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train_ann.py
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train_ann.py
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import argparse
import json
import pickle
import shutil
import typing as t
from time import time
import torch
import wandb
from sklearn.metrics import f1_score
from sklearn.metrics import precision_score
from sklearn.metrics import recall_score
from sklearn.metrics import roc_auc_score
from torch.utils.data import DataLoader
from torchmetrics.functional.classification import binary_accuracy
from tqdm import tqdm
from timebase import criterions
from timebase.criterions import Criteria
from timebase.data.reader import get_datasets
from timebase.data.static import *
from timebase.metrics import secondary_metrics_subjects_get_inputs
from timebase.metrics import subject_accuracy
from timebase.models.models import Classifier
from timebase.models.models import Critic
from timebase.models.models import get_models
from timebase.utils import tensorboard
from timebase.utils import utils
from timebase.utils import yaml
from timebase.utils.scheduler import Scheduler
def load(d: t.Dict[str, torch.Tensor], device: torch.device):
"""Load values in dictionary d to device"""
return {k: v.to(device) for k, v in d.items()}
def load_pre_trained_parameters(
args, classifier: Classifier, path2pretraining_res: str
):
filename = os.path.join(path2pretraining_res, "ckpt_sslearner/model_state.pt")
assert os.path.exists(filename), f"checkpoint was not found at {filename}"
ckpt = torch.load(filename, map_location=args.device)
state_dict = classifier.sslearner.state_dict()
state_dict.update(
{
# the transform head is discarded
k: v
for k, v in ckpt["model"].items()
if any(module in k for module in ["channel_embedding", "feature_encoder"])
}
)
classifier.sslearner.load_state_dict(state_dict)
if args.verbose:
print(
f"Parameters of classifier's representations extractor module "
f"loaded from epoch {ckpt['epoch']} of SS pre-training"
)
@torch.inference_mode()
def get_res(
args,
ds: DataLoader,
classifier: Classifier,
verbose: int = 1,
):
device = args.device
targets, y_pred_probs, representations, labels, metadata = [], [], [], {}, {}
classifier.to(device)
classifier.train(False)
for batch in tqdm(ds, disable=verbose == 0):
inputs = load(batch["data"], device=device)
outputs_classifier, representation = classifier(inputs)
label = load(batch["label"], device=device)
target = batch["target"].to(device)
utils.update_dict(target=labels, source=label)
utils.update_dict(target=metadata, source=batch["metadata"])
y_pred_probs.append(torch.sigmoid(outputs_classifier))
targets.append(target)
representations.append(representation)
res = {
"labels": {k: torch.cat(v, dim=0).cpu().numpy() for k, v in labels.items()},
"metadata": {k: torch.cat(v, dim=0).cpu().numpy() for k, v in metadata.items()},
"targets": torch.concat(targets, dim=0).cpu().numpy(),
"pred_probs": torch.cat(y_pred_probs, dim=0).cpu().numpy(),
"representations": torch.concat(representations, dim=0).cpu().numpy(),
}
res["metadata"]["recording_id"] = np.vectorize(
lambda x: {v: k for k, v in ds.dataset.recording_id_str_to_num.items()}.get(
x, x
)
)(res["metadata"]["recording_id"])
return res
def train_step_time_split(
batch: t.Dict[str, t.Any],
classifier: Classifier,
freeze_representation_module: bool,
critic: Critic,
optimizer_classifier: torch.optim.Optimizer,
optimizer_critic: torch.optim.Optimizer,
criteria: Criteria,
device: torch.device,
):
result = {}
classifier.to(device)
inputs = load(batch["data"], device=device)
targets = batch["target"].to(device)
subject_ids = batch["subject_id"].to(device)
classifier.train(True)
if freeze_representation_module:
classifier.sslearner.requires_grad_(False)
outputs_classifier, representation = classifier(inputs)
classifier_loss = criteria.criterion_classifier(
y_true=targets, y_pred=outputs_classifier
)
classifier_loss.backward()
optimizer_classifier.step()
optimizer_classifier.zero_grad()
result.update(
{
"loss/classifier": classifier_loss.detach(),
"metrics/acc": binary_accuracy(
outputs_classifier.detach(), targets.detach()
),
}
)
outputs = {
"y_pred": outputs_classifier.detach().cpu().numpy(),
"y_true": targets.detach().cpu().numpy(),
"subject_ids": subject_ids.detach().cpu().numpy(),
}
return result, outputs
def train_step_subject_split(
batch: t.Dict[str, t.Any],
