"""On-GPU fine-tuning worker (RunPod or Vast.ai). Modes: sft | rl. This module runs on the provisioned GPU (RunPod or Vast.ai) launched by the selected ``autoslm.providers`` backend. It uses the shared recipe (``autoslm.engine.recipe``) so SFT targets and RL rewards are rendered and scored consistently. Artifacts (adapter, metrics.json, heartbeat.json, checkpoints) are streamed to a Hugging Face dataset repo. HF checkpoints give preemption resilience: if a worker is recycled mid-run we resume from the latest uploaded checkpoint. Metrics are also returned directly to the caller by the launching provider. Core environment variables (set by the launching provider / runner): RUN_MODE sft|rl SEED int HF_REPO Hugging Face dataset repo for artifacts, populated per-run from the JobSpec's [train] hf_repo by whichever provider launches the worker HUGGINGFACE_TOKEN RUN_ID unique id for this run (namespacing in the repo) The AUTOSLM_*/RL_*/SFT_* env vars are A/B overrides documented at their use sites; the JobSpec [train] table is the source of truth for per-run knobs. """ from __future__ import annotations import contextlib import json import os import random import sys import threading import time import traceback from autoslm.engine.accounting import RunMetrics # Shared, substrate-neutral fine-tuning internals (live in this same package). from autoslm.engine.recipe import RECIPE from autoslm.envs.registry import load_environment from autoslm.spec import load_job_spec_from_env HF_REPO = os.environ.get("HF_REPO", "") RUN_ID = os.environ.get("RUN_ID", "local") SEED = int(os.environ.get("SEED", "0")) RUN_MODE = os.environ.get("RUN_MODE", "sft") JOB_SPEC = load_job_spec_from_env() # PHASE is the stable artifact namespace (sft|rl) and matches RUN_MODE for a train run. PHASE = os.environ.get( "PHASE", JOB_SPEC.phase if JOB_SPEC else (RUN_MODE if RUN_MODE in ("sft", "rl") else "sft"), ) def _load_active_env(): """Load the run's verifiers environment from the JobSpec; require an explicit env. There is no default/builtin environment (verifiers-only): a run MUST name a verifiers/ Prime Hub env id. Failing here (instead of falling back to some default) prevents a paid worker from training/evaluating the wrong task. """ if JOB_SPEC is None: # No JobSpec at all (e.g. the module imported for a non-run path / a unit test). There # is nothing to select; defer the hard requirement to the JobSpec-present branch so the # module stays importable. A real run always carries a JobSpec. return None env_id = JOB_SPEC.environment.id if not env_id: # Every supported algorithm (sft/grpo) trains/evaluates against a verifiers env, so a # missing env is always a misconfigured spec. Fail loudly rather than fall back to a # default and burn a paid worker on the wrong task. raise RuntimeError( "JobSpec sets no environment: provide [environment] id (a verifiers/Prime Hub " "slug, e.g. 'owner/name')." ) return load_environment(env_id, JOB_SPEC.environment.params) ACTIVE_ENV = _load_active_env() def require_active_env(): """Return the run's loaded environment, or raise a CLEAR error when there is none. ``ACTIVE_ENV`` is None on the no-JobSpec path (the module is imported with no AUTOSLM_JOB_SPEC_JSON/PATH, e.g. a misconfigured worker launch). Every train/eval consumer needs a real env; without this guard the first ``ACTIVE_ENV.`` access dies with an opaque ``AttributeError: 'NoneType' object has no attribute ...``. Fail loudly with an actionable message instead — mirrors the explicit RuntimeError raised when a JobSpec is present but names no environment. """ if ACTIVE_ENV is None: raise RuntimeError( "no environment is loaded: this worker was started without a JobSpec " "(AUTOSLM_JOB_SPEC_JSON / AUTOSLM_JOB_SPEC_PATH is unset). A train/eval run must " "carry a JobSpec naming [environment] id (a verifiers/Prime Hub slug, e.g. " "'owner/name')." ) return ACTIVE_ENV # Thinking/reasoning mode: one flag per run, consumed identically by SFT rendering, # RL rollouts, and serving. The env fallback serves the bench/no-JobSpec path. THINKING = ( JOB_SPEC.thinking if JOB_SPEC else os.environ.get("AUTOSLM_THINKING", "0") not in ("0", "false", "False") ) # --------------------------------------------------------------------------- # HF helpers (code-delivery + artifact channel; works without inbound network) # --------------------------------------------------------------------------- def error_artifact_name(mode: str) -> str: """Per-mode error filename (e.g. error_sft.txt) so a run's traceback is uploaded under a stable name even though heartbeat.json is single-file/overwritten.""" return f"error_{mode}.txt" def hf_api(): from huggingface_hub import HfApi return HfApi(token=os.environ.get("HUGGINGFACE_TOKEN")) def hf_prefix() -> str: return f"{PHASE}/{RUN_ID}/seed{SEED}" def _hf_upload(do_upload, repo_subpath: str, required: bool, label: str) -> None: """Shared HF upload loop for files/folders: HF_REPO guard + retry/raise-or-warn. ``required=True`` (completion artifacts DONE/metrics.json, the trained adapter) retries and finally raises: a swallowed upload failure would make the control plane mark a finished run failed/retried, or mark the run done while deployment can never download the missing adapter. Optional artifacts (generations, logs) only warn. """ if not HF_REPO: return attempts = 3 if required else 1 for attempt in range(attempts): try: do_upload() return except Exception as e: if required and attempt + 1 < attempts: print(f"{label} retry {attempt + 1}/{attempts}: {e}") time.sleep(5 * (attempt + 1)) continue if required: raise RuntimeError(f"required upload of {repo_subpath!r} failed: {e}") from e print(f"{label} warn:", e) return def hf_upload_file(local_path: str, repo_subpath: str, required: bool = False): """Upload one file to the run's HF prefix.""" _hf_upload( lambda: hf_api().upload_file( path_or_fileobj=local_path, path_in_repo=f"{hf_prefix()}/{repo_subpath}", repo_id=HF_REPO, repo_type="dataset", ), repo_subpath, required, "hf_upload_file", ) def hf_upload_folder(local_dir: str, repo_subpath: str, required: bool = False): """Upload a folder to the run's HF prefix.""" _hf_upload( lambda: hf_api().upload_folder( folder_path=local_dir, path_in_repo=f"{hf_prefix()}/{repo_subpath}", repo_id=HF_REPO, repo_type="dataset", ), repo_subpath, required, "hf_upload_folder", ) def hf_resume_checkpoint() -> str | None: """Latest streamed trainer checkpoint for this run (or None). Checkpoints are uploaded DURING the run by ``make_checkpoint_upload_callback`` as ``/checkpoint/checkpoint-/``; a replacement worker downloads the newest one so a mid-run preemption costs at most one save interval. """ if not HF_REPO: return None try: from huggingface_hub import snapshot_download snapshot_download( repo_id=HF_REPO, repo_type="dataset", allow_patterns=[f"{hf_prefix()}/checkpoint/**"], local_dir="/tmp/resume", token=os.environ.get("HUGGINGFACE_TOKEN"), ) base = os.path.join("/tmp/resume", hf_prefix(), "checkpoint") if not os.path.isdir(base): return None cands = [d for d in os.listdir(base) if d.startswith("checkpoint-")] if not cands: return None latest = max(cands, key=lambda d: int(d.split("-")[-1])) path = os.path.join(base, latest) print(f"[resume] found streamed checkpoint: {path}") return path except Exception as e: print("hf_resume_checkpoint warn:", e) return None def prefetch_model(model_id: str) -> float: """Pull the model weights into the local HF cache up front; return seconds spent. The trainer/vLLM would download lazily anyway — doing it explicitly (a) makes the download a first-class, timed stage in the heartbeat stream (the cold-start metric the speed work optimizes), and (b) fails fast with a clear disk/network error instead of dying inside trainer construction. Idempotent: a warm cache costs ~0 s. """ from huggingface_hub import snapshot_download t0 = time.time() try: snapshot_download( repo_id=model_id, # weights + tokenizer/config only (same exclusions as the image bake) ignore_patterns=["*.pth", "*.gguf", "original/*", "*.onnx", "*.msgpack", "*.h5"], ) except Exception as e: # Surface but don't fail here: gated/local-only models still load fine through # the normal from_pretrained path the trainer uses next. print("prefetch_model warn:", e) secs = round(time.time() - t0, 1) heartbeat( "model_prefetched", model=model_id, download_seconds=secs, hf_transfer=os.environ.get("HF_HUB_ENABLE_HF_TRANSFER", ""), ) return secs def make_checkpoint_upload_callback(): """Stream each trainer save to HF so preemption loses <= one save interval. Uploads run in a background thread (the train loop never blocks on the network); older checkpoints are deleted in the same commit. If an upload is still in flight when the next save fires, the new save is skipped (the following one catches up). """ import threading from transformers import TrainerCallback lock = threading.Lock() class _CheckpointUpload(TrainerCallback): def on_save(self, args, state, control, **kwargs): if not HF_REPO: return step = int(state.global_step) ckpt_dir = os.path.join(args.output_dir, f"checkpoint-{step}") if not os.path.isdir(ckpt_dir): return if not lock.acquire(blocking=False): print(f"[ckpt] upload busy; skipping step {step}") return def _upload(): try: hf_api().upload_folder( folder_path=ckpt_dir, path_in_repo=f"{hf_prefix()}/checkpoint/checkpoint-{step}", repo_id=HF_REPO, repo_type="dataset", delete_patterns=[f"{hf_prefix()}/checkpoint/**"], ) heartbeat("checkpoint_uploaded", step=step) except Exception as e: print("ckpt upload warn:", e) finally: lock.release() threading.Thread(target=_upload, daemon=True).start() return _CheckpointUpload() # Heartbeat HF-commit throttle. Each heartbeat() commits heartbeat.json to the HF artifact # repo; committing every training step (the reward callback fires per step) blows HuggingFace's # per-repo commit rate limit (128/hour), especially when several runs share one HF_REPO. Only # the per-step "rl_step" stage is high-frequency, so throttle JUST that one to once per # AUTOSLM_HEARTBEAT_MIN_S (default 60s); every other stage — including milestones and the # terminal done/already_done — always commits so the control plane never misses a transition. # The local file + stdout line are always written regardless. _HB_LAST_UPLOAD = 0.0 _HB_MIN_INTERVAL_S = float(os.environ.get("AUTOSLM_HEARTBEAT_MIN_S", "60")) _HB_THROTTLED_STAGES = frozenset({"rl_step"}) # Terminal transitions the control plane must never miss — always committed. _HB_TERMINAL_STAGES = frozenset({"done", "already_done"}) # Benchmark/fan-out mode: when many runs share one HF artifact repo, even the # per-milestone commits sum past HuggingFace's 128-commits/hour repo cap and # 429-fail the terminal metrics.json upload. Setting AUTOSLM_HEARTBEAT_TERMINAL_ONLY=1 # throttles EVERY non-terminal stage (not just rl_step) so each run costs ~1-2 # commits; terminal done/already_done/error_* still always commit. # Opt-IN flag (default off): use an explicit truthy allow-list so only intentional enables count # ("off"/"no"/typos stay OFF) — the inverse not-in-falsy form would wrongly enable on "off"/"no". _HB_TERMINAL_ONLY = os.environ.get("AUTOSLM_HEARTBEAT_TERMINAL_ONLY", "0").strip().lower() in ( "1", "true", "yes", "on", ) # Even in terminal-only mode, emit a SLOW heartbeat at this cadence so the control plane's stall # detector (poll_vast_job stall_after_s, default 1500s) keeps seeing progress through a long # training phase and doesn't false-stall the run. 600s -> ~6 commits/hr, far under the 128/hr cap. _HB_TERMINAL_ONLY_INTERVAL_S = 600.0 # Serializes heartbeat.json writes and _HB_LAST_UPLOAD reads/updates. During GRPO, # heartbeat() is called concurrently from the trainer thread (reward callback) and the # checkpoint-upload daemon thread; without this lock two writers can interleave and # truncate/garble heartbeat.json (and race _HB_LAST_UPLOAD). _HB_LOCK = threading.Lock() # Serializes the actual HF upload (a slow network commit) SEPARATELY from _HB_LOCK so the # trainer's frequent local writes never block on the network. Without it, two heartbeat # threads can upload heartbeat.json concurrently: a slower upload could land AFTER a newer # one on HF (reorder), so this lock makes uploads strictly ordered. _HB_UPLOAD_LOCK = threading.Lock() def heartbeat(stage: str, **kw): global _HB_LAST_UPLOAD payload = { "stage": stage, "ts": time.time(), "run_id": RUN_ID, "mode": RUN_MODE, "seed": SEED, **kw, } os.makedirs("/tmp/hb", exist_ok=True) p = "/tmp/hb/heartbeat.json" # _HB_LOCK guards ONLY the fast local work (atomic write + _HB_LAST_UPLOAD + snapshot capture); # the slow HF commit runs OUTSIDE it so the trainer's per-step reward callback never blocks on # the network behind the checkpoint daemon's commit (a GRPO perf regression). with _HB_LOCK: # Atomic write: temp file + os.replace() so a concurrent reader never sees a partial file. tmp = p + f".{os.getpid()}.{threading.get_ident()}.tmp" snapshot = json.dumps(payload) with open(tmp, "w") as f: f.write(snapshot) os.replace(tmp, p) now = time.time() if stage in _HB_TERMINAL_STAGES or stage.startswith("error_"): upload_due = True # never miss a terminal transition elif _HB_TERMINAL_ONLY: # Benchmark fan-out: keep commits far under the 128/hour cap, but still emit a SLOW # heartbeat (~every _HB_TERMINAL_ONLY_INTERVAL_S) so the control-plane stall detector # sees progress during a long training phase and doesn't false-stall the run. upload_due = ( _HB_LAST_UPLOAD == 0.0 or (now - _HB_LAST_UPLOAD) >= _HB_TERMINAL_ONLY_INTERVAL_S ) else: throttled = stage in _HB_THROTTLED_STAGES upload_due = not throttled or (now - _HB_LAST_UPLOAD) >= _HB_MIN_INTERVAL_S if upload_due: _HB_LAST_UPLOAD = now # claim the slot under the lock (throttle stays atomic) if upload_due: # Serialize the network commit under a SEPARATE lock so uploads can't reorder, and # upload the captured snapshot (via a private temp file, since hf_upload_file takes # a path) rather than re-reading p — which a newer heartbeat may already have # overwritten between our slot-claim and this upload. with _HB_UPLOAD_LOCK: up = p + f".{os.getpid()}.