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run_models.py
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run_models.py
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"""
The script for running (including training and testing) all models in this repo.
If you use code in this repository, please cite our paper as below. Many thanks.
@article{DU2023SAITS,
title = {{SAITS: Self-Attention-based Imputation for Time Series}},
journal = {Expert Systems with Applications},
volume = {219},
pages = {119619},
year = {2023},
issn = {0957-4174},
doi = {https://doi.org/10.1016/j.eswa.2023.119619},
url = {https://www.sciencedirect.com/science/article/pii/S0957417423001203},
author = {Wenjie Du and David Cote and Yan Liu},
}
or
Wenjie Du, David Cote, and Yan Liu. SAITS: Self-Attention-based Imputation for Time Series. Expert Systems with Applications, 219:119619, 2023.
"""
import argparse
import math
import os
import warnings
from configparser import ConfigParser, ExtendedInterpolation
from datetime import datetime
import h5py
import numpy as np
import torch
import torch.nn as nn
from torch.utils.tensorboard import SummaryWriter
try:
import nni
except ImportError:
pass
from Global_Config import RANDOM_SEED
from modeling.saits import SAITS
from modeling.transformer import TransformerEncoder
from modeling.brits import BRITS
from modeling.mrnn import MRNN
from modeling.unified_dataloader import UnifiedDataLoader
from modeling.utils import (
Controller,
setup_logger,
save_model,
load_model,
check_saving_dir_for_model,
masked_mae_cal,
masked_rmse_cal,
masked_mre_cal,
)
np.random.seed(RANDOM_SEED)
torch.manual_seed(RANDOM_SEED)
warnings.filterwarnings("ignore") # if to ignore warnings
MODEL_DICT = {
# Self-Attention (SA) based
"Transformer": TransformerEncoder,
"SAITS": SAITS,
# RNN based
"BRITS": BRITS,
"MRNN": MRNN,
}
OPTIMIZER = {"adam": torch.optim.Adam, "adamw": torch.optim.AdamW}
def read_arguments(arg_parser, cfg_parser):
# file path
arg_parser.dataset_base_dir = cfg_parser.get("file_path", "dataset_base_dir")
arg_parser.result_saving_base_dir = cfg_parser.get(
"file_path", "result_saving_base_dir"
)
# dataset info
arg_parser.seq_len = cfg_parser.getint("dataset", "seq_len")
arg_parser.batch_size = cfg_parser.getint("dataset", "batch_size")
arg_parser.num_workers = cfg_parser.getint("dataset", "num_workers")
arg_parser.feature_num = cfg_parser.getint("dataset", "feature_num")
arg_parser.dataset_name = cfg_parser.get("dataset", "dataset_name")
arg_parser.dataset_path = os.path.join(
arg_parser.dataset_base_dir, arg_parser.dataset_name
)
arg_parser.eval_every_n_steps = cfg_parser.getint("dataset", "eval_every_n_steps")
# training settings
arg_parser.MIT = cfg_parser.getboolean("training", "MIT")
arg_parser.ORT = cfg_parser.getboolean("training", "ORT")
arg_parser.lr = cfg_parser.getfloat("training", "lr")
arg_parser.optimizer_type = cfg_parser.get("training", "optimizer_type")
arg_parser.weight_decay = cfg_parser.getfloat("training", "weight_decay")
arg_parser.device = cfg_parser.get("training", "device")
arg_parser.epochs = cfg_parser.getint("training", "epochs")
arg_parser.early_stop_patience = cfg_parser.getint(
"training", "early_stop_patience"
)
arg_parser.model_saving_strategy = cfg_parser.get(
"training", "model_saving_strategy"
)
arg_parser.max_norm = cfg_parser.getfloat("training", "max_norm")
arg_parser.imputation_loss_weight = cfg_parser.getfloat(
"training", "imputation_loss_weight"
)
arg_parser.reconstruction_loss_weight = cfg_parser.getfloat(
"training", "reconstruction_loss_weight"
)
# model settings
arg_parser.model_name = cfg_parser.get("model", "model_name")
arg_parser.model_type = cfg_parser.get("model", "model_type")
return arg_parser
def summary_write_into_tb(summary_writer, info_dict, step, stage):
"""write summary into tensorboard file"""
summary_writer.add_scalar(f"total_loss/{stage}", info_dict["total_loss"], step)
summary_writer.add_scalar(
f"imputation_loss/{stage}", info_dict["imputation_loss"], step
)
summary_writer.add_scalar(
f"imputation_MAE/{stage}", info_dict["imputation_MAE"], step
)
summary_writer.add_scalar(
f"reconstruction_loss/{stage}", info_dict["reconstruction_loss"], step
)
summary_writer.add_scalar(
f"reconstruction_MAE/{stage}", info_dict["reconstruction_MAE"], step
)
def result_processing(results):
"""process results and losses for each training step"""
results["total_loss"] = torch.tensor(0.0, device=args.device)
if args.model_type == "BRITS":
results["total_loss"] = (
