Update LFNA

2021-05-15 16:01:40 +08:00 · 2021-05-15 16:01:40 +08:00 · 72f240bf0a
commit 72f240bf0a
parent b81ef2dd74
12 changed files with 128 additions and 1050 deletions
--- a/exps/LFNA/backup/lfna-fix-init.py
+++ b/exps/LFNA/backup/lfna-fix-init.py
@ -1,239 +0,0 @@
 #####################################################
 # Copyright (c) Xuanyi Dong [GitHub D-X-Y], 2021.04 #
 #####################################################
 # python exps/LFNA/lfna-fix-init.py --env_version v1 --hidden_dim 16
 #####################################################
 import sys, time, copy, torch, random, argparse
 from tqdm import tqdm
 from copy import deepcopy
 from pathlib import Path
 lib_dir = (Path(__file__).parent / ".." / ".." / "lib").resolve()
 if str(lib_dir) not in sys.path:
    sys.path.insert(0, str(lib_dir))
 from procedures import prepare_seed, prepare_logger, save_checkpoint, copy_checkpoint
 from log_utils import time_string
 from log_utils import AverageMeter, convert_secs2time
 from utils import split_str2indexes
 from procedures.advanced_main import basic_train_fn, basic_eval_fn
 from procedures.metric_utils import SaveMetric, MSEMetric, ComposeMetric
 from datasets.synthetic_core import get_synthetic_env
 from models.xcore import get_model
 from xlayers import super_core
 from lfna_utils import lfna_setup, train_model, TimeData
 class LFNAmlp:
    """A LFNA meta-model that uses the MLP as delta-net."""
    def __init__(self, obs_dim, hidden_sizes, act_name, criterion):
        self.delta_net = super_core.SuperSequential(
            super_core.SuperLinear(obs_dim, hidden_sizes[0]),
            super_core.super_name2activation[act_name](),
            super_core.SuperLinear(hidden_sizes[0], hidden_sizes[1]),
            super_core.super_name2activation[act_name](),
            super_core.SuperLinear(hidden_sizes[1], 1),
        )
        self.meta_optimizer = torch.optim.Adam(
            self.delta_net.parameters(), lr=0.001, amsgrad=True
        )
        self.criterion = criterion
    def adapt(self, model, seq_datasets):
        delta_inputs = []
        container = model.get_w_container()
        for iseq, dataset in enumerate(seq_datasets):
            y_hat = model.forward_with_container(dataset.x, container)
            loss = self.criterion(y_hat, dataset.y)
            gradients = torch.autograd.grad(loss, container.parameters())
            with torch.no_grad():
                flatten_g = container.flatten(gradients)
                delta_inputs.append(flatten_g)
        flatten_w = container.no_grad_clone().flatten()
        delta_inputs.append(flatten_w)
        delta_inputs = torch.stack(delta_inputs, dim=-1)
        delta = self.delta_net(delta_inputs)
        delta = torch.clamp(delta, -0.8, 0.8)
        unflatten_delta = container.unflatten(delta)
        future_container = container.no_grad_clone().additive(unflatten_delta)
        return future_container
    def step(self):
        torch.nn.utils.clip_grad_norm_(self.delta_net.parameters(), 1.0)
        self.meta_optimizer.step()
    def zero_grad(self):
        self.meta_optimizer.zero_grad()
        self.delta_net.zero_grad()
    def state_dict(self):
        return dict(
            delta_net=self.delta_net.state_dict(),
            meta_optimizer=self.meta_optimizer.state_dict(),
        )
 def main(args):
    logger, env_info, model_kwargs = lfna_setup(args)
    dynamic_env = env_info["dynamic_env"]
    model = get_model(dict(model_type="simple_mlp"), **model_kwargs)
    total_time = env_info["total"]
    for i in range(total_time):
        for xkey in ("timestamp", "x", "y"):
            nkey = "{:}-{:}".format(i, xkey)
            assert nkey in env_info, "{:} no in {:}".format(nkey, list(env_info.keys()))
    train_time_bar = total_time // 2
    network = get_model(dict(model_type="simple_mlp"), **model_kwargs)
    criterion = torch.nn.MSELoss()
    logger.log("There are {:} weights.".format(network.get_w_container().numel()))
    adaptor = LFNAmlp(1 + args.meta_seq, (20, 20), "leaky_relu", criterion)
    # pre-train the model
    init_dataset = TimeData(0, env_info["0-x"], env_info["0-y"])
    init_loss = train_model(network, init_dataset, args.init_lr, args.epochs)
    logger.log("The pre-training loss is {:.4f}".format(init_loss))
    # LFNA meta-training
    meta_loss_meter = AverageMeter()
    per_epoch_time, start_time = AverageMeter(), time.time()
    for iepoch in range(args.epochs):
        need_time = "Time Left: {:}".format(
            convert_secs2time(per_epoch_time.avg * (args.epochs - iepoch), True)
        )
        logger.log(
            "[{:}] [{:04d}/{:04d}] ".format(time_string(), iepoch, args.epochs)
            + need_time
        )
        adaptor.zero_grad()
        batch_indexes, meta_losses = [], []
        for ibatch in range(args.meta_batch):
            sampled_timestamp = random.random() * train_time_bar
            batch_indexes.append("{:.3f}".format(sampled_timestamp))
            seq_datasets = []
            for iseq in range(args.meta_seq + 1):
                cur_time = sampled_timestamp + iseq * dynamic_env.timestamp_interval
                cur_time, (x, y) = dynamic_env(cur_time)
                seq_datasets.append(TimeData(cur_time, x, y))
            history_datasets, future_dataset = seq_datasets[:-1], seq_datasets[-1]
            future_container = adaptor.adapt(network, history_datasets)
            future_y_hat = network.forward_with_container(
                future_dataset.x, future_container
            )
            future_loss = adaptor.criterion(future_y_hat, future_dataset.y)
            meta_losses.append(future_loss)
        meta_loss = torch.stack(meta_losses).mean()
        meta_loss.backward()
        adaptor.step()
        meta_loss_meter.update(meta_loss.item())
        logger.log(
            "meta-loss: {:.4f} ({:.4f}) batch: {:}".format(
                meta_loss_meter.avg, meta_loss_meter.val, ",".join(batch_indexes[:5])
            )
        )
        if iepoch % 200 == 0:
            save_checkpoint(
                {"adaptor": adaptor.state_dict(), "iepoch": iepoch},
                logger.path("model"),
                logger,
            )
        per_epoch_time.update(time.time() - start_time)
        start_time = time.time()
    w_container_per_epoch = dict()
    for idx in range(1, env_info["total"]):
        future_time = env_info["{:}-timestamp".format(idx)]
        future_x = env_info["{:}-x".format(idx)]
        future_y = env_info["{:}-y".format(idx)]
        seq_datasets = []
        for iseq in range(1, args.meta_seq + 1):
            cur_time = future_time - iseq * dynamic_env.timestamp_interval
            cur_time, (x, y) = dynamic_env(cur_time)
            seq_datasets.append(TimeData(cur_time, x, y))
        seq_datasets.reverse()
        future_container = adaptor.adapt(network, seq_datasets)
        w_container_per_epoch[idx] = future_container.no_grad_clone()
        with torch.no_grad():
            future_y_hat = network.forward_with_container(
                future_x, w_container_per_epoch[idx]
            )
            future_loss = adaptor.criterion(future_y_hat, future_y)
        logger.log("meta-test: [{:03d}] -> loss={:.4f}".format(idx, future_loss.item()))
    save_checkpoint(
        {"w_container_per_epoch": w_container_per_epoch},
        logger.path(None) / "final-ckp.pth",
        logger,
    )
    logger.log("-" * 200 + "\n")
    logger.close()
 if __name__ == "__main__":
    parser = argparse.ArgumentParser("Use the data in the past.")
