_size=[96, 96, 96], pos=1, neg=1, num_samples=4 ), RandRotate90d(keys=["image", "label"], prob=0.5, spatial_axes=[0, 2]), ToTensord(keys=["image", "label"]), ] ) val_transforms = Compose( [ LoadImaged(keys=["image", "label"]), AsChannelFirstd(keys=["image", "label"], channel_dim=-1), ScaleIntensityd(keys=["image", "label"]), ToTensord(keys=["image", "label"]), ] ) # create a training data loader train_ds = monai.data.CacheDataset(data=train_files, transform=train_transforms, cache_rate=0.5) # use batch_size=2 to load images and use RandCropByPosNegLabeld to generate 2 x 4 images for network training train_loader = monai.data.DataLoader(train_ds, batch_size=2, shuffle=True, num_workers=num_workers) # create a validation data loader val_ds = monai.data.CacheDataset(data=val_files, transform=val_transforms, cache_rate=1.0) val_loader = monai.data.DataLoader(val_ds, batch_size=1, num_workers=num_workers) # create UNet, DiceLoss and Adam optimizer net = monai.networks.nets.UNet( spatial_dims=3, in_channels=1, out_channels=1, channels=(16, 32, 64, 128, 256), strides=(2, 2, 2, 2), num_res_units=2, ).to(device) loss = monai.losses.DiceLoss(sigmoid=True) opt = torch.optim.Adam(net.parameters(), 1e-3) lr_scheduler = torch.optim.lr_scheduler.StepLR(opt, step_size=2, gamma=0.1) summary_writer = SummaryWriter(log_dir=root_dir) val_postprocessing = Compose( [ ToTensord(keys=["pred", "label"]), Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold=0.5), KeepLargestConnectedComponentd(keys="pred", applied_labels=[1]), ] ) class _TestEvalIterEvents: def attach(self, engine): engine.add_event_handler(IterationEvents.FORWARD_COMPLETED, self._forward_completed) def _forward_completed(self, engine): pass val_handlers = [ StatsHandler(iteration_log=False), TensorBoardStatsHandler(summary_writer=summary_writer, iteration_log=False), TensorBoardImageHandler( log_dir=root_dir, batch_transform=from_engine(["image", "label"]), output_transform=from_engine("pred") ), CheckpointSaver(save_dir=root_dir, save_dict={"net": net}, save_key_metric=True), _TestEvalIterEvents(), ] evaluator = SupervisedEvaluator( device=device, val_data_loader=val_loader, network=net, inferer=SlidingWindowInferer(roi_size=(96, 96, 96), sw_batch_size=4, overlap=0.5), postprocessing=val_postprocessing, key_val_metric={ "val_mean_dice": MeanDice(include_background=True, output_transform=from_engine(["pred", "label"])) }, additional_metrics={"val_acc": Accuracy(output_transform=from_engine(["pred", "label"]))}, metric_cmp_fn=lambda cur, prev: cur >= prev, # if greater or equal, treat as new best metric val_handlers=val_handlers, amp=bool(amp), to_kwargs={"memory_format": torch.preserve_format}, amp_kwargs={"dtype": torch.float16 if bool(amp) else torch.float32}, ) train_postprocessing = Compose( [ ToTensord(keys=["pred", "label"]), Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold=0.5), KeepLargestConnectedComponentd(keys="pred", applied_labels=[1]), ] ) class _TestTrainIterEvents: def attach(self, engine): engine.add_event_handler(IterationEvents.FORWARD_COMPLETED, self._forward_completed) engine.add_event_handler(IterationEvents.LOSS_COMPLETED, self._loss_completed) engine.add_event_handler(IterationEvents.BACKWARD_COMPLETED, self._backward_completed) engine.add_event_handler(IterationEvents.MODEL_COMPLETED, self._model_completed) def _forward_completed(self, engine): pass def _loss_completed(self, engine): pass def _backward_completed(self, engine): pass def _model_completed(self, engine): pass train_handlers = [ LrScheduleHandler(lr_scheduler=lr_scheduler, print_lr=True), ValidationHandler(validator=evaluator, interval=2, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=from_engine("loss", first=True)), TensorBoardStatsHandler( summary_writer=summary_writer, tag_name="train_loss", output_transform=from_engine("loss", first=True) ), CheckpointSaver(save_dir=root_dir, save_dict={"net": net, "opt": opt}, save_interval=2, epoch_level=True), _TestTrainIterEvents(), ] trainer = SupervisedTrainer( device=device, max_epochs=5, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=loss, inferer=SimpleInferer(), postprocessing=train_postprocessing, key_train_metric={"train_acc": Accuracy(output_transform=from_engine(["pred", "label"]))}, train_handlers=train_handlers, amp=bool(amp), optim_set_to_none=True, to_kwargs={"memory_format": torch.preserve_format}, amp_kwargs={"dtype": torch.float16 if bool(amp) else torch.float32}, ) trainer.run() return evaluator.state.best_metric
def train(data_folder=".", model_folder="runs"): """run a training pipeline.""" images = sorted(glob.glob(os.path.join(data_folder, "*_ct.nii.gz"))) labels = sorted(glob.glob(os.path.join(data_folder, "*_seg.nii.gz"))) logging.info( f"training: image/label ({len(images)}) folder: {data_folder}") amp = True # auto. mixed precision keys = ("image", "label") train_frac, val_frac = 0.8, 0.2 n_train = int(train_frac * len(images)) + 1 n_val = min(len(images) - n_train, int(val_frac * len(images))) logging.info( f"training: train {n_train} val {n_val}, folder: {data_folder}") train_files = [{ keys[0]: img, keys[1]: seg } for img, seg in zip(images[:n_train], labels[:n_train])] val_files = [{ keys[0]: img, keys[1]: seg } for img, seg in zip(images[-n_val:], labels[-n_val:])] # create a training data loader batch_size = 2 