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REVIEW 2 major objections 6 minor 67 references

Reviewed by Pith at T0; open to challenge.

T0 means a machine referee read the full paper against a public rubric. The mark states how deep the mechanical check went, never who wrote it. the ladder, T0–T4 →

T0 review · glm-5.2

Choosing training data is already alignment, not just efficiency

2026-07-09 21:27 UTC pith:DBSHU275

load-bearing objection Solid core finding with fixable gaps the 2 major comments →

arxiv 2607.07023 v1 pith:DBSHU275 submitted 2026-07-08 cs.LG

Online Data Selection Is Implicit Alignment

classification cs.LG
keywords onlinedataalignmentbehavioralselectiondriftimplicitmodel
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved

The pith

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

This paper argues that when you filter which examples to train a language model on during supervised fine-tuning, the selection rule acts as an implicit reward model that shifts the model's behavior along axes normally associated with alignment: refusal rate, verbosity, sycophancy, truthfulness, and jailbreak robustness. The authors formalize online data selection as a reweighting of the SFT objective, where the selector's scores define a tilted training distribution that over-represents certain response styles or safety postures. They show empirically that selectors producing statistically indistinguishable task accuracy can diverge by more than 8 points in harmful-refusal rate and over 3 points in benign over-refusal, with the direction of each shift predictable from which behavioral attributes the selected data enriches. A loss-based selector enriches premise-agreement examples and increases sycophancy; a quality-based selector enriches long answers and refusal markers, raising both helpfulness and over-refusal simultaneously. The paper introduces Alignment Drift Auditing, a protocol that measures this drift under equal token budgets, and Alignment-Aware Selection, a selector that constrains the behavioral attribute mixture of the chosen data to reduce drift while preserving data efficiency.

Core claim

Two SFT runs with identical base model, optimizer, token budget, and task accuracy can produce models with sharply different refusal rates, verbosity, sycophancy, and jailbreak robustness, solely because the online data selector over-represents certain behavioral attributes in the training subset. The direction and magnitude of this drift is predictable from the enrichment ratios of the selected data, formalized through a first-order bound linking the attribute mixture shift to behavioral change via the gradient-behavior Jacobian.

What carries the argument

The central object is the reweighted SFT objective, where an online selector assigns weights w_π(i) to candidate examples, inducing a tilted training distribution q_π. The alignment drift is formalized through Proposition 1, which gives a first-order bound: the behavioral change between two selectors equals the Jacobian mapping parameter updates to behavior, applied to the difference in their weighted gradient means, plus second-order remainder. Under a clustering assumption that gradients concentrate within behavioral attribute groups, this bound reduces to a function of the enrichment gap, the difference in attribute-group mass between the selected subset and the full pool, weighted by how

Load-bearing premise

The clustering assumption that training gradients concentrate within behavioral attribute groups, meaning examples sharing a style like verbosity or refusal format produce similar gradient directions. This bridges the abstract gradient-space theory to the empirical data-mixture diagnostics, but it is verified only on a subset of runs without full quantitative reporting across all attribute groups.

What would settle it

If two selectors with identical task accuracy and identical enrichment ratios on all measured behavioral attributes still produce significantly different behavioral drift, the claimed link from data-mixture diagnostics to behavioral outcomes would break, since the enrichment gap would no longer predict drift direction.

Watch this falsifier — get emailed when new claim-graph text bears on it.

If this is right

  • Any paper or system reporting online SFT data selection results should report behavioral drift metrics alongside task accuracy, since equal efficiency can mask divergent safety and style profiles.
  • Preference optimization stages in post-training pipelines are not starting from a neutral SFT base; the selected data has already moved the model toward or away from desired behavioral regions, so SFT selection and preference optimization should be co-designed.
  • The framing of 'data quality' as a neutral, behaviorally inert concept is insufficient; high-quality data carries a persona with specific verbosity, deference, and caution characteristics that become the model's default behavior.
  • Alignment-Aware Selection demonstrates that constraining the behavioral attribute mixture of selected data via a maximum mean discrepancy penalty can reduce drift by more than half relative to unconstrained selectors while preserving most task gains.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit.