classifier: Classifier,
freeze_representation_module: bool,
critic: Critic,
optimizer_classifier: torch.optim.Optimizer,
optimizer_critic: torch.optim.Optimizer,
criteria: Criteria,
device: torch.device,
):
result = {}
classifier.to(device)
critic.to(device)
inputs = load(batch["data"], device=device)
targets = batch["target"].to(device)
subject_ids = batch["subject_id"].to(device)
# train classifier
classifier.train(True)
if freeze_representation_module:
classifier.sslearner.requires_grad_(False)
critic.train(False)
outputs_classifier, representation = classifier(inputs)
classifier_loss = criteria.criterion_classifier(
y_true=targets, y_pred=outputs_classifier
)
outputs_critic = critic(representation)
representation_loss = criteria.critic_score(
y_true=subject_ids, y_pred=outputs_critic
)
classifier_total_loss = classifier_loss + representation_loss
classifier_total_loss.backward()
optimizer_classifier.step()
optimizer_classifier.zero_grad()
result.update(
{
"loss/classifier": classifier_loss.detach(),
"loss/representation": representation_loss.detach(),
"loss/total": classifier_total_loss.detach(),
}
)
# train critic
representation = representation.detach()
critic.train(True)
outputs_critic = critic(representation)
critic_loss = criteria.criterion_critic(y_true=subject_ids, y_pred=outputs_critic)
critic_loss.backward()
optimizer_critic.step()
optimizer_critic.zero_grad()
result.update(
{
"loss/critic": critic_loss.detach(),
"metrics/acc": binary_accuracy(
outputs_classifier.detach(), targets.detach()
),
}
)
outputs = {
"y_pred": outputs_classifier.detach().cpu().numpy(),
"y_true": targets.detach().cpu().numpy(),
"subject_ids": subject_ids.detach().cpu().numpy(),
}
return result, outputs
TRAIN_STEP_DICT = {
0: train_step_time_split,
1: train_step_subject_split,
}
def train(
args,
ds: DataLoader,
classifier: Classifier,
critic: Critic,
optimizer_critic: torch.optim.Optimizer,
optimizer_classifier: torch.optim.Optimizer,
criteria: Criteria,
summary: tensorboard.Summary,
epoch: int,
):
results, outputs = {}, {}
for batch in tqdm(ds, desc="Train", disable=args.verbose <= 1):
result, output = TRAIN_STEP_DICT[args.split_mode](
batch=batch,
classifier=classifier,
freeze_representation_module=args.task_mode == 2,
critic=critic,
optimizer_classifier=optimizer_classifier,
optimizer_critic=optimizer_critic,
criteria=criteria,
device=args.device,
)
utils.update_dict(target=results, source=result)
utils.update_dict(target=outputs, source=output)
for k, v in results.items():
results[k] = torch.mean(torch.stack(v)).item()
summary.scalar(k, value=results[k], step=epoch, mode=0)
subjects_score = subject_accuracy(
y_pred=np.concatenate(outputs["y_pred"], axis=0),
y_true=np.concatenate(outputs["y_true"], axis=0),
subject_ids=np.concatenate(outputs["subject_ids"], axis=0),
)
summary.scalar("metrics/subjects_accuracy", value=subjects_score, step=epoch)
results["metrics/subjects_accuracy"] = subjects_score
return results
@torch.inference_mode()
def validation_step(
batch: t.Dict[str, t.Any],
classifier: Classifier,
criteria: Criteria,
device: torch.device,
):
result = {}
classifier.to(device)
inputs = load(batch["data"], device=device)
targets = batch["target"].to(device)
subject_ids = batch["subject_id"].to(device)
classifier.train(False)
outputs_classifier, representation = classifier(inputs)
classifier_loss = criteria.criterion_classifier(
y_true=targets, y_pred=outputs_classifier
)
result.update(
{
"loss/classifier": classifier_loss,
"metrics/acc": binary_accuracy(outputs_classifier, targets),
}
)
outputs = {
"y_pred": outputs_classifier.detach().cpu().numpy(),
"y_true": targets.detach().cpu().numpy(),
"subject_ids": subject_ids.detach().cpu().numpy(),
}
return result, outputs
def validate(
args,
ds: DataLoader,
classifier: Classifier,
criteria: Criteria,
summary: tensorboard.Summary,
epoch: int,
mode: int = 1,
):
results, outputs = {}, {}
for batch in tqdm(ds, desc="Validate", disable=args.verbose <= 1):
result, output = validation_step(
batch=batch,
classifier=classifier,
criteria=criteria,
device=args.device,
)
utils.update_dict(target=results, source=result)
utils.update_dict(target=outputs, source=output)
for k, v in results.items():
results[k] = torch.mean(torch.stack(v)).item()
summary.scalar(k, value=results[k], step=epoch, mode=mode)
subjects_score = subject_accuracy(
y_pred=np.concatenate(outputs["y_pred"], axis=0),
