# SPDX-License-Identifier: AGPL-3.0-only # Copyright 2026-present the Unsloth AI Inc. team. All rights reserved. See /studio/LICENSE.AGPL-3.0 """ Training backend — subprocess orchestrator. Each job runs in a fresh spawn subprocess (solving transformers version-switching); the in-process UnslothTrainer singleton is only used inside the worker. This file orchestrates the subprocess lifecycle, pumps events from the worker's mp.Queue, and exposes the same API to routes/training.py. Pattern follows data_recipe/jobs/manager.py. """ import json as _json import math import multiprocessing as mp import os import platform import queue import re import shutil import threading import time import traceback import structlog from datetime import datetime, timezone from loggers import get_logger from dataclasses import dataclass, field, replace from pathlib import Path from typing import Optional, Tuple, Any, Callable, Union, TYPE_CHECKING if TYPE_CHECKING: import matplotlib.pyplot as plt from utils.hardware import prepare_gpu_selection from utils.native_path_leases import ( native_path_secret_removed_for_child_start, run_without_native_path_secret, ) from utils.paths import outputs_root logger = get_logger(__name__) _pyplot = None _pyplot_failed = False def _load_pyplot(): """Lazily import matplotlib.pyplot (headless Agg); return it, or None if matplotlib is unavailable. Deferred so a blocked native wheel (e.g. Windows Smart App Control) never breaks server startup, only loss plotting. """ global _pyplot, _pyplot_failed if _pyplot is not None or _pyplot_failed: return _pyplot try: import matplotlib matplotlib.use("Agg") # headless backend import matplotlib.pyplot as plt _pyplot = plt except Exception as e: _pyplot_failed = True logger.warning("matplotlib unavailable; loss plots disabled", error = str(e)) return _pyplot def _coerce_seed(value, default = 3407) -> int: """Normalize None / non-int to `default` (transformers.set_seed(None) raises).""" if value is None: return int(default) try: return int(value) except (TypeError, ValueError): return int(default) def _coerce_optional_bool(value, default: bool) -> bool: """Treat explicit None as `default` instead of `bool(None) == False`.""" if value is None: return bool(default) if isinstance(value, str): normalized = value.strip().lower() if normalized in ("true", "1", "yes", "on"): return True if normalized in ("false", "0", "no", "off", ""): return False return bool(value) def _coerce_optional_nonneg_float(name: str, value): """Reject negatives; HTTP `ge=0` doesn't cover raw `**kwargs` callers.""" if value is None: return None try: coerced = float(value) except (TypeError, ValueError): raise ValueError(f"Unsloth: {name}={value!r} must be a non-negative float or None.") if coerced < 0: raise ValueError(f"Unsloth: {name}={coerced} must be >= 0 (use 0 or None to disable).") return coerced def is_apple_silicon_training_platform() -> bool: return platform.system() == "Darwin" and platform.machine() == "arm64" def is_mlx_training_device(device: Any) -> bool: return ( str(device).lower() == "mlx" or str(device).lower().endswith(".mlx") or getattr(device, "name", "").lower() == "mlx" ) def should_use_mlx_training_backend(*, device: Optional[Any] = None) -> bool: if device is not None: return is_mlx_training_device(device) return is_apple_silicon_training_platform() def _build_training_worker_config(values: dict[str, Any]) -> dict[str, Any]: """Build the normalized worker config shared by Studio and the CLI adapter.""" config = { "model_name": values["model_name"], "project_name": values.get("project_name"), "training_type": values.get("training_type", "LoRA/QLoRA"), "hf_token": values.get("hf_token", ""), "load_in_4bit": values.get("load_in_4bit", True), "max_seq_length": values.get("max_seq_length", 2048), "vision_image_size": values.get("vision_image_size"), "hf_dataset": values.get("hf_dataset", ""), "local_datasets": values.get("local_datasets"), "local_eval_datasets": values.get("local_eval_datasets"), "format_type": values.get("format_type", ""), "subset": values.get("subset"), "train_split": values.get("train_split", "train"), "eval_split": values.get("eval_split"), "eval_steps": values.get("eval_steps", 0.00), "dataset_streaming": values.get("dataset_streaming", False), "dataset_slice_start": values.get("dataset_slice_start"), "dataset_slice_end": values.get("dataset_slice_end"), "custom_format_mapping": values.get("custom_format_mapping"), "is_dataset_image": values.get("is_dataset_image", False), "is_dataset_audio": values.get("is_dataset_audio", False), "is_embedding": values.get("is_embedding", False), "num_epochs": values.get("num_epochs", 3), "learning_rate": values.get("learning_rate", "2e-4"), "embedding_learning_rate": values.get("embedding_learning_rate"), "batch_size": values.get("batch_size", 2), "gradient_accumulation_steps": values.get("gradient_accumulation_steps", 4), "warmup_steps": values.get("warmup_steps"), "warmup_ratio": values.get("warmup_ratio"), "max_steps": values.get("max_steps", 0), "save_steps": values.get("save_steps", 0), "weight_decay": values.get("weight_decay", 0.001), "max_grad_norm": values.get("max_grad_norm", 0.0), "max_grad_value": _coerce_optional_nonneg_float( "max_grad_value", values.get("max_grad_value") ), "max_grad_leaf_norm": _coerce_optional_nonneg_float( "max_grad_leaf_norm", values.get("max_grad_leaf_norm") ), "cast_norm_output_to_input_dtype": _coerce_optional_bool( values.get("cast_norm_output_to_input_dtype"), True ), "random_seed": _coerce_seed(values.get("random_seed")), "packing": values.get("packing", False), "optim": values.get("optim", "adamw_8bit"), "lr_scheduler_type": values.get("lr_scheduler_type", "linear"), "use_lora": values.get("use_lora", True), "lora_r": values.get("lora_r", 16), "lora_alpha": values.get("lora_alpha", 16), "lora_dropout": values.get("lora_dropout", 0.0), "target_modules": values.get("target_modules"), "gradient_checkpointing": values.get("gradient_checkpointing", "unsloth"), "use_rslora": values.get("use_rslora", False), "use_loftq": values.get("use_loftq", False), "train_on_completions": values.get("train_on_completions", False), "finetune_vision_layers": values.get("finetune_vision_layers", True), "finetune_language_layers": values.get("finetune_language_layers", True), "finetune_attention_modules": values.get("finetune_attention_modules", True), "finetune_mlp_modules": values.get("finetune_mlp_modules", True), "enable_wandb": values.get("enable_wandb", False), "wandb_token": values.get("wandb_token"), "wandb_project": values.get("wandb_project", "unsloth-training"), "enable_tensorboard": values.get("enable_tensorboard", False), "tensorboard_dir": values.get("tensorboard_dir", "runs"), "resume_from_checkpoint": values.get("resume_from_checkpoint"), "trust_remote_code": values.get("trust_remote_code", False), "approved_remote_code_fingerprint": values.get("approved_remote_code_fingerprint"), "subject": values.get("subject"), "gpu_ids": values.get("gpu_ids"), "s3_config": values.get("s3_config"), "disable_xet": values.get("disable_xet", False), } for