M4.5: DiD Estimators — Design Spec

Goal

Add a did pipeline node that runs difference-in-differences estimators as a single coherent analysis. Internally, each estimator composes over existing regression primitives (FE demeaning, OLS, clustered SEs). Externally, it’s one node with typed params and a unified result containing event-study coefficients, ATT summaries, and pre-trends tests.

User story: Researcher pastes R code containing att_gt(), did2s(), or feols() with event-study syntax → Interlyse recognizes it as a DiD analysis → executes the estimator(s) → displays an event-study plot overlaying all estimators with confidence intervals.

Why now (between M4 and M5): DiD is the dominant method in applied econ. 3 of 6 reference papers use it. M5’s replication workflow needs DiD to validate against the JEL-DiD paper. The engine (M3 regression + M4 data pipelines) is ready; this milestone adds the meta-estimator layer on top.

Estimators (Tier 2)

Estimator	R Package	Internal approach
TWFE event-study	fixest (`i()` syntax)	Expand `i(event_time, ref=...)` into binary indicators, run existing `feols()` path
Gardner two-stage	did2s	Stage 1: OLS on untreated obs → residuals. Stage 2: OLS on residualized outcome with event indicators. Two calls to existing regression.ts
Callaway-Sant’Anna	did (`att_gt`)	Loop over (cohort, time) pairs, run 2×2 DiD on subsets via OLS, aggregate with proper weights. Bootstrap for inference (default 1000 iterations)
Sun-Abraham	fixest (`sunab()`)	Construct cohort × relative-time interaction indicators, run feols, reweight coefficients for aggregation
Borusyak imputation	didimputation	OLS on untreated observations → impute Y(0) for treated → ATT = Y - Y_hat(0). Influence-function SEs

Deferred (Tier 3): Roth-Sant’Anna (staggered) — specialized variance formula, lower usage. Slots in later as another run* function.

Architecture: Hybrid Monolithic Executor (Approach C)

One did executor with per-estimator error isolation via try/catch. Failed estimators produce error entries in the result; succeeded estimators display normally.

did-executor
│
├─ validatePanel(dataset, params)     → PanelInfo { units, times, cohorts, neverTreated }
├─ preparePanelData(dataset, params)  → adds time_to_treat, ever_treated, treatment columns
│
├─ try { runTWFE() }       → success | error
├─ try { runGardner() }    → success | error
├─ try { runCS() }         → success | error
├─ try { runSunAbraham() } → success | error
├─ try { runBorusyak() }   → success | error
│
└─ DiDResult
    ├─ succeeded: EstimatorResult[]
    ├─ failed: { estimator, error }[]
    ├─ eventStudyCoefs: Map<estimator, { time, coef, se, ciLower, ciUpper }[]>
    ├─ attSummary: Map<estimator, { att, se, pValue }>
    └─ preTrendsTest: Map<estimator, { fStat, pValue, df }>

Why this approach

One node = one analysis. DiD is conceptually one thing (estimate a treatment effect), even though it runs many regressions internally. Same abstraction level as FE (runs iterative demeaning internally) or GLM (runs IRLS internally).
Partial failure. If bootstrap for C-S fails but TWFE/Gardner succeed, show 4 of 5 results. Try/catch per estimator, no new architectural patterns.
Shared panel prep. Cohort detection, relative-time construction, and panel validation run once and feed all estimators.
Extensible. Adding Tier 3 = one new runStaggered() function + one try/catch block.

Reuses existing infrastructure

regression.ts OLS path — TWFE, Gardner stages, Borusyak imputation
demean.ts FE demeaning — TWFE and Sun-Abraham with unit+time FE
sandwich.ts clustered SEs — all estimators need clustering on unit
expression.ts data manipulation — constructing time_to_treat, treatment indicators
Dataset columnar storage — subsetting for (g,t) pair regressions in C-S

New primitives needed

Bootstrap inference — only for Callaway-Sant’Anna. Analytical SEs for all other estimators. Default 1000 iterations, configurable via params. Resample (unit, all-periods) blocks to preserve panel structure.
Event-study indicator expansion — i(time_to_treat, ref=c(-1, -Inf)) → binary columns for each relative time period, dropping reference periods. Reusable for TWFE and Sun-Abraham.
Cohort detection — identify treatment cohorts from gname column (unique non-zero/non-NA values of first-treatment-period variable).

