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trainer.py — TMT training loop with wandb logging.
Trains on wikitext-2 (or tinystories) using AdamW + cosine warmup schedule.
Logs: train loss, val perplexity, exit rate per layer, and memory anchor norms.
"""
from __future__ import annotations
import os
from dataclasses import dataclass, field
from typing import Optional
import torch
import torch.nn as nn
from torch import Tensor
from torch.optim import AdamW
from torch.utils.data import DataLoader
from ..model.config import TMTConfig
from ..model.model import TMTModel
from .loss import compute_loss
from .scheduler import cosine_warmup_scheduler
@dataclass
class TrainConfig:
# Data
dataset: str = "wikitext-2" # or "tinystories"
batch_size: int = 16
seq_len: int = 256 # shorter than max for memory efficiency
# Optimiser
lr: float = 3e-4
weight_decay: float = 0.1
grad_clip: float = 1.0
warmup_steps: int = 500
total_steps: int = 10_000
# Saving
save_dir: str = "checkpoints"
save_every: int = 500
eval_every: int = 100
# Logging
use_wandb: bool = False # set True when wandb is configured
project: str = "temporal-mesh-transformer"
# Device
device: str = "cuda" if torch.cuda.is_available() else "cpu"
# Loss
exit_gate_coeff: float = 0.1
class TMTTrainer:
def __init__(
self,
model_cfg: TMTConfig,
train_cfg: TrainConfig,
train_loader: DataLoader,
val_loader: Optional[DataLoader] = None,
) -> None:
self.cfg = train_cfg
self.device = torch.device(train_cfg.device)
self.model = TMTModel(model_cfg).to(self.device)
self.optimizer = AdamW(
self.model.parameters(),
lr=train_cfg.lr,
weight_decay=train_cfg.weight_decay,
)
self.scheduler = cosine_warmup_scheduler(
self.optimizer,
warmup_steps=train_cfg.warmup_steps,
total_steps=train_cfg.total_steps,
)
self.train_loader = train_loader
self.val_loader = val_loader
self.step = 0
if train_cfg.use_wandb:
try:
import wandb
wandb.init(project=train_cfg.project, config={
"model": vars(model_cfg),
"train": vars(train_cfg),
})
self.wandb = wandb
except ImportError:
print("wandb not installed — skipping wandb logging")
self.wandb = None
else:
self.wandb = None
os.makedirs(train_cfg.save_dir, exist_ok=True)
print(self.model)
def train(self) -> None:
self.model.train()
data_iter = iter(self.train_loader)
while self.step < self.cfg.total_steps:
try:
batch = next(data_iter)
except StopIteration:
data_iter = iter(self.train_loader)
batch = next(data_iter)
input_ids = batch["input_ids"].to(self.device)
# Next-token prediction: targets are shifted by 1
x = input_ids[:, :-1]
targets = input_ids[:, 1:]
# Forward
output = self.model(x)
total_loss, ce_loss, gate_loss = compute_loss(
output.logits,
targets,
output.confidences,
self.cfg.exit_gate_coeff,
)
# Backward
self.optimizer.zero_grad()
total_loss.backward()
nn.utils.clip_grad_norm_(self.model.parameters(), self.cfg.grad_clip)
self.optimizer.step()
self.scheduler.step()
self.step += 1
# Logging
if self.step % 10 == 0:
lr = self.optimizer.param_groups[0]["lr"]
avg_exit_rate = self._compute_exit_rate(output)
print(
f"step={self.step:5d} | loss={total_loss.item():.4f} | "
f"ce={ce_loss.item():.4f} | gate={gate_loss.item():.4f} | "
f"exit={avg_exit_rate:.3f} | lr={lr:.2e}"
)
if self.wandb:
self.wandb.log({
"loss/total": total_loss.item(),
"loss/ce": ce_loss.item(),
"loss/gate": gate_loss.item(),
"train/exit_rate": avg_exit_rate,
"train/lr": lr,
"step": self.step,
})
if self.val_loader and self.step % self.cfg.eval_every == 0:
val_ppl = self.evaluate()
print(f" val_perplexity={val_ppl:.2f}")
if self.wandb:
self.wandb.log({"val/perplexity": val_ppl, "step": self.step})
self.model.train()
if self.step % self.cfg.save_every == 0:
self._save(f"{self.cfg.save_dir}/ckpt_step{self.step}.pt")
@torch.no_grad()
def evaluate(self) -> float:
self.model.eval()
total_loss, n_batches = 0.0, 0
for batch in self.val_loader:
input_ids = batch["input_ids"].to(self.device)
x, targets = input_ids[:, :-1], input_ids[:, 1:]
out = self.model(x)
loss, *_ = compute_loss(out.logits, targets, out.confidences)
total_loss += loss.item()
n_batches += 1
avg_loss = total_loss / max(n_batches, 1)
import math
return math.exp(avg_loss)
@staticmethod
def _compute_exit_rate(output) -> float:
if not output.exit_masks:
return 0.0
final_mask = output.exit_masks[-1]
return final_mask.float().mean().item()
def _save(self, path: str) -> None:
torch.save({
"step": self.step,
"model_state": self.model.state_dict(),
"optimizer_state": self.optimizer.state_dict(),
}, path)
print(f" saved checkpoint → {path}")
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