results["consistency_loss"] * args.consistency_loss_weight
)
results["reconstruction_loss"] = (
results["reconstruction_loss"] * args.reconstruction_loss_weight
)
results["imputation_loss"] = (
results["imputation_loss"] * args.imputation_loss_weight
)
if args.MIT:
results["total_loss"] += results["imputation_loss"]
if args.ORT:
results["total_loss"] += results["reconstruction_loss"]
return results
def process_each_training_step(
results, optimizer, val_dataloader, training_controller, summary_writer, logger
):
"""process each training step and return whether to early stop"""
state_dict = training_controller(stage="train")
# apply gradient clipping if args.max_norm != 0
if args.max_norm != 0:
nn.utils.clip_grad_norm_(model.parameters(), max_norm=args.max_norm)
results["total_loss"].backward()
optimizer.step()
summary_write_into_tb(summary_writer, results, state_dict["train_step"], "train")
if state_dict["train_step"] % args.eval_every_n_steps == 0:
state_dict_from_val = validate(
model, val_dataloader, summary_writer, training_controller, logger
)
if state_dict_from_val["should_stop"]:
logger.info(f"Early stopping worked, stop now...")
return True
return False
def model_processing(
data,
model,
stage,
# following arguments are only required in the training stage
optimizer=None,
val_dataloader=None,
summary_writer=None,
training_controller=None,
logger=None,
):
if stage == "train":
optimizer.zero_grad()
if not args.MIT:
if args.model_type in ["BRITS", "MRNN"]:
(
indices,
X,
missing_mask,
deltas,
back_X,
back_missing_mask,
back_deltas,
) = map(lambda x: x.to(args.device), data)
inputs = {
"indices": indices,
"forward": {"X": X, "missing_mask": missing_mask, "deltas": deltas},
"backward": {
"X": back_X,
"missing_mask": back_missing_mask,
"deltas": back_deltas,
},
}
else: # then for self-attention based models, i.e. Transformer/SAITS
indices, X, missing_mask = map(lambda x: x.to(args.device), data)
inputs = {"indices": indices, "X": X, "missing_mask": missing_mask}
results = result_processing(model(inputs, stage))
early_stopping = process_each_training_step(
results,
optimizer,
val_dataloader,
training_controller,
summary_writer,
logger,
)
else:
if args.model_type in ["BRITS", "MRNN"]:
(
indices,
X,
missing_mask,
deltas,
back_X,
back_missing_mask,
back_deltas,
X_holdout,
indicating_mask,
) = map(lambda x: x.to(args.device), data)
inputs = {
"indices": indices,
"X_holdout": X_holdout,
"indicating_mask": indicating_mask,
"forward": {"X": X, "missing_mask": missing_mask, "deltas": deltas},
"backward": {
"X": back_X,
"missing_mask": back_missing_mask,
"deltas": back_deltas,
},
}
else:
indices, X, missing_mask, X_holdout, indicating_mask = map(
lambda x: x.to(args.device), data
)
inputs = {
"indices": indices,
"X": X,
"missing_mask": missing_mask,
"X_holdout": X_holdout,
"indicating_mask": indicating_mask,
}
results = result_processing(model(inputs, stage))
early_stopping = process_each_training_step(
results,
optimizer,
val_dataloader,
training_controller,
summary_writer,
logger,
)
return early_stopping
else: # in val/test stage
if args.model_type in ["BRITS", "MRNN"]:
(
indices,
X,
missing_mask,
deltas,
back_X,
back_missing_mask,
back_deltas,
X_holdout,
indicating_mask,
) = map(lambda x: x.to(args.device), data)
inputs = {
"indices": indices,
"X_holdout": X_holdout,
"indicating_mask": indicating_mask,
"forward": {"X": X, "missing_mask": missing_mask, "deltas": deltas},
"backward": {
"X": back_X,
"missing_mask": back_missing_mask,
"deltas": back_deltas,
},
}
inputs["missing_mask"] = inputs["forward"][
"missing_mask"
] # for error calculation in validation stage
else:
indices, X, missing_mask, X_holdout, indicating_mask = map(
lambda x: x.to(args.device), data
)
inputs = {
"indices": indices,
"X": X,
"missing_mask": missing_mask,
"X_holdout": X_holdout,
"indicating_mask": indicating_mask,
}
results = model(inputs, stage)
results = result_processing(results)
return inputs, results
def train(
model,
optimizer,
train_dataloader,
test_dataloader,
summary_writer,
training_controller,
logger,
):
for epoch in range(args.epochs):
early_stopping = False
args.final_epoch = True if epoch == args.epochs - 1 else False
for idx, data in enumerate(train_dataloader):
model.train()
early_stopping = model_processing(
data,
model,
"train",
optimizer,
test_dataloader,
summary_writer,
training_controller,
logger,
)
if early_stopping:
break
if early_stopping:
break
training_controller.epoch_num_plus_1()
logger.info("Finished all epochs. Stop training now.")