y_true=np.concatenate(outputs["y_true"], axis=0),
subject_ids=np.concatenate(outputs["subject_ids"], axis=0),
)
results["metrics/subjects_accuracy"] = subjects_score
summary.scalar(
"metrics/subjects_accuracy", value=subjects_score, step=epoch, mode=mode
)
return results
def main(args, wandb_sweep: bool = False):
utils.set_random_seed(args.seed, verbose=args.verbose)
if args.clear_output_dir and os.path.exists(args.output_dir):
shutil.rmtree(args.output_dir)
if not os.path.exists(args.output_dir):
os.makedirs(args.output_dir)
if args.use_wandb:
utils.wandb_init(args, wandb_sweep=wandb_sweep)
utils.get_device(args)
if args.task_mode in (1, 2):
utils.load_args(args, dir=args.path2pretraining_res)
summary = tensorboard.Summary(args)
train_ds, val_ds, test_ds = get_datasets(args, summary=summary)
classifier, critic = get_models(args, summary=summary)
if args.task_mode in (1, 2):
load_pre_trained_parameters(
args, classifier=classifier, path2pretraining_res=args.path2pretraining_res
)
optimizer_classifier = torch.optim.AdamW(
params=[
{
"params": classifier.parameters() if args.task_mode in (1, 3)
# only classification head is optimized in linear read-out
else classifier.classifier.parameters(),
"name": "classifier",
}
],
lr=args.lr,
weight_decay=args.weight_decay,
)
optimizer_critic = torch.optim.AdamW(
params=[{"params": critic.parameters(), "name": "critic"}],
lr=args.lr,
weight_decay=args.weight_decay,
)
scheduler_classifier = Scheduler(
args,
model=classifier,
checkpoint_dir=os.path.join(args.output_dir, "ckpt_classifier"),
mode="max",
optimizer=optimizer_classifier,
lr_patience=args.lr_patience,
min_epochs=args.min_epochs,
)
scheduler_critic = Scheduler(
args,
model=critic,
checkpoint_dir=os.path.join(args.output_dir, "ckpt_critic"),
mode="min",
optimizer=optimizer_critic,
lr_patience=args.lr_patience,
min_epochs=args.min_epochs,
)
criteria = criterions.get_criterion(
args,
)
utils.save_args(args)
epoch = scheduler_classifier.restore(load_optimizer=True, load_scheduler=True)
if args.split_mode == 1:
_ = scheduler_critic.restore(load_optimizer=True, load_scheduler=True)
results = {k: {} for k in ["train", "validation"]}
while (epoch := epoch + 1) < args.epochs + 1:
if args.skip_training_loop:
break
if args.verbose:
print(f"\nEpoch {epoch:03d}/{args.epochs:03d}")
start = time()
train_results = train(
args,
ds=train_ds,
classifier=classifier,
critic=critic,
optimizer_classifier=optimizer_classifier,
optimizer_critic=optimizer_critic,
criteria=criteria,
summary=summary,
epoch=epoch,
)
val_results = validate(
args,
ds=val_ds,
classifier=classifier,
criteria=criteria,
summary=summary,
epoch=epoch,
)
elapse = time() - start
summary.scalar("elapse", value=elapse, step=epoch, mode=0)
summary.scalar(
f"model/classifier/lr",
value=optimizer_classifier.param_groups[0]["lr"],
step=epoch,
)
if args.split_mode == 1:
summary.scalar(
f"model/critic/lr",
value=optimizer_critic.param_groups[0]["lr"],
step=epoch,
)
utils.update_dict(target=results["train"], source=train_results)
utils.update_dict(target=results["validation"], source=val_results)
if args.verbose:
print(
f'Train\t\tclassifier loss: {train_results["loss/classifier"]:.04f}\t'
f'accuracy: {train_results["metrics/acc"]:.04f}\n'
f'Validation\tclassifier loss: {val_results["loss/classifier"]:.04f}\t'
f'accuracy: {val_results["metrics/acc"]:.04f}\n'
f"Elapse: {elapse:.02f}s\n"
)
if args.split_mode == 1:
scheduler_critic.step(train_results["loss/critic"], epoch=epoch)
metric2optimize = val_results["metrics/subjects_accuracy"]
else:
metric2optimize = val_results["metrics/acc"]
early_stop = scheduler_classifier.step(metric2optimize, epoch=epoch)
if args.use_wandb:
log = {
"train_classifier_loss": train_results["loss/classifier"],
"train_acc": train_results["metrics/acc"],
"train_acc_subjects": train_results["metrics/subjects_accuracy"],
"val_classifier_loss": val_results["loss/classifier"],
"val_acc": val_results["metrics/acc"],
"val_acc_subjects": val_results["metrics/subjects_accuracy"],
"best_acc": scheduler_classifier.best_value,
"elapse": elapse,
}
if args.split_mode == 1:
log["train_critic_loss"] = train_results["loss/critic"]
wandb.log(
log,
step=epoch,
)
if early_stop:
break
if np.isnan(train_results["loss/classifier"]) or np.isnan(
val_results["loss/classifier"]
):
if args.use_wandb:
wandb.finish(exit_code=1) # mark run as failed
exit("\nNaN loss detected, terminate training.")