logging.info(f"batch size {batch_size}") train_transforms = get_xforms("train", keys) train_ds = monai.data.CacheDataset(data=train_files, transform=train_transforms) train_loader = monai.data.DataLoader( train_ds, batch_size=batch_size, shuffle=True, num_workers=2, pin_memory=torch.cuda.is_available(), ) # create a validation data loader val_transforms = get_xforms("val", keys) val_ds = monai.data.CacheDataset(data=val_files, transform=val_transforms) val_loader = monai.data.DataLoader( val_ds, batch_size= 1, # image-level batch to the sliding window method, not the window-level batch num_workers=2, pin_memory=torch.cuda.is_available(), ) # create BasicUNet, DiceLoss and Adam optimizer device = torch.device("cuda" if torch.cuda.is_available() else "cpu") net = get_net().to(device) max_epochs, lr, momentum = 500, 1e-4, 0.95 logging.info(f"epochs {max_epochs}, lr {lr}, momentum {momentum}") opt = torch.optim.Adam(net.parameters(), lr=lr) # create evaluator (to be used to measure model quality during training val_post_transform = monai.transforms.Compose([ AsDiscreted(keys=("pred", "label"), argmax=(True, False), to_onehot=True, n_classes=2) ]) val_handlers = [ ProgressBar(), CheckpointSaver(save_dir=model_folder, save_dict={"net": net}, save_key_metric=True, key_metric_n_saved=3), ] evaluator = monai.engines.SupervisedEvaluator( device=device, val_data_loader=val_loader, network=net, inferer=get_inferer(), post_transform=val_post_transform, key_val_metric={ "val_mean_dice": MeanDice(include_background=False, output_transform=lambda x: (x["pred"], x["label"])) }, val_handlers=val_handlers, amp=amp, ) # evaluator as an event handler of the trainer train_handlers = [ ValidationHandler(validator=evaluator, interval=1, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), ] trainer = monai.engines.SupervisedTrainer( device=device, max_epochs=max_epochs, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=DiceCELoss(), inferer=get_inferer(), key_train_metric=None, train_handlers=train_handlers, amp=amp, ) trainer.run()
def create_trainer(args): set_determinism(seed=args.seed) multi_gpu = args.multi_gpu local_rank = args.local_rank if multi_gpu: dist.init_process_group(backend="nccl", init_method="env://") device = torch.device("cuda:{}".format(local_rank)) torch.cuda.set_device(device) else: device = torch.device("cuda" if args.use_gpu else "cpu") pre_transforms = get_pre_transforms(args.roi_size, args.model_size, args.dimensions) click_transforms = get_click_transforms() post_transform = get_post_transforms() train_loader, val_loader = get_loaders(args, pre_transforms) # define training components network = get_network(args.network, args.channels, args.dimensions).to(device) if multi_gpu: network = torch.nn.parallel.DistributedDataParallel( network, device_ids=[local_rank], output_device=local_rank) if args.resume: logging.info('{}:: Loading Network...'.format(local_rank)) map_location = {"cuda:0": "cuda:{}".format(local_rank)} network.load_state_dict( torch.load(args.model_filepath, map_location=map_location)) # define event-handlers for engine val_handlers = [ StatsHandler(output_transform=lambda x: None), TensorBoardStatsHandler(log_dir=args.output, output_transform=lambda x: None), DeepgrowStatsHandler(log_dir=args.output, tag_name='val_dice', image_interval=args.image_interval), CheckpointSaver(save_dir=args.output, save_dict={"net": network}, save_key_metric=True, save_final=True, save_interval=args.save_interval, final_filename='model.pt') ] val_handlers = val_handlers if local_rank == 0 else None evaluator = SupervisedEvaluator( device=device, val_data_loader=val_loader, network=network, iteration_update=Interaction( transforms=click_transforms, max_interactions=args.max_val_interactions, key_probability='probability', train=False), inferer=SimpleInferer(), post_transform=post_transform, key_val_metric={ "val_dice": MeanDice(include_background=False, output_transform=lambda x: (x["pred"], x["label"])) }, val_handlers=val_handlers) loss_function = DiceLoss(sigmoid=True, squared_pred=True) optimizer = torch.optim.Adam(network.parameters(), args.learning_rate) lr_scheduler = torch.optim.lr_scheduler.StepLR(optimizer, step_size=5000, gamma=0.1) train_handlers = [ LrScheduleHandler(lr_scheduler=lr_scheduler, print_lr=True), ValidationHandler(validator=evaluator, interval=args.val_freq, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), TensorBoardStatsHandler(log_dir=args.output, tag_name="train_loss", output_transform=lambda x: x["loss"]), CheckpointSaver(save_dir=args.output, save_dict={ "net": network, "opt": optimizer, "lr": lr_scheduler }, save_interval=args.save_interval * 2, save_final=True, final_filename='checkpoint.pt'), ] train_handlers = train_handlers if local_rank == 0 else train_handlers[:2] trainer = SupervisedTrainer( device=device, max_epochs=args.epochs, train_data_loader=train_loader, network=network, iteration_update=Interaction( transforms=click_transforms, max_interactions=args.max_train_interactions, key_probability='probability', train=True), optimizer=optimizer, loss_function=loss_function, inferer=SimpleInferer(), post_transform=post_transform, amp=args.amp, key_train_metric={ "train_dice": MeanDice(include_background=False, output_transform=lambda x: (x["pred"], x["label"])) }, train_handlers=train_handlers, ) return trainer