def validate(model, val_iter, summary_writer, training_controller, logger):
model.eval()
evalX_collector, evalMask_collector, imputations_collector = [], [], []
(
total_loss_collector,
imputation_loss_collector,
reconstruction_loss_collector,
reconstruction_MAE_collector,
) = ([], [], [], [])
with torch.no_grad():
for idx, data in enumerate(val_iter):
inputs, results = model_processing(data, model, "val")
evalX_collector.append(inputs["X_holdout"])
evalMask_collector.append(inputs["indicating_mask"])
imputations_collector.append(results["imputed_data"])
total_loss_collector.append(results["total_loss"].data.cpu().numpy())
reconstruction_MAE_collector.append(
results["reconstruction_MAE"].data.cpu().numpy()
)
reconstruction_loss_collector.append(
results["reconstruction_loss"].data.cpu().numpy()
)
imputation_loss_collector.append(
results["imputation_loss"].data.cpu().numpy()
)
evalX_collector = torch.cat(evalX_collector)
evalMask_collector = torch.cat(evalMask_collector)
imputations_collector = torch.cat(imputations_collector)
imputation_MAE = masked_mae_cal(
imputations_collector, evalX_collector, evalMask_collector
)
info_dict = {
"total_loss": np.asarray(total_loss_collector).mean(),
"reconstruction_loss": np.asarray(reconstruction_loss_collector).mean(),
"imputation_loss": np.asarray(imputation_loss_collector).mean(),
"reconstruction_MAE": np.asarray(reconstruction_MAE_collector).mean(),
"imputation_MAE": imputation_MAE.cpu().numpy().mean(),
}
state_dict = training_controller("val", info_dict, logger)
summary_write_into_tb(summary_writer, info_dict, state_dict["val_step"], "val")
if args.param_searching_mode:
nni.report_intermediate_result(info_dict["imputation_MAE"])
if args.final_epoch or state_dict["should_stop"]:
nni.report_final_result(state_dict["best_imputation_MAE"])
if (
state_dict["save_model"] and args.model_saving_strategy
) or args.model_saving_strategy == "all":
saving_path = os.path.join(
args.model_saving,
"model_trainStep_{}_valStep_{}_imputationMAE_{:.4f}".format(
state_dict["train_step"],
state_dict["val_step"],
info_dict["imputation_MAE"],
),
)
save_model(model, optimizer, state_dict, args, saving_path)
logger.info(f"Saved model -> {saving_path}")
return state_dict
def test_trained_model(model, test_dataloader):
logger.info(f"Start evaluating on whole test set...")
model.eval()
evalX_collector, evalMask_collector, imputations_collector = [], [], []
with torch.no_grad():
for idx, data in enumerate(test_dataloader):
inputs, results = model_processing(data, model, "test")
# collect X_holdout, indicating_mask and imputed data
evalX_collector.append(inputs["X_holdout"])
evalMask_collector.append(inputs["indicating_mask"])
imputations_collector.append(results["imputed_data"])
evalX_collector = torch.cat(evalX_collector)
evalMask_collector = torch.cat(evalMask_collector)
imputations_collector = torch.cat(imputations_collector)
imputation_MAE = masked_mae_cal(
imputations_collector, evalX_collector, evalMask_collector
)
imputation_RMSE = masked_rmse_cal(
imputations_collector, evalX_collector, evalMask_collector
)
imputation_MRE = masked_mre_cal(
imputations_collector, evalX_collector, evalMask_collector
)
assessment_metrics = {
"imputation_MAE on the test set": imputation_MAE,
"imputation_RMSE on the test set": imputation_RMSE,
"imputation_MRE on the test set": imputation_MRE,
"trainable parameter num": args.total_params,
}
with open(
os.path.join(args.result_saving_path, "overall_performance_metrics.out"), "w"
) as f:
logger.info("Overall performance metrics are listed as follows:")
for k, v in assessment_metrics.items():
logger.info(f"{k}: {v}")
f.write(k + ":" + str(v))
f.write("\n")
def impute_all_missing_data(model, train_data, val_data, test_data):
logger.info(f"Start imputing all missing data in all train/val/test sets...")