    parser.add_argument(
        "--save_dir",
        type=str,
        default="./outputs/lfna-synthetic/lfna-fix-init",
        help="The checkpoint directory.",
    )
    parser.add_argument(
        "--env_version",
        type=str,
        required=True,
        help="The synthetic enviornment version.",
    )
    parser.add_argument(
        "--hidden_dim",
        type=int,
        required=True,
        help="The hidden dimension.",
    )
    #####
    parser.add_argument(
        "--init_lr",
        type=float,
        default=0.1,
        help="The initial learning rate for the optimizer (default is Adam)",
    )
    parser.add_argument(
        "--meta_batch",
        type=int,
        default=32,
        help="The batch size for the meta-model",
    )
    parser.add_argument(
        "--meta_seq",
        type=int,
        default=10,
        help="The length of the sequence for meta-model.",
    )
    parser.add_argument(
        "--epochs",
        type=int,
        default=1000,
        help="The total number of epochs.",
    )
    # Random Seed
    parser.add_argument("--rand_seed", type=int, default=-1, help="manual seed")
    args = parser.parse_args()
    if args.rand_seed is None or args.rand_seed < 0:
        args.rand_seed = random.randint(1, 100000)
    assert args.save_dir is not None, "The save dir argument can not be None"
    args.save_dir = "{:}-{:}-d{:}".format(
        args.save_dir, args.env_version, args.hidden_dim
    )
    main(args)
--- a/exps/LFNA/backup/lfna-test-hpnet.py
+++ b/exps/LFNA/backup/lfna-test-hpnet.py
@ -1,239 +0,0 @@
 #####################################################
 # Copyright (c) Xuanyi Dong [GitHub D-X-Y], 2021.04 #
 #####################################################
 # python exps/LFNA/lfna-test-hpnet.py --env_version v1 --hidden_dim 16 --layer_dim 16 --epochs 10000 --init_lr 0.01
 # python exps/LFNA/lfna-test-hpnet.py --env_version v1 --hidden_dim 16 --layer_dim 16 --epochs 10000 --init_lr 0.01 --device cuda
 #####################################################
 import sys, time, copy, torch, random, argparse
 from tqdm import tqdm
 from copy import deepcopy
 from pathlib import Path
 lib_dir = (Path(__file__).parent / ".." / ".." / "lib").resolve()
 if str(lib_dir) not in sys.path:
    sys.path.insert(0, str(lib_dir))
 from procedures import prepare_seed, prepare_logger, save_checkpoint, copy_checkpoint
 from log_utils import time_string
 from log_utils import AverageMeter, convert_secs2time
 from utils import split_str2indexes
 from procedures.advanced_main import basic_train_fn, basic_eval_fn
 from procedures.metric_utils import SaveMetric, MSEMetric, ComposeMetric
 from datasets.synthetic_core import get_synthetic_env
 from models.xcore import get_model
 from xlayers import super_core, trunc_normal_
 from lfna_utils import lfna_setup, train_model, TimeData
 # from lfna_models import HyperNet_VX as HyperNet
 from lfna_models import HyperNet
 def main(args):
    logger, env_info, model_kwargs = lfna_setup(args)
    dynamic_env = env_info["dynamic_env"]
    model = get_model(**model_kwargs)
    model = model.to(args.device)
    criterion = torch.nn.MSELoss()
    shape_container = model.get_w_container().to_shape_container()
    total_bar = 100
    hypernet = HyperNet(shape_container, args.layer_dim, args.task_dim, total_bar)
    hypernet = hypernet.to(args.device)
    logger.log(
        "{:} There are {:} weights in the base-model.".format(
            time_string(), model.numel()
        )
    )
    logger.log(
        "{:} There are {:} weights in the meta-model.".format(
            time_string(), hypernet.numel()
        )
    )
    for i in range(total_bar):
        env_info["{:}-x".format(i)] = env_info["{:}-x".format(i)].to(args.device)
        env_info["{:}-y".format(i)] = env_info["{:}-y".format(i)].to(args.device)
    model.train()
    hypernet.train()
    optimizer = torch.optim.Adam(
        hypernet.parameters(), lr=args.init_lr, weight_decay=1e-5, amsgrad=True
    )
    lr_scheduler = torch.optim.lr_scheduler.MultiStepLR(
        optimizer,
        milestones=[
            int(args.epochs * 0.8),
            int(args.epochs * 0.9),
        ],
        gamma=0.1,
    )
    # total_bar = env_info["total"] - 1
    # LFNA meta-training
    loss_meter = AverageMeter()
    per_epoch_time, start_time = AverageMeter(), time.time()
    last_success = 0
    for iepoch in range(args.epochs):
        need_time = "Time Left: {:}".format(
            convert_secs2time(per_epoch_time.avg * (args.epochs - iepoch), True)
        )
        head_str = (
            "[{:}] [{:04d}/{:04d}] ".format(time_string(), iepoch, args.epochs)
            + need_time
        )
        losses = []
        # for ibatch in range(args.meta_batch):
        for cur_time in range(total_bar):
            # cur_time = random.randint(0, total_bar)
            # cur_task_embed = task_embeds[cur_time]
            cur_container = hypernet(cur_time)
            cur_x = env_info["{:}-x".format(cur_time)]
            cur_y = env_info["{:}-y".format(cur_time)]
            cur_dataset = TimeData(cur_time, cur_x, cur_y)
            preds = model.forward_with_container(cur_dataset.x, cur_container)
            optimizer.zero_grad()
            loss = criterion(preds, cur_dataset.y)
            losses.append(loss)
        final_loss = torch.stack(losses).mean()
        final_loss.backward()
        optimizer.step()
        lr_scheduler.step()
        loss_meter.update(final_loss.item())
        success, best_score = hypernet.save_best(-loss_meter.val)
        if success:
            logger.log("Achieve the best with best_score = {:.3f}".format(best_score))
            last_success = iepoch
        if iepoch - last_success >= args.early_stop_thresh:
            logger.log("Early stop at {:}".format(iepoch))
            break
        if iepoch % 20 == 0:
            logger.log(
                head_str
                + " meta-loss: {:.4f} ({:.4f}) :: lr={:.5f}, batch={:}".format(
                    loss_meter.avg,
                    loss_meter.val,
                    min(lr_scheduler.get_last_lr()),
                    len(losses),
                )
            )