Referee Report

2 major / 6 minor

Summary. The paper argues that online data selection during SFT is not a neutral efficiency layer but an implicit alignment mechanism: different online selectors (loss-based, quality-based, diversity-based) induce directional behavioral drift along alignment-relevant axes (refusal rate, verbosity, sycophancy, jailbreak robustness) even when matched on task accuracy. The authors formalize selection as importance reweighting of the SFT objective (§3.1, Eqs. 4–7), derive a first-order drift bound (Proposition 1, Eq. 8), and connect it to data-mixture enrichment under a clustering assumption (Appendix A, Eq. 19). They introduce Alignment Drift Auditing (ADA), a controlled protocol for measuring behavioral drift under equal token budgets, and Alignment-Aware Selection (AAS), a diagnostic selector that constrains drift via an MMD penalty on attribute mixtures. Empirically, Table 1 shows that selectors within 0.8 points of task accuracy differ by >8 points in harmful-refusal rate; Table 2 shows enrichment ratios that track the observed drift directions; Tables 3–4 show budget trends and AAS ablations.

Significance. The conceptual reframing — that an online scorer occupies the role normally held by a reward model — is timely and practically important. The ADA protocol (matched budgets, paired seeds, eight-axis behavioral suite, enrichment diagnostics) is a genuine methodological contribution that could standardize how selection papers report side effects. The formal framework (selection as importance reweighting, first-order drift bound) is correct and provides useful vocabulary. The AAS selector is presented appropriately as a diagnostic rather than a production method. The paper ships falsifiable predictions (drift direction tracks enrichment) and a reproducible experimental grid (budget sweep, judge robustness in Appendix E, ablation in Table 4).

major comments (2)
  1. §5.6 and Appendix A: The clustering assumption A4 (within-group gradient concentration, bounded by τ) is the formal bridge between the abstract Proposition 1 and the empirical enrichment ratios (Eq. 19). The paper states this is 'verified empirically in the mechanistic diagnostics' (§3.1), but §5.6 only describes the diagnostics qualitatively for 'a subset of runs' and never reports numerical values of τ across attribute groups. Without quantifying τ, a reader cannot assess whether Eq. 19's bound is tight enough to be genuinely predictive or merely post-hoc consistent. The gradient alignment measure α(k)_π (Eq. 13) is defined but no actual values are reported in any table or figure. Reporting τ and α(k)_π for the attribute groups in Table 2 would substantially strengthen the mechanistic claim. This is load-bearing because the enrichment-to-drift link is the paper's stronger, more novel贡献
  2. §5.3 and Table 2: The predictability claim ('the direction of the shift is predictable from the attribute mixture of the selected data') is supported by enrichment-drift consistency across only four selectors (Loss, Quality, Diversity, AAS). With n=4 and no held-out validation — e.g., predicting drift direction for a new selector from its enrichment profile alone — 'predictable' overstates what is demonstrated. AAS's success (Tables 1, 4) provides indirect support (if enrichment didn't matter, constraining it shouldn't help), but AAS is evaluated within the same framework and metrics, functioning as a consistency check rather than independent validation. Adding one or two additional selectors with a priori enrichment predictions, or softening the claim to 'consistent with,' would address this without changing the paper's scope.
minor comments (6)
  1. Table 1: The 'Avg. tokens' column header is ambiguous — it is unclear whether this refers to selected-data tokens, output tokens at evaluation, or training tokens per example. Clarifying would help reproducibility.
  2. §4.1: The paper mentions a 'full-fine-tuning run to rule out an adapter artifact' but does not report its results in any table. A one-line summary (e.g., 'full FT confirms the same selector ordering on D_A') would suffice.
  3. Eq. (9): The coverage term c(S) and its submodular properties are referenced but c(S) is never explicitly defined. The greedy rule in Eq. (10) references λΔc(x|S), but the reader must infer the form of c from context.
  4. Figure 2 (right panel): The signed drift heatmap uses a color scale that is difficult to parse in grayscale; the values are readable but the visual encoding could be clearer.
  5. §3.2: The claim that quality and diversity scorers 'subsume the utility-style online selectors' (citing [15, 16]) is stated without justification. A brief argument for why utility-based selectors are instances of these families would help.
  6. Appendix B: The calibrated enrichment estimator (Eq. 20) is a nice detail, but the confusion rates ρ_fp, ρ_fn are reported only as a range (Cohen's κ 0.86–0.94). Reporting the actual confusion rates per attribute family would make the correction fully reproducible.