{threading.get_ident()}.upload.tmp" with open(up, "w") as f: f.write(snapshot) try: hf_upload_file(up, "heartbeat.json") finally: with contextlib.suppress(OSError): os.remove(up) print("HEARTBEAT", json.dumps(payload)) # --------------------------------------------------------------------------- # Decoding parity: render with the model's own chat template and one run-wide thinking # flag (off by default), so SFT targets and RL rollouts use identical prompt # formatting within a run. # --------------------------------------------------------------------------- def render_prompt(tokenizer, item) -> str: item = item if isinstance(item, dict) else {"question": item} msgs = require_active_env().prompt_messages(item) return tokenizer.apply_chat_template( msgs, tokenize=False, add_generation_prompt=True, enable_thinking=THINKING ) def strip_think(completion: str | None) -> str | None: """Drop ... reasoning before the environment grades/rewards a thinking-mode completion. - closed block(s): keep only the text after the LAST . This also covers always-thinking templates that pre-open inside the generation prompt, whose completions contain with no opening tag. - unclosed (completion budget exhausted): keep only the pre-think text (usually empty), so answer extraction fails and the completion scores 0 — deliberate reward pressure to close thinking within budget, and it keeps a last-number fallback from matching numbers inside the reasoning. - no tags: unchanged. """ if completion is None: return None if "" in completion: return completion.rsplit("", 1)[1] if "" in completion: return completion.split("", 1)[0] return completion def graded_text(completion: str | None) -> str | None: """What the env grader/reward sees: thinking runs strip blocks first (a completion whose reasoning never closes grades 0 — see strip_think). Applied once here, before ACTIVE_ENV.grade/reward, so it works for every environment.""" return strip_think(completion) if THINKING else completion def _patch_peft_weight_converter_compat() -> None: """peft 0.19.1 x transformers 5.6-5.10: make MoE adapter loading work. peft's ``build_peft_weight_mapping`` reconstructs transformers ``WeightConverter`` objects passing ``distributed_operation=`` / ``quantization_operation=`` — kwargs the WeightConverter in transformers <5.11 doesn't accept (init=False dataclass fields), so loading a LoRA adapter onto any arch WITH weight conversions dies with ``TypeError: unexpected keyword argument 'distributed_operation'`` (observed on a weight-converting checkpoint eval). The worker can't take transformers>=5.11 (vllm 0.19.1 compat), so accept-and-drop unknown kwargs; on a single GPU those fields are unused. No-op once signatures match. """ import inspect try: from transformers import core_model_loading as cml except Exception: # pragma: no cover - older stacks have no converter module return converter = getattr(cml, "WeightConverter", None) if converter is None or getattr(converter, "_autoslm_compat", False): return accepted = set(inspect.signature(converter.__init__).parameters) if "distributed_operation" in accepted: return orig_init = converter.__init__ def _compat_init(self, *args, **kwargs): dropped = [k for k in kwargs if k not in accepted] for k in dropped: kwargs.pop(k) orig_init(self, *args, **kwargs) converter.__init__ = _compat_init converter._autoslm_compat = True print("[compat] WeightConverter patched (peft<->transformers signature drift)") # --------------------------------------------------------------------------- # SFT # --------------------------------------------------------------------------- # Module-path segments that must never receive LoRA on natively-multimodal checkpoints # trained text-only: the vision tower / projector / MTP head. Critically, adapters that # DO touch them cannot be loaded by vLLM in text-only (language_model_only) serving — # its LoRA loader rejects "unexpected modules" (observed with Qwen3.5-2B). _VL_EXCLUDE_SEGMENTS = ("visual", "vision_tower", "multi_modal_projector", "mtp") def lora_exclude_modules(model_id: str) -> str | None: """Regex (peft fullmatch semantics) excluding vision-tower modules from LoRA. Returns None when no exclusion is needed (pure text architectures). NOTE: peft's list-form exclude_modules uses suffix matching (like target_modules), which does NOT match leaf modules under 'visual.*' — a regex string is required. """ excludes = { "qwen3_5": _VL_EXCLUDE_SEGMENTS, "qwen3_5_moe": _VL_EXCLUDE_SEGMENTS, "qwen3_6": _VL_EXCLUDE_SEGMENTS, } try: from transformers import AutoConfig cfg = AutoConfig.from_pretrained(model_id, trust_remote_code=True) model_type = getattr(cfg, "model_type", "") or "" except Exception as e: print("lora_exclude_modules: config probe failed:", e) return None segments = excludes.get(model_type) if not segments: return None alt = "|".join(segments) return rf"(^|.*\.)({alt})(\..*|$)" def is_vl_checkpoint(model_id: str) -> bool: """True for natively-multimodal checkpoints we train/serve text-only (Qwen3.5/3.6).""" return bool(lora_exclude_modules(model_id)) def vllm_language_model_only_kwargs(model_id: str) -> dict: """Engine kwargs to skip the vision tower for VL checkpoints (vLLM >= 0.19). Besides wasting VRAM, the vision tower's attention path hardcodes vLLM's bundled flash-attn, whose PTX needs a newer driver JIT than many RTX 5090 hosts have ("PTX compiled with unsupported toolchain") — text-only loading sidesteps it and is the officially supported way to run Qwen3.5 as a pure LLM. """ return {"language_model_only": True} if is_vl_checkpoint(model_id) else {} def _attn_impl_for_capability(major: int, minor: int) -> str | None: """Map a CUDA compute capability to the trainer ``attn_implementation``. Attention uses PyTorch SDPA (its flash/efficient backend is already selected automatically on Ampere/Ada/Hopper) — the HF Kernels-Hub FA path is disabled because the torch2.10- compatible ``kernels`` versions break transformers' import. So: sm120 (Blackwell consumer 5090/RTX Pro) -> "sdpa" (forced to the cuDNN backend at train time — its default SDPA can fall to the slow math kernel); all other archs -> None (let transformers pick SDPA, which already flash-backs on Ampere/Ada/Hopper). The big LoRA win comes from the Liger fused kernels, not the attention path. Pure function (no torch) so it's unit-testable on CPU; override the whole thing with AUTOSLM_ATTN_IMPL. """ if major == 12: # Blackwell consumer: force cuDNN SDPA (avoid the math fallback) return "sdpa" return None def _flash_attn_available() -> bool: """True when the ``flash_attn`` wheel is importable (our worker image builds it from source). Gates the packing default: TRL's ``packing_strategy='bfd'`` produces flattened/padding-free batches whose example boundaries are carried by ``position_ids`` and enforced ONLY by an attention impl that honors them (FlashAttention-2 varlen / flex_attention). Under plain SDPA, packed examples attend ACROSS boundaries (silent quality loss). find_spec only — no import side effects (and no CUDA init).""" try: import importlib.util return importlib.util.find_spec("flash_attn") is not None except Exception: return False def _flex_packing_enabled() -> bool: """Opt-in flex_attention packing (default OFF). The no-flash-attn path to boundary-correct example packing on torch 2.10, where flash-attn has no prebuilt wheel.""" return os.environ.get("AUTOSLM_FLEX_PACKING", "0") not in ("0", "false", "False", "") def _flex_attention_available() -> bool: """True when torch's native flex_attention is importable (torch>=2.5; we're on 2.10).""" try: import importlib.util return importlib.util.find_spec("torch.nn.attention.flex_attention") is not None except Exception: return False def _flex_arch_supported(model_id: str) -> bool: """True only when transformers can dispatch this model through flex_attention. MEASURED: transformers 5.12 raises ``Qwen3_5ForConditionalGeneration does not support an attention implementation through torch's flex_attention`` for the whole Qwen3.5/3.6 catalog (the arch isn't wired for flex). So flex-packing would CRASH the run there. We probe the model class's ``_supports_flex_attn`` flag from its config (no weights download); on any uncertainty return False so flex-packing safely no-ops rather than killing a paid run.""" try: from transformers import AutoConfig from transformers.models.auto.modeling_auto import ( MODEL_FOR_CAUSAL_LM_MAPPING, ) cfg = AutoConfig.from_pretrained(model_id, trust_remote_code=True) cls = MODEL_FOR_CAUSAL_LM_MAPPING.get(type(cfg)) return bool(cls is not None and getattr(cls, "_supports_flex_attn", False)) except Exception as e: print(f"[sft] flex arch probe inconclusive ({e}); treating as unsupported") return False def flex_packing_collator(base_collator, fixed_len: int, pad_token_id: int): """Wrap TRL's padding-free collator so packed batches carry the group-id document mask that transformers' flex_attention path needs (it builds ``document_ids`` from a 2D attention mask). TRL ``packing='bfd'`` auto-enables padding_free: each batch is ONE flattened sequence whose ``position_ids`` reset to 0 at every example boundary. We derive the group id per token as ``(position_ids == 0).cumsum`` (-> 1,1,1,2,2,3,...) and expose it AS ``attention_mask`` so ``make_flex_block_causal_mask`` separates documents (``document_ids[q]==document_ids[kv]``). Also PADS every batch to a FIXED total length so flex's BlockMask doesn't recompile on each distinct packed length (pytorch#136196). Pad tokens get group id 0, which flex's padding_mask (``attention_mask_2d > 0``) excludes, and label -100 so they don't contribute to the loss. """ import torch as _torch def _collate(features): batch = base_collator(features) pos = batch.get("position_ids") if pos is None: # not the padding-free/packed path — nothing to do return batch # group ids: bump at every position_ids==0 (document start). 1-based so pad (0) is distinct. group = (pos == 0).long().cumsum(dim=-1) cur = pos.shape[-1] if cur < fixed_len: paddings = fixed_len - cur z = (pos.shape[0], paddings) batch["input_ids"] = _torch.cat( [batch["input_ids"], _torch.full(z, pad_token_id, dtype=batch["input_ids"].dtype)], dim=-1, ) if "labels" in batch: batch["labels"] = _torch.cat( [batch["labels"], _torch.full(z, -100, dtype=batch["labels"].dtype)], dim=-1 ) pos = _torch.cat([pos, _torch.zeros(z, dtype=pos.dtype)], dim=-1) group = _torch.cat([group, _torch.zeros(z, dtype=group.dtype)], dim=-1) # pad -> id 0 batch["position_ids"] = pos elif cur > fixed_len: # truncate the rare over-long pack to keep shapes static batch["input_ids"] = batch["input_ids"][..., :fixed_len] if "labels" in batch: batch["labels"] = batch["labels"][..., :fixed_len] batch["position_ids"] = pos[..., :fixed_len] group = group[..., :fixed_len] batch["attention_mask"] = group # group-id mask; flex reads it as document_ids return batch return _collate def optimal_attn_impl() -> str | None: """Best ``attn_implementation`` for the live GPU (None = leave transformers' default). Overridable with ``AUTOSLM_ATTN_IMPL``; "", "0", "false" all force-disable the override (use transformers' default) — never pass "0" through as a literal impl name. """ forced = os.environ.get("AUTOSLM_ATTN_IMPL") if forced is not None: return forced if forced not in ("", "0", "false", "False") else None try: import torch if not torch.cuda.is_available(): return None major, minor = torch.cuda.get_device_capability(0) except Exception as e: print("optimal_attn_impl probe failed:", e) return None impl = _attn_impl_for_capability(major, minor) if impl: print(f"[attn] sm{major}{minor} -> attn_implementation={impl}") return impl # Liger's fused linear cross-entropy is a MEMORY optimization (it never materializes the fp32 # [B,T,vocab] logits), not a fixed-batch speed win. PR #174 ledger: on a 1B model at fixed batch # it is a measured NET LOSS on EVERY arch (min-of-3: A100 0.86x, H100 0.90x, RTX 3090 0.78x, # RTX 4090 0.83x, RTX 5090 0.79x) — the per-step Triton overhead isn't repaid because the small # model's logits don't dominate memory. Its value appears on LARGE models (lets a bigger batch # fit / avoids OOM). So gate by estimated model size. _LIGER_MIN_PARAMS = 3e9 # ~3B; 1B-class models measured net-negative -> Liger off below this def _estimate_params(cfg) -> float: """Rough param count from a HF config: embeddings (+untied lm_head) + transformer blocks. For multimodal checkpoints (e.g. Qwen3.5-VL) the LM dims live under ``text_config`` — read it when the top-level dims are absent, else the gate underestimates and wrongly disables the memory path (GC/Liger) for the 4B/9B tiers.""" tc = getattr(cfg, "text_config", None) src = cfg if getattr(cfg, "hidden_size", 0) else (tc or cfg) h = getattr(src, "hidden_size", 0) or 0 v = getattr(src, "vocab_size", 0) or getattr(cfg, "vocab_size", 0) or 0 n = getattr(src, "num_hidden_layers", 0) or 0 tied = getattr(src, "tie_word_embeddings", getattr(cfg, "tie_word_embeddings", False)) emb = v * h * (1 if tied else 2) blocks = n * 12 * h * h # ~12 h^2 per transformer block (attn + MLP) return float(emb + blocks) def _liger_default_for_model(model_id: str) -> bool: """Default Liger ON only for models large enough that fused-CE's memory win pays off (≥ AUTOSLM_LIGER_MIN_PARAMS, ~3B). 1B-class models measured net-negative -> default OFF.""" try: from transformers import AutoConfig cfg = AutoConfig.from_pretrained(model_id, trust_remote_code=True) return _estimate_params(cfg) >= _LIGER_MIN_PARAMS except Exception as e: print("liger model-size probe failed (default off):", e) return False def liger_on(default_on: bool) -> bool: """Whether to enable a Liger kernel path. ``default_on`` is the model-size decision (on only for models large enough that fused-CE's memory win pays off; 1B-class is a measured net loss). Even when on, require a CUDA GPU AND that ``liger_kernel`` is importable — the local ``autoslm-train[gpu]`` extra doesn't ship it, so blindly setting use_liger_kernel would crash a local GPU run. No GPU / absent -> off.""" if not default_on: return False try: import importlib.util import torch return bool( torch.cuda.is_available() and importlib.util.find_spec("liger_kernel") is not None ) except Exception: return False def setup_perf_backends() -> None: """Universal, arch-agnostic throughput knobs — safe on every CUDA arch, no JIT/compile cost. - TF32 for fp32 matmuls/cuDNN (Ampere+): the residual fp32 ops in a bf16 LoRA run (some norms, the optimizer's fp32 master step, any fp32 GEMM) run on the TF32 tensor cores at ~no accuracy cost. No-op on pre-Ampere. """ try: import torch if not torch.cuda.is_available(): return torch.set_float32_matmul_precision("high") # TF32 for fp32 matmuls torch.backends.cuda.matmul.allow_tf32 = True torch.backends.cudnn.allow_tf32 = True print("[perf] TF32 matmul/cuDNN enabled") except Exception as e: print("setup_perf_backends skipped:", e) def maybe_regional_compile(model, phase: str = "sft") -> int: """Lever 2 (opt-in, default OFF): REGIONAL torch.compile of the repeated decoder block. Returns the number of layers compiled (0 = no-op / disabled / skipped). Why regional, not full-graph: full-graph ``torch.compile`` traces the WHOLE model into one graph, which graph-breaks and CRASHES on our stack — PEFT LoRA wrappers plus the Qwen Gated-DeltaNet / flash-linear-attention custom ops are not capturable as a single graph (a benchmark on Qwen3.5-4B reproduced an Inductor AssertionError; the full-graph AUTOSLM_TORCH_COMPILE path was removed for this reason). Compiling just ONE repeated unit — each ``model.model.layers[i]`` decoder block — with ``fullgraph=False`` lets Inductor fuse the pointwise/norm/MLP ops INSIDE a block (where most of the steady-state win is) while tolerating graph breaks at the LoRA/fla boundaries, and because all N layers share the same compiled artifact the cold-start cost is ~1 block's compile. Safety: fully guarded. No-op unless AUTOSLM_TORCH_COMPILE_REGIONAL is set; and every step is wrapped in try/except so a compile failure NEVER blocks training (the eager model is used unchanged). ``torch.compile(layer, ...)