def main(tempdir): monai.config.print_config() logging.basicConfig(stream=sys.stdout, level=logging.INFO) ################################ DATASET ################################ # create a temporary directory and 40 random image, mask pairs print(f"generating synthetic data to {tempdir} (this may take a while)") for i in range(40): im, seg = create_test_image_3d(128, 128, 128, num_seg_classes=1, channel_dim=-1) n = nib.Nifti1Image(im, np.eye(4)) nib.save(n, os.path.join(tempdir, f"img{i:d}.nii.gz")) n = nib.Nifti1Image(seg, np.eye(4)) nib.save(n, os.path.join(tempdir, f"seg{i:d}.nii.gz")) images = sorted(glob(os.path.join(tempdir, "img*.nii.gz"))) segs = sorted(glob(os.path.join(tempdir, "seg*.nii.gz"))) train_files = [{"image": img, "label": seg} for img, seg in zip(images[:20], segs[:20])] val_files = [{"image": img, "label": seg} for img, seg in zip(images[-20:], segs[-20:])] # define transforms for image and segmentation train_transforms = Compose( [ LoadImaged(keys=["image", "label"]), AsChannelFirstd(keys=["image", "label"], channel_dim=-1), ScaleIntensityd(keys="image"), RandCropByPosNegLabeld( keys=["image", "label"], label_key="label", spatial_size=[96, 96, 96], pos=1, neg=1, num_samples=4 ), RandRotate90d(keys=["image", "label"], prob=0.5, spatial_axes=[0, 2]), ToTensord(keys=["image", "label"]), ] ) val_transforms = Compose( [ LoadImaged(keys=["image", "label"]), AsChannelFirstd(keys=["image", "label"], channel_dim=-1), ScaleIntensityd(keys="image"), ToTensord(keys=["image", "label"]), ] ) # create a training data loader train_ds = monai.data.CacheDataset(data=train_files, transform=train_transforms, cache_rate=0.5) # use batch_size=2 to load images and use RandCropByPosNegLabeld to generate 2 x 4 images for network training train_loader = monai.data.DataLoader(train_ds, batch_size=2, shuffle=True, num_workers=4) # create a validation data loader val_ds = monai.data.CacheDataset(data=val_files, transform=val_transforms, cache_rate=1.0) val_loader = monai.data.DataLoader(val_ds, batch_size=1, num_workers=4) ################################ DATASET ################################ ################################ NETWORK ################################ # create UNet, DiceLoss and Adam optimizer device = torch.device("cuda" if torch.cuda.is_available() else "cpu") net = monai.networks.nets.UNet( dimensions=3, in_channels=1, out_channels=1, channels=(16, 32, 64, 128, 256), strides=(2, 2, 2, 2), num_res_units=2, ).to(device) ################################ NETWORK ################################ ################################ LOSS ################################ loss = monai.losses.DiceLoss(sigmoid=True) ################################ LOSS ################################ ################################ OPT ################################ opt = torch.optim.Adam(net.parameters(), 1e-3) ################################ OPT ################################ ################################ LR ################################ lr_scheduler = torch.optim.lr_scheduler.StepLR(opt, step_size=2, gamma=0.1) ################################ LR ################################ val_post_transforms = Compose( [ Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold_values=True), KeepLargestConnectedComponentd(keys="pred", applied_labels=[1]), ] ) val_handlers = [ StatsHandler(output_transform=lambda x: None), TensorBoardStatsHandler(log_dir="./runs/", output_transform=lambda x: None), TensorBoardImageHandler( log_dir="./runs/", batch_transform=lambda x: (x["image"], x["label"]), output_transform=lambda x: x["pred"], ), CheckpointSaver(save_dir="./runs/", save_dict={"net": net}, save_key_metric=True), ] evaluator = SupervisedEvaluator( device=device, val_data_loader=val_loader, network=net, inferer=SlidingWindowInferer(roi_size=(96, 96, 96), sw_batch_size=4, overlap=0.5), post_transform=val_post_transforms, key_val_metric={ "val_mean_dice": MeanDice(include_background=True, output_transform=lambda x: (x["pred"], x["label"])) }, additional_metrics={"val_acc": Accuracy(output_transform=lambda x: (x["pred"], x["label"]))}, val_handlers=val_handlers, # if no FP16 support in GPU or PyTorch version < 1.6, will not enable AMP evaluation amp=True if monai.utils.get_torch_version_tuple() >= (1, 6) else False, ) train_post_transforms = Compose( [ Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold_values=True), KeepLargestConnectedComponentd(keys="pred", applied_labels=[1]), ] ) train_handlers = [ LrScheduleHandler(lr_scheduler=lr_scheduler, print_lr=True), ValidationHandler(validator=evaluator, interval=2, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), TensorBoardStatsHandler(log_dir="./runs/", tag_name="train_loss", output_transform=lambda x: x["loss"]), CheckpointSaver(save_dir="./runs/", save_dict={"net": net, "opt": opt}, save_interval=2, epoch_level=True), ] trainer = SupervisedTrainer( device=device, max_epochs=5, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=loss, inferer=SimpleInferer(), post_transform=train_post_transforms, key_train_metric={"train_acc": Accuracy(output_transform=lambda x: (x["pred"], x["label"]))}, train_handlers=train_handlers, # if no FP16 support in GPU or PyTorch version < 1.6, will not enable AMP training amp=True if monai.utils.get_torch_version_tuple() >= (1, 6) else False, ) trainer.run()