            save_checkpoint(
                {
                    "hypernet": hypernet.state_dict(),
                    "lr_scheduler": lr_scheduler.state_dict(),
                    "iepoch": iepoch,
                },
                logger.path("model"),
                logger,
            )
            loss_meter.reset()
        per_epoch_time.update(time.time() - start_time)
        start_time = time.time()
    print(model)
    print(hypernet)
    hypernet.load_best()
    w_container_per_epoch = dict()
    for idx in range(0, total_bar):
        future_time = env_info["{:}-timestamp".format(idx)]
        future_x = env_info["{:}-x".format(idx)]
        future_y = env_info["{:}-y".format(idx)]
        # future_container = hypernet(task_embeds[idx])
        future_container = hypernet(idx)
        w_container_per_epoch[idx] = future_container.no_grad_clone()
        with torch.no_grad():
            future_y_hat = model.forward_with_container(
                future_x, w_container_per_epoch[idx]
            )
            future_loss = criterion(future_y_hat, future_y)
        logger.log("meta-test: [{:03d}] -> loss={:.4f}".format(idx, future_loss.item()))
    save_checkpoint(
        {"w_container_per_epoch": w_container_per_epoch},
        logger.path(None) / "final-ckp.pth",
        logger,
    )
    logger.log("-" * 200 + "\n")
    logger.close()
 if __name__ == "__main__":
    parser = argparse.ArgumentParser("Use the data in the past.")
    parser.add_argument(
        "--save_dir",
        type=str,
        default="./outputs/lfna-synthetic/lfna-test-hpnet",
        help="The checkpoint directory.",
    )
    parser.add_argument(
        "--env_version",
        type=str,
        required=True,
        help="The synthetic enviornment version.",
    )
    parser.add_argument(
        "--hidden_dim",
        type=int,
        required=True,
        help="The hidden dimension.",
    )
    parser.add_argument(
        "--layer_dim",
        type=int,
        required=True,
        help="The hidden dimension.",
    )
    parser.add_argument(
        "--early_stop_thresh",
        type=int,
        default=100,
        help="The maximum epochs for early stop.",
    )
    #####
    parser.add_argument(
        "--init_lr",
        type=float,
        default=0.1,
        help="The initial learning rate for the optimizer (default is Adam)",
    )
    parser.add_argument(
        "--meta_batch",
        type=int,
        default=64,
        help="The batch size for the meta-model",
    )
    parser.add_argument(
        "--epochs",
        type=int,
        default=2000,
        help="The total number of epochs.",
    )
    parser.add_argument(
        "--device",
        type=str,
        default="cpu",
        help="",
    )
    # Random Seed
    parser.add_argument("--rand_seed", type=int, default=-1, help="manual seed")
    args = parser.parse_args()
    if args.rand_seed is None or args.rand_seed < 0:
        args.rand_seed = random.randint(1, 100000)
    assert args.save_dir is not None, "The save dir argument can not be None"
    args.task_dim = args.layer_dim
    args.save_dir = "{:}-{:}-d{:}".format(
        args.save_dir, args.env_version, args.hidden_dim
    )
    main(args)
--- a/exps/LFNA/backup/lfna-ttss-hpnet.py
+++ b/exps/LFNA/backup/lfna-ttss-hpnet.py
@ -1,134 +0,0 @@
 #####################################################
 # Copyright (c) Xuanyi Dong [GitHub D-X-Y], 2021.04 #
 #####################################################
 # python exps/LFNA/lfna-ttss-hpnet.py --env_version v1 --hidden_dim 16
 #####################################################
 import sys, time, copy, torch, random, argparse
 from tqdm import tqdm
 from copy import deepcopy
 from pathlib import Path
 lib_dir = (Path(__file__).parent / ".." / ".." / "lib").resolve()
 if str(lib_dir) not in sys.path:
    sys.path.insert(0, str(lib_dir))
 from procedures import prepare_seed, prepare_logger, save_checkpoint, copy_checkpoint
 from log_utils import time_string
 from log_utils import AverageMeter, convert_secs2time
 from utils import split_str2indexes
 from procedures.advanced_main import basic_train_fn, basic_eval_fn
 from procedures.metric_utils import SaveMetric, MSEMetric, ComposeMetric
 from datasets.synthetic_core import get_synthetic_env
 from models.xcore import get_model
 from xlayers import super_core
 from lfna_utils import lfna_setup, train_model, TimeData
 from lfna_models import HyperNet_VX as HyperNet
 def main(args):
    logger, env_info, model_kwargs = lfna_setup(args)
    dynamic_env = env_info["dynamic_env"]
    model = get_model(**model_kwargs)
    total_time = env_info["total"]
    for i in range(total_time):
        for xkey in ("timestamp", "x", "y"):
            nkey = "{:}-{:}".format(i, xkey)
            assert nkey in env_info, "{:} no in {:}".format(nkey, list(env_info.keys()))
    train_time_bar = total_time // 2
    criterion = torch.nn.MSELoss()
    logger.log("There are {:} weights.".format(model.get_w_container().numel()))
    # pre-train the model
    dataset = init_dataset = TimeData(0, env_info["0-x"], env_info["0-y"])
    shape_container = model.get_w_container().to_shape_container()
    hypernet = HyperNet(shape_container, 16)
    print(hypernet)
    optimizer = torch.optim.Adam(hypernet.parameters(), lr=args.init_lr, amsgrad=True)
    best_loss, best_param = None, None
    for _iepoch in range(args.epochs):
        container = hypernet(None)
        preds = model.forward_with_container(dataset.x, container)
        optimizer.zero_grad()
        loss = criterion(preds, dataset.y)
        loss.backward()
        optimizer.step()
        # save best
        if best_loss is None or best_loss > loss.item():
            best_loss = loss.item()
            best_param = copy.deepcopy(model.state_dict())
    print("hyper-net : best={:.4f}".format(best_loss))
    init_loss = train_model(model, init_dataset, args.init_lr, args.epochs)
    logger.log("The pre-training loss is {:.4f}".format(init_loss))
    print(model)
    print(hypernet)
    logger.log("-" * 200 + "\n")
    logger.close()
 if __name__ == "__main__":
    parser = argparse.ArgumentParser("Use the data in the past.")