`` returns an OptimizedModule wrapper that is module-API compatible, so swapping it back into the layer list is transparent to PEFT/TRL. """ if os.environ.get("AUTOSLM_TORCH_COMPILE_REGIONAL") not in ("1", "true", "True"): return 0 try: import torch if not torch.cuda.is_available(): return 0 # Locate the decoder-layer ModuleList. For a PEFT-wrapped causal LM the chain is # model.base_model.model.model.layers; for a plain HF causal LM it's model.model.layers; # VL/text checkpoints nest the LM under .model.language_model.layers. Walk a few known # locations and use the first ``layers`` that looks like an indexable ModuleList of blocks. candidates = [] base = getattr(model, "base_model", None) inner = getattr(base, "model", None) if base is not None else None for root in (inner, model): if root is None: continue m = getattr(root, "model", root) for path in (m, getattr(m, "language_model", None)): if path is None: continue layers = getattr(path, "layers", None) if layers is not None and hasattr(layers, "__len__") and len(layers) > 0: candidates.append(layers) if not candidates: print(f"[{phase}] regional compile: could not locate decoder layers; skipping") return 0 layers = candidates[0] mode = os.environ.get("AUTOSLM_TORCH_COMPILE_REGIONAL_MODE", "default") n = 0 for i in range(len(layers)): try: layers[i] = torch.compile(layers[i], fullgraph=False, mode=mode) n += 1 except Exception as e: # compile one bad layer? keep the rest eager print(f"[{phase}] regional compile: layer {i} failed ({e}); leaving it eager") if n: print( f"[{phase}] regional torch.compile enabled on {n} decoder block(s) " f"(fullgraph=False, mode={mode})" ) return n except Exception as e: # never block training on the compile wiring print(f"[{phase}] regional compile skipped (error):", e) return 0 def finalize_alloc_conf_for_sleep() -> None: """Sync the CUDA allocator conf with the worker's RESOLVED vLLM sleep default. The launcher (providers/*/train.py build_worker_env) must pick PYTORCH_ALLOC_CONF before this process starts, but it can't always know the GRPO sleep decision: for a small model with RL_VLLM_SLEEP unset the worker resolves sleep OFF (the speed default), yet the launcher conservatively assumes sleep ON and picks the non-expandable conf (safe, but fragments a long colocate run). When the launcher cedes the decision (it sets AUTOSLM_ALLOC_AUTO=1 — only when it applied a DEFAULT, never an operator override), we resolve the same sleep default here (we have the model config + GPU) and, if sleep is OFF, switch to expandable_segments — which only crashes WITH sleep on, a case we've just ruled out. PYTORCH_ALLOC_CONF is read lazily at the first CUDA allocation, so this must run before any allocation (it does — called at boot).""" if os.environ.get("AUTOSLM_ALLOC_AUTO") != "1": return try: model_id = os.environ.get("BENCH_HF_MODEL", "") # Resolve the GRPO context the SAME way the sleep gate does (run_rl): RL_VLLM_MAX_LEN OR # [train].max_length. Using only RL_VLLM_MAX_LEN (often unset at boot) would mis-resolve a # long-context run configured via train.max_length -> wrong sleep default -> wrong alloc conf. _spec_len = 0 try: if JOB_SPEC and JOB_SPEC.train and JOB_SPEC.train.max_length: _spec_len = int(JOB_SPEC.train.max_length) except Exception: _spec_len = 0 ctx = int(os.environ.get("RL_VLLM_MAX_LEN") or _spec_len or 0) if not _memory_mode(model_id, ctx): # sleep resolves OFF -> expandable is safe + better conf = "expandable_segments:True" os.environ["PYTORCH_ALLOC_CONF"] = conf os.environ["PYTORCH_CUDA_ALLOC_CONF"] = conf print(f"[alloc] sleep resolves OFF -> {conf} (anti-fragmentation, matches worker gate)") else: print("[alloc] sleep resolves ON -> keeping launcher's non-expandable conf") except Exception as e: print("[alloc] auto-conf skipped:", e) def _remove_fla_from_disk() -> tuple[list[str], bool]: """Physically delete every importable ``fla`` package dir from the worker's REAL sys.path. Loops until ``find_spec('fla')`` is clean (removing one copy can expose another further down the path) and invalidates import caches so transformers' is_fla_available() probe sees it gone. ``pip uninstall`` alone is unreliable here — it targets one site-packages but the base image bakes ``fla`` into another dir on the path (and can report success while leaving the package dir). Returns ``(removed_dirs, still_importable)``. Shared by the AUTOSLM_DISABLE_FLA escape hatch and the Hopper auto-drop. """ import importlib import importlib.util import shutil removed: list[str] = [] for _ in range(6): # a few passes: removing one copy can reveal another earlier on the path importlib.invalidate_caches() spec = importlib.util.find_spec("fla") if spec is None: break # Resolve the package directory (submodule_search_locations for a package, else the file dir). locs = list(getattr(spec, "submodule_search_locations", None) or []) if not locs and spec.origin: locs = [os.path.dirname(spec.origin)] progressed = False for loc in locs: if loc and os.path.isdir(loc) and os.path.basename(loc.rstrip("/")) == "fla": try: shutil.rmtree(loc) removed.append(loc) progressed = True except Exception as e: print(f"[fla] could not remove {loc}: {e}", flush=True) if not progressed: break importlib.invalidate_caches() return removed, importlib.util.find_spec("fla") is not None def disable_fla_if_requested() -> None: """Hopper Gated-DeltaNet escape hatch — remove flash-linear-attention IN the worker process. flash-linear-attention's Triton backward is wrong on H100/H200 (Triton>=3.4, fla #640) and its tilelang fallback aborts in TVM FFI, so Qwen3.5/3.6 Gated-DeltaNet crashes in backward. With AUTOSLM_DISABLE_FLA=1 we make transformers fall back to its native pure-PyTorch delta rule — correct everywhere (slower, but the only working Hopper path). The on-disk removal runs here (not in the bootstrap's `pip uninstall`) because it uses the worker's REAL sys.path; logs land in console_.txt (the bootstrap's own prints do not), so the effect is observable. """ if os.environ.get("AUTOSLM_DISABLE_FLA") not in ("1", "true", "True"): return removed, still = _remove_fla_from_disk() print( f"[fla] AUTOSLM_DISABLE_FLA: removed {removed or 'nothing'}; " f"find_spec('fla') -> {'STILL PRESENT' if still else 'gone (native delta-rule)'}", flush=True, ) # Long-context runs are memory-bound (activations + vLLM KV cache scale with sequence length), so # they need the memory features even on a SMALL model — PR #174 measured a 1B model OOM on GRPO at # 4096 ctx in speed mode, but it fits in memory mode. So "memory mode" = large model OR long ctx. _LONG_CONTEXT_TOKENS = 2048 def _memory_mode(model_id: str, max_length: int = 0) -> bool: """Whether to default the memory-saving features (Liger, grad-checkpointing, vLLM sleep) ON: a large model (fused-CE memory win) OR a long context (activations/KV dominate). Small model + short context -> off (optimize for speed).""" if max_length and max_length >= _LONG_CONTEXT_TOKENS: return True return _liger_default_for_model(model_id) def grad_checkpointing_on(model_id: str, max_length: int = 0) -> bool: """Gradient checkpointing recomputes the forward in backward (~25% slower) to save activation memory — a MEMORY feature, not speed. ON for large models / long context that need the headroom; OFF for small+short runs that fit without it (the speed win).""" return _memory_mode(model_id, max_length) def fused_optim_name(memory_default: bool = False) -> str: """TRL/HF ``optim`` value. Fused foreach AdamW (single-kernel optimizer step) by default. AUTOSLM_OPTIM overrides entirely with any HF optim enum string (e.g. paged_adamw_8bit for QLoRA OOM-spike safety, ademamix / ademamix_8bit for token efficiency) — research-backed A/B levers. ``memory_default``: on the memory-tight paths (QLoRA / colocated GRPO) the default becomes 8-bit paged AdamW (bitsandbytes int8 optimizer state paged to host RAM, so training fits a smaller GPU) instead of the fused-foreach speed default. AUTOSLM_OPTIM still overrides.""" override = os.environ.get("AUTOSLM_OPTIM") if override and override not in ("0", "false", "False"): return override if memory_default: return "paged_adamw_8bit" return "adamw_torch_fused" def wandb_report_to() -> list[str]: """TRL/HF ``report_to`` targets. Restores the W&B logging the legacy freesolo training path had but the autoslm migration dropped: report to W&B when WANDB_API_KEY is present (and not explicitly disabled). No key / WANDB_DISABLED -> [] (silent, the metrics.json artifact is still the source of truth). Sets a default project so runs land in one place.""" if not os.environ.get("WANDB_API_KEY"): return [] if os.environ.get("WANDB_DISABLED") in ("1", "true", "True"): return [] if os.environ.get("WANDB_MODE", "").strip().lower() == "disabled": return [] import importlib.util if importlib.util.find_spec("wandb") is None: print("[wandb] WANDB_API_KEY set but the wandb package is missing; skipping W&B logging") return [] os.environ.setdefault("WANDB_PROJECT", "autoslm") return ["wandb"] def wandb_run_name() -> str: """Stable, human-readable W&B run name tying the dashboard run to the AutoSLM run id.""" return f"autoslm-{PHASE}-{RUN_ID}-seed{SEED}" def wandb_run_info() -> dict: """The live W&B run's {url, id, project} if W&B is active, else {}. Recorded in metrics.json so the W&B run is verifiable + the freesolo agent's `wandb_runs` / the SDK's link_wandb can point at the real dashboard URL — the link the autoslm migration otherwise dropped. Never raises.""" try: import wandb run = getattr(wandb, "run", None) if run is None: return {} return { "wandb_url": getattr(run, "url", None), "wandb_id": getattr(run, "id", None), "wandb_project": getattr(run, "project", None), } except Exception: return {} def _sdpa_cudnn_ctx(attn_impl: str | None): """Context forcing the cuDNN SDPA backend (real Blackwell-consumer kernels) when we fell back to plain SDPA on sm120; a no-op context otherwise. Best-effort.""" if attn_impl != "sdpa": return contextlib.nullcontext() try: from torch.nn.attention import SDPBackend, sdpa_kernel # Priority-ordered: prefer the fast cuDNN/flash/efficient kernels, but ALWAYS include MATH # as the final fallback. Restricting to only [CUDNN, EFFICIENT] makes sm120 GRPO crash with # "RuntimeError: No available kernel" when neither has a kernel for the completion-batch # attention shape (MEASURED: Qwen3.5 GRPO on RTX 5090). MATH is universal, so the candidate # set is never empty; set_priority keeps cuDNN first whenever it CAN serve the shape (SFT # fast path unchanged), only falling through for the shapes cuDNN/efficient reject. return sdpa_kernel( [ SDPBackend.CUDNN_ATTENTION, SDPBackend.FLASH_ATTENTION, SDPBackend.EFFICIENT_ATTENTION, SDPBackend.MATH, ], set_priority=True, ) except Exception as e: print("[attn] cuDNN SDPA backend unavailable, using default SDPA:", e) return contextlib.nullcontext() def patch_vllm_language_model_only(model_id: str) -> bool: """Force ``language_model_only=True`` on vLLM engines created by third-party code (TRL's colocated GRPO rollout engine) for VL checkpoints. Returns True if patched.""" extra = vllm_language_model_only_kwargs(model_id) if not extra: return False try: import vllm if getattr(vllm.LLM.__init__, "_autoslm_lmo_patched", False): return True orig = vllm.LLM.__init__ def patched(self, *args, **kwargs): kwargs.setdefault("language_model_only", True) return orig(self, *args, **kwargs) patched._autoslm_lmo_patched = True vllm.LLM.__init__ = patched print(f"[vllm] language_model_only patch active for {model_id}") return True except Exception as e: print("patch_vllm_language_model_only warn:", e) return False def make_lora(model_id: str | None = None): """LoRA config. We target 'all-linear' (every nn.Linear) rather than a hardcoded q/k/v/o list: it is architecture-agnostic, so the same recipe works for the dense default (Qwen3-4B-Instruct-2507) and for newer models with extra projection types (e.g. the Qwen3.5 hybrid Gated-DeltaNet) without missing any adapters. For natively-multimodal checkpoints the vision tower is excluded (see ``lora_exclude_modules``).""" from peft import LoraConfig # PEFT target_modules accepts the special string "all-linear" OR a LIST of module-name # suffixes. A comma-separated env (e.g. "q_proj,k_proj,v_proj,o_proj" to adapt attention only # and leave the MoE experts frozen) MUST be split into a list — else PEFT treats the whole # string as ONE module name and raises "Target modules ... not found in the base model". _parts = [ t.strip() for t in os.environ.get("LORA_TARGETS", "all-linear").split(",") if t.strip() ] # "all-linear" is a PEFT SPECIAL string, not a module name — keep it as a string (incl. when a # stray trailing comma made it the sole element, e.g. "all-linear," -> ["all-linear"]). Any # real multi-module value becomes a list of suffixes. targets = "all-linear" if (not _parts or _parts == ["all-linear"]) else _parts rank = JOB_SPEC.train.lora_rank if JOB_SPEC else RECIPE.lora.rank alpha = JOB_SPEC.train.lora_alpha if JOB_SPEC else RECIPE.lora.alpha kwargs = { "r": rank, "lora_alpha": alpha, "lora_dropout": RECIPE.lora.dropout, "target_modules": targets, "task_type": "CAUSAL_LM", } # Adapter initialization (convergence lever): AUTOSLM_LORA_INIT picks PEFT's init_lora_weights. # "pissa_niter_16" inits A/B from the base weight's top singular vectors (fast SVD, ~seconds) so # LoRA converges faster + to higher quality than the default zero-B init (arXiv 2404.02948); # "olora"/"eva"/"gaussian" also available. Default unset -> PEFT default (True). NOTE: PiSSA # mutates the effective base, so the saved adapter is a PiSSA-residual unless converted — fine for # our train+eval+serve-same-stack flow; rsLoRA via AUTOSLM_RSLORA=1 helps only at high rank. _init = os.environ.get("AUTOSLM_LORA_INIT") if _init and _init not in ("0", "false", "False"): kwargs["init_lora_weights"] = _init if _init not in ("true", "True", "1") else True print(f"[lora] init_lora_weights={kwargs['init_lora_weights']}") if