key in ("output_dir", "allow_external_output_dir"): if key in values: config[key] = values.get(key) if config["training_type"] == "Full Finetuning": config["load_in_4bit"] = False return config _HF_TMP_CHECKPOINT_RE = re.compile(r"^tmp-checkpoint-\d+$") def _sanitize_db_config(config: dict[str, Any]) -> dict[str, Any]: # ``subject`` (the run owner's username / API-key id) is worker-only metadata; never # persist it to config_json, which run-history GET returns to any authenticated user. db_config = { k: v for k, v in config.items() if k not in {"hf_token", "wandb_token", "s3_config", "subject"} } s3_config = config.get("s3_config") if hasattr(s3_config, "model_dump"): s3_config = s3_config.model_dump() if isinstance(s3_config, dict) and s3_config: db_config["dataset_source"] = "s3" db_config["s3_dataset"] = { "bucket": s3_config.get("bucket"), "region": s3_config.get("region"), "prefix": s3_config.get("prefix"), "use_iam_role": bool(s3_config.get("use_iam_role")), } return db_config def _s3_dataset_name(s3_dataset: Any) -> Optional[str]: if not isinstance(s3_dataset, dict): return None bucket = s3_dataset.get("bucket") if not bucket: return None prefix = s3_dataset.get("prefix") return f"s3://{bucket}/{prefix}" if prefix else f"s3://{bucket}" def _cleanup_cancelled_checkpoints(output_dir: Union[str, os.PathLike]) -> None: """Remove only HF Trainer ``tmp-checkpoint-/`` partials after a cancel. Completed ``checkpoint-/`` dirs survive. Symlinked output_dir / children are skipped so containment can't be bypassed. """ out = Path(output_dir) if not out.exists() or not out.is_dir() or out.is_symlink(): return try: out_real = out.resolve() out_root_real = Path(outputs_root()).resolve() except OSError: return try: out_real.relative_to(out_root_real) except ValueError: logger.warning( "Skipping checkpoint cleanup - %s is not under outputs_root %s", out_real, out_root_real, ) return removed = 0 for entry in out.iterdir(): if not entry.is_dir() or entry.is_symlink(): continue if not _HF_TMP_CHECKPOINT_RE.match(entry.name): continue try: shutil.rmtree(entry, ignore_errors = False) removed += 1 except OSError as exc: logger.warning("Could not remove %s: %s", entry, exc) logger.info( "Cancelled-run cleanup removed %d in-flight tmp-checkpoint dir(s) under %s", removed, out, ) _CTX = mp.get_context("spawn") # Plot styling constants PLOT_WIDTH = 8 PLOT_HEIGHT = 3.5 @dataclass class TrainingProgress: """Shared training progress payload for Studio and backend-aware trainers.""" epoch: float = 0 step: int = 0 total_steps: int = 0 loss: Optional[float] = None learning_rate: Optional[float] = None is_training: bool = False is_completed: bool = False error: Optional[str] = None status_message: str = "Ready to train" elapsed_seconds: Optional[float] = None eta_seconds: Optional[float] = None grad_norm: Optional[float] = None num_tokens: Optional[int] = None eval_loss: Optional[float] = None peak_memory_gb: Optional[float] = None output_dir: Optional[str] = None class _MLXTrainerAdapter: """Adapts the legacy UnslothTrainer API to the shared Studio MLX worker path.""" def __init__(self): self.model = None self.tokenizer = None self.trainer = None self.training_thread = None self.training_progress = TrainingProgress() self.progress_callbacks: list[Callable[[TrainingProgress], None]] = [] self.is_training = False self.should_stop = False self.save_on_stop = True self.load_in_4bit = True self.output_dir = None self.is_cpt = False self.is_vlm = False self.is_audio = False self.is_audio_vlm = False self.model_name = None self.max_seq_length = None self._model_config: dict[str, Any] = {} self._peft_config: dict[str, Any] = {} self._dataset_config: dict[str, Any] = {} self._event_queue: Optional[queue.Queue] = None self._stop_queue: Optional[queue.Queue] = None self._pump_thread: Optional[threading.Thread] = None self._lock = threading.Lock() def _activate_transformers_for_model(self, model_name: str, hf_token: Optional[str]) -> None: try: from utils.transformers_version import activate_transformers_for_subprocess activate_transformers_for_subprocess(model_name, hf_token) except Exception as exc: logger.warning("MLX trainer adapter Transformers activation failed", error = str(exc)) def add_progress_callback(self, callback: Callable[[TrainingProgress], None]): self.progress_callbacks.append(callback) def _update_progress(self, **kwargs): with self._lock: for key, value in kwargs.items(): if hasattr(self.training_progress, key): setattr(self.training_progress, key, value) progress = self.training_progress for callback in self.progress_callbacks: try: callback(progress) except Exception: pass def load_model( self, model_name: str, max_seq_length: int = 2048, load_in_4bit: bool = True, hf_token: Optional[str] = None, is_dataset_image: bool = False, is_dataset_audio: bool = False, trust_remote_code: bool = False, full_finetuning: bool = False, gpu_ids: Optional[list[int]] = None, ) -> bool: self.model_name = model_name self.max_seq_length = max_seq_length self.load_in_4bit = load_in_4bit self._audio_type = None self._activate_transformers_for_model(model_name, hf_token) try: from utils.models import detect_audio_type, is_vision_model self._audio_type = detect_audio_type(model_name, hf_token) if self._audio_type == "audio_vlm": self.is_audio = False self.is_audio_vlm = bool(is_dataset_audio) self._audio_type = None else: self.is_audio = self._audio_type is not None self.is_audio_vlm = False vision = is_vision_model(model_name, hf_token = hf_token) if not self.is_audio else False self.is_vlm = not self.is_audio_vlm and vision and bool(is_dataset_image) except Exception as exc: logger.warning("MLX trainer adapter model type detection failed", error = str(exc)) self.is_vlm = False self.is_audio = False self.is_audio_vlm = False self.model = object() self.tokenizer = object() self._model_config = { "model_name": model_name, "max_seq_length": max_seq_length, "load_in_4bit": load_in_4bit, "hf_token": hf_token or "", "is_dataset_image": bool(is_dataset_image), "is_dataset_audio": bool(is_dataset_audio), "trust_remote_code": bool(trust_remote_code), "gpu_ids": gpu_ids, } self._update_progress( is_training = False, is_completed = False, error = None, step = 0, loss = 0.0, epoch = 0, status_message = f"Queued MLX model load: {model_name}", ) return True def prepare_model_for_training( self, use_lora: bool = True, finetune_vision_layers: bool = True, finetune_language_layers: bool = True, finetune_attention_modules: bool = True, finetune_mlp_modules: bool = True, target_modules: Optional[Union[list, str]] = None, lora_r: int = 16, lora_alpha: int = 16, lora_dropout: float = 0.0, use_gradient_checkpointing: Union[str, bool] = "unsloth", use_rslora: bool = False, use_loftq: bool = False, ) -> bool: self._peft_config = { "use_lora": bool(use_lora), "lora_r": lora_r, "lora_alpha": lora_alpha, "lora_dropout": lora_dropout, "target_modules": target_modules, "gradient_checkpointing": use_gradient_checkpointing, "use_rslora": bool(use_rslora), "use_loftq": bool(use_loftq), "finetune_vision_layers": bool(finetune_vision_layers), "finetune_language_layers": bool(finetune_language_layers), "finetune_attention_modules": bool(finetune_attention_modules), "finetune_mlp_modules": bool(finetune_mlp_modules), } self._update_progress(status_message = "Queued MLX training setup") return True def load_and_format_dataset( self, dataset_source: Optional[str], format_type: str = "auto", local_datasets: Optional[list[str]] = None, local_eval_datasets: Optional[list[str]] = None, custom_format_mapping: Optional[dict[str, Any]] = None, subset: Optional[str] = None, train_split: str = "train", eval_split: Optional[str] = None, dataset_streaming: bool = False, eval_steps: float = 0.00, dataset_slice_start: Optional[int] = None, dataset_slice_end: Optional[int] = None, is_cpt: bool = False, s3_config: dict = None, ) -> Optional[tuple]: self._dataset_config = { "hf_dataset": dataset_source or "", "local_datasets": local_datasets, "local_eval_datasets": local_eval_datasets, "format_type": format_type or "", "custom_format_mapping": custom_format_mapping, "subset": subset, "train_split": train_split or "train", "eval_split": eval_split, "dataset_streaming": bool(dataset_streaming), "eval_steps": eval_steps or 0.0, "dataset_slice_start": dataset_slice_start, "dataset_slice_end": dataset_slice_end, "s3_config": s3_config, } self.is_cpt = bool(is_cpt) self._update_progress(status_message = "Queued MLX dataset load") return ({"dataset": [], "final_format": "deferred_mlx_cli", "success": True}, None) def start_training( self, dataset = None, eval_dataset = None, **training_args, ) -> bool: if self.is_training and self.training_thread and self.training_thread.is_alive(): return False if self._pump_thread and self._pump_thread.is_alive(): self._pump_thread.join(timeout = 2.0) if self._pump_thread.is_alive(): self._update_progress(error = "Previous training event pump is still finalizing") return False if not self._model_config: self._update_progress(error = "Model not loaded") return False if not self._dataset_config: self._update_progress(error = "Dataset not loaded") return False if self.is_cpt: self._update_progress( error = "Continued Pretraining is not supported for MLX training yet.", is_training = False, is_completed = False, ) return False config = self._build_worker_config(training_args) event_queue = queue.Queue() stop_queue = queue.Queue() self._event_queue = event_queue self._stop_queue = stop_queue self.should_stop = False self.is_training = True self.training_progress = TrainingProgress( is_training = True, status_message = "Initializing MLX training...", ) self.training_thread = threading.Thread( target = self._run_training_thread, args = (config, event_queue, stop_queue), daemon = True, ) self._pump_thread = threading.Thread( target = self._pump_events, args = (event_queue, self.training_thread), daemon = True, ) self.training_thread.start() self._pump_thread.start() return True def _build_worker_config(self, training_args: dict[str, Any]) -> dict[str, Any]: peft = { "use_lora": True, "lora_r": 16, "lora_alpha": 16, "lora_dropout": 0.0, "target_modules": None, "gradient_checkpointing": "unsloth", "use_rslora": False, "use_loftq": False, "finetune_vision_layers": True, "finetune_language_layers": True, "finetune_attention_modules": True, "finetune_mlp_modules": True, **self._peft_config, } output_dir = training_args.get("output_dir") if output_dir: output_dir = os.path.abspath(os.path.expanduser(str(output_dir))) values = { **self._model_config, **self._dataset_config, **training_args, "training_type": ( "Continued Pretraining" if self.is_cpt else "LoRA/QLoRA" if peft["use_lora"] else "Full Finetuning" ), **peft, "output_dir": output_dir, "allow_external_output_dir": bool(output_dir), } config = _build_training_worker_config(values) config["resolved_gpu_ids"] = None config["gpu_selection"] = None return config def _run_training_thread( self, config: dict[str, Any], event_queue: queue.Queue, stop_queue: queue.Queue ): try: self._run_mlx_worker(config, event_queue, stop_queue) except Exception as exc: if event_queue is not None: event_queue.put( { "type": "error", "error": str(exc), "stack": traceback.format_exc(limit = 20), "ts": time.time(), } ) def _run_mlx_worker( self, config: dict[str, Any], event_queue: queue.Queue, stop_queue: queue.Queue ): from .worker import run_mlx_training_process run_mlx_training_process( event_queue = event_queue, stop_queue = stop_queue, config = config, ) def _pump_events(self, event_queue: queue.Queue, training_thread: threading.Thread): while True: event = None try: event = event_queue.get(timeout = 0.25) except queue.Empty: pass if event is not None: self._handle_event(event) continue if not training_thread.is_alive(): self._drain_events(event_queue) with self._lock: if self.training_progress.is_training: self.training_progress.is_training = False if self.should_stop: self.training_progress.status_message = "Training stopped." elif ( not self.training_progress.error and not self.training_progress.is_completed ): self.training_progress.error = "Training process exited unexpectedly" self.is_training = False self._event_queue = None self._stop_queue = None return def _drain_events(self, event_queue: Optional[queue.Queue] = None): event_queue = event_queue or self._event_queue if event_queue is None: return while True: try: self._handle_event(event_queue.get_nowait()) except queue.Empty: return def _handle_event(self, event: dict[str, Any]): etype = event.get("type") if etype == "status": self._update_progress( status_message = event.get("status_message") or event.get("message") or "" ) return if etype == "progress": self._update_progress( step = event.get("step", self.training_progress.step), epoch = event.get("epoch", self.training_progress.epoch), loss = event.get("loss", self.training_progress.loss), learning_rate = event.get("learning_rate", self.training_progress.learning_rate), total_steps = event.get("total_steps", self.training_progress.total_steps), elapsed_seconds = event.get( "elapsed_seconds", self.training_progress.elapsed_seconds, ), eta_seconds = event.get("eta_seconds", self.training_progress.eta_seconds), grad_norm = event.get("grad_norm", self.training_progress.grad_norm), num_tokens = event.get("num_tokens", self.training_progress.num_tokens), eval_loss = event.get("eval_loss", self.training_progress.eval_loss), peak_memory_gb = event.get("peak_memory_gb", self.training_progress.peak_memory_gb), ) return if etype == "complete": status_message = event.get("status_message") or "Training completed" output_dir = event.get("output_dir") was_cancelled = self.should_stop or status_message.strip().lower() in { "training cancelled", "training stopped", } self.output_dir = output_dir self._update_progress( is_training = False, is_completed = not was_cancelled, error = None, status_message = status_message, output_dir = output_dir, ) self.is_training = False return if etype == "error": self._update_progress( is_training = False, is_completed = False, error = event.get("error") or event.get("message") or "Training failed", ) self.is_training = False return def stop_training(self, save: bool = True): self.should_stop = True self.save_on_stop = bool(save) if self._stop_queue is not None: self._stop_queue.put({"type": "stop", "save": save}) status_message = ( "Stopping training and saving checkpoint..." if save else "Cancelling training..." ) self._update_progress(status_message = status_message) return True def get_training_progress(self) -> TrainingProgress: pump_thread = self._pump_thread training_thread = self.training_thread if ( pump_thread is not None and pump_thread.is_alive() and (training_thread is None or not training_thread.is_alive()) and threading.current_thread() is not pump_thread ): pump_thread.join(timeout = 5.0) if pump_thread is None or not pump_thread.is_alive(): self._drain_events() with self._lock: return replace(self.training_progress) def create_mlx_trainer_adapter(*args, **kwargs): return _MLXTrainerAdapter(*args, **kwargs) class TrainingBackend: """ Training orchestration backend — subprocess-based. Launches a fresh subprocess per job, communicates via mp.Queue. """ FLUSH_THRESHOLD: int = 10 def __init__(self): # Subprocess state self._proc: Optional[mp.Process] = None self._event_queue: Any = None self._stop_queue: Any = None self._pump_thread: Optional[threading.Thread] = None # True while a pump thread should be running; cleared on intended exits. # Left True after an abnormal death so _ensure_pump_alive spots a crash. self._pump_running: bool = False self._lock = threading.Lock() # Progress state (updated by pump thread from subprocess events) self._progress = TrainingProgress() self._should_stop = False self._cancel_requested = False # True only for stop(save=False) # Training metrics (consumed by routes for SSE and /metrics) self.loss_history: list = [] self.lr_history: list = [] self.step_history: list = [] self.grad_norm_history: list = [] self.grad_norm_step_history: list = [] self.eval_loss_history: list = [] self.eval_step_history: list = [] self.eval_enabled: bool = False self.current_theme: str = "light" # Job metadata self.current_job_id: Optional[str] = None self._output_dir: Optional[str] = None # DB persistence self._metric_buffer: list[dict] = [] self._run_finalized: bool = False self._db_run_created: bool = False self._db_total_steps_set: bool = False self._db_config: Optional[dict] = None self._db_started_at: Optional[str] = None # Xet -> HTTP model-load fallback state (config kept for the respawn). self._last_full_config: Optional[dict] = None self._in_model_load: bool = False self._xet_fallback_used: bool = False self._needs_xet_respawn: bool = False logger.info("TrainingBackend initialized (subprocess mode)") # ------------------------------------------------------------------ # Public API (called by routes/training.py) # ------------------------------------------------------------------ def start_training( self, job_id: str, *, before_spawn = None, **kwargs, ) -> bool: """Spawn a subprocess to run the full training pipeline. All kwargs are serialized into a config dict and sent to the worker. Returns True if the subprocess started successfully. ``before_spawn`` is an optional no-arg callable run after synchronous validation (start guards, config build, explicit gpu_ids) passes but before VRAM-dependent auto GPU-selection and the spawn -- used to free VRAM (e.g. unload chat) without tearing it down on a refused start, while still letting auto-selection place training against the freed memory. Hook failures never block the start. """ with self._lock: if self._proc is not None and self._proc.is_alive(): logger.warning("Training subprocess already running") return False # Join prior pump thread — refuse to start if it won't die if self._pump_thread is not None and self._pump_thread.is_alive(): self._pump_thread.join(timeout = 5.0) if self._pump_thread.is_alive(): logger.warning("Previous pump thread did not exit within 5s — refusing to start") return False self._pump_thread = None # Clear a stale crash flag from a prior died pump so the watchdog can't # treat this fresh setup as a recoverable death. self._pump_running = False config = _build_training_worker_config(kwargs) # Split GPU validation from placement around the VRAM hook: # * Explicit gpu_ids are validated here (raises -> the route returns 400 # before any teardown) and their placement is VRAM-independent, so it # stays correct after the hook frees memory. # * Auto-selection ranks GPUs by *free* VRAM, so it is deferred until # after the hook frees export/chat -- otherwise it could pin training # onto a GPU the hook is about to clear (and onto a kept chat model). from utils.hardware import hardware as _hw gpu_ids = kwargs.get("gpu_ids") gpu_selection_kwargs = dict( model_name = config["model_name"], hf_token = config["hf_token"] or None, training_type = config["training_type"], load_in_4bit = config["load_in_4bit"], batch_size = config.get("batch_size", 4), max_seq_length = config.get("max_seq_length", 2048), lora_rank = config.get("lora_r", 16), target_modules = config.get("target_modules"), gradient_checkpointing = config.get("gradient_checkpointing", "unsloth"), optimizer = config.get("optim", "adamw_8bit"), ) defer_auto_selection = False if should_use_mlx_training_backend(device = _hw.DEVICE): config["resolved_gpu_ids"] = None config["gpu_selection"] = None elif gpu_ids: resolved_gpu_ids, gpu_selection = prepare_gpu_selection(gpu_ids, **gpu_selection_kwargs) config["resolved_gpu_ids"] = resolved_gpu_ids config["gpu_selection"] = gpu_selection else: defer_auto_selection = True # Synchronous validation passed -> free VRAM (export + chat) now, before # auto-selection and the spawn, so placement sees the freed memory. if before_spawn is not None: try: before_spawn() except Exception: logger.warning("before_spawn hook failed; continuing", exc_info = True) if defer_auto_selection: resolved_gpu_ids, gpu_selection = prepare_gpu_selection(None, **gpu_selection_kwargs) config["resolved_gpu_ids"] = resolved_gpu_ids config["gpu_selection"] = gpu_selection from .worker import run_training_process try: with native_path_secret_removed_for_child_start(): event_queue = _CTX.Queue() stop_queue = _CTX.Queue() proc = _CTX.Process( target = run_without_native_path_secret, args = (run_training_process,), kwargs = { "event_queue": event_queue, "stop_queue": stop_queue, "config": config, }, daemon = True, ) proc.start() from utils.process_lifetime import adopt_pid adopt_pid(proc.pid) # bind to parent lifetime (Windows job / sweep) except Exception: logger.error("Failed to start training subprocess", exc_info = True) return False logger.info("Training subprocess started (pid=%s)", proc.pid) # Reset state (old pump thread dead, proc.start() succeeded). self.current_job_id = job_id self._should_stop = False self._cancel_requested = False self._progress = TrainingProgress( is_training = True, status_message = "Initializing training..." ) self.loss_history.clear() self.lr_history.clear() self.step_history.clear() self.grad_norm_history.clear() self.grad_norm_step_history.clear() self.eval_loss_history.clear() self.eval_step_history.clear() self.eval_enabled = False self._output_dir = None self._metric_buffer.clear() self._run_finalized = False self._db_run_created = False self._db_total_steps_set = False self._db_config = _sanitize_db_config(config) self._db_started_at = datetime.now(timezone.utc).isoformat() # Start each job Xet-first; keep config so a stall can respawn over HTTP. self._last_full_config = config self._in_model_load = False self._xet_fallback_used = False self._needs_xet_respawn = False # Create the DB run row before the pump can consume events, so it appears # in history during model loading and a fast terminal worker can't race the # pump into a duplicate create/finalize. From here the pump only finalizes. self._ensure_db_run_created() # Assign handles and start the pump together under the lock so a concurrent # poll can't see a live _proc with no pump and spawn a duplicate. new_pump = threading.Thread(target = self._pump_loop, daemon = True) with self._lock: self._pump_running = False self._event_queue = event_queue self._stop_queue = stop_queue self._proc = proc self._pump_thread = new_pump new_pump.start() return True def stop_training(self, save: bool = True) -> bool: """Send stop signal to the training subprocess.""" self._should_stop = True if not save: self._cancel_requested = True with self._lock: if self._stop_queue is not None: try: self._stop_queue.put({"type": "stop", "save": save}) except (OSError, ValueError): pass # Update progress immediately for responsive UI. self._progress.status_message = ( "Stopping training and saving checkpoint..." if save else "Cancelling training..." ) return True def force_terminate(self) -> None: """Force-kill the training subprocess so state can be reset immediately.""" with self._lock: if self._proc is not None and self._proc.is_alive(): logger.info("Force-terminating training subprocess (pid=%s)", self._proc.pid) self._proc.terminate() proc = self._proc cancelled = self._cancel_requested output_dir = self._output_dir if proc is not None: proc.join(timeout = 5.0) if proc.is_alive(): proc.kill() proc.join(timeout = 2.0) # Wait for pump thread to finish DB finalization (8s covers SQLite's 5s lock timeout). if self._pump_thread is not None and self._pump_thread.is_alive(): self._pump_thread.join(timeout = 8.0) if cancelled and output_dir: try: _cleanup_cancelled_checkpoints(output_dir) except Exception: logger.exception( "Failed to clean up cancelled-run checkpoints under %s", output_dir, ) def _handle_stall_event(self, event: dict) -> None: """A worker reported a no-progress download stall. On the first model-load, terminate the worker so the pump loop respawns it over HTTP. A later stall (already on HTTP, or outside model-load) surfaces as an error instead. """ msg = event.get("message", "Download stalled") with self._lock: recover = self._in_model_load and not self._xet_fallback_used proc = self._proc if recover: self._xet_fallback_used = True self._needs_xet_respawn = True self._progress.status_message = ( "Model download stalled on Xet; retrying over HTTP..." ) else: self._progress.error = self._progress.error or ( "Model download stalled even over HTTP -- check your network connection" ) if recover: logger.warning("Training model-load stalled on Xet; respawning over HTTP: %s", msg) else: logger.error("Training download stalled with no further fallback: %s", msg) # Terminate either way so the pump loop proceeds (respawn or finalize). if proc is not None and proc.is_alive(): proc.terminate() def _respawn_worker_disable_xet(self) -> None: """Respawn the worker once with HF_HUB_DISABLE_XET=1 after a model-load stall. Runs on the exiting pump thread, reaps the terminated worker, and starts a fresh worker + pump. DB/progress run-state is preserved so the history row is not duplicated; the new worker re-formats and loads over HTTP. """ config = self._last_full_config if config is None: logger.error("Cannot respawn training worker: no stored config") return with self._lock: old_proc = self._proc if old_proc is not None: old_proc.join(timeout = 5.0) if old_proc.is_alive(): old_proc.kill() old_proc.join(timeout = 2.0) config = {**config, "disable_xet": True} self._last_full_config = config logger.warning("Respawning training worker with HF_HUB_DISABLE_XET=1 after Xet stall") from .worker import run_training_process try: with native_path_secret_removed_for_child_start(): event_queue = _CTX.Queue() stop_queue = _CTX.Queue() new_proc = _CTX.Process( target = run_without_native_path_secret, args = (run_training_process,), kwargs = { "event_queue": event_queue, "stop_queue": stop_queue, "config": config, }, daemon = True, ) new_proc.start() from utils.process_lifetime import adopt_pid adopt_pid(new_proc.pid) # bind to parent lifetime (Windows job / sweep) except Exception: logger.error("Failed to respawn training subprocess", exc_info = True) with self._lock: # No replacement pump will run; clear the flag so a later run can't # inherit a stale _pump_running=True and spawn a duplicate. self._pump_running = False self._progress.is_training = False self._progress.error = "Failed to recover stalled model download" self._ensure_db_run_created() self._finalize_run_in_db( status = "error", error_message = "Failed to recover stalled model download", ) return logger.info("Training subprocess respawned with Xet disabled (pid=%s)", new_proc.pid) new_pump = threading.Thread(target = self._pump_loop, daemon = True) with self._lock: self._in_model_load = False self._event_queue = event_queue self._stop_queue = stop_queue self._proc = new_proc self._pump_thread = new_pump # Start under the lock so _ensure_pump_alive can never observe the # new pump as a not-yet-started (dead) thread and spawn a duplicate. new_pump.start() def _ensure_pump_alive(self) -> bool: """Restart the event pump if it crashed, even after the worker exited. Defence in depth behind _pump_loop's guards. _pump_running stays True only after an abnormal exit (the loop clears it on intended exits), so a True flag plus a dead thread is an unambiguous crash. Restarts even