    parser.add_argument(
        "--save_dir",
        type=str,
        default="./outputs/lfna-synthetic/lfna-debug",
        help="The checkpoint directory.",
    )
    parser.add_argument(
        "--env_version",
        type=str,
        required=True,
        help="The synthetic enviornment version.",
    )
    parser.add_argument(
        "--hidden_dim",
        type=int,
        required=True,
        help="The hidden dimension.",
    )
    #####
    parser.add_argument(
        "--init_lr",
        type=float,
        default=0.1,
        help="The initial learning rate for the optimizer (default is Adam)",
    )
    parser.add_argument(
        "--meta_batch",
        type=int,
        default=32,
        help="The batch size for the meta-model",
    )
    parser.add_argument(
        "--meta_seq",
        type=int,
        default=10,
        help="The length of the sequence for meta-model.",
    )
    parser.add_argument(
        "--epochs",
        type=int,
        default=2000,
        help="The total number of epochs.",
    )
    # Random Seed
    parser.add_argument("--rand_seed", type=int, default=-1, help="manual seed")
    args = parser.parse_args()
    if args.rand_seed is None or args.rand_seed < 0:
        args.rand_seed = random.randint(1, 100000)
    assert args.save_dir is not None, "The save dir argument can not be None"
    args.save_dir = "{:}-{:}-d{:}".format(
        args.save_dir, args.env_version, args.hidden_dim
    )
    main(args)
--- a/exps/LFNA/backup/lfna-v1.py
+++ b/exps/LFNA/backup/lfna-v1.py
@ -1,272 +0,0 @@
 #####################################################
 # Copyright (c) Xuanyi Dong [GitHub D-X-Y], 2021.04 #
 #####################################################
 # python exps/LFNA/lfna-v1.py
 #####################################################
 import sys, time, copy, torch, random, argparse
 from tqdm import tqdm
 from copy import deepcopy
 from pathlib import Path
 lib_dir = (Path(__file__).parent / ".." / ".." / "lib").resolve()
 if str(lib_dir) not in sys.path:
    sys.path.insert(0, str(lib_dir))
 from procedures import prepare_seed, prepare_logger, save_checkpoint, copy_checkpoint
 from log_utils import time_string
 from log_utils import AverageMeter, convert_secs2time
 from utils import split_str2indexes
 from procedures.advanced_main import basic_train_fn, basic_eval_fn
 from procedures.metric_utils import SaveMetric, MSEMetric, ComposeMetric
 from datasets.synthetic_core import get_synthetic_env
 from models.xcore import get_model
 from xlayers import super_core
 class LFNAmlp:
    """A LFNA meta-model that uses the MLP as delta-net."""
    def __init__(self, obs_dim, hidden_sizes, act_name):
        self.delta_net = super_core.SuperSequential(
            super_core.SuperLinear(obs_dim, hidden_sizes[0]),
            super_core.super_name2activation[act_name](),
            super_core.SuperLinear(hidden_sizes[0], hidden_sizes[1]),
            super_core.super_name2activation[act_name](),
            super_core.SuperLinear(hidden_sizes[1], 1),
        )
        self.meta_optimizer = torch.optim.Adam(
            self.delta_net.parameters(), lr=0.01, amsgrad=True
        )
    def adapt(self, model, criterion, w_container, seq_datasets):
        w_container.requires_grad_(True)
        containers = [w_container]
        for idx, dataset in enumerate(seq_datasets):
            x, y = dataset.x, dataset.y
            y_hat = model.forward_with_container(x, containers[-1])
            loss = criterion(y_hat, y)
            gradients = torch.autograd.grad(loss, containers[-1].tensors)
            with torch.no_grad():
                flatten_w = containers[-1].flatten().view(-1, 1)
                flatten_g = containers[-1].flatten(gradients).view(-1, 1)
                input_statistics = torch.tensor([x.mean(), x.std()]).view(1, 2)
                input_statistics = input_statistics.expand(flatten_w.numel(), -1)
            delta_inputs = torch.cat((flatten_w, flatten_g, input_statistics), dim=-1)
            delta = self.delta_net(delta_inputs).view(-1)
            delta = torch.clamp(delta, -0.5, 0.5)
            unflatten_delta = containers[-1].unflatten(delta)
            future_container = containers[-1].no_grad_clone().additive(unflatten_delta)
            # future_container = containers[-1].additive(unflatten_delta)
            containers.append(future_container)
        # containers = containers[1:]
        meta_loss = []
        temp_containers = []
        for idx, dataset in enumerate(seq_datasets):
            if idx == 0:
                continue
            current_container = containers[idx]
            y_hat = model.forward_with_container(dataset.x, current_container)
            loss = criterion(y_hat, dataset.y)
            meta_loss.append(loss)
            temp_containers.append((dataset.timestamp, current_container, -loss.item()))
        meta_loss = sum(meta_loss)
        w_container.requires_grad_(False)
        # meta_loss.backward()
        # self.meta_optimizer.step()
        return meta_loss, temp_containers
    def step(self):
        torch.nn.utils.clip_grad_norm_(self.delta_net.parameters(), 1.0)
        self.meta_optimizer.step()
    def zero_grad(self):
        self.meta_optimizer.zero_grad()
        self.delta_net.zero_grad()
 class TimeData:
    def __init__(self, timestamp, xs, ys):
        self._timestamp = timestamp
        self._xs = xs
        self._ys = ys
    @property
    def x(self):
        return self._xs
    @property
    def y(self):
        return self._ys
    @property
    def timestamp(self):
        return self._timestamp
 class Population:
    """A population used to maintain models at different timestamps."""