os.environ.get("AUTOSLM_RSLORA") in ("1", "true", "True"): kwargs["use_rslora"] = True print("[lora] rsLoRA scaling enabled") if model_id and targets == "all-linear": exclude = lora_exclude_modules(model_id) if exclude: kwargs["exclude_modules"] = exclude print(f"[lora] excluding modules for {model_id}: {exclude}") return LoraConfig(**kwargs) def model_quant(model_id: str) -> str: """Quantization tier for this model: catalog entry > AUTOSLM_QUANT env > bf16.""" env_q = os.environ.get("AUTOSLM_QUANT") if env_q: return env_q try: from autoslm.catalog import MODELS info = MODELS.get(model_id) if info is not None: return info.quant except Exception as e: print("model_quant: catalog probe failed:", e) return "bf16" def qlora_model_init_kwargs() -> dict: """Model-load kwargs for the 4-bit QLoRA tier: bf16 compute + a bitsandbytes NF4 (double-quant) config so the frozen base loads in 4-bit and only the LoRA adapter trains.""" import torch from transformers import BitsAndBytesConfig return { "dtype": torch.bfloat16, "quantization_config": BitsAndBytesConfig( load_in_4bit=True, bnb_4bit_compute_dtype=torch.bfloat16, bnb_4bit_quant_type="nf4", bnb_4bit_use_double_quant=True, ), } def require_vllm_for_rollout_func(use_rollout_func: bool, use_vllm: bool, model_id: str) -> None: """Fail fast when a multi-turn GRPO run needs colocated vLLM but it's disabled. The multi-turn rollout closure (``multiturn_rollout.build_rollout_func``) drives generation through ``trainer.vllm_generation.llm``. TRL only creates that engine when ``use_vllm`` is True, so with vLLM disabled (catalog ``grpo_use_vllm=False`` or ``RL_USE_VLLM=0``) the rollout would AttributeError at the first turn. Reject the combination up front with an actionable message instead of crashing deep in training. """ if use_rollout_func and not use_vllm: raise RuntimeError( f"multi-turn GRPO needs colocated vLLM, which is disabled for {model_id} " "(grpo_use_vllm=False / RL_USE_VLLM=0). Use a single-turn environment for this " "model, or a model tier that keeps vLLM enabled for rollouts." ) def run_sft(): from datasets import Dataset from transformers import AutoTokenizer from trl import SFTConfig as TRLSFTConfig from trl import SFTTrainer require_active_env() # fail loudly (not AttributeError: NoneType) on the no-JobSpec path t_start = time.time() heartbeat("sft_start") # SFT only fits the single assistant `sft_target` per row; a multi-turn/ToolEnv env's # tool/env turns are not represented, so SFT on one would silently mis-train (imitating a # collapsed single-turn target). Warn loudly so it is not mistaken for proper multi-turn SFT. if getattr(ACTIVE_ENV, "multi_turn", False): print( "[sft][warn] this is a multi-turn / tool verifiers environment, but SFT only fits " "the single assistant target per row (tool/env turns are ignored). The model will be " "trained on collapsed single-turn targets; multi-turn SFT is not supported. Use a " "single-turn environment, or expect a single-turn-only fit." ) wait_for_gpu() setup_perf_backends() model_id = JOB_SPEC.model if JOB_SPEC else RECIPE.hf_model_id download_seconds = prefetch_model(model_id) tok = AutoTokenizer.from_pretrained(model_id, trust_remote_code=True) if tok.pad_token is None: tok.pad_token = tok.eos_token # Build SFT text dataset (seeded shuffle for reproducibility) train = ACTIVE_ENV.dataset("train") rng = random.Random(SEED) rng.shuffle(train) max_examples = int(os.environ.get("SFT_MAX_EXAMPLES", "0")) if max_examples > 0: train = train[:max_examples] texts = [] for ex in train: msgs = [ *ACTIVE_ENV.prompt_messages(ex), {"role": "assistant", "content": ACTIVE_ENV.sft_target(ex)}, ] texts.append( { "text": tok.apply_chat_template( msgs, tokenize=False, add_generation_prompt=False, enable_thinking=THINKING ) } ) if THINKING and not any("" in t["text"] for t in texts[:256]): print( "WARN: thinking mode is ON but no sampled SFT target contains a " "trace — training on non-reasoning targets teaches the model to SKIP " "thinking. Use a dataset with reasoning traces, or set thinking = false." ) ds = Dataset.from_list(texts) setup_seconds = time.time() - t_start heartbeat("sft_model_load", setup_seconds=setup_seconds) default_epochs = ( JOB_SPEC.train.epochs if JOB_SPEC and JOB_SPEC.train.epochs is not None else RECIPE.sft.num_epochs ) epochs = int(os.environ.get("SFT_EPOCHS", str(default_epochs))) # SDK [train] knobs override the recipe default; an operator env var still wins last. _t = JOB_SPEC.train if JOB_SPEC else None per_device_bs = int(os.environ.get("SFT_PER_DEVICE_BS", "4")) # batch_size is the GLOBAL/effective batch: grad-accum is sized to reach it. Cap the # per-device micro-batch at the target (so a target < per_device doesn't overshoot) and # use CEIL division so the realized global batch is never BELOW the requested one (floor # would undershoot when target isn't a multiple of per_device, e.g. 16/6 -> 12). effective_batch = ( _t.batch_size if _t and _t.batch_size is not None else RECIPE.sft.effective_batch ) per_device_bs = max(1, min(per_device_bs, effective_batch)) grad_accum = max(1, -(-effective_batch // per_device_bs)) sft_lr = _t.learning_rate if _t and _t.learning_rate is not None else RECIPE.sft.learning_rate sft_max_len = ( _t.max_length if _t and _t.max_length is not None else (RECIPE.sft.max_seq_len_thinking if THINKING else RECIPE.sft.max_seq_len) ) sft_save_default = _t.save_every if _t and _t.save_every is not None else 50 out_dir = f"/tmp/sft_seed{SEED}" resume_ckpt = hf_resume_checkpoint() # SFT_MAX_STEPS>0 caps optimizer steps (used by the cheap pre-flight smoke). max_steps = int(os.environ.get("SFT_MAX_STEPS", "0")) cfg_kwargs = { "output_dir": out_dir, "num_train_epochs": epochs, "per_device_train_batch_size": per_device_bs, "gradient_accumulation_steps": grad_accum, "learning_rate": sft_lr, "warmup_ratio": RECIPE.sft.warmup_frac, "logging_steps": 10, "save_steps": int(os.environ.get("SFT_SAVE_STEPS", str(sft_save_default))), "save_total_limit": 1, # Memory-light checkpoints: save ONLY the (small LoRA) model, not the optimizer / # scheduler / RNG state — skips the optimizer-state serialization spike at save and # writes just the adapter. (We don't resume mid-run; seeds restart cleanly.) "save_only_model": True, "max_length": sft_max_len, "bf16": True, "report_to": wandb_report_to(), # W&B when WANDB_API_KEY present (restored post-autoslm-migration) "run_name": wandb_run_name(), # Dataloader parallelism: overlap host-side collation/tokenization with GPU compute so a # real (large) training set isn't dataloader-bound. Pure throughput, zero quality change. # Negligible on the tiny benchmark (pre-tokenized, in-memory); a real win at production # dataset sizes. "dataloader_num_workers": 4, "dataloader_pin_memory": True, "dataloader_persistent_workers": True, "seed": SEED, "gradient_checkpointing": grad_checkpointing_on(model_id, sft_max_len), # Non-reentrant: composes with save_on_cpu activation offload + autograd hooks (verl #3629). "gradient_checkpointing_kwargs": {"use_reentrant": False}, "completion_only_loss": False, # Optimizer: fused foreach AdamW (free single-kernel step) for the speed-default tiers, # 8-bit paged AdamW (int8 state paged to host RAM -> fits a smaller GPU) for the # memory-tight QLoRA tier. AUTOSLM_OPTIM overrides; AUTOSLM_FUSED_OPTIM=0 -> plain adamw_torch. "optim": fused_optim_name(memory_default=model_quant(model_id) == "4bit-qlora"), } if max_steps > 0: cfg_kwargs["max_steps"] = max_steps # Example packing: concatenate short examples into full max_length sequences so a batch isn't # mostly pad tokens — PR #174 measured a 4.4-10.7x SFT speedup (h100 8.2x, 4090 10.7x) because # instruction targets are far shorter than max_seq_len; unpacked batches waste most of their # FLOPs on padding. TRL's 'bfd' strategy makes padding-free batches whose example boundaries are # honored ONLY by an attention impl that reads them — under plain SDPA packed examples # cross-contaminate (silent quality loss). Two correct backends: # - FlashAttention-2 varlen (reads position_ids). FASTEST, but flash-attn has NO prebuilt wheel # for torch 2.10 (PyPI sdist-only; Dao-AILab wheels stop at torch 2.9) so it would build from # source on every cold start (~20 min, fragile) — it is NOT in the worker image. So _fa_ok is # False on the current stack and the FA path is effectively unavailable until flash-attn is # baked into a prebuilt image. # - flex_attention (torch>=2.5 native, no install): boundary-correct via a group-id document # mask. TRL doesn't emit that mask, so we synthesize it from the per-doc-reset position_ids # ((position_ids==0).cumsum) in a collator wrapper below, gated on AUTOSLM_FLEX_PACKING=1. # Default: packing ON when FA2 is importable; else flex-packing when AUTOSLM_FLEX_PACKING=1; else # SKIP (don't silently cross-contaminate). SFT_PACKING=0 disables; SFT_PACKING=1 forces. _packing_env = os.environ.get("SFT_PACKING") _want_packing = (_packing_env or "1") not in ("0", "false", "False") _packing_forced = _packing_env not in (None, "") _fa_ok = _flash_attn_available() _flex_packing = False if _want_packing and _fa_ok: cfg_kwargs["packing"] = True print("[sft] example packing enabled (FA2 varlen; SFT_PACKING=0 to disable)") elif ( _want_packing and _flex_packing_enabled() and _flex_attention_available() and _flex_arch_supported(model_id) ): cfg_kwargs["packing"] = True _flex_packing = True print("[sft] example packing enabled (flex_attention group-mask, no flash-attn needed)") elif ( _want_packing and _flex_packing_enabled() and not _flex_arch_supported(model_id) and not _packing_forced ): # DEFAULT (not explicitly forced): flex requested but the arch can't use flex_attention here # -> skip rather than crash. An explicit SFT_PACKING=1 falls through to the forced branch # below (bfd packing under SDPA, with the cross-contamination warning) — honor the override. print( f"[sft] flex-packing requested but {model_id}'s arch isn't flex_attention-capable in " "this transformers (e.g. Qwen3.5/3.6); skipping packing (would crash). Needs flash-attn." ) elif _want_packing and _packing_forced: cfg_kwargs["packing"] = True print( "[sft] WARNING: packing forced without FA2 or flex — 'bfd' boundaries need varlen/flex; " "examples may cross-contaminate under SDPA. Set AUTOSLM_FLEX_PACKING=1 or SFT_PACKING=0." ) elif _want_packing: print( "[sft] packing SKIPPED: no boundary-correct attn backend (flash-attn absent on torch " "2.10; flex off). Set AUTOSLM_FLEX_PACKING=1 to pack via flex_attention." ) # Liger fused CE/RMSNorm/RoPE kernels (default on for GPU; SFT_LIGER=0 to disable). The # fused linear cross-entropy is the big large-vocab (Qwen ~152k) memory/throughput win. # Skip it when AUTOSLM_CCE=1: Cut Cross-Entropy patches the SAME loss path (post-trainer), # so enabling both would double-patch the LM head — CCE wins the loss, Liger would conflict. from autoslm.engine.cce import cce_will_install if not cce_will_install() and liger_on(_memory_mode(model_id, sft_max_len)): cfg_kwargs["use_liger_kernel"] = True print("[sft] liger fused kernels enabled") _attn = optimal_attn_impl() # arch-aware FlashAttention (Kernels Hub) / SDPA # Packing correctness: 'bfd' packed batches are boundary-correct ONLY under a varlen/flex attn. # With FA2 importable force flash_attention_2 (fastest); else, when flex-packing is on, force # flex_attention (the collator wrap below feeds it the group-id document mask). Either is a pure # win over the SDPA default which would cross-contaminate packed examples. if cfg_kwargs.get("packing") and _fa_ok: _attn = "flash_attention_2" print("[sft] attn_implementation=flash_attention_2 (packing boundary-correct varlen)") elif _flex_packing: _attn = "flex_attention" print("[sft] attn_implementation=flex_attention (packing boundary-correct document mask)") quant = model_quant(model_id) if quant == "4bit-qlora": # QLoRA tier: 4-bit NF4 base + bf16 LoRA adapters (e.g. Qwen3.5-9B on a 5090). _patch_peft_weight_converter_compat() # adapter (re)load, e.g. ckpt resume mik = qlora_model_init_kwargs() print(f"[sft] loading {model_id} in 4-bit (QLoRA tier)") else: # Explicit bf16 + no auto device-map: TRL/transformers-5 string loading can # otherwise fall back to fp32 (2x VRAM; observed 18.6 GB for a 4.66B model) or # accelerate-offload large models to meta ("expected device meta but got # cuda:0" in backward on the 9B). mik = {"dtype": "bfloat16", "device_map": None} if _attn: mik["attn_implementation"] = _attn cfg_kwargs["model_init_kwargs"] = mik # Activation offloading (MEMORY lever, prioritized): TRL moves checkpointed activations to CPU # during the forward and fetches them back in the backward (torchtune OffloadActivations, pinned # + stream-overlapped). Frees activation VRAM so a memory-tight tier (large model / long context) # can fit a bigger batch or longer sequence; ~<1% slowdown when it overlaps compute (only pays off # WITH gradient checkpointing, so gate on the same memory-mode signal). Feature-detected so an # older TRL without the field doesn't crash. AUTOSLM_ACT_OFFLOAD=1/0 overrides the gate. import dataclasses as _dc _sft_fields = {f.name for f in _dc.fields(TRLSFTConfig)} if "activation_offloading" in _sft_fields: _ao_env = os.environ.get("AUTOSLM_ACT_OFFLOAD") _ao = ( _ao_env not in ("0", "false", "False") if _ao_env is not None else (cfg_kwargs.get("gradient_checkpointing") and _memory_mode(model_id, sft_max_len)) ) if _ao: cfg_kwargs["activation_offloading"] = True print("[sft] activation offloading enabled (memory: activations -> CPU)") # NEFTune (arXiv 2310.05914): add uniform noise (scaled by alpha) to the embedding activations # during the forward at TRAIN time only — a free instruction-tuning quality win, removed at # inference so it never affects serving or adds memory. Opt-in via SFT_NEFTUNE_ALPHA (HF/TRL # recommends 5). Feature-detected so an older TRL without the field is simply skipped. _neftune = os.environ.get("SFT_NEFTUNE_ALPHA") if ( _neftune and _neftune not in ("0", "false", "False") and "neftune_noise_alpha" in _sft_fields ): try: cfg_kwargs["neftune_noise_alpha"] = float(_neftune) print(f"[sft] NEFTune embedding noise alpha={_neftune} (train-only quality lever)") except ValueError: print(f"[sft] ignoring non-numeric SFT_NEFTUNE_ALPHA={_neftune!r}") cfg = TRLSFTConfig(**cfg_kwargs) # LoRA+ (convergence lever, arXiv 2402.12354): give the LoRA B matrices a higher LR than A # (ratio AUTOSLM_LORAPLUS_RATIO, ~16). Reported ~2x fewer steps to target at identical per-step # FLOPs. TRL builds the model from a string inside __init__, so the optimizer (which needs the # instantiated params) can't be pre-built — override create_optimizer to construct it from # self.model once it exists. Falls