Pipeline Types

Node type

interface DiDNode extends BaseNode {
  type: 'did';
  params: DiDParams;
  result?: DiDResult;
}

interface DiDParams {
  yname: string;                          // outcome variable
  tname: string;                          // calendar time variable
  idname: string;                         // unit/panel ID variable
  gname: string;                          // cohort variable (first treatment period; 0/Infinity = never-treated)
  estimators: DiDEstimator[];             // which estimators to run
  xformla?: Formula;                      // optional covariates (RHS of ~)
  weights?: string;                       // optional weight column
  clusterVar?: string;                    // cluster variable (defaults to idname)
  controlGroup: 'nevertreated' | 'notyettreated';  // who is the comparison group
  eventHorizon?: [number, number];        // relative time range [min_e, max_e] (default: data-driven)
  bootstrapIterations?: number;           // for C-S bootstrap (default: 1000)
  confidenceLevel?: number;               // for CIs (default: 0.95)
}

type DiDEstimator = 'twfe' | 'gardner' | 'callaway-santanna' | 'sun-abraham' | 'borusyak';

Result type

interface DiDResult {
  type: 'did';
  panelInfo: PanelInfo;
  estimatorResults: EstimatorOutcome[];
  eventStudyCoefs: Record<DiDEstimator, EventStudyCoefficient[]>;
  attSummary: Record<DiDEstimator, ATTSummary>;
  preTrendsTest: Record<DiDEstimator, PreTrendsTest>;
}

type EstimatorOutcome =
  | { estimator: DiDEstimator; status: 'success' }
  | { estimator: DiDEstimator; status: 'error'; error: string };

interface PanelInfo {
  nUnits: number;
  nPeriods: number;
  cohorts: { treatmentTime: number; nUnits: number }[];
  nNeverTreated: number;
  balancedPanel: boolean;
}

interface EventStudyCoefficient {
  relativeTime: number;   // e.g., -3, -2, -1, 0, 1, 2, 3
  estimate: number;
  se: number;
  ciLower: number;
  ciUpper: number;
  pValue: number;
  isReference: boolean;   // true for omitted reference period
}

interface ATTSummary {
  att: number;            // overall average treatment effect on the treated
  se: number;
  pValue: number;
  ciLower: number;
  ciUpper: number;
  nTreatedObs: number;
}

interface PreTrendsTest {
  fStat: number;
  pValue: number;
  df: [number, number];
  preCoefs: EventStudyCoefficient[];  // just the t < 0 coefficients
}

Ports

'did': {
  inputs: [{ name: 'dataset', type: 'dataset', label: 'Panel Data' }],
  outputs: [{ name: 'result', type: 'did-result', label: 'DiD Result' }],
}

Recognizer Patterns

Individual estimator calls → single `did` node

# Callaway-Sant'Anna
att_gt(yname = "y", tname = "year", idname = "id", gname = "first_treat",
       data = df, control_group = "notyettreated")
# → did node with estimators: ['callaway-santanna']

# Gardner two-stage
did2s(data, yname = "y", first_stage = ~0 | id + year,
      second_stage = ~i(time_to_treat), treatment = "treat", cluster_var = "id")
# → did node with estimators: ['gardner']

# Borusyak imputation
did_imputation(data, yname = "y", gname = "g", tname = "t", idname = "i")
# → did node with estimators: ['borusyak']

`event_study()` wrapper → single `did` node with multiple estimators

event_study(data = df, yname = "y", idname = "id", tname = "year",
            gname = "first_treat", estimator = "all")
# → did node with estimators: ['twfe', 'gardner', 'callaway-santanna', 'sun-abraham', 'borusyak']