    def __init__(self):
        self._time2model = dict()
        self._time2score = dict()  # higher is better
    def append(self, timestamp, model, score):
        if timestamp in self._time2model:
            if self._time2score[timestamp] > score:
                return
        self._time2model[timestamp] = model.no_grad_clone()
        self._time2score[timestamp] = score
    def query(self, timestamp):
        closet_timestamp = None
        for xtime, model in self._time2model.items():
            if closet_timestamp is None or (
                xtime < timestamp and timestamp - closet_timestamp >= timestamp - xtime
            ):
                closet_timestamp = xtime
        return self._time2model[closet_timestamp], closet_timestamp
    def debug_info(self, timestamps):
        xstrs = []
        for timestamp in timestamps:
            if timestamp in self._time2score:
                xstrs.append(
                    "{:04d}: {:.4f}".format(timestamp, self._time2score[timestamp])
                )
        return ", ".join(xstrs)
 def main(args):
    prepare_seed(args.rand_seed)
    logger = prepare_logger(args)
    cache_path = (logger.path(None) / ".." / "env-info.pth").resolve()
    if cache_path.exists():
        env_info = torch.load(cache_path)
    else:
        env_info = dict()
        dynamic_env = get_synthetic_env()
        env_info["total"] = len(dynamic_env)
        for idx, (timestamp, (_allx, _ally)) in enumerate(tqdm(dynamic_env)):
            env_info["{:}-timestamp".format(idx)] = timestamp
            env_info["{:}-x".format(idx)] = _allx
            env_info["{:}-y".format(idx)] = _ally
        env_info["dynamic_env"] = dynamic_env
        torch.save(env_info, cache_path)
    total_time = env_info["total"]
    for i in range(total_time):
        for xkey in ("timestamp", "x", "y"):
            nkey = "{:}-{:}".format(i, xkey)
            assert nkey in env_info, "{:} no in {:}".format(nkey, list(env_info.keys()))
    train_time_bar = total_time // 2
    base_model = get_model(
        dict(model_type="simple_mlp"),
        act_cls="leaky_relu",
        norm_cls="identity",
        input_dim=1,
        output_dim=1,
    )
    w_container = base_model.get_w_container()
    criterion = torch.nn.MSELoss()
    print("There are {:} weights.".format(w_container.numel()))
    adaptor = LFNAmlp(4, (50, 20), "leaky_relu")
    pool = Population()
    pool.append(0, w_container, -100)
    # LFNA meta-training
    per_epoch_time, start_time = AverageMeter(), time.time()
    for iepoch in range(args.epochs):
        need_time = "Time Left: {:}".format(
            convert_secs2time(per_epoch_time.avg * (args.epochs - iepoch), True)
        )
        logger.log(
            "[{:}] [{:04d}/{:04d}] ".format(time_string(), iepoch, args.epochs)
            + need_time
        )
        adaptor.zero_grad()
        debug_timestamp = set()
        all_meta_losses = []
        for ibatch in range(args.meta_batch):
            sampled_timestamp = random.randint(0, train_time_bar)
            query_w_container, query_timestamp = pool.query(sampled_timestamp)
            # def adapt(self, model, w_container, xs, ys):
            seq_datasets = []
            # xs, ys = [], []
            for it in range(sampled_timestamp, sampled_timestamp + args.max_seq):
                xs = env_info["{:}-x".format(it)]
                ys = env_info["{:}-y".format(it)]
                seq_datasets.append(TimeData(it, xs, ys))
            temp_meta_loss, temp_containers = adaptor.adapt(
                base_model, criterion, query_w_container, seq_datasets
            )
            all_meta_losses.append(temp_meta_loss)
            for temp_time, temp_container, temp_score in temp_containers:
                pool.append(temp_time, temp_container, temp_score)
                debug_timestamp.add(temp_time)
        meta_loss = torch.stack(all_meta_losses).mean()
        meta_loss.backward()
        adaptor.step()
        debug_str = pool.debug_info(debug_timestamp)
        logger.log("meta-loss: {:.4f}".format(meta_loss.item()))
        per_epoch_time.update(time.time() - start_time)
        start_time = time.time()
    logger.log("-" * 200 + "\n")
    logger.close()
 if __name__ == "__main__":
    parser = argparse.ArgumentParser("Use the data in the past.")
    parser.add_argument(
        "--save_dir",
        type=str,
        default="./outputs/lfna-synthetic/lfna-v1",
        help="The checkpoint directory.",
    )
    parser.add_argument(
        "--init_lr",
        type=float,
        default=0.1,
        help="The initial learning rate for the optimizer (default is Adam)",
    )
    parser.add_argument(
        "--meta_batch",
        type=int,
        default=5,
        help="The batch size for the meta-model",
    )
    parser.add_argument(
        "--epochs",
        type=int,
        default=1000,
        help="The total number of epochs.",
    )
    parser.add_argument(
        "--max_seq",
        type=int,
        default=5,
        help="The maximum length of the sequence.",
    )
    parser.add_argument(
        "--workers",
        type=int,
        default=4,
        help="The number of data loading workers (default: 4)",
    )
    # Random Seed
    parser.add_argument("--rand_seed", type=int, default=-1, help="manual seed")
    args = parser.parse_args()
    if args.rand_seed is None or args.rand_seed < 0:
        args.rand_seed = random.randint(1, 100000)
    assert args.save_dir is not None, "The save dir argument can not be None"
    main(args)
--- a/exps/LFNA/backup/lfna_models.py
+++ b/exps/LFNA/backup/lfna_models.py
@ -1,50 +0,0 @@
 #####################################################
 # Copyright (c) Xuanyi Dong [GitHub D-X-Y], 2021.04 #
 #####################################################
 import copy
 import torch
 from xlayers import super_core
 from xlayers import trunc_normal_
 from models.xcore import get_model
 class HyperNet(super_core.SuperModule):
    def __init__(self, shape_container, input_embeding, return_container=True):
        super(HyperNet, self).__init__()
        self._shape_container = shape_container
        self._num_layers = len(shape_container)
        self._numel_per_layer = []
        for ilayer in range(self._num_layers):
            self._numel_per_layer.append(shape_container[ilayer].numel())
        self.register_parameter(
            "_super_layer_embed",
            torch.nn.Parameter(torch.Tensor(self._num_layers, input_embeding)),
        )
        trunc_normal_(self._super_layer_embed, std=0.02)
        model_kwargs = dict(
            input_dim=input_embeding,
            output_dim=max(self._numel_per_layer),