back to the stock fused-AdamW path when the knob is unset. # LoRA+ only when a MEANINGFUL ratio (>1) is set: "0"/"1"/"" are truthy strings but mean "off" # (ratio 1 == plain LoRA), so parse to float and gate on >1 — else a stray "0" would enable a # degenerate B-LR=0 optimizer. try: _lp_ratio = float(os.environ.get("AUTOSLM_LORAPLUS_RATIO") or "0") except ValueError: _lp_ratio = 0.0 _SFT = SFTTrainer if _lp_ratio > 1: class _SFT(SFTTrainer): # local LoRA+ subclass def create_optimizer(self): if self.optimizer is None: try: import torch as _torch from peft.optimizers import create_loraplus_optimizer # PEFT's create_loraplus_optimizer forwards extra kwargs to the optimizer; # the lr keyword name has shifted across PEFT versions, so pass it via # optimizer_kwargs (the stable form) and fall back to a top-level lr=. try: self.optimizer = create_loraplus_optimizer( model=self.model, optimizer_cls=_torch.optim.AdamW, optimizer_kwargs={"lr": self.args.learning_rate}, loraplus_lr_ratio=_lp_ratio, ) except TypeError: self.optimizer = create_loraplus_optimizer( model=self.model, optimizer_cls=_torch.optim.AdamW, lr=self.args.learning_rate, loraplus_lr_ratio=_lp_ratio, ) print(f"[lora+] optimizer enabled (B-matrix LR ratio={_lp_ratio})") return self.optimizer except Exception as e: # never block training on the LoRA+ wiring print("[lora+] setup failed, falling back to default optimizer:", e) return super().create_optimizer() # Pass model as a string id + tokenizer as processing_class so TRL takes the # text/causal-LM path (not the VLM processor path) for this multimodal checkpoint. trainer = _SFT( model=model_id, args=cfg, train_dataset=ds, peft_config=make_lora(model_id), processing_class=tok, callbacks=[make_checkpoint_upload_callback()], ) if _flex_packing: # Feed flex_attention the group-id document mask (TRL's padding-free collator emits only # position_ids). Bucket to a FIXED total length so flex's BlockMask doesn't recompile per # distinct packed length; raise dynamo's cache cap so any residual shape variation doesn't # blow the compile cache (Axolotl uses 256 for exactly this). import torch as _t _t._dynamo.config.accumulated_cache_size_limit = max( 256, _t._dynamo.config.accumulated_cache_size_limit ) _fixed_len = max(1, int(cfg_kwargs.get("max_length") or sft_max_len)) * max( 1, int(cfg_kwargs.get("per_device_train_batch_size") or 1) ) trainer.data_collator = flex_packing_collator( trainer.data_collator, _fixed_len, int(tok.pad_token_id or 0) ) print(f"[sft] flex-packing collator installed (bucketed to {_fixed_len} tokens)") from autoslm.engine.cce import install_cce install_cce(trainer.model) # opt-in Cut Cross-Entropy (AUTOSLM_CCE=1; self-tests) maybe_regional_compile( trainer.model, "sft" ) # opt-in regional torch.compile (Lever 2; default off) t_train = time.time() with _sdpa_cudnn_ctx(_attn): # force cuDNN SDPA on sm120 (no-op otherwise) trainer.train(resume_from_checkpoint=resume_ckpt) train_wall = time.time() - t_train adapter_dir = f"{out_dir}/adapter" trainer.model.save_pretrained(adapter_dir) tok.save_pretrained(adapter_dir) hf_upload_folder(adapter_dir, "adapter", required=True) heartbeat("sft_trained", train_wall=train_wall) # count train tokens train_tokens = int(sum(len(tok(t["text"])["input_ids"]) for t in texts) * epochs) # Write train metadata + the completion sentinel (metrics.json/DONE) for this phase. write_train_meta( phase="sft", adapter_dir=adapter_dir, model_id=model_id, train_wall=train_wall, setup_seconds=setup_seconds, train_tokens=train_tokens, generated_tokens=0, notes={ "epochs": epochs, "resumed": bool(resume_ckpt), "download_seconds": download_seconds, "hf_transfer": os.environ.get("HF_HUB_ENABLE_HF_TRANSFER", ""), "thinking": THINKING, # Persist the loss curve so a CONVERGENCE A/B (PiSSA / LoRA+ init, etc.) is measurable # without a checkpoint: trainer_state.json is only written on a save_step, and the # console is only uploaded on failure, so a short successful run otherwise drops its # loss history entirely. "loss_curve": _metric_curve(trainer, "loss"), **wandb_run_info(), }, ) free_gpu(trainer) # --------------------------------------------------------------------------- # RL (GRPO) with TRL + colocated vLLM # --------------------------------------------------------------------------- def compute_grpo_batching(prompts_per_step: int, group_size: int, per_device_comps: int) -> dict: """Translate an intended ``prompts_per_step`` into a TRL GRPO batch configuration. TRL's GRPO batch sizing is denominated in **completions (prompt-completion pairs), not prompts**. The number of *unique prompts* optimized per step is (per_device_train_batch_size * gradient_accumulation_steps * num_processes) / num_generations So to actually optimize ``prompts_per_step`` prompts per step, the global *completion* batch must equal ``prompts_per_step * group_size``. We keep ``per_device`` small (it, not grad-accum, sets peak VRAM) and put the rest in gradient accumulation. The bug this fixes: ``grad_accum = prompts_per_step // per_device`` treated ``per_device_train_batch_size`` as a *prompt* count, omitting the ``* group_size`` factor, so a run intended as 64 prompts/step actually optimized only ``64 / group_size = 8`` prompts/step (an 8x smaller effective batch). """ import math group_size = max(1, int(group_size)) prompts_per_step = max(1, int(prompts_per_step)) per_device = max(1, int(per_device_comps)) target_comps = prompts_per_step * group_size # total completions / optimizer step # Never let the per-device completion micro-batch exceed the target completion batch: # a small prompts_per_step would otherwise overshoot it (mirrors run_sft's # `min(per_device_bs, effective_batch)`). No-op at the default (prompts_per_step=64). per_device = max(1, min(per_device, target_comps)) grad_accum = max(1, target_comps // per_device) # TRL rejects a global completion batch (per_device * grad_accum) that is not # divisible by num_generations (= group_size), failing only AFTER the paid worker # is provisioned. per_device is the fixed VRAM knob, so round grad_accum UP to the # next multiple that makes the batch divisible (grad_accum must be a multiple of # group_size // gcd(per_device, group_size)). This only ever raises the effective # batch slightly; the common per_device|group_size cases are unchanged. accum_step = group_size // math.gcd(per_device, group_size) grad_accum = ((grad_accum + accum_step - 1) // accum_step) * accum_step generations_per_step = per_device * grad_accum unique_prompts_per_step = generations_per_step // group_size return { "per_device_train_batch_size": per_device, "gradient_accumulation_steps": grad_accum, "generations_per_step": generations_per_step, "unique_prompts_per_step": unique_prompts_per_step, # TRL requires the global completion batch be divisible by num_generations. "divisible_by_group": (generations_per_step % group_size == 0), } def rl_per_device_comps( completion_len: int = 0, vocab: int = 152_000, *, use_vllm: bool = True, params_b: float | None = None, ) -> int: """Per-device *completion* micro-batch for GRPO (TRL counts completions, not prompts). This, not grad-accum, sets peak trainer VRAM: the logprob pass materializes fp32 logits of shape [per_device, completion_len, vocab]. At Qwen's ~152k vocab a long completion is enormous (measured: per_device 8 x 4096 tok x 152k x 4 B = ~20 GiB single alloc -> OOMs a small card). So we MEMORY-CAP per_device to a logits budget (RL_LOGITS_BUDGET_GB, default 6) for the given completion length, then push the difference into grad-accum (compute_grpo_batching) so the effective batch is unchanged. This keeps long-completion GRPO on a cheaper GPU. RL_PER_DEVICE_PROMPTS forces an explicit value. The logits budget is NOT the whole story: the per-device forward also holds the model's attention/activation memory (the Qwen3.5 GDN/FLA kernels peak per micro-batch even with grad checkpointing), which the logits term can't see. Under colocated vLLM (the rollout engine + its card-sized KV pool + a 2nd weight copy share the GPU) that activation peak is what OOMs a small card -- and Liger, which fuses away the logits, does NOT touch it. MEASURED: Qwen3.5-2B (width ~1.41) group8 seq2048 OOMs a 32 GB card at per_device=8 but TRAINS at 4. So for colocate, additionally cap per_device to the live card's VRAM scaled by model width (~sqrt(params)): ~vram_gb/8 at 2B-width, tightened for wider models (4B/9B). """ base = int(os.environ.get("RL_PER_DEVICE_PROMPTS", "2" if THINKING else "8")) if "RL_PER_DEVICE_PROMPTS" in os.environ: # Explicit operator force (A/B knob): bypass BOTH auto-caps -- they own the OOM risk. return max(1, base) if completion_len > 0: budget = float(os.environ.get("RL_LOGITS_BUDGET_GB", "6")) * 1e9 cap = max(1, int(budget / (max(1, completion_len) * vocab * 4))) base = min(base, cap) if use_vllm: try: import torch if torch.cuda.is_available(): vram_gb = torch.cuda.get_device_properties(0).total_memory / (1024**3) width = (max(float(params_b), 0.1) ** 0.5) if params_b else 1.41 act_cap = max(1, int(vram_gb / (7.5 * (width / 1.41)))) base = min(base, act_cap) except Exception as e: print("rl_per_device_comps colocate cap probe failed (keeping logits cap):", e) return max(1, base) def _maybe_activation_offload(trainer) -> None: """verl-inspired SINGLE-GPU activation offload (opt-in: AUTOSLM_ACT_OFFLOAD=1). Wraps the trainer's per-step forward+backward in ``torch.autograd.graph.save_on_cpu`` so the autograd-saved activations live in pinned CPU RAM and are paged back to the GPU only for the backward. This frees a large chunk of VRAM (activations are the seq/batch-scaling term), so a bigger base or a longer context fits ONE GPU -- e.g. a long-context backward that would otherwise overflow the card. It composes with gradient checkpointing (that recomputes; this offloads what's still saved) and with Liger (logits fused away). verl exposes the same idea as ``enable_activation_offload``, but its implementation is bound to the FSDP backend; ``save_on_cpu`` is backend-agnostic and works on a single device -- no sharding, no 2nd GPU. The cost is real: pinned-host<->GPU copies every step (~1.2-2x slower), so it's gated OFF by default and only worth enabling to fit a run that otherwise OOMs. """ # Opt-in: enable ONLY on an explicit truthy value. An empty string / "0" / "false" stays off # (an unset-but-empty env must NOT silently turn it on). if os.environ.get("AUTOSLM_ACT_OFFLOAD", "").strip().lower() not in ("1", "true", "yes", "on"): return import torch if not hasattr(torch.autograd.graph, "save_on_cpu"): print("[offload] save_on_cpu unavailable in this torch; activation offload skipped") return _orig_step = trainer.training_step def _offloaded_step(*args, **kwargs): with torch.autograd.graph.save_on_cpu(pin_memory=True): return _orig_step(*args, **kwargs) trainer.training_step = _offloaded_step print("[offload] activation offload ON (save_on_cpu, pin_memory) -- trades step speed for VRAM") def make_reward_heartbeat_callback(): """A TRL/transformers callback that streams the per-step mean reward to the HF heartbeat channel, giving the worker a live RL signal (no pod log API) and recording a ``reward_history``. Built lazily so the module imports without transformers installed.""" from transformers import TrainerCallback class _RewardHeartbeat(TrainerCallback): def __init__(self): self.reward_history = [] def on_log(self, args, state, control, logs=None, **kwargs): if not logs: return r = logs.get("reward") if r is None: return try: r = float(r) except (TypeError, ValueError): return self.reward_history.append(r) step = int(getattr(state, "global_step", len(self.reward_history))) heartbeat("rl_step", step=step, reward=r, reward_last=self.reward_history[-8:]) return _RewardHeartbeat() def grpo_overrides() -> dict: """The GRPO recipe knobs, read off the job spec's ``[train]`` table (``TrainSpec``). A field left unset (None) is omitted here so the recipe default applies downstream. Knobs: group_size, temperature, max_tokens (completion budget), kl_penalty_coef (the KL beta), advantage_clip (centered-advantage clip), and thinking_length_penalty_coef (a per--token reward deduction). These live in ``[train]`` — NOT in ``[environment.params]``, which is forwarded verbatim to the verifiers env loader.""" if not JOB_SPEC: return {} train = JOB_SPEC.train cfg = { "group_size": train.group_size, "temperature": train.temperature, "max_tokens": train.max_tokens, "kl_penalty_coef": train.kl_penalty_coef, "advantage_clip": train.advantage_clip, "thinking_length_penalty_coef": train.thinking_length_penalty_coef, } return {k: v for k, v in cfg.items() if v is not None} def think_token_count(completion: str | None, tokenizer) -> int: """Number of tokens inside the completion's ... span (0 if none). Used for the thinking-length reward deduction: long reasoning is penalized in proportion to the tokens it spent, mirroring the SDK's thinking_length_penalty_coef. """ if not completion or "" not in completion: return 0 after = completion.split("", 1)[1] think_text = after.split("", 1)[0] if "" in after else after if not think_text: return 0 return len(tokenizer(think_text, add_special_tokens=False)["input_ids"]) def _init_adapter_model(model_id: str): """Base model + the ``train.init_from_adapter`` adapter loaded as a trainable PeftModel, or the plain ``model_id`` string + a fresh LoRA when it is unset. GRPO continuing an SFT adapter: TRL trains the LOADED adapter (peft_config=None) instead of attaching a fresh one.""" prefix = JOB_SPEC.train.init_from_adapter if JOB_SPEC else "" if not prefix: return model_id, make_lora(model_id) adir = _download_adapter(prefix) if not adir: # The user explicitly asked GRPO to continue from this adapter; silently # falling back to a fresh base-model LoRA would spend a full paid run # optimizing the wrong starting point. Fail hard instead. raise RuntimeError( f"train.init_from_adapter={prefix!r} could not be downloaded from the artifact " "store (wrong/missing prefix or no access); refusing to silently start GRPO from " "the base model. Fix the adapter prefix / HF credentials, or omit " "init_from_adapter to train a fresh LoRA." ) from peft import PeftModel from transformers import AutoModelForCausalLM print(f"[init-adapter] initializing LoRA from {prefix}") # 4-bit-QLoRA tier: load the frozen base in NF4 so a continued-adapter GRPO run fits # the same memory budget as a fresh-LoRA one (and TRL still sees Linear4bit modules -> # bitsandbytes vLLM rollout). if model_quant(model_id) == "4bit-qlora": _patch_peft_weight_converter_compat() _attn = optimal_attn_impl() # arch-aware attention on the QLoRA path too _mik = qlora_model_init_kwargs() if _attn: # else leave transformers' default (sdpa) _mik["attn_implementation"] = _attn base = AutoModelForCausalLM.from_pretrained( model_id, trust_remote_code=True, **_mik, ) else: _attn = optimal_attn_impl() base = AutoModelForCausalLM.from_pretrained( model_id, dtype="bfloat16", trust_remote_code=True, **({"attn_implementation": _attn} if _attn else {}), ) model = PeftModel.from_pretrained(base, adir, is_trainable=True) return model, None def _grpo_rmpad_enabled(attn_impl: str | None) -> bool: """Whether to take the GRPO remove-padding / varlen logprob path (Lever 1). Opt-in via AUTOSLM_GRPO_RMPAD=1 (default OFF). The varlen forward flattens the batch and runs FlashAttention with cu_seqlens, which ONLY exists in the FA2/FA3 kernels — SDPA/eager have no varlen entry point — so we require attn_implementation in {flash_attention_2, flash_attention_3}. Anything else (the SDPA default, eager, unset) -> skip with a warning so the run silently falls back to TRL's normal padded logprob path instead of mis-training. """ if os.environ.get("AUTOSLM_GRPO_RMPAD") not in ("1", "true", "True"): return False if attn_impl not in ("flash_attention_2", "flash_attention_3"): print( f"[rl][rmpad] AUTOSLM_GRPO_RMPAD set but attn_implementation={attn_impl!r} is not " "FlashAttention (varlen/cu_seqlens needs FA2/FA3); skipping rmpad, using TRL's " "normal padded logprob path. Set AUTOSLM_ATTN_IMPL=flash_attention_2 to enable." ) return False return True def make_rmpad_grpo_trainer(GRPOTrainer): """Return a GRPOTrainer subclass whose per-token logprob forward is UNPADDED (Lever 1). Context: GRPO scores `group_size` completions per prompt whose lengths vary a lot. TRL's `_get_per_token_logps_and_entropies` left-pads every (prompt+completion) row to the batch max and runs the policy + reference forward over the full padded `[B, T]` block — so on a high-variance batch most of the attention/MLP FLOPs are spent on pad tokens. verl's `use_remove_padding` instead flattens all real tokens into one packed sequence and runs FlashAttention in varlen mode (cu_seqlens marks the per-row boundaries, so no token attends across rows), wasting zero compute on padding — ~1.5-2x on the policy forward for skewed rollouts, single-GPU. We mirror the LoRA+ `_SFT(SFTTrainer)` local-subclass pattern: override ONE method and fall back to `super()` on any mismatch. This is correct-by-construction + default-OFF + FA-gated + try/except, because getting the token->logprob mapping wrong silently corrupts the GRPO gradient (it would optimize the wrong logprobs against the right advantages). INVARIANT we preserve (verified against TRL 1.6 `_get_per_token_logps_and_entropies`): the method returns `(logps, entropies)` where `logps[i, j]` is the log-prob the model assigns to `input_ids[i, -logits_to_keep + j]` GIVEN the preceding context — i.e. logps is shape `[B, logits_to_keep]`, the prediction for the LAST `logits_to_keep` positions of row i, using the standard next-token shift (logits[:, :-1] predicts input_ids[:, 1:]) and `logits.div_(self.temperature)`. The caller multiplies this elementwise by completion_mask, so we MUST return EXACTLY that padded `[B, logits_to_keep]` layout — same dtype/device, same masked positions (we leave masked/pad positions at 0.0; they are zeroed by completion_mask downstream regardless). We do NOT touch entropies/pixel/multimodal kwargs: if ANY of those are requested, or batch_size chunking is requested, or shapes don't line up, we defer to super() so we never silently diverge from TRL's reference math on a path we didn't validate. """ import torch class _RmpadGRPO(GRPOTrainer): # local remove-padding / varlen subclass # Set True the first time we successfully fall back, so we don't spam the log per step. _rmpad_warned = False def _rmpad_fallback(self, reason, *args, **kwargs): if not _RmpadGRPO._rmpad_warned: print(f"[rl][rmpad] falling back to padded logprob path: {reason}") _RmpadGRPO._rmpad_warned = True return super()._get_per_token_logps_and_entropies(*args, **kwargs) def _get_per_token_logps_and_entropies( self, model, input_ids, attention_mask, logits_to_keep, batch_size=None, compute_entropy=False, **kwargs, ): # Capture the original call once so every fallback re-invokes super() with the EXACT # arguments TRL passed (no chance of dropping a kwarg on the deferral path). _args = (model, input_ids, attention_mask, logits_to_keep) _kw = {"batch_size": batch_size, "compute_entropy": compute_entropy, **kwargs} fb = lambda why: self._rmpad_fallback(why, *_args, **_kw) # noqa: E731 # Only handle the plain text, no-entropy, no-multimodal, single-chunk case. Anything # else -> defer to TRL's reference implementation (correctness over coverage). if compute_entropy: return fb("entropy requested") # Any multimodal / token_type kwarg present and non-None -> defer (varlen path here is # text-only; the VL tiers are trained text-only but TRL may still pass these through). if any(v is not None for v in kwargs.values()): return fb("multimodal/extra kwargs present") try: B, T = input_ids.shape if attention_mask is None or attention_mask.shape != input_ids.shape: return fb("missing/mismatched attention_mask") # Per-row real-token lengths (GRPO left-pads prompts, so the real tokens are a # contiguous RIGHT-aligned span; we assert that to avoid a wrong scatter). seqlens = attention_mask.sum(dim=1).to(torch.int32) # (B,) if int(seqlens.min()) <= int(logits_to_keep): # A row with <= logits_to_keep real tokens means the completion region would # spill into pad — outside the contract we validated. Defer. return fb("row shorter than logits_to_keep") # Verify the left-pad assumption: for each row the real tokens must be the LAST # seqlen positions (mask is 0...0 1...1). If any row isn't right-aligned, the # flatten/scatter indices below would be wrong -> defer rather than risk it. idx = torch.arange(T, device=input_ids.device).unsqueeze(0).expand(B, -1) right_aligned = (idx >= (T - seqlens.unsqueeze(1))).int() if not torch.equal(right_aligned, attention_mask.int()): return fb("attention_mask not left-padded (right-aligned) as expected") # ---- Flatten: pack every row's REAL tokens into one [1, total] sequence. ---- flat_ids = input_ids[attention_mask.bool()].unsqueeze(0) # (1, total) # cu_seqlens: prefix-sum boundaries FA varlen uses so row i's tokens only attend to # row i (no cross-row leakage). position_ids restart at 0 per row (RoPE per row). cu_seqlens = torch.zeros(B + 1, dtype=torch.int32, device=input_ids.device) cu_seqlens[1:] = torch.cumsum(seqlens, dim=0) position_ids = torch.cat( [torch.arange(int(n), device=input_ids.device) for n in seqlens] ).unsqueeze(0) # (1, total) # Run the UNPADDED forward. transformers' FA2/FA3 path reads varlen geometry from a # 2D position_ids that restarts per packed sequence (the documented padding-free # forward); we pass it WITHOUT an attention_mask so FA builds cu_seqlens from the # position resets. logits_to_keep is per-row, so request all logits and slice below. out = model(input_ids=flat_ids, position_ids=position_ids, use_cache=False) logits = out.logits # (1, total, V) if logits.shape[1] != flat_ids.shape[1]: return fb("unpadded forward returned unexpected length") logits = logits.squeeze(0) # (total, V) logits = logits.div_(self.temperature) # ---- Scatter logprobs back to the padded [B, logits_to_keep] layout. ---- # For row i (real tokens occupy flat slice [c_i, c_{i+1})), the per-token logprob # for predicting the LAST `logits_to_keep` tokens uses logits at the positions # IMMEDIATELY BEFORE each target (next-token shift). The j-th kept logprob # (j in [0, logits_to_keep)) targets the token at row offset (n_i - logits_to_keep + j) # and is read from the logit at offset (n_i - logits_to_keep + j - 1). This exactly # mirrors TRL's logits[:, :-1] shift + selective_log_softmax(logits, completion_ids). from trl.trainer.utils import selective_log_softmax out_logps = torch.zeros(B, logits_to_keep, dtype=logits.dtype, device=logits.device) starts = cu_seqlens[:-1] for i in range(B): c = int(starts[i]) n = int(seqlens[i]) # target token offsets within the row: the last logits_to_keep tokens tgt_offsets = torch.arange(n - logits_to_keep, n, device=logits.device) target_ids = flat_ids[0, c + tgt_offsets] # (logits_to_keep,) # predicting logits sit one position earlier (next-token shift) pred_logits = logits[c + tgt_offsets - 1] # (logits_to_keep, V) out_logps[i] = selective_log_softmax( pred_logits.unsqueeze(0), target_ids.unsqueeze(0) ).squeeze(0) return out_logps, None except Exception as e: # never corrupt/kill training on the rmpad path return fb(f"exception in rmpad forward ({type(e).__name__}: {e})") return _RmpadGRPO def run_rl(): from datasets import Dataset from transformers import AutoTokenizer from trl import GRPOConfig, GRPOTrainer require_active_env() # fail loudly (not AttributeError: NoneType) on the no-JobSpec path t_start = time.time() heartbeat("rl_start") # GRPO rollout strategy by env shape (trl 1.6 adds the hooks these need): # * single-turn -> TRL single-shot generation + per-completion reward (below); # * tool (ToolEnv & subs: # Stateful/Sandbox/Python) -> TRL drives the tool-call loop natively via # GRPOTrainer(tools=...) (it parses tool calls, executes the tools, and masks the # tool-result tokens itself); the reward scores the full transcript; # * pure multi-turn -> a custom rollout_func (autoslm.engine.multiturn_rollout) # drives THIS env's turn loop on the colocate engine and returns the interleaved # token sequence with an env_mask so only the model's tokens are trained. is_tool_env = getattr(ACTIVE_ENV, "is_tool_env", False) is_multi_turn = getattr(ACTIVE_ENV, "multi_turn", False) conversational = is_multi_turn # message-list prompts (tool + pure multi-turn) vs strings wait_for_gpu() setup_perf_backends() model_id = JOB_SPEC.model if JOB_SPEC else RECIPE.hf_model_id # QLoRA tier loads the base bf16 checkpoint; vLLM/transformers quantize it to 4-bit NF4 at load. quant = model_quant(model_id) download_seconds = prefetch_model(model_id) rl = RECIPE.rl steps = int(os.environ.get("RL_STEPS", str(rl.num_steps))) # Throughput/quality knobs (env-overridable): the number of prompts optimized per step, # completions per prompt, and whether vLLM offloads weights between steps. Sleep mode # frees memory for the optimizer but reloads ~weights each step (a large per-step cost); # disable it (RL_VLLM_SLEEP=0) with a higher RL_VLLM_GPU_UTIL when both fit resident. # SDK-supplied GRPO knobs (datums parity) override the recipe; env vars still win. gcfg = grpo_overrides() _t = JOB_SPEC.train if JOB_SPEC else None # batch_size = prompts per optimizer step for GRPO. _pps_default = _t.batch_size if _t and _t.batch_size is not None else rl.prompts_per_step prompts_per_step = int(os.environ.get("RL_PROMPTS_PER_STEP", str(_pps_default))) group_size = int(os.environ.get("RL_GROUP_SIZE", gcfg.get("group_size") or rl.group_size)) # temperature: explicit None check, NOT `or` — a configured 0.0 (greedy/deterministic # rollouts) must be honored, not fall back to the recipe sampling temperature. _gcfg_temp = gcfg.get("temperature") _temperature = float(_gcfg_temp if _gcfg_temp is not None else rl.sampling_temperature) _kl_beta = float(gcfg.get("kl_penalty_coef") or 0.0) _adv_clip = float(gcfg.get("advantage_clip") or 0.0) _think_penalty = float(gcfg.get("thinking_length_penalty_coef") or 0.0) # vLLM sleep mode offloads the rollout engine's weights between steps to free memory for the # optimizer, but reloading each step is a large per-step cost — PR #174 measured ~2-2.6x faster # GRPO with it OFF on models that fit. Default it by model size (same small=speed / large=memory # gate as gradient checkpointing): OFF for small/fitting models, ON for large. RL_VLLM_SLEEP wins. _sleep_env = os.environ.get("RL_VLLM_SLEEP") if _sleep_env is not None: sleep_mode = _sleep_env not in ("0", "false", "False") else: # Gate on the RESOLVED GRPO rollout context (RL_VLLM_MAX_LEN sizes the engine + KV cache), # not just _t.max_length: a long-context GRPO run set via RL_VLLM_MAX_LEN is memory-tight and # needs sleep mode even when _t.max_length is unset/small. Matches the liger-loss gate below. _grpo_ctx = int( os.environ.get("RL_VLLM_MAX_LEN") or (_t.max_length if _t and _t.max_length else 0) or 0 ) sleep_mode = _memory_mode(model_id, _grpo_ctx) # Rollout backend: colocated vLLM (fast) unless the catalog disables it for this model # (e.g. fused-MoE tiers whose experts bnb can't 4-bit, so a 2nd vLLM copy won't fit one # GPU) — then TRL generates with the trainer model via transformers. Env RL_USE_VLLM wins. from autoslm.catalog import MODELS as _CATALOG _info = _CATALOG.get(model_id) _catalog_use_vllm = _info.grpo_use_vllm if _info is not None else True use_vllm = os.environ.get("RL_USE_VLLM", "1" if _catalog_use_vllm else "0") not in ( "0", "false", "False", ) print(f"[rl] rollout backend: {'colocated vLLM' if use_vllm else 'transformers generation'}") tok = AutoTokenizer.from_pretrained(model_id, trust_remote_code=True) if tok.pad_token is None: tok.pad_token = tok.eos_token train = ACTIVE_ENV.dataset("train") rng = random.Random(SEED) rng.shuffle(train) if conversational: # Message-list prompts so the chat template applies roles + (for tool envs) the tool # schemas; per-turn length is managed by the tool loop / rollout_func, not a flat budget. prompts = [{"prompt": ACTIVE_ENV.prompt_messages(ex), "example": ex} for ex in train] else: prompts = [{"prompt": render_prompt(tok, ex), "example": ex} for ex in train] # The colocated vLLM engine's model length is the hard cap on prompt+completion at # rollout. Size it (honoring RL_VLLM_MAX_LEN) and derive the prompt budget from it so a # bigger engine or a smaller completion automatically admits longer prompts (rather than # a fixed rl.max_prompt_len that no env override could lift). _max_completion = int( os.environ.get( "RL_MAX_COMPLETION", gcfg.get("max_tokens") or (rl.max_completion_len_thinking if THINKING else rl.max_completion_len), ) ) # Engine context = RL_VLLM_MAX_LEN if set, else the run's [train].max_length (so a long-context # GRPO config sized/paid for by the allocator actually RUNS at that length), else the recipe # default. Without the train.max_length fallback the allocator provisions a big GPU for the long # context but the engine runs short — paying for headroom we never use. _train_ctx = _t.max_length if (_t and _t.max_length) else 0 vllm_max_len = int( os.environ.get("RL_VLLM_MAX_LEN") or _train_ctx or max(1024, rl.max_prompt_len + _max_completion) ) # The engine must fit completion + at least some prompt. If RL_VLLM_MAX_LEN is set below # the completion budget, no prompt can ever fit — fail fast here rather than passing a # 1-token budget that