""" train/utils.py — Training utility functions. Provides: get_cosine_schedule_with_warmup : LambdaLR scheduler with linear warmup + cosine decay save_checkpoint : Persist model/optimizer/scheduler state to disk load_checkpoint : Restore state from a saved checkpoint directory get_grad_norm : Compute total L2 gradient norm across all parameters setup_ddp : Initialise NCCL distributed process group cleanup_ddp : Tear down distributed process group is_main_process : True when this process is rank 0 (or non-distributed) """ from __future__ import annotations import math import os import shutil from pathlib import Path from typing import Optional, Tuple import numpy as np import torch import torch.distributed as dist import yaml from torch.optim import Optimizer from torch.optim.lr_scheduler import LambdaLR # --------------------------------------------------------------------------- # Learning-rate schedule # --------------------------------------------------------------------------- def get_cosine_schedule_with_warmup( optimizer: Optimizer, warmup_steps: int, total_steps: int, min_lr_ratio: float = 0.1, ) -> LambdaLR: """ Create a LambdaLR scheduler with: - Linear warmup: lr scales from 0 → 1 over [0, warmup_steps) - Cosine decay: lr scales from 1 → min_lr_ratio over [warmup_steps, total_steps] Args: optimizer: The wrapped optimizer. warmup_steps: Number of linear-warmup steps. total_steps: Total number of training steps. min_lr_ratio: Minimum lr as a fraction of the peak lr (default 0.1). Returns: A LambdaLR scheduler instance. """ if warmup_steps < 0: raise ValueError(f"warmup_steps must be >= 0, got {warmup_steps}") if total_steps <= 0: raise ValueError(f"total_steps must be > 0, got {total_steps}") if not (0.0 <= min_lr_ratio <= 1.0): raise ValueError(f"min_lr_ratio must be in [0, 1], got {min_lr_ratio}") def lr_lambda(current_step: int) -> float: # Linear warmup phase. if current_step < warmup_steps: return float(current_step) / float(max(1, warmup_steps)) # After total_steps, hold at min_lr_ratio. if current_step >= total_steps: return min_lr_ratio # Cosine decay phase. decay_steps = total_steps - warmup_steps progress = float(current_step - warmup_steps) / float(max(1, decay_steps)) cosine_factor = 0.5 * (1.0 + math.cos(math.pi * progress)) # Scale cosine output from [0, 1] into [min_lr_ratio, 1]. return min_lr_ratio + (1.0 - min_lr_ratio) * cosine_factor return LambdaLR(optimizer, lr_lambda) # --------------------------------------------------------------------------- # Checkpoint save / load # --------------------------------------------------------------------------- def save_checkpoint( model: torch.nn.Module, optimizer: Optimizer, scheduler: LambdaLR, step: int, loss: float, path: str | Path, suffix: str | None = None, ) -> Path: """ Save a training checkpoint to ``path/checkpoint-{step:07d}/``. Saves: - model.pt : model state_dict - optimizer.pt : optimizer state_dict - scheduler.pt : scheduler state_dict - train_state.pt : step and loss scalars - config.yaml : model LMConfig (if the model exposes a ``.config`` attribute) Handles both plain ``nn.Module`` and DDP-wrapped models by unwrapping via ``.module`` when present. Args: model: The model (plain or DDP-wrapped). optimizer: The optimizer. scheduler: The LR scheduler. step: Current training step (used in directory name). loss: Current loss value (stored for reference). path: Root checkpoint directory. Returns: Path to the created checkpoint sub-directory. """ dir_name = f"checkpoint-{suffix}" if suffix else f"checkpoint-{step:07d}" ckpt_dir = Path(path) / dir_name tmp_dir = Path(path) / f".tmp_{dir_name}" # Write to temp directory first for crash safety if tmp_dir.exists(): shutil.rmtree(tmp_dir) tmp_dir.mkdir(parents=True, exist_ok=True) raw_model: torch.nn.Module = getattr(model, "module", model) torch.save(raw_model.state_dict(), tmp_dir / "model.pt") torch.save(optimizer.state_dict(), tmp_dir / "optimizer.pt") torch.save(scheduler.state_dict(), tmp_dir / "scheduler.pt") import random as _random train_state = { "step": step, "loss": loss, "rng_state": { "python": _random.getstate(), "numpy": np.random.get_state(), "torch_cpu": torch.random.get_rng_state(), "torch_cuda": torch.cuda.get_rng_state_all(), }, } torch.save(train_state, tmp_dir / "train_state.pt") # Persist the model config when available. if hasattr(raw_model, "config"): cfg = raw_model.config if hasattr(cfg, "to_dict"): config_dict = cfg.to_dict() else: # Fallback: try __dict__ for plain dataclasses. config_dict = { k: v for k, v in vars(cfg).items() if not k.startswith("_") } with open(tmp_dir / "config.yaml", "w", encoding="utf-8") as f: yaml.safe_dump(config_dict, f, default_flow_style=False, sort_keys=False) # Atomic swap: rename old → trash, tmp → final, delete trash trash_dir = Path(path) / f".trash_{dir_name}" if trash_dir.exists(): shutil.rmtree(trash_dir) if ckpt_dir.exists(): ckpt_dir.rename(trash_dir) tmp_dir.rename(ckpt_dir) if