            hidden_dim=input_embeding * 4,
            act_cls="sigmoid",
            norm_cls="identity",
        )
        self._generator = get_model(dict(model_type="simple_mlp"), **model_kwargs)
        self._return_container = return_container
        print("generator: {:}".format(self._generator))
    def forward_raw(self, input):
        weights = self._generator(self._super_layer_embed)
        if self._return_container:
            weights = torch.split(weights, 1)
            return self._shape_container.translate(weights)
        else:
            return weights
    def forward_candidate(self, input):
        raise NotImplementedError
    def extra_repr(self) -> str:
        return "(_super_layer_embed): {:}".format(list(self._super_layer_embed.shape))
--- a/exps/LFNA/basic-maml.py
+++ b/exps/LFNA/basic-maml.py
@ -1,7 +1,7 @@
 #####################################################
 # Copyright (c) Xuanyi Dong [GitHub D-X-Y], 2021.04 #
 #####################################################
-# python exps/LFNA/basic-maml.py --env_version v1 --hidden_dim 16 --inner_step 5
+# python exps/LFNA/basic-maml.py --env_version v1 --inner_step 5
 # python exps/LFNA/basic-maml.py --env_version v2
 #####################################################
 import sys, time, copy, torch, random, argparse
@ -20,7 +20,7 @@ from utils import split_str2indexes
 from procedures.advanced_main import basic_train_fn, basic_eval_fn
 from procedures.metric_utils import SaveMetric, MSEMetric, ComposeMetric
-from datasets.synthetic_core import get_synthetic_env
+from datasets.synthetic_core import get_synthetic_env, EnvSampler
 from models.xcore import get_model
 from xlayers import super_core
@ -42,11 +42,10 @@ class MAML:
        self.meta_lr_scheduler = torch.optim.lr_scheduler.MultiStepLR(
            self.meta_optimizer,
            milestones=[
-                int(epochs * 0.25),
+                int(epochs * 0.8),
-                int(epochs * 0.5),
+                int(epochs * 0.9),
                int(epochs * 0.75),
            ],
-            gamma=0.3,
+            gamma=0.1,
        )
        self.inner_lr = inner_lr
        self.inner_step = inner_step
@ -85,33 +84,27 @@ class MAML:
        self.meta_optimizer.load_state_dict(state_dict["meta_optimizer"])
        self.meta_lr_scheduler.load_state_dict(state_dict["meta_lr_scheduler"])
-    def save_best(self, iepoch, score):
+    def state_dict(self):
-        if self._best_info["score"] is None or self._best_info["score"] < score:
+        state_dict = dict()
-            state_dict = dict(
+        state_dict["criterion"] = self.criterion.state_dict()
-                criterion=self.criterion.state_dict(),
+        state_dict["network"] = self.network.state_dict()
-                network=self.network.state_dict(),
+        state_dict["meta_optimizer"] = self.meta_optimizer.state_dict()
-                meta_optimizer=self.meta_optimizer.state_dict(),
+        state_dict["meta_lr_scheduler"] = self.meta_lr_scheduler.state_dict()
-                meta_lr_scheduler=self.meta_lr_scheduler.state_dict(),
+        return state_dict
-            )
+
-            self._best_info["state_dict"] = state_dict
+    def save_best(self, score):
-            self._best_info["score"] = score
+        success, best_score = self.network.save_best(score)
-            self._best_info["iepoch"] = iepoch
+        return success, best_score
-            is_best = True
+
-        else:
+    def load_best(self):
-            is_best = False
+        self.network.load_best()
        return self._best_info, is_best
 def main(args):
    logger, env_info, model_kwargs = lfna_setup(args)
-    model = get_model(dict(model_type="simple_mlp"), **model_kwargs)
+    model = get_model(**model_kwargs)
-    total_time = env_info["total"]
+    dynamic_env = get_synthetic_env(mode="train", version=args.env_version)
    for i in range(total_time):
        for xkey in ("timestamp", "x", "y"):
            nkey = "{:}-{:}".format(i, xkey)
            assert nkey in env_info, "{:} no in {:}".format(nkey, list(env_info.keys()))
    train_time_bar = total_time // 2
    criterion = torch.nn.MSELoss()
@ -120,83 +113,65 @@ def main(args):
    )
    # meta-training
    last_success_epoch = 0
    per_epoch_time, start_time = AverageMeter(), time.time()
-    # for iepoch in range(args.epochs):
+    for iepoch in range(args.epochs):
    iepoch = 0
    while iepoch < args.epochs:
        need_time = "Time Left: {:}".format(
            convert_secs2time(per_epoch_time.avg * (args.epochs - iepoch), True)
        )
-        logger.log(
+        head_str = (
            "[{:}] [{:04d}/{:04d}] ".format(time_string(), iepoch, args.epochs)
            + need_time
        )
        maml.zero_grad()
-        batch_indexes, meta_losses = [], []
+        meta_losses = []
        for ibatch in range(args.meta_batch):
-            sampled_timestamp = random.randint(0, train_time_bar)
+            future_timestamp = dynamic_env.random_timestamp()
-            batch_indexes.append("{:5d}".format(sampled_timestamp))
+            _, (future_x, future_y) = dynamic_env(future_timestamp)
-            past_dataset = TimeData(
+            past_timestamp = (
-                sampled_timestamp,
+                future_timestamp - args.prev_time * dynamic_env.timestamp_interval
                env_info["{:}-x".format(sampled_timestamp)],
                env_info["{:}-y".format(sampled_timestamp)],
            )
-            future_dataset = TimeData(
+            _, (past_x, past_y) = dynamic_env(past_timestamp)
-                sampled_timestamp + 1,
+
-                env_info["{:}-x".format(sampled_timestamp + 1)],
+            future_container = maml.adapt(TimeData(past_timestamp, past_x, past_y))
-                env_info["{:}-y".format(sampled_timestamp + 1)],
+            future_y_hat = maml.predict(future_x, future_container)
-            )
+            future_loss = maml.criterion(future_y_hat, future_y)
            future_container = maml.adapt(past_dataset)
            future_y_hat = maml.predict(future_dataset.x, future_container)
            future_loss = maml.criterion(future_y_hat, future_dataset.y)
            meta_losses.append(future_loss)
        meta_loss = torch.stack(meta_losses).mean()
        meta_loss.backward()
        maml.step()
-        logger.log(
+        logger.log(head_str + " meta-loss: {:.4f}".format(meta_loss.item()))
-            "meta-loss: {:.4f}  batch: {:}".format(
+        success, best_score = maml.save_best(-meta_loss.item())
-                meta_loss.item(), ",".join(batch_indexes)
+        if success:
-            )