lets prompts through and then OOMs/overflows mid-rollout. if vllm_max_len <= _max_completion: raise ValueError( f"RL_VLLM_MAX_LEN={vllm_max_len} leaves no room for the {_max_completion}-token " "completion; raise RL_VLLM_MAX_LEN or lower RL_MAX_COMPLETION" ) prompt_budget = vllm_max_len - _max_completion # TRL 1.5's GRPOConfig has no max_prompt_length and does NOT truncate prompts, so a prompt # that leaves no room for the completion within the engine length would fail mid-rollout # AFTER the paid worker is provisioned. Drop prompts that don't fit the budget up front. # render_prompt returns an apply_chat_template(tokenize=False) string that already carries # the special tokens, so tokenize with add_special_tokens=False (the default re-adds # BOS/EOS and over-counts). # Drop prompts that leave no room for the completion within the engine length — applies to # BOTH single-turn (string prompts) and conversational (message-list) prompts, so a tool / # multi-turn rollout can't overflow the colocate engine mid-generation. Conversational # prompts are length-checked via the chat template (with the generation prompt). # Tool schemas TRL injects into the prompt for native tools= GRPO — include them in the # budget for a tool env so a prompt isn't undercounted at filter time vs. rollout time. _oai_tools = ( getattr(getattr(ACTIVE_ENV, "_env", None), "oai_tools", None) if is_tool_env else None ) def _prompt_tokens(p) -> int: if conversational: # Render to text then tokenize — the SAME path the rollout uses — so the filter # count matches the rollout's count (avoids a tokenize=True vs text mismatch). kw = {"tools": _oai_tools} if _oai_tools else {} try: text = tok.apply_chat_template( p["prompt"], add_generation_prompt=True, tokenize=False, enable_thinking=THINKING, **kw, ) except Exception as exc: # Fail fast WITH context: a tokenizer/template incompatibility would render every # prompt uncountable and otherwise surface as a misleading "all prompts exceed # budget" — raise so the model/template can be fixed before a paid run trains on # a degenerate dataset. raise RuntimeError( "failed to render a conversational prompt with this model's chat template " f"(fix the model/template or the env's prompts): {exc}" ) from exc return len(tok(text, add_special_tokens=False).input_ids) return len(tok(p["prompt"], add_special_tokens=False).input_ids) kept = [p for p in prompts if 0 < _prompt_tokens(p) <= prompt_budget] if len(kept) < len(prompts): print( f"[rl] dropped {len(prompts) - len(kept)} prompts over the {prompt_budget}-token " f"prompt budget (engine {vllm_max_len} - completion {_max_completion})" ) if not kept: raise ValueError( f"every training prompt exceeds the {prompt_budget}-token prompt budget (engine " f"{vllm_max_len} - completion {_max_completion}); raise RL_VLLM_MAX_LEN, lower " "RL_MAX_COMPLETION, or shorten the environment's prompts" ) prompts = kept ds = Dataset.from_list(prompts) def reward_fn(completions, **kwargs): # rollout_func (pure multi-turn) path: the per-rollout reward is computed by the env # during the rollout and forwarded as the "reward" extra field — pass it through. if kwargs.get("reward") is not None: return [float(r) for r in kwargs["reward"]] # Score the -stripped text (graded_text), then — datums parity — deduct # the thinking-length penalty computed from the RAW completion's span. examples = kwargs.get("example") rewards = [] for comp, ex in zip(completions, examples, strict=False): if isinstance(comp, list): # Tool / conversational transcript (TRL passes a list of messages): score the # whole transcript via the rubric (no stripping — multi-turn content). rewards.append(ACTIVE_ENV.reward_from_messages(comp, ex)) continue r = ACTIVE_ENV.reward(graded_text(comp), ex) if _think_penalty > 0 and THINKING: r -= _think_penalty * think_token_count(comp, tok) rewards.append(r) return rewards # TRL's per_device_train_batch_size counts COMPLETIONS, not prompts. Size grad-accum so # the global completion batch = prompts_per_step * group_size, i.e. each optimizer step # actually optimizes `prompts_per_step` prompts. The per-device *completion* micro-batch # is the VRAM knob (thinking-aware; see rl_per_device_comps). from autoslm.engine.vram import fetch_hf_params_b, params_b_from_str _params_b = params_b_from_str(getattr(_info, "params", None)) if _info else None # Open-model (uncataloged) GRPO: _info carries no param count, so size the colocate # activation cap from the HF safetensors metadata (no download). Without this, a large # open model falls back to the ~2B-width default in rl_per_device_comps and gets too LOOSE # a per-device cap -> colocate OOM. Best-effort: stays None offline, keeping prior behavior. if _params_b is None: _params_b = fetch_hf_params_b(model_id) per_device_comps = rl_per_device_comps(_max_completion, use_vllm=use_vllm, params_b=_params_b) batching = compute_grpo_batching(prompts_per_step, group_size, per_device_comps) if not batching["divisible_by_group"]: print("WARN: generation batch not divisible by group size; check RL_PER_DEVICE_PROMPTS") print( f"[rl] GRPO batching: per_device={batching['per_device_train_batch_size']} " f"grad_accum={batching['gradient_accumulation_steps']} " f"generations/step={batching['generations_per_step']} " f"unique_prompts/step={batching['unique_prompts_per_step']} " f"(target prompts/step={prompts_per_step}, group={group_size}, sleep={sleep_mode})" ) out_dir = f"/tmp/rl_seed{SEED}" resume_ckpt = hf_resume_checkpoint() grpo_kwargs = { "output_dir": out_dir, "learning_rate": ( _t.learning_rate if _t and _t.learning_rate is not None else rl.learning_rate ), "per_device_train_batch_size": batching["per_device_train_batch_size"], "gradient_accumulation_steps": batching["gradient_accumulation_steps"], "num_generations": group_size, # NB: GRPOConfig has no max_prompt_length field (TRL 1.5) and does not truncate # prompts; the dataset is pre-filtered above to prompts that fit prompt_budget # (vllm_max_len - completion), so every prompt fits the engine sized here. "max_completion_length": _max_completion, "max_steps": steps, "temperature": _temperature, "top_p": rl.sampling_top_p, "use_vllm": use_vllm, "logging_steps": 1, "save_steps": int( os.environ.get( "RL_SAVE_STEPS", str(_t.save_every if _t and _t.save_every is not None else 20) ) ), "save_total_limit": 1, # Memory-light checkpoints: adapter only, no optimizer/scheduler/RNG state -> no # serialization spike at save (the save-step OOM guard). "save_only_model": True, "bf16": True, "report_to": wandb_report_to(), # W&B when WANDB_API_KEY present (restored post-autoslm-migration) "run_name": wandb_run_name(), "seed": SEED, "gradient_checkpointing": grad_checkpointing_on(model_id, vllm_max_len), # Non-reentrant checkpointing: the modern path that composes correctly with the # save_on_cpu activation offload (_maybe_activation_offload) and autograd saved-tensor # hooks, and avoids the reentrant path's extra graph retention. (verl #3629.) "gradient_checkpointing_kwargs": {"use_reentrant": False}, # Pin a stable, well-conditioned GRPO recipe instead of inheriting TRL's defaults # (which on a short run suppress the lift): constant LR (TRL default 'linear' decays # to 0 over the run), advantages centered by group mean only (no std scaling, which # biases by difficulty/length — matches datums.centered_advantages), and no # length-normalized loss. beta is the KL-to-reference coef (datums kl_masks -> # kl_penalty_coef). "lr_scheduler_type": "constant", "warmup_ratio": 0.0, "beta": _kl_beta, "scale_rewards": "none", "loss_type": "dr_grpo", # Optimizer: colocated GRPO is memory-tight (trainer + vLLM share one GPU), so default to # 8-bit paged AdamW (int8 state paged to host RAM -> fits a smaller GPU). AUTOSLM_OPTIM # overrides; AUTOSLM_FUSED_OPTIM=0 -> plain adamw_torch. "optim": fused_optim_name(memory_default=True), } # Liger fused GRPO loss: fuses the lm_head + per-token logprob so the fp32 # [batch, seq, ~152k vocab] logits never materialize — the documented GRPO OOM driver. # TRL 1.6's GRPOConfig flag is `use_liger_kernel` (NOT `use_liger_loss`, which doesn't # exist in 1.6). DEFAULT ON for the GRPO path regardless of model size: MEASURED that # WITHOUT it even Qwen3.5-0.8B GRPO OOMs a 24 GB (and 32 GB) card because the per-completion # logits over the 152k vocab dominate — the small-scale JIT cost is far cheaper than the OOM. # (This differs from SFT, where Liger is gated by size since 1B-class SFT can be net-negative.) if liger_on(True): grpo_kwargs["use_liger_kernel"] = True print("[rl] liger fused GRPO loss enabled") if use_vllm: # Colocate shares one GPU between the policy model and the vLLM rollout engine. # vllm_max_model_length bounds the KV cache to what GRPO needs (else vLLM sizes for # the model's FULL context and won't start on a consumer GPU). RL_VLLM_GPU_UTIL # sizes vLLM's pool; RL_VLLM_SLEEP offloads its weights between steps. grpo_kwargs.update( vllm_mode="colocate", vllm_max_model_length=vllm_max_len, vllm_gpu_memory_utilization=float(os.environ.get("RL_VLLM_GPU_UTIL", "0.45")), vllm_enable_sleep_mode=sleep_mode, ) # Rollout-memory + throughput knobs, applied ONLY if this TRL exposes the field (so an # older TRL never crashes on an unknown kwarg). All verl-validated for GRPO colocate (#174). _grpo_fields = set(getattr(GRPOConfig, "__dataclass_fields__", {})) def _set_vllm_field(names, value, label): for _f in names: if _f in _grpo_fields: grpo_kwargs[_f] = value print(f"[rl] {label} ({_f}={value})") return True return False # fp8 KV cache only where the silicon has native fp8 (compute capability >= 8.9: Ada / # Hopper / Blackwell) — ~halves the rollout KV pool. Ampere (A100/A5000/3090, sm80) lacks # fp8, so it stays fp16 there (forcing it on would error / silently emulate). try: import torch as _torch _want_fp8 = _torch.cuda.get_device_capability() >= (8, 9) except Exception: _want_fp8 = False if _want_fp8: _set_vllm_field(("vllm_kv_cache_dtype", "kv_cache_dtype"), "fp8", "fp8 KV cache") # PREFIX CACHING: every GRPO group of `num_generations` rollouts shares the SAME prompt # prefix, so caching the prompt KV computes it once and reuses it — the dominant rollout win # on one GPU. CHUNKED PREFILL interleaves prefill with decode so a long prompt doesn't stall # the batch. CUDAGRAPH MODE sets verl's full-graph-decode + piecewise-fallback rollout mode. _set_vllm_field( ("vllm_enable_prefix_caching", "enable_prefix_caching"), True, "vLLM prefix caching (shared GRPO prompt KV reuse)", ) _set_vllm_field( ("vllm_enable_chunked_prefill", "enable_chunked_prefill"), True, "vLLM chunked prefill", ) _set_vllm_field( ("vllm_compilation_config", "compilation_config"), {"cudagraph_mode": "FULL_AND_PIECEWISE"}, "vLLM cudagraph_mode (verl rollout default)", ) # Adapter init: continue training the SFT adapter (peft_config=None, model is the # loaded PeftModel) when train.init_from_adapter is set, else a fresh LoRA on the # string model id (model_init_kwargs forces bf16 — TRL string-loading can fall back # to fp32 and double VRAM). init_model, init_peft = _init_adapter_model(model_id) if init_peft is not None: # Fresh LoRA: TRL loads the string model id with these kwargs, then attaches the # adapter. For the 4-bit-QLoRA tier load the base in NF4 — TRL detects the # bnb.Linear4bit modules and brings up its colocated vLLM rollout engine with # quantization="bitsandbytes" (so a 36B MoE fits an 80 GB GPU in 4-bit on both the # trainer and rollout sides). Otherwise force bf16 (TRL string-loading can fall # back to fp32 and double VRAM). _attn = optimal_attn_impl() # arch-aware FlashAttention (Kernels Hub) / SDPA if quant == "4bit-qlora": _patch_peft_weight_converter_compat() # adapter (re)load compatibility grpo_kwargs["model_init_kwargs"] = qlora_model_init_kwargs() _vllm_note = "; vLLM rollout -> bitsandbytes" if use_vllm else "" print(f"[rl] loading {model_id} in 4-bit (QLoRA tier){_vllm_note}") else: grpo_kwargs["model_init_kwargs"] = {"dtype": "bfloat16"} if _attn: grpo_kwargs["model_init_kwargs"]["attn_implementation"] = _attn else: _attn = optimal_attn_impl() # stop_sequences: TRL forwards generation_kwargs to the (vLLM) sampler, whose # SamplingParams.stop truncates each rollout at the requested delimiter — so the reward # sees the same completion the config intends, instead of generating to max_completion. if _t and _t.stop_sequences: grpo_kwargs["generation_kwargs"] = {"stop": list(_t.stop_sequences)} # advantage_clip>0 is the datums centered-advantage clamp; TRL has no advantage-value # clip knob (it clips the importance ratio), so honor the default (clip off == # centered) and surface a note when a config asks for an explicit clamp. if _adv_clip > 0: print(f"[rl] advantage_clip={_adv_clip} recorded; TRL centers advantages (no value clip)") # num_iterations (the one promoted GRPO speed lever, measured 1.38x faster) is feature-detected # so an older TRL that lacks the field is simply skipped (GRPOConfig rejects unknown kwargs). # Generation dominates GRPO wall-clock, so reusing each rollout batch for 2 optimizer steps is # the cheapest large speedup; mu=2 is the standard GRPO config and TRL's importance-sampling # correction (on by default) keeps the step stable. (The GSPO/DAPO A/B levers were dropped: the # framework-scan in gpu-bench/RESEARCH_FINDINGS.md measured no robust win over baseline.) import dataclasses as _dc try: _grpo_fields = {f.name for f in _dc.fields(GRPOConfig)} except TypeError: _grpo_fields = set() # not a dataclass on this TRL -> skip the feature-detected knob if "num_iterations" in _grpo_fields: grpo_kwargs["num_iterations"] = 2 print("[rl] rollout amortization: num_iterations=2 (reuse each generation batch)") cfg = GRPOConfig(**grpo_kwargs) setup_seconds = time.time() - t_start heartbeat("rl_train_start", setup_seconds=setup_seconds) # VL checkpoints (Qwen3.5/3.6) train text-only: make TRL's colocated rollout # engine skip the vision tower (VRAM + 5090 PTX-compat; see the patch docstring). # Only relevant when vLLM drives rollouts; transformers generation uses the trainer # model (already text-only via the LoRA target/exclude config). if use_vllm: patch_vllm_language_model_only(model_id) hb_cb = make_reward_heartbeat_callback() # Multi-turn / tool wiring (trl 1.6): tool envs hand TRL the tool callables so it runs the # tool-call loop natively; pure multi-turn envs hand TRL a rollout_func that drives the # env's own turn loop on the colocate engine (env_mask masks the non-model tokens). extra_trainer_kwargs: dict = {} tools = ACTIVE_ENV.tools() if is_tool_env else [] # A tool env exposing NO tools would silently degrade to single-shot under tools=[]; drive # it through the rollout_func turn loop instead so it isn't mis-trained