"""Cross-provider GPU allocation: the cheapest class that comfortably fits the run. Given a base model (+ algorithm), compute the VRAM the FULL run needs — sized for the heavier phase, GRPO, since the typical pipeline is SFT followed by GRPO — then rank every provisionable candidate across ALL registered providers by live $/hr and pick the cheapest: runpod every Flash-provisionable class (live pricing, cached; static fallback) vast live verified-datacenter offers (usable_offers' quality floors applied) Allocation happens at SUBMIT time in the runner (offers are a volatile market); the parse-time resolution in schema is a RunPod-static provisional for validation/dry-run display. Offline (AUTOSLM_SKIP_NET) the allocator degrades to exactly ``cheapest_gpu``'s deterministic static-rate answer (RunPod only — Vast is offline-off). Provider-agnostic by construction: it walks the registered providers and asks each for its ``gpu_classes()`` + ``hourly_rate()``; the only provider-specific knowledge is that Vast classes come from a live offer book (collected through the provider's ``usable_offers`` and carried opaquely on ``Candidate.offer``). """ from __future__ import annotations from autoslm._logging import get_logger from autoslm.providers import PROVIDER_NAMES, available_providers, get_provider from autoslm.providers.base import ( Allocation, Candidate, UnsupportedGpuError, canonical_gpu, unvalidated_allowed, ) logger = get_logger(__name__) # "Comfortably" = the open-model VRAM estimate plus headroom, so a full SFT+GRPO run # never lands in check_fit's "tight" band by construction. Curated catalog entries # already carry measured minimums and are used as-is. The headroom (default 1.1 == # model_required_vram_gb's own default) is read at call time via vram_headroom() so allocate() # and resolve_gpu_policy size identically and pick up a value exported after import. def vram_headroom() -> float: """The sizing headroom multiplier, honored by both the submit-time allocator and the parse-time resolve_gpu_policy so they never disagree (PR #176 review). A validated constant.""" return 1.1 def required_vram_gb( model_id: str, algorithm: str, *, train=None, thinking: bool = False, gpu_count: int = 1, ) -> int: """VRAM the full run needs, sized to the run's actual knobs (context length, LoRA rank, batch / group size, thinking) via the shared ``model_required_vram_gb`` matrix. Catalog GRPO floors stay hard floors (never under-provision a validated model); the matrix sizes up from there for big contexts/groups and down to a cheaper card for small runs. Unlisted open models size from HF metadata, falling back to the 24 GB tier when unreadable (handled inside model_required_vram_gb).""" from autoslm.engine.vram import model_required_vram_gb colocate = model_required_vram_gb( model_id, algorithm, train=train, thinking=thinking, headroom=vram_headroom(), ) # Disaggregated GRPO ([train].inference_gpus>0) splits memory across the node's GPUs: the # inference server (full bf16 weights + KV) and the trainer (quant weights + LoRA optimizer + # activations) live on SEPARATE cards, so no single GPU needs the colocate total. The binding # per-GPU need is max(server bf16 weights + KV/overhead, the trainer's share ~= colocate minus # the vLLM engine/KV). Sizing to that lets a big model fit a per-role card (e.g. Qwen3.6-35B-A3B # served bf16 on a 94GB H100 NVL, 4-bit trainer on the other) instead of demanding the colocate # floor (~96GB) — which no available 2-GPU node meets — while staying FLOORED by the bf16 weights # so the server can never be under-provisioned into an OOM. Also unblocks 4B 1:2 on a 5090 (the # disaggregated server/trainer each fit 32GB though colocate 4B needs ~35GB). if train is not None and int(getattr(train, "inference_gpus", 0) or 0) > 0: pb = _params_b_for_vram(model_id) if pb: infer = max(1, int(getattr(train, "inference_gpus", 1) or 1)) # Total GPUs on the node (rollout + trainer). The trainer pool is everything that # isn't a rollout GPU; default to a single trainer when the caller didn't pass a count # (the colocate cap below still protects that degenerate case). total = max(infer + 1, int(gpu_count or (infer + 1))) n_trainer = max(1, total - infer) base = 2.0 * pb # frozen base model, bf16, ALL params resident (MoE: every expert loaded) # ROLLOUT card. The baked verl default is DATA-PARALLEL (TP=1) — each replica holds the # FULL base + KV. A base too large to fit one 80GB card as a DP replica is served # TENSOR-PARALLEL across the inference GPUs instead (verl_runner auto-bumps # AUTOSLM_VERL_ROLLOUT_TP to match), so size per shard. Floors the per-card need so the # inference GPU is never under-provisioned into a KV/weights OOM. rollout_tp = infer