Circularity Check

0 steps flagged

No significant circularity found; derivation chain is self-contained with standard assumptions

full rationale

The paper's derivation chain is not circular. Proposition 1 (Eq. 8) is a standard first-order Taylor expansion of a behavior function b(θ) under gradient descent — the inputs (gradient means, Jacobian) are not defined in terms of the output (behavioral drift). The enrichment bound (Eq. 19) follows from the clustering assumption A4, which is an explicitly stated empirical assumption, not a definition that forces the conclusion. The 'predictability' claim — that drift direction tracks attribute enrichment — is tested by comparing enrichment ratios (Table 2, computed from selected data) against behavioral metrics (Table 1, measured on held-out benchmarks like TruthfulQA and HarmBench). These are independent measurements; the correlation between them is an empirical observation, not a tautology. AAS (Eq. 9-10) uses an MMD penalty to match attribute distributions, and its reduced drift (Table 1) is measured on the same independent behavioral benchmarks — this is a legitimate test of the theory, not circular reasoning. Self-citations ([26], [51], [52], [57], [58], [61]) appear in Related Work and Limitations for context, none are load-bearing for the central claim. The score of 2 reflects minor self-citation presence that is not load-bearing; the central derivation is parameter-free and independently testable.

Axiom & Free-Parameter Ledger

3 free parameters · 4 axioms · 2 invented entities

The axiom ledger is lean. The paper introduces no new physical entities or ad-hoc mathematical objects. The free parameters (lambda, rho, w_j) are standard hyperparameters of the AAS method, not fitted constants of a theory. The clustering assumption A4 is the most consequential axiom and is only partially verified.

free parameters (3)
  • lambda (coverage weight in AAS) = not reported
    Weight on the coverage term c(S) in the AAS objective (Eq. 9). Value not specified in the paper.
  • rho (MMD penalty strength in AAS) = not reported
    Controls the trade-off between utility selection and attribute matching in AAS (Eq. 9). Value not specified; the paper says it interpolates between pure utility (rho=0) and attribute-matched (rho→∞).
  • w_j (safety-critical axis weights) = default 1
    Optional weights in the drift magnitude DA (Eq. 12) that upweight safety-critical axes. Default is w_j≡1 but the paper does not report what values were used.
axioms (4)
  • domain assumption Clustering assumption (A4): within-group gradient concentration, gi = ḡ(k) + εi with bounded ||Σεi/N|| ≤ τ
    Invoked in Appendix A to derive the enrichment bound (Eq. 19) that connects data-mixture diagnostics to behavioral drift. This is the load-bearing assumption for the paper's central bridge between selected-data attributes and model behavior.
  • domain assumption Behavior vector b(θ) is a smooth functional of parameters with bounded Jacobian (A2: β-smooth)
    Invoked in Appendix A for the first-order Taylor expansion in Prop. 1. Standard for neural networks but the smoothness constant β is not estimated.
  • domain assumption SFT loss is twice differentiable with bounded Hessian (A1: ||∇²ℓ|| ≤ L)
    Invoked in Appendix A. Standard assumption for gradient-based optimization analysis.
  • domain assumption LLM judges provide reliable behavioral evaluations
    The behavioral metrics (helpfulness, sycophancy, truthfulness) rely on LLM judges. The paper acknowledges this is imperfect (§Limitations) and provides a robustness check (Table 5) showing stable rankings, but absolute metric validity is assumed.
invented entities (2)
  • Alignment Drift Auditing (ADA) independent evidence
    purpose: Protocol for quantifying selection-induced behavioral movement across 8 axes under matched budgets
    ADA is a methodological framework, not a physical entity. Its validity is tested by the experiments in §5 showing measurable drift. It is falsifiable: if selectors produced no behavioral differences, ADA would show zero drift.
  • Alignment-Aware Selection (AAS) independent evidence
    purpose: Diagnostic online selector that constrains drift via MMD penalty on behavioral attributes
    AAS is a concrete algorithm (Eq. 9-10) with a greedy selection rule. Its effectiveness is tested in Table 1 and Table 4, showing reduced drift while preserving task performance. Falsifiable: if AAS did not reduce drift, the method would be invalid.

