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preference-optimization

Align a fine-tuned model with preference data using DPO, ORPO, KTO, or SimPO. Use when preference pairs or thumbs-up/down feedback exist, when choosing between preference-optimization methods, or when a DPO run needs hyperparameters or debugging.

How do I install this agent skill?

npx skills add https://github.com/wshobson/agents --skill preference-optimization
view source ↗

Is this agent skill safe to install?

  • Gen Agent Trust Hubpass

    This skill provides technical guidance and configuration templates for fine-tuning models using preference optimization techniques like DPO and ORPO. It uses standard machine learning libraries and follows established training best practices. No security risks were identified.

  • Socketpass

    No alerts

  • Snykpass

    Risk: LOW · No issues

What does this agent skill do?

Preference Optimization

This skill assumes finetuning-method-selection already routed here because the data shape is preference pairs or unpaired thumbs-up/down feedback, not demonstrations (that's lora-qlora-recipes) or a verifiable reward signal (that's grpo-rlvr-training). What follows is method selection among the DPO family, the evidence for how much that selection actually matters, the production training pattern, and how to build the pairs in the first place.

Input: a routing decision (preference optimization) plus preference pairs or unpaired feedback, usually from an SFT checkpoint. Output format: a validated method choice plus a config — the kwarg values in references/method-configs.md, not free-form advice — that llm-finetuning-training-engineer consumes directly.

Method Selection

Data shapeMethodKey parameters
Preference pairs, default caseDPOβ=0.1, LR 5e-7–1e-6, 1–2 epochs
Memory-bound or no SFT checkpointORPOreference-free, fused SFT+preference in one loss
Unpaired thumbs-up/downKTObinary label per example, no pairing needed
Length bias observed, sweep budget availableSimPOreference-free; see sweep grid below
  • DPO is the safe default. Use β=0.1 and a learning rate of 5e-7 to 1e-6 for 1–2 epochs. This LR is lower than the SFT LR that produced the checkpoint being aligned — porting an SFT- scale LR into a DPO run is the most common misconfiguration here, not an edge case.
  • ORPO routes in when memory is the constraint, or when there's no separate SFT checkpoint to start from — it's reference-free and fuses the SFT and preference objectives into one loss, skipping the separate SFT pass and the reference-model memory cost DPO carries.
  • KTO routes in when feedback is unpaired binary signal (thumbs-up/down) rather than matched preference pairs — don't force unpaired feedback into synthetic pairs to use DPO instead.
  • SimPO fixes DPO's length bias but only pays off with disciplined sweeping — its published gains are a ceiling reported under a tuned sweep, not a baseline any single config will reproduce. Route here only when there's sweep budget; use DPO instead if there isn't.
  • Classic RLHF (reward model + PPO) is retired outside frontier labs. Don't reach for it in a production pipeline — every method above is cheaper and better-supported for the same data shapes.

Worked Examples

  • "We have an SFT checkpoint and clean paired preference data, no length-bias complaints yet." → default case → DPO at β=0.1.
  • "Reviewers click thumbs-up/down per response; nothing is paired." → unpaired signal → KTO, not DPO — don't synthesize pairs to force DPO onto unpaired data.
  • "GPU budget doesn't cover a separate SFT pass plus a DPO reference model." → memory-bound, no separate checkpoint → ORPO.
  • "DPO output favors longer answers regardless of quality, and there's time to run a sweep." → length bias plus sweep budget → SimPO. Skip it if the sweep budget isn't actually there.

The Low-Leverage Truth

A 2026 240-H100-run study (arXiv 2603.19335) is the load-bearing evidence behind the table above: loss-function choice is worth roughly 1 percentage point of leverage, model scale is worth roughly 50. Zero of 20 DPO variants tested beat vanilla DPO. Rankings also invert with scale — a variant that wins in a small pilot can lose at deployment size.

Two practical consequences:

  • Don't spend a routing decision agonizing over DPO-variant bake-offs. The table above is sufficient; deeper variant selection is low-leverage compared to data quality and scale.
  • Validate at deployment scale before trusting a ranking. A method comparison run on a small pilot model doesn't transfer to the production size class — re-check the winner once scale changes.

This is also why the Method Selection table above is deliberately short: it encodes the ~1pp lever, not a ranking of DPO variants that the same study shows doesn't hold up across scale. Treat any variant-selection advice that isn't in that table — including advice that claims a specific variant "wins" — as unproven until it's been validated at the target deployment size.

Production Pattern: Iterative On-Policy DPO

A single offline DPO pass on a static preference dataset is a starting point, not the production pattern. The policy drifts away from the distribution the pairs were sampled from as training proceeds, and a static dataset goes stale against that drift. Production pipelines run DPO iteratively and on-policy instead:

  1. Sample completions from the current policy checkpoint.
  2. Score or rank the completions (reward model, judge, or task grader).
  3. Run a DPO pass using the current checkpoint as the reference model.
  4. The resulting checkpoint becomes both the new policy and the new reference for the next round.

Repeat. Each round's reference model is the prior round's output, not a fixed initial checkpoint — that's what keeps the preference signal on-policy instead of scoring against an increasingly stale distribution.

A single-pass DPO run is still a reasonable first iteration — it just isn't the whole pipeline. Plan for at least one more round once the first checkpoint exists, rather than treating pass one as the finished artifact.

Pair Construction

Build DPO/ORPO pairs from same-task passing-vs-failing trajectories — two attempts at the same underlying task, not unrelated best-and-worst examples pulled from different tasks. Within that trajectory set, select the rejected member at μ−2σ of the reward distribution, never the minimum. Naive best-vs-worst pair construction (max reward vs. absolute minimum) degrades as scale increases; the μ−2σ selection is more robust to the same scale sensitivity the low-leverage study surfaced above.

sorted_by_reward = sort(trajectories, key=reward)
chosen   = sorted_by_reward[-1]                # highest reward
mu, sigma = mean(rewards), stdev(rewards)
rejected = closest(sorted_by_reward, mu - 2 * sigma)
# NOT sorted_by_reward[0] — the absolute minimum
# is the naive best-vs-worst construction that
# degrades as scale increases.

For the mechanics of turning graded traces into these pairs — including rejection sampling and judge-scored delta selection — see trace-to-training-data.

References

Complete TRL config blocks per method — DPOConfig, ORPOConfig, KTOConfig, and the SimPO sweep grid — plus Unsloth wrappers and a catastrophic-forgetting note live in references/method-configs.md. Those configs use the same current-TRL API conventions established in lora-qlora-recipes's references/unsloth-trl-mapping.md (processing_class, not tokenizer=).

references/method-configs.md also carries the catastrophic-forgetting note: a too-high learning rate is the usual cause when a preference-tuned checkpoint loses general capability, and the fix is almost always to drop the LR toward the low end of the range in the Method Selection table above before reaching for any other remediation.

Related skills: finetuning-method-selection routes here once preference pairs or unpaired feedback exist; lora-qlora-recipes produces the SFT checkpoint DPO/KTO/SimPO align (ORPO's fused path can skip it); trace-to-training-data converts passing/failing trajectories into the pairs this skill's Pair Construction section consumes.

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/preference-optimization">View preference-optimization on skillZs</a>