if (base * 1.35 + 4) > 78 else 1 rollout_need = int(base * 1.35 / rollout_tp) + 4 # weights/shard + KV / CUDA-graph / overhead # TRAINER card. FSDP2 shards the frozen base (+ tiny LoRA grads/optim) across the # n_trainer trainer GPUs; activations and the one_step_off *bucketed* weight-transfer # staging do NOT shard, so floor each card at base/n_trainer + a bounded transfer buffer + # fixed overhead. n_trainer==1 keeps the whole base on one card (matches the observed 4B # one-trainer OOM on a 24GB card — needed ~26GB, fits 40GB — while 4B sharded across two # trainers fits 24GB). The bucketed sync stages only a few layers, NOT a full second copy, # so 35B-A3B (70GB base) trains across 2 trainers at ~58GB/card and fits an 80GB H100/A100. transfer_buf = min(0.5 * base, 10.0) trainer_need = int(base / n_trainer + transfer_buf + 13) # Per-card requirement is the heavier role on a homogeneous node. This is already a true # per-card figure (both roles divided by their parallel degree), so no colocate cap — a # multi-GPU FSDP/TP split legitimately needs LESS per card than the whole colocated total. return max(rollout_need, trainer_need) return colocate def _params_b_for_vram(model_id: str) -> float | None: """Param count (billions) for disaggregated VRAM sizing: catalog first, then HF metadata.""" from autoslm.engine.vram import fetch_hf_params_b, params_b_from_str try: from autoslm.catalog import get_model pb = params_b_from_str(getattr(get_model(model_id), "params", None)) if pb: return pb except Exception: pass try: return fetch_hf_params_b(model_id) except Exception: return None def _runpod_candidates(need: int, pinned_gpu: str | None, allow_unval: bool) -> list[Candidate]: """RunPod's fitting classes priced live (static fallback).""" provider = get_provider("runpod") out: list[Candidate] = [] for g in provider.gpu_classes(): if g.vram_gb < need: continue if pinned_gpu and g.name != pinned_gpu: continue if "runpod" not in g.validated_on and not allow_unval: continue out.append( Candidate( "runpod", g.name, provider.hourly_rate(g.name), g.vram_gb, "runpod" in g.validated_on, ) ) return out def _vast_candidates( need: int, pinned_gpu: str | None, allow_unval: bool, disk_gb: int, exclude_machine_ids, *, required: bool, num_gpus: int = 1, ) -> tuple[list[Candidate], tuple]: """Vast's fitting classes from the live offer book (cheapest per class). Returns (candidates, full_offer_book). ``required`` (a hard ``provider="vast"`` pin) re-raises a search failure; otherwise it degrades to RunPod-only. """ from autoslm.providers.base import GPU_INFO from autoslm.providers.vast.jobs import MIN_DISK_GB, usable_offers # When a larger class is pinned for a small model, search at the PINNED class's VRAM, # not the (smaller) model requirement: the offer search returns the cheapest ``limit`` # offers from a VRAM floor, so a search at ``need`` can fill that window entirely with # small cheap cards and never surface the pinned larger class. ``need`` is still the # validity floor (allocate() rejects an undersized pin before we get here). search_vram = max(need, GPU_INFO[pinned_gpu].vram_gb) if pinned_gpu else need book: list = [] try: # The offer search must use the SAME disk floor instances are actually # provisioned with (``create_instance``/``_effective_disk_gb``); searching at a # smaller requested ``disk_gb`` would surface offers that then fail to rent. book = usable_offers( search_vram, max(float(disk_gb), MIN_DISK_GB), exclude_machine_ids=exclude_machine_ids, num_gpus=num_gpus, ) except Exception as exc: if required: raise UnsupportedGpuError(f"vast offer search failed: {exc}") from exc logger.warning("vast offer search failed (%s); allocating on runpod only", exc) out: list[Candidate] = [] seen: set[str] = set() for o in book: if pinned_gpu and o.gpu != pinned_gpu: continue info = GPU_INFO[o.gpu] if "vast" not in info.validated_on and not allow_unval: continue if o.gpu in seen: # offers are price-sorted; keep the cheapest per class continue seen.add(o.gpu) out.append( Candidate( "vast", o.gpu, o.dph_total, info.vram_gb, "vast" in info.validated_on, offer=o ) ) return out, tuple(book) def allocate( model_id: str, algorithm: str, *, gpu: str | None = None, provider: str = "auto", disk_gb: int = 60, allow_unvalidated: bool | None = None, exclude_machine_ids: set[int] | frozenset[int] = frozenset(), exclude_gpu_classes: set[str] | frozenset[str] = frozenset(), gpu_count: int = 1, train=None, thinking: bool = False, ) -> Allocation: """Pick the cheapest (provider, GPU class) able to run the job across providers. ``gpu`` pins the class (the allocator then only picks the provider); ``provider`` pins the substrate ("auto"/"runpod"/"vast"). Both default to fully