+            logger.log("Achieve the best with best_score = {:.3f}".format(best_score))
-        )
+            save_checkpoint(maml.state_dict(), logger.path("model"), logger)
-        best_info, is_best = maml.save_best(iepoch, -meta_loss.item())
+            last_success_epoch = iepoch
-        if is_best:
+        if iepoch - last_success_epoch >= args.early_stop_thresh:
-            save_checkpoint(best_info, logger.path("best"), logger)
+            logger.log("Early stop at {:}".format(iepoch))
-            logger.log("Save the best into {:}".format(logger.path("best")))
+            break
-        if iepoch >= 10 and (
+
            torch.isnan(meta_loss).item() or meta_loss.item() >= args.fail_thresh
        ):
            xdata = torch.load(logger.path("best"))
            maml.load_state_dict(xdata["state_dict"])
            iepoch = xdata["iepoch"]
            logger.log(
                "The training failed, re-use the previous best epoch [{:}]".format(
                    iepoch
                )
            )
        else:
            iepoch = iepoch + 1
        per_epoch_time.update(time.time() - start_time)
        start_time = time.time()
    # meta-test
    maml.load_best()
    eval_env = env_info["dynamic_env"]
    assert eval_env.timestamp_interval == dynamic_env.timestamp_interval
    w_container_per_epoch = dict()
-    for idx in range(1, env_info["total"]):
+    for idx in range(args.prev_time, len(eval_env)):
-        past_dataset = TimeData(
+        future_timestamp, (future_x, future_y) = eval_env[idx]
-            idx - 1,
+        past_timestamp = (
-            env_info["{:}-x".format(idx - 1)],
+            future_timestamp.item() - args.prev_time * eval_env.timestamp_interval
            env_info["{:}-y".format(idx - 1)],
        )
-        current_container = maml.adapt(past_dataset)
+        _, (past_x, past_y) = eval_env(past_timestamp)
-        w_container_per_epoch[idx] = current_container.no_grad_clone()
+        future_container = maml.adapt(TimeData(past_timestamp, past_x, past_y))
        w_container_per_epoch[idx] = future_container.no_grad_clone()
        with torch.no_grad():
-            current_x = env_info["{:}-x".format(idx)]
+            future_y_hat = maml.predict(future_x, w_container_per_epoch[idx])
-            current_y = env_info["{:}-y".format(idx)]
+            future_loss = maml.criterion(future_y_hat, future_y)
-            current_y_hat = maml.predict(current_x, w_container_per_epoch[idx])
+        logger.log("meta-test: [{:03d}] -> loss={:.4f}".format(idx, future_loss.item()))
            current_loss = maml.criterion(current_y_hat, current_y)
        logger.log(
            "meta-test: [{:03d}] -> loss={:.4f}".format(idx, current_loss.item())
        )
    save_checkpoint(
        {"w_container_per_epoch": w_container_per_epoch},
        logger.path(None) / "final-ckp.pth",
@ -224,13 +199,13 @@ if __name__ == "__main__":
    parser.add_argument(
        "--hidden_dim",
        type=int,
-        required=True,
+        default=16,
        help="The hidden dimension.",
    )
    parser.add_argument(
        "--meta_lr",
        type=float,
-        default=0.05,
+        default=0.01,
        help="The learning rate for the MAML optimizer (default is Adam)",
    )
    parser.add_argument(
@ -242,24 +217,36 @@ if __name__ == "__main__":
    parser.add_argument(
        "--inner_lr",
        type=float,
-        default=0.01,
+        default=0.005,
        help="The learning rate for the inner optimization",
    )
    parser.add_argument(
        "--inner_step", type=int, default=1, help="The inner loop steps for MAML."
    )
    parser.add_argument(
        "--prev_time",
        type=int,
        default=5,
        help="The gap between prev_time and current_timestamp",
    )
    parser.add_argument(
        "--meta_batch",
        type=int,
-        default=10,
+        default=64,
        help="The batch size for the meta-model",
    )
    parser.add_argument(
        "--epochs",
        type=int,
-        default=1000,
+        default=2000,
        help="The total number of epochs.",
    )
    parser.add_argument(
        "--early_stop_thresh",
        type=int,
        default=50,
        help="The maximum epochs for early stop.",
    )
    parser.add_argument(
        "--workers",
        type=int,
@ -272,7 +259,13 @@ if __name__ == "__main__":
    if args.rand_seed is None or args.rand_seed < 0:
        args.rand_seed = random.randint(1, 100000)
    assert args.save_dir is not None, "The save dir argument can not be None"
-    args.save_dir = "{:}-s{:}-{:}-d{:}".format(
+    args.save_dir = "{:}-s{:}-mlr{:}-d{:}-prev{:}-e{:}-env{:}".format(
-        args.save_dir, args.inner_step, args.env_version, args.hidden_dim
+        args.save_dir,
        args.inner_step,
        args.meta_lr,
        args.hidden_dim,
        args.prev_time,
        args.epochs,
        args.env_version,
    )
    main(args)
--- a/exps/LFNA/basic-prev.py
+++ b/exps/LFNA/basic-prev.py
@ -1,7 +1,7 @@
 #####################################################
 # Copyright (c) Xuanyi Dong [GitHub D-X-Y], 2021.04 #
 #####################################################
-# python exps/LFNA/basic-prev.py --env_version v1 --hidden_dim 16 --epochs 500 --init_lr 0.1
+# python exps/LFNA/basic-prev.py --env_version v1 --prev_time 5 --hidden_dim 16 --epochs 500 --init_lr 0.1
 # python exps/LFNA/basic-prev.py --env_version v2 --hidden_dim 16 --epochs 1000 --init_lr 0.05
 #####################################################
 import sys, time, copy, torch, random, argparse
@ -41,7 +41,7 @@ def main(args):
    w_container_per_epoch = dict()
    per_timestamp_time, start_time = AverageMeter(), time.time()
-    for idx in range(1, env_info["total"]):
+    for idx in range(args.prev_time, env_info["total"]):
        need_time = "Time Left: {:}".format(
            convert_secs2time(per_timestamp_time.avg * (env_info["total"] - idx), True)
@ -53,8 +53,8 @@ def main(args):
            + need_time
        )
        # train the same data
-        historical_x = env_info["{:}-x".format(idx - 1)]
+        historical_x = env_info["{:}-x".format(idx - args.prev_time)]
-        historical_y = env_info["{:}-y".format(idx - 1)]
+        historical_y = env_info["{:}-y".format(idx - args.prev_time)]
        # build model
        model = get_model(**model_kwargs)
        print(model)
@ -160,6 +160,12 @@ if __name__ == "__main__":
        default=0.1,
        help="The initial learning rate for the optimizer (default is Adam)",
    )
    parser.add_argument(
        "--prev_time",
        type=int,
        default=5,
        help="The gap between prev_time and current_timestamp",
    )