if args.test_time:
epoch = scheduler_classifier.restore()
test_results = validate(
args,
ds=test_ds,
classifier=classifier,
criteria=criteria,
summary=summary,
epoch=epoch,
mode=2,
)
test_res = get_res(
args,
ds=test_ds,
classifier=classifier,
verbose=args.verbose,
)
(
subjects_pred,
subjects_true,
subjects_scores,
) = secondary_metrics_subjects_get_inputs(
y_pred=test_res["pred_probs"],
y_true=test_res["targets"],
subject_ids=test_res["labels"]["Sub_ID"],
)
log = {
"test_loss": test_results["loss/classifier"],
"test_acc": test_results["metrics/acc"],
"test_acc_subjects": test_results["metrics/subjects_accuracy"],
"test_precision": precision_score(
y_true=test_res["targets"],
y_pred=np.where(test_res["pred_probs"] > 0.5, 1, 0),
),
"test_precision_subjects": precision_score(
y_true=subjects_true,
y_pred=subjects_pred,
),
"test_recall": recall_score(
y_true=test_res["targets"],
y_pred=np.where(test_res["pred_probs"] > 0.5, 1, 0),
),
"test_recall_subjects": recall_score(
y_true=subjects_true,
y_pred=subjects_pred,
),
"test_f1_score": f1_score(
y_true=test_res["targets"],
y_pred=np.where(test_res["pred_probs"] > 0.5, 1, 0),
),
"test_f1_subjects": f1_score(
y_true=subjects_true,
y_pred=subjects_pred,
),
"test_auroc": roc_auc_score(
y_true=test_res["targets"], y_score=test_res["pred_probs"]
),
"test_auroc_subjects": roc_auc_score(
y_true=subjects_true, y_score=subjects_scores
),
}
if args.use_wandb:
wandb.log(
log,
step=epoch,
)
if args.save_test_model_outputs:
with open(
os.path.join(args.output_dir, "test_model_outputs.pkl"), "wb"
) as file:
pickle.dump(test_res, file)
with open(os.path.join(args.output_dir, "test_results.json"), "w") as file:
json.dump(log, file)
print(f"Test ACC={log['test_acc']}, ACC_subject={log['test_acc_subjects']}")
with open(os.path.join(args.output_dir, "train_results.json"), "w") as file:
json.dump(results, file)
if __name__ == "__main__":
parser = argparse.ArgumentParser()
# training configuration
parser.add_argument(
"--e4selflearning",
action="store_true",
help="allows users with no access to INTREPIBD/TIMEBASE data to use "
"the pre-trained E4mer for their own task",
)
parser.add_argument(
"--task_mode",
type=int,
default=3,
choices=[1, 2, 3],
help="criterion for train/val/test split:"
"0) Self-supervised learning"
"1) Pre-trained encoder is fine-tuned"
"2) Pre-trained encoder is frozen (features are simply "
"read out) only the classification is trained on the target task"
"3) Encoder and classification head are trained together end-to-end on "
"target task directly"
"4) Classical machine learning (XGBoost)"
"9) Post-hoc analyses",
)
parser.add_argument(
"--critic_score_lambda",
type=float,
default=0,
help="when > 0, during training, the autoencoder model pays a price for "
"encoding into h (i.e. the shared-between-tasks representation learned "
"with feature_encoder) information that makes it easier for the critic "
"model to tell subjects apart",
)
parser.add_argument("--output_dir", type=str, required=True)
parser.add_argument("--batch_size", type=int, default=16)
parser.add_argument("--epochs", type=int, default=20)
parser.add_argument(
"--device", type=str, default=None, choices=["cpu", "cuda", "mps"]
)
parser.add_argument("--seed", type=int, default=1234)
parser.add_argument(
"--num_workers", type=int, default=2, help="number of workers for DataLoader"
)
parser.add_argument(
"--min_epochs",
type=int,
default=20,
help="number of epochs to train before enforcing in early stopping",
)
parser.add_argument(
"--lr_patience",
type=int,
default=10,
help="number of epochs to wait before reducing lr.",
)
parser.add_argument(
"--save_test_model_outputs", action="store_true", help="save test set outputs"
)
parser.add_argument(
"--test_time", action="store_true", help="perform inference on test set"
)
parser.add_argument(