model.eval()
imputed_data_dict = {}
with torch.no_grad():
for dataloader, set_name in zip(
[train_data, val_data, test_data], ["train", "val", "test"]
):
indices_collector, imputations_collector = [], []
for idx, data in enumerate(dataloader):
if args.model_type in ["BRITS", "MRNN"]:
(
indices,
X,
missing_mask,
deltas,
back_X,
back_missing_mask,
back_deltas,
) = map(lambda x: x.to(args.device), data)
inputs = {
"indices": indices,
"forward": {
"X": X,
"missing_mask": missing_mask,
"deltas": deltas,
},
"backward": {
"X": back_X,
"missing_mask": back_missing_mask,
"deltas": back_deltas,
},
}
else: # then for self-attention based models, i.e. Transformer/SAITS
indices, X, missing_mask = map(lambda x: x.to(args.device), data)
inputs = {"indices": indices, "X": X, "missing_mask": missing_mask}
imputed_data, _ = model.impute(inputs)
indices_collector.append(indices)
imputations_collector.append(imputed_data)
indices_collector = torch.cat(indices_collector)
indices = indices_collector.cpu().numpy().reshape(-1)
imputations_collector = torch.cat(imputations_collector)
imputations = imputations_collector.data.cpu().numpy()
ordered = imputations[np.argsort(indices)] # to ensure the order of samples
imputed_data_dict[set_name] = ordered
imputation_saving_path = os.path.join(args.result_saving_path, "imputations.h5")
with h5py.File(imputation_saving_path, "w") as hf:
hf.create_dataset("imputed_train_set", data=imputed_data_dict["train"])
hf.create_dataset("imputed_val_set", data=imputed_data_dict["val"])
hf.create_dataset("imputed_test_set", data=imputed_data_dict["test"])
logger.info(f"Done saving all imputed data into {imputation_saving_path}.")
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument("--config_path", type=str, help="path of config file")
parser.add_argument(
"--test_mode",
dest="test_mode",
action="store_true",
help="test mode to test saved model",
)
parser.add_argument(
"--param_searching_mode",
dest="param_searching_mode",
action="store_true",
help="use NNI to help search hyper parameters",
)
args = parser.parse_args()
assert os.path.exists(
args.config_path
), f'Given config file "{args.config_path}" does not exists'
# load settings from config file
cfg = ConfigParser(interpolation=ExtendedInterpolation())
cfg.read(args.config_path)
args = read_arguments(args, cfg)
if args.model_type in ["Transformer", "SAITS"]: # if SA-based model
args.input_with_mask = cfg.getboolean("model", "input_with_mask")
args.n_groups = cfg.getint("model", "n_groups")
args.n_group_inner_layers = cfg.getint("model", "n_group_inner_layers")
args.param_sharing_strategy = cfg.get("model", "param_sharing_strategy")
assert args.param_sharing_strategy in [
"inner_group",
"between_group",
], 'only "inner_group"/"between_group" sharing'
args.d_model = cfg.getint("model", "d_model")
args.d_inner = cfg.getint("model", "d_inner")
args.n_head = cfg.getint("model", "n_head")
args.d_k = cfg.getint("model", "d_k")
args.d_v = cfg.getint("model", "d_v")
args.dropout = cfg.getfloat("model", "dropout")
args.diagonal_attention_mask = cfg.getboolean(
"model", "diagonal_attention_mask"
)
dict_args = vars(args)
if args.param_searching_mode:
tuner_params = nni.get_next_parameter()
dict_args.update(tuner_params)
experiment_id = nni.get_experiment_id()
trial_id = nni.get_trial_id()
args.model_name = f"{args.model_name}/{experiment_id}/{trial_id}"
dict_args["d_k"] = dict_args["d_model"] // dict_args["n_head"]
model_args = {
"device": args.device,
"MIT": args.MIT,
# imputer args
"n_groups": dict_args["n_groups"],
"n_group_inner_layers": args.n_group_inner_layers,
"d_time": args.seq_len,
"d_feature": args.feature_num,
"dropout": dict_args["dropout"],
"d_model": dict_args["d_model"],
"d_inner": dict_args["d_inner"],