automatic. ``train``/``thinking`` size the requirement to the run's actual knobs (context, group, rank, batch) via the matrix — long context / large group route up, small runs down. ``exclude_gpu_classes`` drops whole GPU classes (any provider) from the candidate pool — the orchestrator adds a class here after it failed ``no_capacity`` (capacity-starved / throttled) so re-allocation walks to the next-cheapest AVAILABLE class instead of retrying the same starved one on another provider. """ _excluded_classes = {canonical_gpu(c) for c in exclude_gpu_classes} if provider not in ("auto", *PROVIDER_NAMES): raise UnsupportedGpuError( f"unknown provider {provider!r} (auto, {', '.join(PROVIDER_NAMES)})" ) pinned_gpu = canonical_gpu(gpu) if gpu else None # The model's requirement is the floor regardless of a pin: an undersized concrete # pin (e.g. Qwen3-8B on a 24 GB card) must drop out of the candidate filter and # raise here, not provision a paid worker that OOMs. The pin only narrows WHICH # fitting class is chosen, never lowers the VRAM bar. need = required_vram_gb(model_id, algorithm, train=train, thinking=thinking, gpu_count=gpu_count) allow_unval = unvalidated_allowed(allow_unvalidated) live = available_providers() if provider != "auto" and provider not in live: raise UnsupportedGpuError( f"provider {provider!r} requested but not available on this control plane " f"(available: {', '.join(live) or '(none)'}; vast needs VAST_API_KEY)" ) def _gather(pin: str | None) -> tuple[list[Candidate], tuple]: cands: list[Candidate] = [] book: tuple = () if provider in ("auto", "runpod") and "runpod" in live: cands += _runpod_candidates(need, pin, allow_unval) if provider in ("auto", "vast") and "vast" in live: vcands, book = _vast_candidates( need, pin, allow_unval, disk_gb, exclude_machine_ids, required=(provider == "vast"), num_gpus=gpu_count, ) cands += vcands if _excluded_classes: cands = [c for c in cands if c.gpu not in _excluded_classes] return cands, book candidates, offer_book = _gather(pinned_gpu) # NEVER hard-fail on availability: a pin that no live provider can serve (the class isn't # offered right now, or is below ``need`` so it's filtered out) escalates to the cheapest # FITTING class across providers instead of raising -- "one spot larger, and so on". The # ``need`` floor is still absolute (we never drop below it -> no OOM), and the pin is only a # preference. We only raise when NOTHING >= need is available anywhere (truly unsatisfiable). escalated_from = None if not candidates and pinned_gpu is not None: escalated_from = pinned_gpu candidates, offer_book = _gather(None) if not candidates: raise UnsupportedGpuError( f"no allocatable GPU (>= {need} GB VRAM for {model_id}, provider={provider}, " f"validated_only={not allow_unval}); widen with gpu.allow_unvalidated = true, add a " f"provider (VAST_API_KEY), or the run genuinely exceeds every available GPU class" ) if escalated_from is not None: order0 = {n: i for i, n in enumerate(PROVIDER_NAMES)} _cheapest = sorted(candidates, key=lambda c: (c.hourly_usd, c.vram_gb, order0.get(c.provider, 99)))[0] # WARNING level so it surfaces at default `slm train` verbosity (configure_logging is # WARNING) — a silently-escalated pin changes cost/hardware and operators must see it; # still routed through the logger (stderr), so machine-readable stdout stays clean. logger.warning( "pinned GPU %r unavailable or below need (%s GB) on provider=%s; " "escalated to cheapest fitting class %s (%s GB, %s)", escalated_from, need, provider, _cheapest.gpu, _cheapest.vram_gb, _cheapest.provider, ) # Cheapest first; equal rates prefer less VRAM (don't burn a big card on a small # job), then registry order (runpod is the longest-validated substrate). order = {n: i for i, n in enumerate(PROVIDER_NAMES)} ranked = sorted(candidates, key=lambda c: (c.hourly_usd, c.vram_gb, order.get(c.provider, 99))) best = ranked[0] return Allocation( provider=best.provider, gpu=best.gpu, hourly_usd=best.hourly_usd, min_vram_gb=need, candidates=tuple(ranked), offer=best.offer, provider_offers=offer_book, ) def allocation_summary(a: Allocation) -> str: head = ( f"allocated {a.gpu} on {a.provider} at ${a.hourly_usd:.2f}/hr " f"(need >= {a.min_vram_gb} GB VRAM" ) # ``a.offer`` is an OPAQUE per-provider provisioning hint, not necessarily a Vast # offer — only format Vast specifics when the chosen provider is vast, so a future # provider's hint never misformats or raises on a missing attribute. if a.provider == "vast" and a.offer is not None: head += f", vast offer {a.offer.offer_id} in {a.offer.geolocation}" head += ")" if len(a.candidates) > 1: nxt = a.candidates[1] head += f"; next-best: {nxt.gpu}@{nxt.provider} ${nxt.hourly_usd:.2f}/hr" return head