    parser.add_argument(
        "--batch_size",
        type=int,
@ -184,7 +190,12 @@ if __name__ == "__main__":
    if args.rand_seed is None or args.rand_seed < 0:
        args.rand_seed = random.randint(1, 100000)
    assert args.save_dir is not None, "The save dir argument can not be None"
-    args.save_dir = "{:}-{:}-d{:}".format(
+    args.save_dir = "{:}-d{:}_e{:}_lr{:}-prev{:}-env{:}".format(
-        args.save_dir, args.env_version, args.hidden_dim
+        args.save_dir,
        args.hidden_dim,
        args.epochs,
        args.init_lr,
        args.prev_time,
        args.env_version,
    )
    main(args)
--- a/exps/LFNA/basic-same.py
+++ b/exps/LFNA/basic-same.py
@ -41,7 +41,7 @@ def main(args):
    w_container_per_epoch = dict()
    per_timestamp_time, start_time = AverageMeter(), time.time()
-    for idx in range(env_info["total"]):
+    for idx in range(1, env_info["total"]):
        need_time = "Time Left: {:}".format(
            convert_secs2time(per_timestamp_time.avg * (env_info["total"] - idx), True)
@ -184,7 +184,7 @@ if __name__ == "__main__":
    if args.rand_seed is None or args.rand_seed < 0:
        args.rand_seed = random.randint(1, 100000)
    assert args.save_dir is not None, "The save dir argument can not be None"
-    args.save_dir = "{:}-{:}-d{:}".format(
+    args.save_dir = "{:}-d{:}_e{:}_lr{:}-env{:}".format(
-        args.save_dir, args.env_version, args.hidden_dim
+        args.save_dir, args.hidden_dim, args.epochs, args.init_lr, args.env_version
    )
    main(args)
--- a/exps/LFNA/lfna.py
+++ b/exps/LFNA/lfna.py
@ -157,11 +157,11 @@ def main(args):
        per_epoch_time.update(time.time() - start_time)
        start_time = time.time()
-    # meta-training
+    # meta-test
    meta_model.load_best()
    eval_env = env_info["dynamic_env"]
    w_container_per_epoch = dict()
-    for idx in range(args.seq_length, env_info["total"]):
+    for idx in range(args.seq_length, len(eval_env)):
        # build-timestamp
        future_time = env_info["{:}-timestamp".format(idx)]
        time_seqs = []
@ -176,8 +176,8 @@ def main(args):
            future_container = seq_containers[-1]
            w_container_per_epoch[idx] = future_container.no_grad_clone()
            # evaluation
-            future_x = env_info["{:}-x".format(idx)]
+            future_x = env_info["{:}-x".format(idx)].to(args.device)
-            future_y = env_info["{:}-y".format(idx)]
+            future_y = env_info["{:}-y".format(idx)].to(args.device)
            future_y_hat = base_model.forward_with_container(
                future_x, w_container_per_epoch[idx]
            )
@ -299,12 +299,12 @@ if __name__ == "__main__":
    if args.rand_seed is None or args.rand_seed < 0:
        args.rand_seed = random.randint(1, 100000)
    assert args.save_dir is not None, "The save dir argument can not be None"
-    args.save_dir = "{:}-{:}-d{:}_{:}_{:}-e{:}".format(
+    args.save_dir = "{:}-d{:}_{:}_{:}-e{:}-env{:}".format(
        args.save_dir,
        args.env_version,
        args.hidden_dim,
        args.layer_dim,
        args.time_dim,
        args.epochs,
        args.env_version,
    )
    main(args)
--- a/exps/LFNA/vis-synthetic.py
+++ b/exps/LFNA/vis-synthetic.py
@ -237,18 +237,20 @@ def compare_algs(save_dir, version, alg_dir="./outputs/lfna-synthetic"):
    env_info = torch.load(cache_path)
    alg_name2dir = OrderedDict()
    alg_name2dir["Optimal"] = "use-same-timestamp"
    # alg_name2dir["Supervised Learning (History Data)"] = "use-all-past-data"
    # alg_name2dir["MAML"] = "use-maml-s1"
    # alg_name2dir["LFNA (fix init)"] = "lfna-fix-init"
    alg_name2dir["LFNA (debug)"] = "lfna-tall-hpnet"
    alg_name2all_containers = OrderedDict()
    if version == "v1":
-        poststr = "v1-d16"
+        # alg_name2dir["Optimal"] = "use-same-timestamp"
        alg_name2dir["LFNA"] = "lfna-battle-v1-d16_16_16-e200"
        alg_name2dir[
            "Previous Timestamp"
        ] = "use-prev-timestamp-d16_e500_lr0.1-prev5-envv1"
    else:
        raise ValueError("Invalid version: {:}".format(version))
    alg_name2all_containers = OrderedDict()
    for idx_alg, (alg, xdir) in enumerate(alg_name2dir.items()):
-        ckp_path = Path(alg_dir) / "{:}-{:}".format(xdir, poststr) / "final-ckp.pth"
+        ckp_path = Path(alg_dir) / str(xdir) / "final-ckp.pth"
        xdata = torch.load(ckp_path, map_location="cpu")
        alg_name2all_containers[alg] = xdata["w_container_per_epoch"]
    # load the basic model
@ -267,11 +269,11 @@ def compare_algs(save_dir, version, alg_dir="./outputs/lfna-synthetic"):
    dynamic_env = env_info["dynamic_env"]
    min_t, max_t = dynamic_env.min_timestamp, dynamic_env.max_timestamp
-    linewidths = 10
+    linewidths, skip = 10, 5
    for idx, (timestamp, (ori_allx, ori_ally)) in enumerate(
        tqdm(dynamic_env, ncols=50)
    ):
-        if idx == 0:
+        if idx <= skip:
            continue
        fig = plt.figure(figsize=figsize)
        cur_ax = fig.add_subplot(2, 1, 1)
@ -335,9 +337,9 @@ def compare_algs(save_dir, version, alg_dir="./outputs/lfna-synthetic"):
        cur_ax.set_ylim(0, 10)
        cur_ax.legend(loc=1, fontsize=LegendFontsize)
-        pdf_save_path = save_dir / "pdf" / "v{:}-{:05d}.pdf".format(version, idx)
+        pdf_save_path = save_dir / "pdf" / "v{:}-{:05d}.pdf".format(version, idx - skip)
        fig.savefig(str(pdf_save_path), dpi=dpi, bbox_inches="tight", format="pdf")
-        png_save_path = save_dir / "png" / "v{:}-{:05d}.png".format(version, idx)
+        png_save_path = save_dir / "png" / "v{:}-{:05d}.png".format(version, idx - skip)
        fig.savefig(str(png_save_path), dpi=dpi, bbox_inches="tight", format="png")
        plt.close("all")
    save_dir = save_dir.resolve()
--- a/lib/datasets/synthetic_env.py
+++ b/lib/datasets/synthetic_env.py
@ -80,6 +80,12 @@ class SyntheticDEnv(data.Dataset):
    def timestamp_interval(self):
        return self._timestamp_generator.interval
    def random_timestamp(self):
        return (
            random.random() * (self.max_timestamp - self.min_timestamp)
            + self.min_timestamp
        )
    def reset_max_seq_length(self, seq_length):
        self._seq_length = seq_length
--- a/lib/datasets/synthetic_utils.py
+++ b/lib/datasets/synthetic_utils.py
@ -56,11 +56,11 @@ class TimeStamp(UnifiedSplit, data.Dataset):
    @property
    def min_timestamp(self):
-        return self._min_timestamp
+        return self._min_timestamp + self._interval * min(self._indexes)
    @property
    def max_timestamp(self):
-        return self._max_timestamp
+        return self._min_timestamp + self._interval * max(self._indexes)
    @property
    def interval(self):