"n_head": dict_args["n_head"],
"d_k": dict_args["d_k"],
"d_v": dict_args["d_v"],
"input_with_mask": args.input_with_mask,
"diagonal_attention_mask": args.diagonal_attention_mask,
"param_sharing_strategy": args.param_sharing_strategy,
}
elif args.model_type in ["BRITS", "MRNN"]: # if RNN-based model
if args.model_type == "BRITS":
args.consistency_loss_weight = cfg.getfloat(
"training", "consistency_loss_weight"
)
args.rnn_hidden_size = cfg.getint("model", "rnn_hidden_size")
dict_args = vars(args)
if args.param_searching_mode:
tuner_params = nni.get_next_parameter()
dict_args.update(tuner_params)
experiment_id = nni.get_experiment_id()
trial_id = nni.get_trial_id()
args.model_name = f"{args.model_name}/{experiment_id}/{trial_id}"
model_args = {
"device": args.device,
"MIT": args.MIT,
# imputer args
"seq_len": args.seq_len,
"feature_num": args.feature_num,
"rnn_hidden_size": dict_args["rnn_hidden_size"],
}
else:
assert (
ValueError
), f"Given model_type {args.model_type} is not in {MODEL_DICT.keys()}"
# parameter insurance
assert args.model_saving_strategy.lower() in [
"all",
"best",
"none",
], "model saving strategy must be all/best/none"
if args.model_saving_strategy.lower() == "none":
args.model_saving_strategy = False
assert (
args.optimizer_type in OPTIMIZER.keys()
), f"optimizer type should be in {OPTIMIZER.keys()}, but get{args.optimizer_type}"
assert args.device in ["cpu", "cuda"], "device should be cpu or cuda"
time_now = datetime.now().__format__("%Y-%m-%d_T%H:%M:%S")
args.model_saving, args.log_saving = check_saving_dir_for_model(args, time_now)
logger = setup_logger(args.log_saving + "_" + time_now, "w")
logger.info(f"args: {args}")
logger.info(f"Config file path: {args.config_path}")
logger.info(f"Model name: {args.model_name}")
unified_dataloader = UnifiedDataLoader(
args.dataset_path,
args.seq_len,
args.feature_num,
args.model_type,
args.batch_size,
args.num_workers,
args.MIT,
)
model = MODEL_DICT[args.model_type](**model_args)
args.total_params = sum(p.numel() for p in model.parameters() if p.requires_grad)
logger.info(f"Num of total trainable params is: {args.total_params}")
# if utilize GPU and GPU available, then move
if "cuda" in args.device and torch.cuda.is_available():
model = model.to(args.device)
if args.test_mode:
logger.info("Entering testing mode...")
args.model_path = cfg.get("test", "model_path")
args.save_imputations = cfg.getboolean("test", "save_imputations")
args.result_saving_path = cfg.get("test", "result_saving_path")
os.makedirs(args.result_saving_path) if not os.path.exists(
args.result_saving_path
) else None
model = load_model(model, args.model_path, logger)
test_dataloader = unified_dataloader.get_test_dataloader()
test_trained_model(model, test_dataloader)
if args.save_imputations:
(
train_data,
val_data,
test_data,
) = unified_dataloader.prepare_all_data_for_imputation()
impute_all_missing_data(model, train_data, val_data, test_data)
else: # in the training mode
logger.info(f"Creating {args.optimizer_type} optimizer...")
optimizer = OPTIMIZER[args.optimizer_type](
model.parameters(), lr=dict_args["lr"], weight_decay=args.weight_decay
)
logger.info("Entering training mode...")
train_dataloader, val_dataloader = unified_dataloader.get_train_val_dataloader()
training_controller = Controller(args.early_stop_patience)
train_set_size = unified_dataloader.train_set_size
logger.info(
f"train set len is {train_set_size}, batch size is {args.batch_size},"
f"so each epoch has {math.ceil(train_set_size / args.batch_size)} steps"
)
tb_summary_writer = SummaryWriter(
os.path.join(args.log_saving, "tensorboard_" + time_now)
)
train(
model,
optimizer,
train_dataloader,
val_dataloader,
tb_summary_writer,
training_controller,
logger,
)
logger.info("All Done.")