def train(data_folder=".", model_folder="runs", continue_training=False): """run a training pipeline.""" #/== files for synthesis path_parent = Path( '/content/drive/My Drive/Datasets/covid19/COVID-19-20_augs_cea/') path_synthesis = Path( path_parent / 'CeA_BASE_grow=1_bg=-1.00_step=-1.0_scale=-1.0_seed=1.0_ch0_1=-1_ch1_16=-1_ali_thr=0.1' ) scans_syns = os.listdir(path_synthesis) decreasing_sequence = get_decreasing_sequence(255, splits=20) keys2 = ("image", "label", "synthetic_lesion") # READ THE SYTHETIC HEALTHY TEXTURE path_synthesis_old = '/content/drive/My Drive/Datasets/covid19/results/cea_synthesis/patient0/' texture_orig = np.load(f'{path_synthesis_old}texture.npy.npz') texture_orig = texture_orig.f.arr_0 texture = texture_orig + np.abs(np.min(texture_orig)) + .07 texture = np.pad(texture, ((100, 100), (100, 100)), mode='reflect') print(f'type(texture) = {type(texture)}, {np.shape(texture)}') #==/ images = sorted(glob.glob(os.path.join(data_folder, "*_ct.nii.gz"))[:10]) #OMM labels = sorted(glob.glob(os.path.join(data_folder, "*_seg.nii.gz"))[:10]) #OMM logging.info( f"training: image/label ({len(images)}) folder: {data_folder}") amp = True # auto. mixed precision keys = ("image", "label") train_frac, val_frac = 0.8, 0.2 n_train = int(train_frac * len(images)) + 1 n_val = min(len(images) - n_train, int(val_frac * len(images))) logging.info( f"training: train {n_train} val {n_val}, folder: {data_folder}") train_files = [{ keys[0]: img, keys[1]: seg } for img, seg in zip(images[:n_train], labels[:n_train])] val_files = [{ keys[0]: img, keys[1]: seg } for img, seg in zip(images[-n_val:], labels[-n_val:])] # create a training data loader batch_size = 1 # XX was 2 logging.info(f"batch size {batch_size}") train_transforms = get_xforms("synthesis", keys, keys2, path_synthesis, decreasing_sequence, scans_syns, texture) train_ds = monai.data.CacheDataset(data=train_files, transform=train_transforms) train_loader = monai.data.DataLoader( train_ds, batch_size=batch_size, shuffle=True, num_workers=2, pin_memory=torch.cuda.is_available(), # collate_fn=pad_list_data_collate, ) # create a validation data loader val_transforms = get_xforms("val", keys) val_ds = monai.data.CacheDataset(data=val_files, transform=val_transforms) val_loader = monai.data.DataLoader( val_ds, batch_size= 1, # image-level batch to the sliding window method, not the window-level batch num_workers=2, pin_memory=torch.cuda.is_available(), ) # create BasicUNet, DiceLoss and Adam optimizer device = torch.device("cuda" if torch.cuda.is_available() else "cpu") net = get_net().to(device) # if continue training if continue_training: ckpts = sorted(glob.glob(os.path.join(model_folder, "*.pt"))) ckpt = ckpts[-1] logging.info(f"continue training using {ckpt}.") net.load_state_dict(torch.load(ckpt, map_location=device)) # max_epochs, lr, momentum = 500, 1e-4, 0.95 max_epochs, lr, momentum = 20, 1e-4, 0.95 #OMM logging.info(f"epochs {max_epochs}, lr {lr}, momentum {momentum}") opt = torch.optim.Adam(net.parameters(), lr=lr) # create evaluator (to be used to measure model quality during training val_post_transform = monai.transforms.Compose([ AsDiscreted(keys=("pred", "label"), argmax=(True, False), to_onehot=True, n_classes=2) ]) val_handlers = [ ProgressBar(), MetricsSaver(save_dir="./metrics_val", metrics="*"), CheckpointSaver(save_dir=model_folder, save_dict={"net": net}, save_key_metric=True, key_metric_n_saved=6), ] evaluator = monai.engines.SupervisedEvaluator( device=device, val_data_loader=val_loader, network=net, inferer=get_inferer(), post_transform=val_post_transform, key_val_metric={ "val_mean_dice": MeanDice(include_background=False, output_transform=lambda x: (x["pred"], x["label"])) }, val_handlers=val_handlers, amp=amp, ) # evaluator as an event handler of the trainer train_handlers = [ ValidationHandler(validator=evaluator, interval=1, epoch_level=True), # MetricsSaver(save_dir="./metrics_train", metrics="*"), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), ] trainer = monai.engines.SupervisedTrainer( device=device, max_epochs=max_epochs, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=DiceCELoss(), inferer=get_inferer(), key_train_metric=None, train_handlers=train_handlers, amp=amp, ) trainer.run()
def run_training(train_file_list, valid_file_list, config_info): """ Pipeline to train a dynUNet segmentation model in MONAI. It is composed of the following main blocks: * Data Preparation: Extract the filenames and prepare the training/validation processing transforms * Load Data: Load training and validation data to PyTorch DataLoader * Network Preparation: Define the network, loss function, optimiser and learning rate scheduler * MONAI Evaluator: Initialise the dynUNet evaluator, i.e. the class providing utilities to perform validation during training. Attach handlers to save the best model on the validation set. A 2D sliding window approach on the 3D volume is used at evaluation. The mean 3D Dice is used as validation metric. * MONAI Trainer: Initialise the dynUNet trainer, i.e. the class providing utilities to perform the training loop. * Run training: The MONAI trainer is run, performing training and validation during training. Args: train_file_list: .txt or .csv file (with no header) storing two-columns filenames for training: image