`feols()` with event-study syntax → routed to `did` instead of `linear-model`

# i() event-study syntax → did node (estimators: ['twfe'])
feols(y ~ i(time_to_treat, ref = c(-1, -Inf)) | id + year, data = df)

# sunab() syntax → did node (estimators: ['sun-abraham'])
feols(y ~ sunab(first_treat, time_to_treat) | id + year, data = df)

The recognizer inspects the formula: if it contains i(event_var, ref=...) or sunab(...), route to did node. Plain feols(y ~ treat | id + year) without event-study syntax stays as linear-model — that’s standard TWFE, not necessarily a DiD event study.

Grouping: multiple individual calls → one `did` node

When multiple DiD calls in the same script share the same panel structure (same yname, tname, idname, gname — matched by string equality on the column name arguments), the mapper merges them into a single did node with the union of their estimators. Similar to how multiple feols() calls get grouped in the spec explorer today. If panel structures differ (different outcome variable, different unit ID), they remain separate did nodes.

# These three calls share panel structure → one did node with 3 estimators
cs_result <- att_gt(yname="y", tname="year", idname="id", gname="g", data=df)
gardner_result <- did2s(df, yname="y", ...)
feols(y ~ i(time_to_treat, ref=-1) | id + year, data = df)
# → did node with estimators: ['callaway-santanna', 'gardner', 'twfe']

`aggte()` → modifies the parent `did` node’s aggregation params

result <- att_gt(yname="y", tname="year", idname="id", gname="g", data=df)
aggte(result, type = "dynamic", min_e = -5, max_e = 10)
# → sets eventHorizon: [-5, 10] on the did node; aggte is not a separate node

UI Output

Primary: Event-Study Plot

Observable Plot chart showing: - X-axis: relative time (periods before/after treatment) - Y-axis: estimated coefficient (treatment effect) - One series per estimator, color-coded (reuse COLORS from plot-theme.ts) - 95% CI bands (shaded or error bars) - Vertical dashed line at t = 0 (treatment onset) - Horizontal dashed line at y = 0 (null effect) - Reference period marked (typically t = -1)

Secondary: ATT Summary Table

Estimator	ATT	SE	95% CI	p-value
TWFE	0.045	0.012	[0.021, 0.069]	0.000
Gardner	0.042	0.011	[0.020, 0.064]	0.000
C-S	0.038	0.013	[0.013, 0.063]	0.003
…

Secondary: Pre-Trends Test

Estimator	Joint F	p-value	Pre-trend?
TWFE	1.23	0.294	No
Gardner	0.98	0.421	No
…

Panel Info Summary

Displayed in the property sheet or results header: - N units, N periods, balanced/unbalanced - Treatment cohorts with counts - Never-treated count - Control group type

Estimator Implementation Notes

TWFE Event-Study

Expand i(time_to_treat, ref=c(-1, -Inf)) into binary indicator columns (one per relative time period, omitting reference periods). Construct design matrix, run existing feols() regression path with unit + time FE. Clustered SEs on idname. Straightforward — mostly indicator generation + existing infrastructure.

Gardner Two-Stage (did2s)

Subset to untreated observations (time_to_treat < 0 or ever_treated == FALSE)
Run OLS: y ~ 0 | unit + time on untreated subset → get unit/time FE estimates
Residualize outcome for full dataset: y_resid = y - unit_FE - time_FE
Run OLS: y_resid ~ event_indicators on full dataset
Adjust SEs for two-stage estimation (cluster on idname)

Two calls to existing regression.ts. The SE adjustment is the main new piece — standard two-stage correction analogous to 2SLS SE adjustment we already have.

Callaway-Sant’Anna (att_gt)

For each (cohort g, time period t) where t >= g: 1. Subset data to: units in cohort g + control units (never-treated or not-yet-treated at t) 2. Take two time periods: t and a base period (typically g - 1 for universal base) 3. Compute ATT(g,t) via outcome regression (difference-in-means or with covariates) 4. Store influence function values for inference

Aggregate ATT(g,t) → overall ATT (simple weighted average) and event-study (average across cohorts at each relative time).