pith-pipeline@v1.1.0-glm · 21866 in / 2797 out tokens · 245696 ms · 2026-07-09T21:27:33.019742+00:00 · methodology

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read the original abstract

Supervised fine-tuning (SFT) is often treated as a capability-adaptation step, while alignment is attributed to later preference optimization or reinforcement learning. This separation is incomplete: when examples are scored and kept online during fine-tuning, the choice of which data to train on already changes the model's behavioral preferences. We study online data selection as an implicit alignment mechanism. Given the same base model, optimizer, and selected-token budget, we compare random, loss-based, quality-based, and diversity-based online selectors and measure the behavioral drift they induce without any preference optimization. The proposed evaluation tracks helpfulness, refusal rate, verbosity, truthfulness, sycophancy, calibration, and jailbreak robustness, together with diagnostics for which behavioral modes are over-represented in the selected data. We formalize online selection as a reweighted SFT objective whose weights define an implicit preference over response styles and safety postures, so that an online scorer plays the role usually assigned to a reward model. This view predicts that high-scoring data can systematically favor longer, more assertive, more compliant, or more refusal-prone behaviors depending on how the online score is defined. Empirically, selectors that are statistically indistinguishable in task accuracy diverge sharply in refusal rate, verbosity, and sycophancy, and we show that the direction of the shift is predictable from the attribute mixture of the selected data. We introduce Alignment Drift Auditing (ADA), a controlled protocol for quantifying selection-induced behavioral movement, and Alignment-Aware Selection (AAS), a diagnostic online selector that retains data efficiency while constraining drift along safety and style axes.

Figures

Figures reproduced from arXiv: 2607.07023 by Aoxiong Zeng, Xiangquan Yang, Yuxin Yang.

Figure 1
Figure 1. Figure 1: Data selection changes the empirical SFT ob [PITH_FULL_IMAGE:figures/full_fig_p002_1.png] view at source ↗
Figure 2
Figure 2. Figure 2: Result visualizations. Left: task/helpfulness improvements and alignment drift are not monotonically [PITH_FULL_IMAGE:figures/full_fig_p008_2.png] view at source ↗
Figure 3
Figure 3. Figure 3: Enrichment plot. High-utility and high-quality [PITH_FULL_IMAGE:figures/full_fig_p008_3.png] view at source ↗
Figure 4
Figure 4. Figure 4: Budget sweep. Online selection pressure is [PITH_FULL_IMAGE:figures/full_fig_p009_4.png] view at source ↗
Figure 6
Figure 6. Figure 6: Safety-boundary geometry. Off-diagonal movement indicates a conditional rather than global change in refusal behavior. AAS strengthens harmful refusal with little benign over-refusal. harmful refusal) while still raising benign refusal, a particularly undesirable combination. AAS lands near the harmful axis with little benign movement, i.e., it strengthens the boundary where it should without becoming glob… view at source ↗

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