filename in the first column and segmentation filename in the second column. The two columns should be separated by a comma. See monaifbs/config/mock_train_file_list_for_dynUnet_training.txt for an example of the expected format. valid_file_list: .txt or .csv file (with no header) storing two-columns filenames for validation: image filename in the first column and segmentation filename in the second column. The two columns should be separated by a comma. See monaifbs/config/mock_valid_file_list_for_dynUnet_training.txt for an example of the expected format. config_info: dict, contains configuration parameters for sampling, network and training. See monaifbs/config/monai_dynUnet_training_config.yml for an example of the expected fields. """ """ Read input and configuration parameters """ # print MONAI config information logging.basicConfig(stream=sys.stdout, level=logging.INFO) print_config() # print to log the parameter setups print(yaml.dump(config_info)) # extract network parameters, perform checks/set defaults if not present and print them to log if 'seg_labels' in config_info['training'].keys(): seg_labels = config_info['training']['seg_labels'] else: seg_labels = [1] nr_out_channels = len(seg_labels) print("Considering the following {} labels in the segmentation: {}".format(nr_out_channels, seg_labels)) patch_size = config_info["training"]["inplane_size"] + [1] print("Considering patch size = {}".format(patch_size)) spacing = config_info["training"]["spacing"] print("Bringing all images to spacing = {}".format(spacing)) if 'model_to_load' in config_info['training'].keys() and config_info['training']['model_to_load'] is not None: model_to_load = config_info['training']['model_to_load'] if not os.path.exists(model_to_load): raise FileNotFoundError("Cannot find model: {}".format(model_to_load)) else: print("Loading model from {}".format(model_to_load)) else: model_to_load = None # set up either GPU or CPU usage if torch.cuda.is_available(): print("\n#### GPU INFORMATION ###") print("Using device number: {}, name: {}\n".format(torch.cuda.current_device(), torch.cuda.get_device_name())) current_device = torch.device("cuda:0") else: current_device = torch.device("cpu") print("Using device: {}".format(current_device)) # set determinism if required if 'manual_seed' in config_info['training'].keys() and config_info['training']['manual_seed'] is not None: seed = config_info['training']['manual_seed'] else: seed = None if seed is not None: print("Using determinism with seed = {}\n".format(seed)) set_determinism(seed=seed) """ Setup data output directory """ out_model_dir = os.path.join(config_info['output']['out_dir'], datetime.now().strftime('%Y-%m-%d_%H-%M-%S') + '_' + config_info['output']['out_postfix']) print("Saving to directory {}\n".format(out_model_dir)) # create cache directory to store results for Persistent Dataset if 'cache_dir' in config_info['output'].keys(): out_cache_dir = config_info['output']['cache_dir'] else: out_cache_dir = os.path.join(out_model_dir, 'persistent_cache') persistent_cache: Path = Path(out_cache_dir) persistent_cache.mkdir(parents=True, exist_ok=True) """ Data preparation """ # Read the input files for training and validation print("*** Loading input data for training...") train_files = create_data_list_of_dictionaries(train_file_list) print("Number of inputs for training = {}".format(len(train_files))) val_files = create_data_list_of_dictionaries(valid_file_list) print("Number of inputs for validation = {}".format(len(val_files))) # Define MONAI processing transforms for the training data. This includes: # - Load Nifti files and convert to format Batch x Channel x Dim1 x Dim2 x Dim3 # - CropForegroundd: Reduce the background from the MR image # - InPlaneSpacingd: Perform in-plane resampling to the desired spacing, but preserve the resolution along the # last direction (lowest resolution) to avoid introducing motion artefact resampling errors # - SpatialPadd: Pad the in-plane size to the defined network input patch size [N, M] if needed # - NormalizeIntensityd: Apply whitening # - RandSpatialCropd: Crop a random patch from the input with size [B, C, N, M, 1] # - SqueezeDimd: Convert the 3D patch to a 2D one as input to the network (i.e. bring it to size [B, C, N, M]) # - Apply data augmentation (RandZoomd, RandRotated, RandGaussianNoised, RandGaussianSmoothd, RandScaleIntensityd, # RandFlipd) # - ToTensor: convert to pytorch tensor train_transforms = Compose( [ LoadNiftid(keys=["image", "label"]), AddChanneld(keys=["image", "label"]), CropForegroundd(keys=["image", "label"], source_key="image"), InPlaneSpacingd( keys=["image", "label"], pixdim=spacing, mode=("bilinear", "nearest"), ), SpatialPadd(keys=["image", "label"], spatial_size=patch_size, mode=["constant", "edge"]), NormalizeIntensityd(keys=["image"], nonzero=False, channel_wise=True), RandSpatialCropd(keys=["image", "label"], roi_size=patch_size, random_size=False), SqueezeDimd(keys=["image", "label"], dim=-1), RandZoomd( keys=["image", "label"], min_zoom=0.9, max_zoom=1.2, mode=("bilinear", "nearest"), align_corners=(True, None), prob=0.16, ), RandRotated(keys=["image", "label"], range_x=90, range_y=90, prob=0.2, keep_size=True, mode=["bilinear", "nearest"], padding_mode=["zeros", "border"]), RandGaussianNoised(keys=["image"], std=0.01, prob=0.15), RandGaussianSmoothd( keys=["image"], sigma_x=(0.5, 