"--skip_training_loop",
action="store_true",
)
parser.add_argument(
"--include_hr",
action="store_true",
help="HR is included as an input " "to the deep learning pipeline",
)
# optimizer configuration
parser.add_argument("--lr", type=float, default=0.001)
parser.add_argument(
"--weight_decay",
type=float,
default=0.0,
help="weight decay L2 in AdamW optimizer",
)
# matplotlib
parser.add_argument("--save_plots", action="store_true")
parser.add_argument(
"--format", type=str, default="svg", choices=["pdf", "png", "svg"]
)
parser.add_argument("--dpi", type=int, default=120)
parser.add_argument(
"--plot_mode",
type=int,
default=0,
choices=[0, 1, 2, 3],
help="control which plots are printed"
"0) no plots"
"1) data summary plots"
"2) training loop plots"
"3) both data summary and training loop plots",
)
# misc
parser.add_argument("--verbose", type=int, default=2, choices=[0, 1, 2, 3])
parser.add_argument("--clear_output_dir", action="store_true")
parser.add_argument("--use_wandb", action="store_true")
parser.add_argument("--wandb_group", type=str, default="")
parser.add_argument(
"--reuse_stats",
action="store_true",
help="reuse previously computed stats from either training or "
"pre-training set for features scaling",
)
temp_args = parser.parse_known_args()[0]
if temp_args.task_mode in (1, 2):
parser.add_argument("--path2pretraining_res", type=str, required=True)
# temp_args = utils.load_args(temp_args, dir= parser.parse_known_args()[
# 0].path2pretraining_res)
if temp_args.task_mode == 1: # fine-tuning
assert os.path.exists(parser.parse_known_args()[0].path2pretraining_res)
parser.add_argument(
"--a_dropout",
type=float,
default=0.0,
help="dropout rate of MHA",
)
parser.add_argument(
"--m_dropout",
type=float,
default=0.0,
help="dropout rate of MLP",
)
parser.add_argument(
"--drop_path",
type=float,
default=0.0,
help="dropout rate of stochastic depth",
)
else:
# dataset configuration
parser.add_argument(
"--dataset",
type=str,
required=True,
help="path to directory where preprocessed data are stored",
)
parser.add_argument(
"--scaling_mode",
type=int,
default=2,
choices=[0, 1, 2, 3],
help="normalize features: "
"0) no scaling "
"1) normalize features by the overall min and max values from the "
"training set"
"2) standardize features by the overall mean and std from the training "
"set"
"3) standardize features by the overall median and iqr from the "
"training set",
)
# channel embeddings configuration
parser.add_argument(
"--emb_num_filters",
type=int,
default=4,
help="number of filters in the convolutional embedding",
)
# representation module configuration
parser.add_argument(
"--num_blocks", type=int, default=3, help="number of MHA blocks"
)
parser.add_argument(
"--num_heads", type=int, default=3, help="number of attention heads"
)
parser.add_argument(
"--num_units",
type=int,
default=64,
help="number of hidden units, or embed_dim in MHA",
)
parser.add_argument(
"--mlp_dim",
type=int,
default=64,
help="hidden size in Transformer MLP",
)
parser.add_argument(
"--a_dropout",
type=float,
default=0.0,
help="dropout rate of MHA",
)
parser.add_argument(
"--m_dropout", type=float, default=0.0, help="dropout rate of MLP"
)
parser.add_argument(
"--drop_path",
type=float,
default=0.0,
help="dropout rate of stochastic depth",
)
parser.add_argument(
"--disable_bias",
action="store_true",
help="disable bias term in Transformer",
)
parser.add_argument(
"--split_mode",
type=int,
default=0,
choices=[0, 1],
help="criterion for train/val/test split:"
"0) time-split: each session is split into 70:15:15 along the temporal "
"dimension such that segments from different splits map to "
"different parts of the recording"
"1) subject-split: cases and controls are split into 70:15:15 "
"train/val/test such that subjects are not shared across splits",
)
del temp_args
main(parser.parse_args())