lora-qlora-recipes
Configure LoRA and QLoRA supervised fine-tuning with current best-practice hyperparameters. Use when writing or reviewing a LoRA/QLoRA training configuration, choosing rank/alpha/target modules, or deciding between LoRA, QLoRA, and full fine-tuning.
How do I install this agent skill?
npx skills add https://github.com/wshobson/agents --skill lora-qlora-recipesIs this agent skill safe to install?
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This skill provides configuration best practices and code templates for LoRA and QLoRA supervised fine-tuning using the Unsloth library. It includes hyperparameter recommendations, memory optimization strategies, and technical workarounds for specific library behaviors. No security risks or malicious patterns were detected.
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What does this agent skill do?
LoRA & QLoRA Recipes
This skill assumes the routing decision already
happened — finetuning-method-selection should
have already pointed here because the data shape
is demonstrations (SFT), not preference pairs or
a verifiable reward signal. What follows is the
current best-practice recipe for configuring the
adapter itself: which modules to target, how to
size rank and alpha, what learning rate to use,
and when QLoRA buys real headroom versus when it
just adds risk. Dataset preparation and quality
checks are a separate concern — see
dataset-curation.
Input: a routing decision (SFT via LoRA/
QLoRA) plus a target size class.
Output format: a validated adapter config —
the kwarg values below, not free-form advice —
that llm-finetuning-training-engineer consumes
directly when it generates a runnable script.
The Reference Recipe
The reference recipe is "LoRA Without Regret" (Thinking Machines/Schulman, 2025-09), now the settled convention for LoRA/QLoRA SFT.
Target Modules
Target all-linear modules, not just attention:
target_modules = [
"q_proj", "k_proj", "v_proj", "o_proj", # attention
"gate_proj", "up_proj", "down_proj", # MLP — matters most
]
The MLP layers (gate_proj, up_proj,
down_proj) matter most — attention-only
targeting was the older, weaker convention.
Dropping modules to save memory is a Failure
Mode below, not a valid optimization.
Alpha and Learning Rate
lora_alpha = 2 * ris the settled convention (NeurIPS 2025 "intruder dimensions" result). Don't hand-tune alpha independently of rank — derive it from rank every time.- LoRA learning rate ≈ 10x the equivalent
full-fine-tune LR. For QLoRA specifically,
2e-4 is the standard starting point. Full
hyperparameter tables and worked examples:
references/hyperparameters.md.
Rank by Task
Rank is task-shaped, not a single global default:
| Task | Rank |
|---|---|
| RL (GRPO/RLVR adapters) | 1–32 |
| General default | 16–32 |
| SFT at scale | up to ~256 |
Higher rank isn't automatically better — it raises capacity to memorize as fast as it raises capacity to generalize. Start at the row matching the task, and only move up a row if the lower rank measurably underfits on held-out eval, not as a default hedge.
Effective Batch Size
Keep effective batch size under 32. This recipe was validated at that scale — pushing effective batch higher is an untested extrapolation, not a free throughput win.
Unsloth Defaults
Unsloth is the reference implementation this
plugin assumes as the default fast path — except
for messages-shaped conversational SFT with
assistant_only_loss=True, where Unsloth
2026.7.x's compiled trainer has no messages-shaped
path at all and the plain-TRL escape hatch
(references/unsloth-trl-mapping.md) is the
default for that combination, not a rare-regression
fallback. Its out-of-the-box defaults, and why
each one is set that way:
lora_dropout=0— the optimized kernel path assumes zero dropout; setting a nonzero value forfeits the fused-kernel speedup.bias="none"— bias terms add adapter parameters for negligible quality gain at this rank range.use_gradient_checkpointing="unsloth"— Unsloth's checkpointing variant, not vanilla HF checkpointing; saves roughly 30% VRAM over no checkpointing.optim="adamw_8bit"— 8-bit AdamW cuts optimizer-state memory with negligible quality impact at LoRA/QLoRA adapter scale.random_statefixed — pins LoRA initialization for reproducibility across runs; treat it like any other seed, not a tunable.
These show up together on the get_peft_model
call:
model = FastLanguageModel.get_peft_model(
model,
r=32,
target_modules=target_modules,
lora_alpha=64, # 2 * r
lora_dropout=0,
bias="none",
use_gradient_checkpointing="unsloth",
random_state=3407,
)
Exact kwarg names and their plain-TRL/PEFT
equivalents, plus a full worked config including
SFTConfig: references/unsloth-trl-mapping.md
and references/hyperparameters.md.
LoRA vs QLoRA vs Full FT
| Situation | Default choice |
|---|---|
| Adapting behavior on demonstrations | LoRA |
| Base model doesn't fit in bf16 at target rank | QLoRA |
| Injecting dense new domain knowledge | Full FT (see finetuning-method-selection) |
| Unsure which one | LoRA — upgrade to QLoRA only if memory forces it |
- QLoRA = NF4-quantized frozen base weights + BF16 adapters. This is what makes a 65B-class model trainable on 48GB — the quantized base is the memory win, not the adapter itself.
- Full fine-tuning is not a default. Reserve it for dense knowledge injection where the goal is changing what the model knows at the weight level, not adapting a behavior. For everything else in this skill's scope, LoRA or QLoRA is the starting assumption.
- On DGX Spark, QLoRA can OOM before an
equivalent bf16 LoRA run would, even though
QLoRA's steady-state footprint is smaller —
bitsandbytes dequantization buffers are
transient CUDA-side allocations that spike
during load. A QLoRA OOM is not proof the model
doesn't fit; the
dgx-spark-opsplugin'sspark-memory-thermal-opsskill covers the full OOM remediation ladder (bf16 LoRA is the next thing to try, not a further QLoRA shrink).
Failure Modes
-
fp16 divergence on non-BF16 GPUs. Training in fp16 on hardware that doesn't have solid BF16 support is a known source of loss spikes and silent divergence. Force
bf16=Truewherever the hardware supports it; don't fall back to fp16 as if it were equivalent. Check hardware support before picking a dtype:python -c "import torch; print(torch.cuda.is_bf16_supported())" -
Rank too high on a small dataset overfits. A rank picked for "SFT at scale" (up to ~256) on a dataset that doesn't have scale behind it memorizes rather than generalizes. Match rank to the Rank by Task table above, not to the largest number available.
-
Removing target modules to save memory costs quality for negligible savings. The adapter parameters on
gate_proj/up_proj/down_projare a small fraction of total model size — cutting them barely moves memory but measurably hurts quality. If memory is tight, move to QLoRA or reduce rank/batch/pack length before trimming target modules.
All three failure modes share a pattern: they look like a training-loop bug (loss spikes, plateaus, memorization) but are actually a config choice that contradicts the reference recipe above. Check configuration against this skill before debugging the training loop itself.
References
references/hyperparameters.md— full rank/ alpha/LR tables by task type, rsLoRA notes, batch/packing interactions, and a complete worked Unsloth config block.references/unsloth-trl-mapping.md— every Unsloth kwarg mapped to its TRL/PEFT equivalent, current TRL API notes, and the escape-hatch rule for when to drop back to plain TRL.
Related skills: finetuning-method-selection
routes here; dataset-curation covers the data
side this skill doesn't; llm-finetuning-training-engineer
is the downstream consumer of the config this
skill produces.
How can the creator link this skill?
Add the canonical catalog link to the repository README so users can inspect current installs and available audits. The publishing guide covers the complete discovery path.
<a href="https://skillzs.dev/skills/wshobson/agents/lora-qlora-recipes">View lora-qlora-recipes on skillZs</a>