1.15), sigma_y=(0.5, 1.15), sigma_z=(0.5, 1.15), prob=0.15, ), RandScaleIntensityd(keys=["image"], factors=0.3, prob=0.15), RandFlipd(["image", "label"], spatial_axis=[0, 1], prob=0.5), ToTensord(keys=["image", "label"]), ] ) # Define MONAI processing transforms for the validation data # - Load Nifti files and convert to format Batch x Channel x Dim1 x Dim2 x Dim3 # - CropForegroundd: Reduce the background from the MR image # - InPlaneSpacingd: Perform in-plane resampling to the desired spacing, but preserve the resolution along the # last direction (lowest resolution) to avoid introducing motion artefact resampling errors # - SpatialPadd: Pad the in-plane size to the defined network input patch size [N, M] if needed # - NormalizeIntensityd: Apply whitening # - ToTensor: convert to pytorch tensor # NOTE: The validation data is kept 3D as a 2D sliding window approach is used throughout the volume at inference val_transforms = Compose( [ LoadNiftid(keys=["image", "label"]), AddChanneld(keys=["image", "label"]), CropForegroundd(keys=["image", "label"], source_key="image"), InPlaneSpacingd( keys=["image", "label"], pixdim=spacing, mode=("bilinear", "nearest"), ), SpatialPadd(keys=["image", "label"], spatial_size=patch_size, mode=["constant", "edge"]), NormalizeIntensityd(keys=["image"], nonzero=False, channel_wise=True), ToTensord(keys=["image", "label"]), ] ) """ Load data """ # create training data loader train_ds = PersistentDataset(data=train_files, transform=train_transforms, cache_dir=persistent_cache) train_loader = DataLoader(train_ds, batch_size=config_info['training']['batch_size_train'], shuffle=True, num_workers=config_info['device']['num_workers']) check_train_data = misc.first(train_loader) print("Training data tensor shapes:") print("Image = {}; Label = {}".format(check_train_data["image"].shape, check_train_data["label"].shape)) # create validation data loader if config_info['training']['batch_size_valid'] != 1: raise Exception("Batch size different from 1 at validation ar currently not supported") val_ds = PersistentDataset(data=val_files, transform=val_transforms, cache_dir=persistent_cache) val_loader = DataLoader(val_ds, batch_size=1, shuffle=False, num_workers=config_info['device']['num_workers']) check_valid_data = misc.first(val_loader) print("Validation data tensor shapes (Example):") print("Image = {}; Label = {}\n".format(check_valid_data["image"].shape, check_valid_data["label"].shape)) """ Network preparation """ print("*** Preparing the network ...") # automatically extracts the strides and kernels based on nnU-Net empirical rules spacings = spacing[:2] sizes = patch_size[:2] strides, kernels = [], [] while True: spacing_ratio = [sp / min(spacings) for sp in spacings] stride = [2 if ratio <= 2 and size >= 8 else 1 for (ratio, size) in zip(spacing_ratio, sizes)] kernel = [3 if ratio <= 2 else 1 for ratio in spacing_ratio] if all(s == 1 for s in stride): break sizes = [i / j for i, j in zip(sizes, stride)] spacings = [i * j for i, j in zip(spacings, stride)] kernels.append(kernel) strides.append(stride) strides.insert(0, len(spacings) * [1]) kernels.append(len(spacings) * [3]) # initialise the network net = DynUNet( spatial_dims=2, in_channels=1, out_channels=nr_out_channels, kernel_size=kernels, strides=strides, upsample_kernel_size=strides[1:], norm_name="instance", deep_supervision=True, deep_supr_num=2, res_block=False, ).to(current_device) print(net) # define the loss function loss_function = choose_loss_function(nr_out_channels, config_info) # define the optimiser and the learning rate scheduler opt = torch.optim.SGD(net.parameters(), lr=float(config_info['training']['lr']), momentum=0.95) scheduler = torch.optim.lr_scheduler.LambdaLR( opt, lr_lambda=lambda epoch: (1 - epoch / config_info['training']['nr_train_epochs']) ** 0.9 ) """ MONAI evaluator """ print("*** Preparing the dynUNet evaluator engine...\n") # val_post_transforms = Compose( # [ # Activationsd(keys="pred", sigmoid=True), # ] # ) val_handlers = [ StatsHandler(output_transform=lambda x: None), TensorBoardStatsHandler(log_dir=os.path.join(out_model_dir, "valid"), output_transform=lambda x: None, global_epoch_transform=lambda x: trainer.state.iteration), CheckpointSaver(save_dir=out_model_dir, save_dict={"net": net, "opt": opt}, save_key_metric=True, file_prefix='best_valid'), ] if config_info['output']['val_image_to_tensorboad']: val_handlers.append(TensorBoardImageHandler(log_dir=os.path.join(out_model_dir, "valid"), batch_transform=lambda x: (x["image"], x["label"]), output_transform=lambda x: x["pred"], interval=2)) # Define customized evaluator class DynUNetEvaluator(SupervisedEvaluator): def _iteration(self, engine, batchdata): inputs, targets = self.prepare_batch(batchdata) inputs, targets = inputs.to(engine.state.device), targets.to(engine.state.device) flip_inputs_1 = torch.flip(inputs, dims=(2,)) flip_inputs_2 = torch.flip(inputs, dims=(3,)) flip_inputs_3 = torch.flip(inputs, dims=(2, 3)) def _compute_pred(): pred = self.inferer(inputs, self.network) # use random flipping as data augmentation at inference flip_pred_1 = torch.flip(self.inferer(flip_inputs_1, self.network), dims=(2,)) flip_pred_2 = torch.flip(self.inferer(flip_inputs_2, self.network), dims=(3,)) flip_pred_3 = torch.flip(self.inferer(flip_inputs_3, self.network), dims=(2, 3)) return (pred + flip_pred_1 + flip_pred_2 + flip_pred_3) / 4 # execute forward computation self.network.eval() with torch.no_grad(): if self.amp: with torch.cuda.amp.autocast(): predictions = _compute_pred() else: predictions = _compute_pred() return {"image": inputs, "label": targets, "pred": predictions} evaluator = DynUNetEvaluator( device=current_device, val_data_loader=val_loader, network=net, inferer=SlidingWindowInferer2D(roi_size=patch_size, sw_batch_size=4, overlap=0.0), post_transform=None, key_val_metric={ "Mean_dice": MeanDice( include_background=False, to_onehot_y=True, mutually_exclusive=True, output_transform=lambda x: (x["pred"], x["label"]), ) }, val_handlers=val_handlers, amp=False, ) """ MONAI trainer """ print("*** Preparing the dynUNet trainer engine...\n") # train_post_transforms = Compose( # [ # Activationsd(keys="pred", sigmoid=True), # ] # ) validation_every_n_epochs = config_info['training']['validation_every_n_epochs'] epoch_len = len(train_ds) // train_loader.batch_size validation_every_n_iters = validation_every_n_epochs * epoch_len # define event handlers for the trainer writer_train = SummaryWriter(log_dir=os.path.join(out_model_dir, "train")) train_handlers = [ LrScheduleHandler(lr_scheduler=scheduler, print_lr=True), ValidationHandler(validator=evaluator, interval=validation_every_n_iters, epoch_level=False), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), TensorBoardStatsHandler(summary_writer=writer_train, log_dir=os.path.join(out_model_dir, "train"), tag_name="Loss", output_transform=lambda x: x["loss"], global_epoch_transform=lambda x: trainer.state.iteration), CheckpointSaver(save_dir=out_model_dir, save_dict={"net": net, "opt": opt}, save_final=True, save_interval=2, epoch_level=True, n_saved=config_info['output']['max_nr_models_saved']), ] if model_to_load is not None: train_handlers.append(CheckpointLoader(load_path=model_to_load, load_dict={"net": net, "opt": opt})) # define customized trainer class DynUNetTrainer(SupervisedTrainer): def _iteration(self, engine, batchdata): inputs, targets = self.prepare_batch(batchdata) inputs, targets = inputs.to(engine.state.device), targets.to(engine.state.device) def _compute_loss(preds, label): labels = [label] + [interpolate(label, pred.shape[2:]) for pred in preds[1:]] return sum([0.5 ** i * self.loss_function(p, l) for i, (p, l) in enumerate(zip(preds, labels))]) self.network.train() self.optimizer.zero_grad() if self.amp and self.scaler is not None: with torch.cuda.amp.autocast(): predictions = self.inferer(inputs, self.network) loss = _compute_loss(predictions, targets) self.scaler.scale(loss).backward() self.scaler.step(self.optimizer) self.scaler.update() else: predictions = self.inferer(inputs, self.network) loss = _compute_loss(predictions, targets).mean() loss.backward() self.optimizer.step() return {"image": inputs, "label": targets, "pred": predictions, "loss": loss.item()} trainer = DynUNetTrainer( device=current_device, max_epochs=config_info['training']['nr_train_epochs'], train_data_loader=train_loader, network=net, optimizer=opt, loss_function=loss_function, inferer=SimpleInferer(), post_transform=None, key_train_metric=None, train_handlers=train_handlers, amp=False, ) """ Run training """ print("*** Run training...") trainer.run() print("Done!")
def main(config): now = datetime.now().strftime("%Y%m%d-%H:%M:%S") # path csv_path = config['path']['csv_path'] trained_model_path = config['path'][ 'trained_model_path'] # if None, trained from scratch training_model_folder = os.path.join( config['path']['training_model_folder'], now) # '/path/to/folder' if not os.path.exists(training_model_folder): os.makedirs(training_model_folder) logdir = os.path.join(training_model_folder, 'logs') if not os.path.exists(logdir): os.makedirs(logdir) # PET CT scan params image_shape = tuple(config['preprocessing']['image_shape']) # (x, y, z) in_channels = config['preprocessing']['in_channels'] voxel_spacing = tuple( config['preprocessing'] ['voxel_spacing']) # (4.8, 4.8, 4.8) # in millimeter, (x, y, z) data_augment = config['preprocessing'][ 'data_augment'] # True # for training dataset only resize = config['preprocessing']['resize'] # True # not use yet origin = config['preprocessing']['origin'] # how to set the new origin normalize = config['preprocessing'][ 'normalize'] # True # whether or not to normalize the inputs number_class = config['preprocessing']['number_class'] # 2 # CNN params architecture = config['model']['architecture'] # 'unet' or 'vnet' cnn_params = config['model'][architecture]['cnn_params'] # transform list to tuple for key, value in cnn_params.items(): if isinstance(value, list): cnn_params[key] = tuple(value) # Training params epochs = config['training']['epochs'] batch_size = config['training']['batch_size'] shuffle = config['training']['shuffle'] opt_params = config['training']["optimizer"]["opt_params"] # Get Data DM = DataManager(csv_path=csv_path) train_images_paths, val_images_paths, test_images_paths = DM.get_train_val_test( wrap_with_dict=True) # Input preprocessing # use data augmentation for training train_transforms = Compose([ # read img + meta info LoadNifti(keys=["pet_img", "ct_img", "mask_img"]), Roi2Mask(keys=['pet_img', 