Bootstrap inference: resample unit-level blocks (all periods for a unit stay together), re-compute all ATT(g,t) + aggregation, derive SEs and CIs from bootstrap distribution. Default 1000 iterations.

Performance note: For typical applied econ panels (500-5000 units, 10-30 periods, 3-8 cohorts), each (g,t) regression is small. The bootstrap is the bottleneck — 1000 iterations × ~50 (g,t) pairs × small OLS = ~50K small regressions. At ~0.1ms each on modern hardware, this is ~5 seconds. Acceptable for a one-shot analysis.

Sun-Abraham (sunab)

Construct interaction indicators: for each cohort g and relative time e, create I(cohort == g) * I(time_to_treat == e). Run feols with these interactions + unit/time FE. Then reweight: the TWFE coefficient on I(time_to_treat == e) is a weighted average of cohort-specific effects; Sun-Abraham recovers the properly-weighted average by summing cohort-specific coefficients weighted by cohort shares.

Uses existing feols path for the regression. New logic: indicator construction + coefficient reweighting.

Borusyak Imputation (did_imputation)

Subset to untreated observations (pre-treatment + never-treated)
Run OLS: y ~ unit_FE + time_FE (+ covariates) on untreated subset
Predict Y(0) for all treated observations using estimated FEs
Imputed ATT for each treated (i,t): tau_hat(i,t) = Y(i,t) - Y_hat(0)(i,t)
Aggregate imputed ATTs by relative time for event-study, or overall
Influence-function SEs (analytical, no bootstrap needed)

One regression + prediction + aggregation. The influence-function SE derivation is the complex part.

Testing Strategy

Unit tests (per estimator, validated against R output)

Run each estimator in R on a known dataset, capture coefficients/SEs/p-values, assert Interlyse matches within tolerance. Use the same tolerance standards as existing regression tests: <0.00005 for statistics, <0.00001 for p-values.

Test datasets: - Simulated staggered adoption panel — small (100 units × 10 periods × 3 cohorts) with known DGP so we can verify both point estimates and SEs - Castle doctrine dataset (from did2s package) — real data with published R output to validate against

Integration tests

Full parse → recognize → map → execute chain with realistic R code from reference papers
Multiple DiD calls in one script merge into single did node
feols() with i() routes to did, plain feols() stays as linear-model

E2E tests

Paste JEL-DiD R code → upload dataset → see event-study plot with multiple estimators
Verify partial failure: introduce invalid estimator config → remaining estimators display

Validates against

JEL-DiD paper (Baker et al. 2025): att_gt() + aggte() with CDC/Medicaid panel data
did2s package event_study() wrapper: multi-estimator horse race on Castle doctrine data

File structure

src/core/stats/
  did/
    panel.ts          — PanelInfo, validatePanel(), preparePanelData()
    indicators.ts     — event-study indicator expansion, i() and sunab() column generation
    twfe.ts           — runTWFE()
    gardner.ts        — runGardner()
    callaway.ts       — runCS(), bootstrap logic
    sun-abraham.ts    — runSunAbraham()
    borusyak.ts       — runBorusyak()
    aggregate.ts      — ATT aggregation, pre-trends test
    bootstrap.ts      — panel bootstrap (unit-block resampling)
    types.ts          — DiDParams, DiDResult, EventStudyCoefficient, etc.
    index.ts          — did executor entry point (orchestrates all of the above)
    *.test.ts         — colocated tests per file
src/core/pipeline/
  types.ts            — add DiDNode to PipelineNode union
  executor.ts         — register 'did' executor
src/core/parsers/r/
  recognizer.ts       — add att_gt, did2s, event_study, did_imputation patterns;
                        route feols+i()/sunab() to did
src/ui/components/
  results/
    event-study-plot.tsx  — Observable Plot event-study chart
    did-results.tsx       — ATT table + pre-trends table + panel info