trash_dir.exists(): shutil.rmtree(trash_dir) # Clean up old checkpoints (keep recent N + best) cleanup_old_checkpoints(Path(path)) return ckpt_dir def cleanup_old_checkpoints(path: Path, keep: int = 5) -> None: """Remove old checkpoints, keeping the most recent `keep` plus checkpoint-best.""" ckpts = sorted( [d for d in path.glob("checkpoint-[0-9]*") if d.is_dir()], key=lambda d: d.stat().st_mtime, ) for old in ckpts[:-keep]: shutil.rmtree(old) def load_checkpoint( path: str | Path, model: torch.nn.Module, optimizer: Optional[Optimizer] = None, scheduler: Optional[LambdaLR] = None, ) -> Tuple[int, float]: """ Load a checkpoint from a directory created by :func:`save_checkpoint`. The model weights are always restored. Optimizer and scheduler states are only restored when the corresponding objects are provided. Args: path: Path to the checkpoint directory (e.g. ``checkpoints/checkpoint-0001000``). model: Model to load weights into (plain or DDP-wrapped). optimizer: Optional optimizer to restore state into. scheduler: Optional LR scheduler to restore state into. Returns: ``(step, loss)`` — the training step and loss recorded at save time. """ ckpt_dir = Path(path) if not ckpt_dir.is_dir(): raise FileNotFoundError(f"Checkpoint directory not found: {ckpt_dir}") # Unwrap DDP model if necessary. raw_model: torch.nn.Module = getattr(model, "module", model) # Determine the device the model lives on. try: device = next(raw_model.parameters()).device except StopIteration: device = torch.device("cpu") raw_model.load_state_dict( torch.load(ckpt_dir / "model.pt", map_location=device, weights_only=True) ) if optimizer is not None: optimizer.load_state_dict( torch.load(ckpt_dir / "optimizer.pt", map_location=device, weights_only=True) ) if scheduler is not None: scheduler.load_state_dict( torch.load(ckpt_dir / "scheduler.pt", map_location=device, weights_only=True) ) train_state = torch.load( ckpt_dir / "train_state.pt", map_location="cpu", weights_only=True ) step: int = int(train_state["step"]) loss: float = float(train_state["loss"]) # Restore RNG states if available (for exact resume reproducibility) rng_state = train_state.get("rng_state") if rng_state is not None: import random as _random try: _random.setstate(rng_state["python"]) np.random.set_state(rng_state["numpy"]) torch.random.set_rng_state(rng_state["torch_cpu"]) torch.cuda.set_rng_state_all(rng_state["torch_cuda"]) except Exception as e: print(f"[WARN] RNG state restore failed (non-fatal): {e}") return step, loss # --------------------------------------------------------------------------- # Gradient utilities # --------------------------------------------------------------------------- def get_grad_norm(model: torch.nn.Module) -> float: """ Compute the total L2 norm of all parameter gradients. Uses a single GPU kernel + one GPU-CPU sync instead of one sync per parameter (the naive loop approach). Only parameters with non-None ``.grad`` attribute contribute. Args: model: The model (plain or DDP-wrapped). Returns: Scalar float — the global gradient L2 norm. """ raw_model: torch.nn.Module = getattr(model, "module", model) grads = [p.grad.detach().float() for p in raw_model.parameters() if p.grad is not None] if not grads: return 0.0 # Stack individual norms and compute the L2 norm of norms — single sync. return torch.stack([g.norm(2) for g in grads]).norm(2).item() # --------------------------------------------------------------------------- # Distributed training helpers # --------------------------------------------------------------------------- def setup_ddp() -> Tuple[int, int, int, torch.device]: """ Initialise the NCCL distributed process group for DDP training. Reads ``RANK``, ``LOCAL_RANK``, and ``WORLD_SIZE`` from the environment (set automatically by ``torchrun``). Returns: ``(rank, local_rank, world_size, device)`` """ rank = int(os.environ["RANK"]) local_rank = int(os.environ["LOCAL_RANK"]) world_size = int(os.environ["WORLD_SIZE"]) # Limit CPU thread count per process to avoid contention across 8 ranks. # 72 cores / 8 ranks = 9; use 4 to leave headroom for DataLoader workers. os.environ.setdefault("OMP_NUM_THREADS", "4") os.environ.setdefault("MKL_NUM_THREADS", "4") import datetime as _dt dist.init_process_group( backend="nccl", timeout=_dt.timedelta(seconds=7200), # 2h for large checkpoint loads ) torch.cuda.set_device(local_rank) device = torch.device(f"cuda:{local_rank}") return rank, local_rank, world_size, device def cleanup_ddp() -> None: """Tear down the distributed process group (call at end of training).""" if dist.is_available() and dist.is_initialized(): dist.destroy_process_group() def is_main_process() -> bool: """ Return ``True`` when this process is rank 0 or when running without DDP. Reads the ``RANK`` environment variable; if it is absent the process is assumed to be the sole process (rank 0). """ return int(os.environ.get("RANK", "0")) == 0