'mask_img'], method='otsu', tval=0.0, idx_channel=0), ResampleReshapeAlign(target_shape=image_shape, target_voxel_spacing=voxel_spacing, keys=['pet_img', "ct_img", 'mask_img'], origin='head', origin_key='pet_img'), Sitk2Numpy(keys=['pet_img', 'ct_img', 'mask_img']), # user can also add other random transforms RandAffined(keys=("pet_img", "ct_img", "mask_img"), spatial_size=None, prob=0.4, rotate_range=(0, np.pi / 30, np.pi / 15), shear_range=None, translate_range=(10, 10, 10), scale_range=(0.1, 0.1, 0.1), mode=("bilinear", "bilinear", "nearest"), padding_mode="border"), # normalize input ScaleIntensityRanged( keys=["pet_img"], a_min=0.0, a_max=25.0, b_min=0.0, b_max=1.0, clip=True, ), ScaleIntensityRanged( keys=["ct_img"], a_min=-1000.0, a_max=1000.0, b_min=0.0, b_max=1.0, clip=True, ), # Prepare for neural network ConcatModality(keys=['pet_img', 'ct_img']), AddChanneld(keys=["mask_img"]), # Add channel to the first axis ToTensord(keys=["image", "mask_img"]), ]) # without data augmentation for validation val_transforms = Compose([ # read img + meta info LoadNifti(keys=["pet_img", "ct_img", "mask_img"]), Roi2Mask(keys=['pet_img', 'mask_img'], method='otsu', tval=0.0, idx_channel=0), ResampleReshapeAlign(target_shape=image_shape, target_voxel_spacing=voxel_spacing, keys=['pet_img', "ct_img", 'mask_img'], origin='head', origin_key='pet_img'), Sitk2Numpy(keys=['pet_img', 'ct_img', 'mask_img']), # normalize input ScaleIntensityRanged( keys=["pet_img"], a_min=0.0, a_max=25.0, b_min=0.0, b_max=1.0, clip=True, ), ScaleIntensityRanged( keys=["ct_img"], a_min=-1000.0, a_max=1000.0, b_min=0.0, b_max=1.0, clip=True, ), # Prepare for neural network ConcatModality(keys=['pet_img', 'ct_img']), AddChanneld(keys=["mask_img"]), # Add channel to the first axis ToTensord(keys=["image", "mask_img"]), ]) # create a training data loader train_ds = monai.data.CacheDataset(data=train_images_paths, transform=train_transforms, cache_rate=0.5) # use batch_size=2 to load images to generate 2 x 4 images for network training train_loader = monai.data.DataLoader(train_ds, batch_size=batch_size, shuffle=shuffle, num_workers=2) # create a validation data loader val_ds = monai.data.CacheDataset(data=val_images_paths, transform=val_transforms, cache_rate=1.0) val_loader = monai.data.DataLoader(val_ds, batch_size=batch_size, num_workers=2) # Model # create UNet, DiceLoss and Adam optimizer device = torch.device("cuda" if torch.cuda.is_available() else "cpu") net = UNet( dimensions=3, # 3D in_channels=in_channels, out_channels=1, kernel_size=5, channels=(8, 16, 32, 64, 128), strides=(2, 2, 2, 2), num_res_units=2, ).to(device) loss = monai.losses.DiceLoss(sigmoid=True, squared_pred=True) opt = torch.optim.Adam(net.parameters(), 1e-3) # training val_post_transforms = Compose([ Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold_values=True), ]) val_handlers = [ StatsHandler(output_transform=lambda x: None), TensorBoardStatsHandler(log_dir="./runs/", output_transform=lambda x: None), # TensorBoardImageHandler( # log_dir="./runs/", # batch_transform=lambda x: (x["image"], x["label"]), # output_transform=lambda x: x["pred"], # ), CheckpointSaver(save_dir="./runs/", save_dict={ "net": net, "opt": opt }, save_key_metric=True), ] evaluator = SupervisedEvaluator( device=device, val_data_loader=val_loader, network=net, inferer=SimpleInferer(), post_transform=val_post_transforms, key_val_metric={ "val_mean_dice": MeanDice(include_background=True, output_transform=lambda x: (x["pred"], x["label"])) }, additional_metrics={ "val_acc": Accuracy(output_transform=lambda x: (x["pred"], x["label"])), "val_precision": Precision(output_transform=lambda x: (x["pred"], x["label"])), "val_recall": Recall(output_transform=lambda x: (x["pred"], x["label"])) }, val_handlers=val_handlers, # if no FP16 support in GPU or PyTorch version < 1.6, will not enable AMP evaluation # amp=True if monai.config.get_torch_version_tuple() >= (1, 6) else False, ) train_post_transforms = Compose([ Activationsd(keys="pred", sigmoid=True), AsDiscreted(keys="pred", threshold_values=True), ]) train_handlers = [ # LrScheduleHandler(lr_scheduler=lr_scheduler, print_lr=True), ValidationHandler(validator=evaluator, interval=1, epoch_level=True), StatsHandler(tag_name="train_loss", output_transform=lambda x: x["loss"]), TensorBoardStatsHandler(log_dir="./runs/", tag_name="train_loss", output_transform=lambda x: x["loss"]), CheckpointSaver(save_dir="./runs/", save_dict={ "net": net, "opt": opt }, save_interval=2, epoch_level=True), ] trainer = SupervisedTrainer( device=device, max_epochs=5, train_data_loader=train_loader, network=net, optimizer=opt, loss_function=loss, prepare_batch=lambda x: (x['image'], x['mask_img']), inferer=SimpleInferer(), post_transform=train_post_transforms, key_train_metric={ "train_mean_dice": MeanDice(include_background=True, output_transform=lambda x: (x["pred"], x["label"])) }, additional_metrics={ "train_acc": Accuracy(output_transform=lambda x: (x["pred"], x["label"])), "train_precision": Precision(output_transform=lambda x: (x["pred"], x["label"])), "train_recall": Recall(output_transform=lambda x: (x["pred"], x["label"])) }, train_handlers=train_handlers, # if no FP16 support in GPU or PyTorch version < 1.6, will not enable AMP training amp=True if monai.config.get_torch_version_tuple() >= (1, 6) else False, ) trainer.run()