after worker exit so a fresh pump can drain the terminal events and finalize; otherwise the run looks stuck "running" forever. Returns True if restarted. """ with self._lock: if not self._pump_running: return False # A restarted pump needs the worker handle and queue to drain/finalize; # their absence means nothing is left to recover. if self._proc is None or self._event_queue is None: return False if self._pump_thread is not None and self._pump_thread.is_alive(): return False logger.error( "Training event pump thread died while the worker is still running; " "restarting it so progress updates resume." ) new_pump = threading.Thread(target = self._pump_loop, daemon = True) self._pump_thread = new_pump # Start under the lock so a concurrent _ensure_pump_alive can't see # this thread as not-yet-started and spawn yet another pump. new_pump.start() return True def is_training_active(self) -> bool: """Check if training is currently active.""" # Self-heal a crashed pump first: a dead pump must never leave the worker # training invisibly behind a frozen UI. Cheap enough for per-second polls. self._ensure_pump_alive() with self._lock: if self._proc is not None and self._proc.is_alive(): return True if self._should_stop: return False p = self._progress if p.is_training: return True if p.is_completed or p.error: return False # Infer activity from the status message. status_lower = (p.status_message or "").lower() if any( k in status_lower for k in [ "cancelled", "canceled", "stopped", "completed", "ready to train", ] ): return False if any( k in status_lower for k in [ "loading", "preparing", "training", "configuring", "tokenizing", "starting", "importing", ] ): return True return False def get_training_status(self, theme: str = "light") -> Tuple: """Get current training status and loss plot.""" with self._lock: progress = self._progress if not (progress.is_training or progress.is_completed or progress.error): return (None, progress) plot = self._create_loss_plot(progress, theme) return (plot, progress) def refresh_plot_for_theme(self, theme: str) -> "Optional[plt.Figure]": """Refresh plot with new theme.""" if theme and isinstance(theme, str) and theme in ["light", "dark"]: self.current_theme = theme if self.loss_history: with self._lock: progress = self._progress return self._create_loss_plot(progress, self.current_theme) return None # ------------------------------------------------------------------ # Compatibility shims — routes/training.py accesses these # ------------------------------------------------------------------ class _TrainerShim: """Minimal shim so routes that access backend.trainer.* still work.""" def __init__(self, backend: "TrainingBackend"): self._backend = backend self.should_stop = False @property def training_progress(self): return self._backend._progress @training_progress.setter def training_progress(self, value): self._backend._progress = value def get_training_progress(self): return self._backend._progress def _update_progress(self, **kwargs): with self._backend._lock: for key, value in kwargs.items(): if hasattr(self._backend._progress, key): setattr(self._backend._progress, key, value) @property def trainer(self): """Compatibility shim for routes that access backend.trainer.*""" return self._TrainerShim(self) # ------------------------------------------------------------------ # Event pump (background thread) # ------------------------------------------------------------------ def _safe_handle_event(self, event: dict) -> None: """Apply one event, swallowing any handler error. The pump is the only writer of the progress state every status surface reads, so a malformed event must never propagate and kill it. """ try: self._handle_event(event) except Exception: etype = event.get("type") if isinstance(event, dict) else type(event).__name__ logger.exception("Training event pump: failed to handle %s event; skipping", etype) def _pump_loop(self) -> None: """Background thread: consume subprocess events and update state. Sole writer of the in-memory progress state that /progress, /status, /metrics and DB history read. If it exited while the worker still ran, the run would burn GPU with events piling up while every surface froze. So no single bad event or transient queue/DB error may end it; it returns only through intended exits (worker gone, respawn handed off, finalized). """ self._pump_running = True while True: if self._proc is None or self._event_queue is None: self._pump_running = False return try: event = self._read_queue(self._event_queue, timeout_sec = 0.25) except Exception: # If a read keeps raising after the worker died, fall through to # finalize instead of spinning; only retry while the worker lives. logger.exception("Training event pump: queue read failed; continuing") if self._proc is not None and self._proc.is_alive(): time.sleep(0.1) continue event = None if event is not None: self._safe_handle_event(event) continue if self._proc.is_alive(): continue # Worker exited. Drain the backlog and finalize, guarded so a slow or # failing DB write can't strand the thread; we return either way. try: for e in self._drain_queue(self._event_queue): self._safe_handle_event(e) # Model-load stall: respawn over HTTP instead of finalizing as failure. # Starts a fresh pump on this thread (no self-join); it takes over # _pump_running, so this exit leaves the flag set. if self._needs_xet_respawn: self._needs_xet_respawn = False self._respawn_worker_disable_xet() return # Mark done if no explicit complete/error was received. with self._lock: if self._progress.is_training: if self._should_stop: self._progress.is_training = False self._progress.status_message = "Training stopped." else: self._progress.is_training = False self._progress.error = ( self._progress.error or "Training process exited unexpectedly" ) self._ensure_db_run_created() self._finalize_run_in_db( status = "stopped" if self._should_stop else "error", error_message = None if self._should_stop else "Training process terminated unexpectedly", ) except Exception: logger.exception("Training event pump: finalization after worker exit failed") self._pump_running = False return def _handle_event(self, event: dict) -> None: """Apply a subprocess event to local state. State updates happen inside self._lock; DB I/O happens after releasing it so status-polling endpoints aren't blocked by slow SQLite writes. """ etype = event.get("type") db_action: Optional[str] = None db_action_kwargs: dict = {} # Model-load lifecycle + stall recovery (no DB metrics); handled first. if etype == "model_load_started": with self._lock: self._in_model_load = True return if etype == "model_load_completed": with self._lock: self._in_model_load = False return if etype == "stall": self._handle_stall_event(event) return with self._lock: if etype == "progress": self._progress.step = event.get("step", self._progress.step) self._progress.epoch = event.get("epoch", self._progress.epoch) # loss/lr sanitized below. _raw_loss = event.get("loss") _raw_lr = event.get("learning_rate") try: _safe_loss = float(_raw_loss) if _raw_loss is not None else None except (TypeError, ValueError): logger.debug("Could not convert loss to float: %s", _raw_loss) _safe_loss = None _loss_is_nonfinite = _safe_loss is not None and not math.isfinite(_safe_loss) if _loss_is_nonfinite: # Drop the value rather than laundering it back to the last # finite loss; clients see loss=None at this step so the NaN # is not hidden behind a stale value. Training continues. _safe_loss = None if not getattr(self._progress, "_nonfinite_loss_warned", False): self._progress._nonfinite_loss_warned = True logger.warning( "Training produced non-finite loss at step %s; " "loss field will report null until it recovers.", event.get("step", "?"), ) try: _safe_lr = float(_raw_lr) if _raw_lr is not None else None except (TypeError, ValueError): logger.debug("Could not convert learning_rate to float: %s", _raw_lr) _safe_lr = None if _safe_lr is not None and not math.isfinite(_safe_lr): _safe_lr = None if _safe_loss is not None: self._progress.loss = _safe_loss elif _loss_is_nonfinite: # Clear stale finite loss so the API doesn't keep # reporting the last good value while NaN is happening. self._progress.loss = None if _safe_lr is not None: self._progress.learning_rate = _safe_lr self._progress.total_steps = event.get("total_steps", self._progress.total_steps) self._progress.elapsed_seconds = event.get("elapsed_seconds") self._progress.eta_seconds = event.get("eta_seconds") self._progress.grad_norm = event.get("grad_norm") self._progress.num_tokens = event.get("num_tokens") self._progress.eval_loss = event.get("eval_loss") _peak = event.get("peak_memory_gb") if _peak is not None: try: self._progress.peak_memory_gb = float(_peak) except (TypeError, ValueError): pass self._progress.is_training = True status = event.get("status_message", "") if status: self._progress.status_message = status # Update metric histories using sanitized values. step = event.get("step", 0) loss = _safe_loss lr = _safe_lr if step > 0 and loss is not None: self.loss_history.append(loss) self.lr_history.append(lr if lr is not None else 0.0) self.step_history.append(step) grad_norm = event.get("grad_norm") gn = None if grad_norm is not None: try: gn = float(grad_norm) except (TypeError, ValueError): gn = None if step > 0 and gn is not None and math.isfinite(gn): self.grad_norm_history.append(gn) self.grad_norm_step_history.append(step) else: gn = None eval_loss = event.get("eval_loss") if eval_loss is not None: try: eval_loss = float(eval_loss) except (TypeError, ValueError): logger.debug("Could not convert eval_loss to float: %s", eval_loss) eval_loss = None if step > 0 and eval_loss is not None and math.isfinite(eval_loss): self.eval_loss_history.append(eval_loss) self.eval_step_history.append(step) self.eval_enabled = True else: eval_loss = None # Buffer metric for DB flush. self._metric_buffer.append( { "step": step, "loss": loss, "learning_rate": lr, "grad_norm": gn, "eval_loss": eval_loss, "epoch": event.get("epoch"), "num_tokens": event.get("num_tokens"), "elapsed_seconds": event.get("elapsed_seconds"), } ) # Pick the DB action to run after releasing the lock. if not self._db_run_created and self.current_job_id and self._db_config: db_action = "create_run" db_action_kwargs = { "job_id": self.current_job_id, "model_name": self._db_config["model_name"], "dataset_name": self._db_config.get("hf_dataset") or next(iter(self._db_config.get("local_datasets") or []), "unknown"), "config_json": _json.dumps(self._db_config), "started_at": self._db_started_at or datetime.now(timezone.utc).isoformat(), "total_steps": event.get("total_steps"), } elif ( event.get("total_steps") and self._db_run_created and not self._db_total_steps_set ): db_action = "update_total_steps" db_action_kwargs = { "job_id": self.current_job_id, "total_steps": event["total_steps"], } elif len(self._metric_buffer) >= self.FLUSH_THRESHOLD: db_action = "flush" elif etype == "eval_configured": self.eval_enabled = True elif etype == "status": self._progress.status_message = event.get("message", "") self._progress.is_training = True elif etype == "complete": msg = event.get("status_message", "Training completed") stopped = self._should_stop or msg.strip().lower() in { "training cancelled", "training stopped", } self._progress.is_training = False self._progress.is_completed = not stopped self._output_dir = event.get("output_dir") self._progress.output_dir = self._output_dir self._progress.status_message = msg if not self._db_run_created and self.current_job_id and self._db_config: db_action = "create_and_finalize" else: db_action = "finalize" db_action_kwargs = { "status": "stopped" if stopped else "completed", "output_dir": self._output_dir, } elif etype == "error": self._progress.is_training = False self._progress.error = event.get("error", "Unknown error") logger.error("Training error: %s", event.get("error")) stack = event.get("stack", "") if stack: logger.error("Stack trace:\n%s", stack) if not self._db_run_created and self.current_job_id and self._db_config: db_action = "create_and_finalize" else: db_action = "finalize" db_action_kwargs = { "status": "stopped" if self._should_stop else "error", "error_message": event.get("error", "Unknown error"), } # --- DB I/O outside the lock --- if db_action == "create_run": try: from storage.studio_db import create_run create_run( id = db_action_kwargs["job_id"], model_name = db_action_kwargs["model_name"], dataset_name = db_action_kwargs["dataset_name"], config_json = db_action_kwargs["config_json"], started_at = db_action_kwargs["started_at"], total_steps = db_action_kwargs["total_steps"], ) self._db_run_created = True if db_action_kwargs["total_steps"]: self._db_total_steps_set = True except Exception: logger.warning("Failed to create DB run record", exc_info = True) elif db_action == "create_and_finalize": self._ensure_db_run_created() self._finalize_run_in_db(**db_action_kwargs) elif db_action == "update_total_steps": try: from storage.studio_db import update_run_total_steps update_run_total_steps(db_action_kwargs["job_id"], db_action_kwargs["total_steps"]) self._db_total_steps_set = True except Exception: logger.warning("Failed to update total_steps in DB", exc_info = True) elif db_action == "flush": self._flush_metrics_to_db() elif db_action == "finalize": self._finalize_run_in_db(**db_action_kwargs) def _ensure_db_run_created(self) -> None: """Create the DB row if it doesn't exist yet. Called outside the lock.""" if self._db_run_created or not self.current_job_id or not self._db_config: return try: from storage.studio_db import create_run dataset_name = ( self._db_config.get("hf_dataset") or next(iter(self._db_config.get("local_datasets") or []), None) or _s3_dataset_name(self._db_config.get("s3_dataset")) or "unknown" ) create_run( id = self.current_job_id, model_name = self._db_config["model_name"], dataset_name = dataset_name, config_json = _json.dumps(self._db_config), started_at = self._db_started_at or datetime.now(timezone.utc).isoformat(), total_steps = self._progress.total_steps or None, ) self._db_run_created = True except Exception: logger.warning("Failed to create DB run record for early failure", exc_info = True) def _finalize_run_in_db( self, status: str, error_message: Optional[str] = None, output_dir: Optional[str] = None, ) -> None: """Flush remaining metrics and mark a run as finished in the DB.""" if not self.current_job_id or not self._db_run_created or self._run_finalized: return self._flush_metrics_to_db() try: from storage.studio_db import finish_run from utils.downsample import downsample sparkline = downsample(self.loss_history, 50) finish_run( id = self.current_job_id, status = status, ended_at = datetime.now(timezone.utc).isoformat(), final_step = self._progress.step, final_loss = self._progress.loss if (self._progress.loss is not None and math.isfinite(self._progress.loss)) else None, duration_seconds = self._progress.elapsed_seconds, loss_sparkline = _json.dumps(sparkline), output_dir = output_dir, error_message = error_message, ) self._run_finalized = True except Exception: logger.warning("Failed to finalize run in DB (status=%s)", status, exc_info = True) def _flush_metrics_to_db(self) -> None: """Flush buffered metrics to the database and update live progress.""" if not self._metric_buffer or not self.current_job_id or not self._db_run_created: return # Cap buffer to bound memory growth. if len(self._metric_buffer) > 500: logger.warning( "Metric buffer exceeded 500 entries (%d) — trimming oldest", len(self._metric_buffer), ) self._metric_buffer = self._metric_buffer[-500:] # Snapshot before insert so metrics arriving during the write survive. batch = list(self._metric_buffer) try: from storage.studio_db import insert_metrics_batch, update_run_progress insert_metrics_batch(self.current_job_id, batch) del self._metric_buffer[: len(batch)] update_run_progress( id = self.current_job_id, step = self._progress.step, loss = self._progress.loss if (self._progress.loss is not None and math.isfinite(self._progress.loss)) else None, duration_seconds = self._progress.elapsed_seconds, ) except Exception: # Leave buffer intact for retry on next flush logger.warning("Failed to flush metrics to DB", exc_info = True) @staticmethod def _read_queue(q: Any, timeout_sec: float) -> Optional[dict]: try: return q.get(timeout = timeout_sec) except queue.Empty: return None except (EOFError, OSError, ValueError): # A closed/broken queue reads as "no event"; any other error is left to # _pump_loop's guarded block, which logs and backs off. return None @staticmethod def _drain_queue(q: Any) -> list: events = [] while True: try: events.append(q.get_nowait()) except queue.Empty: return events except Exception: # A drain error must not abort finalization: return what we have so # the run finalizes rather than wedging "active" behind a dead worker. logger.exception( "Training event pump: queue drain failed; finalizing with drained events" ) return events # ------------------------------------------------------------------ # Plot generation # ------------------------------------------------------------------ def _create_loss_plot( self, progress: TrainingProgress, theme: str = "light", ) -> "Optional[plt.Figure]": """Create training loss plot with theme-aware styling. matplotlib is loaded lazily; returns None if it is unavailable. """ plt = _load_pyplot() if plt is None: return None plt.close("all") LIGHT_STYLE = { "facecolor": "#ffffff", "grid_color": "#d1d5db", "line": "#16b88a", "text": "#1f2937", "empty_text": "#6b7280", } DARK_STYLE = { "facecolor": "#292929", "grid_color": "#404040", "line": "#4ade80", "text": "#e5e7eb", "empty_text": "#9ca3af", } style = LIGHT_STYLE if theme == "light" else DARK_STYLE fig, ax = plt.subplots(figsize = (PLOT_WIDTH, PLOT_HEIGHT)) fig.patch.set_facecolor(style["facecolor"]) ax.set_facecolor(style["facecolor"]) if self.loss_history: steps = self.step_history losses = self.loss_history scatter_color = "#60a5fa" ax.scatter( steps, losses, s = 16, alpha = 0.6, color = scatter_color, linewidths = 0, label = "Training Loss (raw)", ) MA_WINDOW = 20 window = min(MA_WINDOW, len(losses)) if window >= 2: cumsum = [0.0] for v in losses: cumsum.append(cumsum[-1] + float(v)) ma = [] for i in range(len(losses)): start = max(0, i - window + 1) denom = i - start + 1 ma.append((cumsum[i + 1] - cumsum[start]) / denom) ax.plot( steps, ma, color = style["line"], linewidth = 2.5, alpha = 0.95, label = f"Moving Avg ({ma[-1]:.4f})", ) leg = ax.legend(frameon = False, fontsize = 9) for t in leg.get_texts(): t.set_color(style["text"]) ax.set_xlabel("Steps", fontsize = 10, color = style["text"]) ax.set_ylabel("Loss", fontsize = 10, color = style["text"]) if progress.error: title = f"Error: {progress.error}" elif progress.is_completed: loss_str = f"{progress.loss:.4f}" if progress.loss is not None else "--" title = f"Training completed! Final loss: {loss_str}" elif progress.status_message: title = progress.status_message elif progress.step > 0: loss_str = f"{progress.loss:.4f}" if progress.loss is not None else "--" title = f"Epoch: {progress.epoch} | Step: {progress.step}/{progress.total_steps} | Loss: {loss_str}" else: title = "Training Loss" ax.set_title(title, fontsize = 11, fontweight = "bold", pad = 10, color = style["text"]) ax.grid(True, alpha = 0.4, linestyle = "--", color = style["grid_color"]) ax.tick_params(colors = style["text"], which = "both") ax.spines["top"].set_visible(False) ax.spines["right"].set_visible(False) ax.spines["bottom"].set_color(style["text"]) ax.spines["left"].set_color(style["text"]) else: display_msg = ( progress.status_message if progress.status_message else "Waiting for training data..." ) ax.text( 0.5, 0.5, display_msg, ha = "center", va = "center", fontsize = 16, color = style["empty_text"], transform = ax.transAxes, ) ax.set_xticks([]) ax.set_yticks([]) for spine in ax.spines.values(): spine.set_visible(False) fig.tight_layout() return fig def _transfer_to_inference_backend(self) -> bool: """Transfer model to inference backend. No-op: with subprocess training the model is freed on exit, so inference must load from the saved checkpoint on disk. """ logger.info( "_transfer_to_inference_backend: subprocess training — " "model must be loaded from disk (output_dir=%s)", self._output_dir, ) return False # ========== GLOBAL INSTANCE ========== _training_backend = None def get_training_backend() -> TrainingBackend: """Get global training backend instance""" global _training_backend if _training_backend is None: _training_backend = TrainingBackend() return _training_backend