as single-turn. if is_tool_env and not tools: print("[rl][warn] tool env exposes no tools — using the multi-turn rollout_func path") use_rollout_func = is_multi_turn and not (is_tool_env and tools) require_vllm_for_rollout_func(use_rollout_func, use_vllm, model_id) if is_tool_env and tools: extra_trainer_kwargs["tools"] = tools print(f"[rl] tool env: handing {len(tools)} tool(s) to TRL's native tool loop") if use_rollout_func: from autoslm.engine.multiturn_rollout import ( build_examples_index, build_rollout_func, index_collisions, ) examples_by_key = build_examples_index(train, ACTIVE_ENV.prompt_messages) ncol = index_collisions(train, ACTIVE_ENV.prompt_messages) if ncol: print( f"[rl][warn] {ncol} duplicate prompt(s) collide in the reward index; the shared " "prompt scores against the last example's answer/info" ) extra_trainer_kwargs["rollout_func"] = build_rollout_func( active_env=ACTIVE_ENV, tok=tok, examples_by_key=examples_by_key, max_completion=_max_completion, max_turns=getattr(ACTIVE_ENV, "max_turns", 10), temperature=_temperature, top_p=rl.sampling_top_p, stop=(list(_t.stop_sequences) if _t and _t.stop_sequences else None), thinking=THINKING, engine_max_len=vllm_max_len, ) print("[rl] multi-turn env: driving the turn loop via rollout_func") # Lever 1 (opt-in, default OFF): GRPO remove-padding / varlen logprob forward. Only when # AUTOSLM_GRPO_RMPAD=1 AND the run is on FlashAttention (varlen needs FA2/FA3) — otherwise # _grpo_rmpad_enabled prints a warning and we keep the stock GRPOTrainer. Liger fuses the # logprob+lm_head itself, so don't layer rmpad on top of it (they patch the same forward). _Trainer = GRPOTrainer if _grpo_rmpad_enabled(_attn): if grpo_kwargs.get("use_liger_kernel"): print( "[rl][rmpad] AUTOSLM_GRPO_RMPAD ignored: Liger fused GRPO loss is enabled " "(set RL_LIGER=0 to use rmpad instead)" ) else: try: _Trainer = make_rmpad_grpo_trainer(GRPOTrainer) print("[rl] rmpad varlen logprob forward enabled (AUTOSLM_GRPO_RMPAD, FA varlen)") except Exception as e: # never block training on the rmpad wiring print("[rl][rmpad] subclass build failed, using stock GRPOTrainer:", e) _Trainer = GRPOTrainer trainer = _Trainer( model=init_model, args=cfg, train_dataset=ds, reward_funcs=reward_fn, peft_config=init_peft, processing_class=tok, callbacks=[hb_cb, make_checkpoint_upload_callback()], **extra_trainer_kwargs, ) maybe_regional_compile( trainer.model, "rl" ) # opt-in regional torch.compile (Lever 2; default off) _maybe_activation_offload( trainer ) # opt-in CPU activation offload (memory; AUTOSLM_ACT_OFFLOAD) t_train = time.time() with _sdpa_cudnn_ctx(_attn): # force cuDNN SDPA on sm120 (no-op otherwise) trainer.train(resume_from_checkpoint=resume_ckpt) train_wall = time.time() - t_train reward_history = list(getattr(hb_cb, "reward_history", [])) adapter_dir = f"{out_dir}/adapter" trainer.model.save_pretrained(adapter_dir) tok.save_pretrained(adapter_dir) hf_upload_folder(adapter_dir, "adapter", required=True) heartbeat("rl_trained", train_wall=train_wall) # Upper bound on generated tokens: completions actually optimized (the intended # prompts_per_step after the batch fix) x the max completion length. Over-counts (most # completions are shorter); reported as an upper bound, used only for a rough throughput. gen_tokens = steps * batching["unique_prompts_per_step"] * group_size * _max_completion write_train_meta( phase="rl", adapter_dir=adapter_dir, model_id=model_id, train_wall=train_wall, setup_seconds=setup_seconds, train_tokens=0, generated_tokens=gen_tokens, notes={ "steps": steps, "resumed": bool(resume_ckpt), "download_seconds": download_seconds, "hf_transfer": os.environ.get("HF_HUB_ENABLE_HF_TRANSFER", ""), "reward_history": reward_history, "loss_curve": _metric_curve(trainer, "loss"), **wandb_run_info(), "gen_tokens_is_upper_bound": True, "thinking": THINKING, "max_completion_len": _max_completion, "prompts_per_step": batching["unique_prompts_per_step"], "generations_per_step": batching["generations_per_step"], "group_size": group_size, "per_device_train_batch_size": batching["per_device_train_batch_size"], "gradient_accumulation_steps": batching["gradient_accumulation_steps"], "grpo_recipe": { "lr_scheduler": "constant", "beta": _kl_beta, "scale_rewards": "none", "loss_type": "dr_grpo", "temperature": _temperature, "advantage_clip": _adv_clip, "thinking_length_penalty_coef": _think_penalty, "init_from_adapter": JOB_SPEC.train.init_from_adapter if JOB_SPEC else "", }, }, ) free_gpu(trainer) # --------------------------------------------------------------------------- # Completion: train phase writes metrics.json + the DONE sentinel (see _finalize). # --------------------------------------------------------------------------- def gpu_diagnostics() -> dict: """Collect CUDA/driver diagnostics to pin down GPU init failures on rented nodes.""" diag = {} try: import torch diag["torch"] = torch.__version__ diag["torch_cuda"] = torch.version.cuda diag["cuda_available"] = torch.cuda.is_available() try: diag["device_count"] = torch.cuda.device_count() diag["device_name"] = torch.cuda.get_device_name(0) except Exception as e: diag["device_query_err"] = str(e)[:160] except Exception as e: diag["torch_import_err"] = str(e)[:160] try: import subprocess out = subprocess.run( ["nvidia-smi", "--query-gpu=driver_version,name,memory.total", "--format=csv,noheader"], capture_output=True, text=True, timeout=20, ) diag["nvidia_smi"] = (out.stdout or out.stderr).strip()[:200] except Exception as e: diag["nvidia_smi_err"] = str(e)[:160] return diag def wait_for_gpu(max_tries=12, sleep_s=10): """Rented nodes sometimes report 'CUDA device not ready' transiently at startup. Poll a trivial CUDA op until it succeeds before doing real work; raise if never ready.""" import time as _t last = None for i in range(max_tries): try: import torch if torch.cuda.is_available(): # Force an actual kernel launch (alloc + add) to confirm the GPU is live. _ = torch.zeros(8, device="cuda") + 1 torch.cuda.synchronize() print(f"GPU ready after {i} retries: {torch.cuda.get_device_name(0)}") return True last = "cuda not available" except Exception as e: last = str(e)[:160] print(f"GPU not ready (try {i + 1}/{max_tries}): {last}; sleeping {sleep_s}s") _t.sleep(sleep_s) raise RuntimeError(f"GPU never became ready after {max_tries} tries: {last}") def free_gpu(trainer=None): try: import gc import torch try: if trainer is not None and hasattr(trainer, "model"): trainer.model = None except Exception: # Best-effort VRAM release before gc; any failure here is non-fatal cleanup. pass gc.collect() if torch.cuda.is_available(): torch.cuda.empty_cache() except Exception as e: print("free_gpu warn:", e) def _metric_curve(trainer, key: str, cap: int = 400) -> list: """The logged values of `key` (e.g. 'loss' or 'reward') from the trainer's log history, rounded + capped. Lets metrics.json carry the convergence/reward curve for an A/B without relying on a checkpoint's trainer_state.json (only written on save_steps) or the console (only uploaded on failure). Never raises.""" try: vals = [round(float(h[key]), 4) for h in trainer.state.log_history if key in h] return vals[:cap] except Exception: return [] def write_train_meta( phase, adapter_dir, model_id, train_wall, setup_seconds, train_tokens, generated_tokens, notes ): meta = { "phase": phase, "adapter_dir": adapter_dir, "model_id": model_id, "train_wall": train_wall, "setup_seconds": setup_seconds, "train_tokens": train_tokens, "generated_tokens": generated_tokens, "notes": notes or {}, } with open("/tmp/train_meta.json", "w") as f: json.dump(meta, f) hf_upload_file("/tmp/train_meta.json", "train_meta.json") heartbeat( f"{phase}_train_done", **{k: meta[k] for k in ("train_wall", "train_tokens", "generated_tokens")}, ) # Finalize directly from the training phase: build the run-metrics record (training # metrics only — loss/reward are streamed by the trainer; reward_history is in notes) # and write the completion sentinel. There is no separate eval phase. m = RunMetrics( # Substrate the worker actually ran on. Each provider's launcher sets AUTOSLM_ARM # in the worker env (runpod -> "runpod", vast -> "vast"); default to "runpod" only # when unset so the persisted metrics correctly attribute the compute backend. arm=os.environ.get("AUTOSLM_ARM", "runpod"), phase=phase, seed=SEED, model_id=model_id, wall_seconds=train_wall, setup_seconds=setup_seconds, train_throughput_toks_per_s=( (generated_tokens or train_tokens) / train_wall if train_wall else 0.0 ), train_tokens=train_tokens, generated_tokens=generated_tokens, notes={ **(notes or {}), "renderer": "autoslm_env", "thinking": THINKING, "train_wall": train_wall, "model_id": model_id, "environment": ACTIVE_ENV.id, "job_spec": JOB_SPEC.to_dict() if JOB_SPEC else None, }, ) _finalize(m, adapter_dir) def _download_adapter(adapter_prefix: str | None) -> str | None: if not (adapter_prefix and HF_REPO): return None from huggingface_hub import snapshot_download snapshot_download( repo_id=HF_REPO, repo_type="dataset", allow_patterns=[f"{adapter_prefix}/adapter/*"], local_dir="/tmp/evdl", token=os.environ.get("HUGGINGFACE_TOKEN"), ) adir = os.path.join("/tmp/evdl", adapter_prefix, "adapter") return adir if os.path.isdir(adir) else None def _finalize(metrics: RunMetrics, adapter_dir: str): metrics.save("/tmp/metrics.json") # Required: a swallowed upload would make the control plane fail/retry a finished run. hf_upload_file("/tmp/metrics.json", "metrics.json", required=True) # DONE sentinel so the controller knows it's safe to tear down with open("/tmp/DONE", "w") as f: f.write(str(time.time())) hf_upload_file("/tmp/DONE", "DONE", required=True) heartbeat("done") print("NODE DONE:", metrics.to_json()) def _drop_fla_on_hopper() -> None: """Remove flash-linear-attention when running on a Hopper GPU (sm90, H100/H200). fla's gated chunk_bwd Triton kernel is miscomputed on Hopper with Triton>=3.4 and HARD-RAISES (fla #640), so every gated-delta (Qwen3.5/3.6 family) GRPO backward crashes. The worker base image BAKES fla in, and per-run installs (extra_pip / `prime env install`) can pull it back, so the only reliable place to drop it is HERE: in the worker process, after all installs and BEFORE any model import. transformers then uses the correct pure-PyTorch delta rule (2-3x slower but it RUNS). Runs on BOTH substrates (RunPod and Vast both exec this module). importlib caches are invalidated so the later is_fla_available() probe sees it gone. Ampere/Ada/Blackwell keep fla for the speedup. """ import importlib.util import subprocess try: import torch if not (torch.cuda.is_available() and torch.cuda.get_device_capability()[0] == 9): return # not Hopper: fla's Triton kernel is correct here, keep it. except Exception: return if importlib.util.find_spec("fla") is None: return # pip first (clears metadata); _remove_fla_from_disk then deletes any package dir pip left # behind (incomplete RECORD / non-pip base-image install / a copy on another sys.path entry). subprocess.run( [sys.executable, "-m", "pip", "uninstall", "-y", "flash-linear-attention"], check=False ) removed, still = _remove_fla_from_disk() print( f"[hopper] fla removed {removed or 'nothing'} (still_importable={still}) -> " f"{'WARNING fla remains' if still else 'pure-PyTorch delta rule'} (fla #640)", flush=True, ) def main(): # Idempotency: if DONE was already uploaded, a re-delivered job re-fetches the final # metrics from HF and returns them immediately. (The previous behavior — sleeping in # an infinite loop — kept a billable GPU worker alive until the execution timeout.) try: # Idempotency FIRST — before any env-mutating pip install / package removal: a re-delivered # job whose DONE already exists must return the persisted metrics and exit WITHOUT running # _drop_fla_on_hopper() (pip-uninstalls fla) — that wasted a worker mutating its env on an # already-complete run. It is called after the DONE check below (see _drop_fla_on_hopper()). if HF_REPO: from huggingface_hub import hf_hub_download try: hf_hub_download( repo_id=HF_REPO, repo_type="dataset", filename=f"{hf_prefix()}/DONE", token=os.environ.get("HUGGINGFACE_TOKEN"), ) done = True except Exception: done = False if done: print("Run already complete (DONE present); returning persisted metrics.") heartbeat("already_done") try: got = hf_hub_download( repo_id=HF_REPO, repo_type="dataset", filename=f"{hf_prefix()}/metrics.json", token=os.environ.get("HUGGINGFACE_TOKEN"), ) import shutil shutil.copy(got, "/tmp/metrics.json") sys.stdout.flush() os._exit(0) except Exception as e: raise SystemExit(f"DONE present but metrics.json unavailable: {e}") from e # Not a DONE re-delivery -> this worker will train. These must run before any model import: _drop_fla_on_hopper() # Hopper fla guard (see _drop_fla_on_hopper) heartbeat("boot") finalize_alloc_conf_for_sleep() # sync CUDA alloc conf to resolved sleep (before first CUDA alloc) disable_fla_if_requested() # Hopper Gated-DeltaNet escape hatch (before any transformers import) # Dispatch table — register new algorithms (e.g. ppo) here as they land. modes = { "sft": run_sft, # SFT (TRL SFTTrainer) "rl": run_rl, # GRPO (TRL GRPOTrainer + colocated vLLM) } handler = modes.get(RUN_MODE) if handler is None: raise SystemExit(f"unknown RUN_MODE {RUN_MODE}; known: {sorted(modes)}") handler() # All artifacts (adapter, train_meta, metrics, DONE) are uploaded to HF *inside* the # handler. The RL trainer's colocated vLLM can DEADLOCK at interpreter shutdown # during NCCL/IPC/CUDA teardown — not segfault-and-exit (which `check=False` on the # train subprocess already tolerates), but hang forever. That would block the Flash # handler's *blocking* `subprocess.run` (heartbeat frozen at "rl_train_done") and the # whole run stalls until the wall-clock cap. Hard-exit to bypass the hanging teardown now that # every output is safely persisted. sys.stdout.flush() sys.stderr.flush() os._exit(0) except Exception as e: tb = traceback.format_exc() traceback.print_exc() # Upload the FULL traceback under a phase-specific name (error_.txt) so the # train (sft/rl) root-cause error survives for debugging. heartbeat.json is # single-file/overwritten, so the per-phase error file is the persistent signal. try: err_name = error_artifact_name(RUN_MODE) err_path = f"/tmp/{err_name}" with open(err_path, "w") as f: f.write(tb) hf_upload_file(err_path, err_name) except Exception as up_err: print("error-upload warn:", up_err) try: heartbeat(f"error_{RUN_MODE}", error=str(e)[:500], diag=gpu_diagnostics()) except Exception: heartbeat(f"error_{RUN_MODE}", error=str(e)[:500]) # keep container alive briefly so logs flush, then exit non-zero -> restart time.sleep(10) raise if __name__ == "__main__": main()