WebR Integration — Design Spec

Date: 2026-04-20 Milestone: M6 enabler (pulled forward from M6 Architecture Notes) Scope: Full framework (Scope C): dispatch infrastructure, data marshaling, lifecycle, and one typed marshaler (lm_robust from estimatr). Opaque R-value path scaffolded in the worker but not wired in the recognizer.

1. Context

Today, every R function we can’t execute natively in TypeScript becomes an UnsupportedNode with a warning — a dead end for replication. The gap analysis (reference-papers/GAP-ANALYSIS.md) and the 2026-04-18 audit (REPLICATION-AUDIT.md) both show the long tail — readRDS(), rdrobust(), custom functions, obscure packages — has low-ROI individual implementations but high cumulative cost on coverage.

WebR (R compiled to WebAssembly, maintained by Posit) provides a full R interpreter in-browser. Of 27 critical econometrics packages, 25 are available on repo.r-wasm.org. Pulling WebR forward from M6 changes the product story from “88% executable, 12% blocked” to “100% executable; X% on the TS fast path.”

Framework goal: unsupported calls route to WebR as a universal fallback. As TS implementations land, they replace the WebR path for those specific calls. Recognition (parser) and execution (engine choice) become independent decisions.

2. Scope

In

• src/core/webr/ framework module: protocol types, TS-side dispatcher, dataset marshaler, per-result-type marshaler registry.
• src/workers/webr-worker.ts: dedicated Web Worker running WebR, handles init, package install, dispatch.
• Opaque dispatch path in the worker protocol (scaffolded, tested internally; no recognizer emission).
• Typed dispatch path end-to-end: recognizer → mapper → WebRTypedNode → worker → marshaled RegressionResult.
• One typed marshaler: lm_robust (estimatr).
• Inline-expression data arguments via Strategy 1 (lift to TS node) — supports data = df %>% filter(...), data = df %>% filter(...) %>% mutate(...), and data = filter(df, ...) / data = subset(df, ...) direct-call forms. The inline expression is recursively recognized and emitted as upstream TS pipeline node(s); the outer WebR-typed node references the lifted synthetic binding. Falls back to UnsupportedNode if any stage of the inline expression is unrecognized.
• Unit, integration, validation (golden comparison vs native OLS+HC), and E2E tests.
• Dev-only kill switch (VITE_DISABLE_WEBR=1).

Out (future sessions, tracked but not implemented here)

• Opaque R-value nodes wired through the recognizer (session 2).
• Binding-level recognizer walk (session 2).
• Statement-block opaque nodes for parse failures (session 2+).
• Broom auto-typing bridge from opaque to typed (Tier 3, future session).
• UI “cast opaque to regression” inspector (Tier 4, future session).
• Marshalers for other functions (rdrobust, felm, att_gt, …) — added per function, 15-minute increments.
• Base-R bracket subsetting in data args (e.g., data = df[df$year > 2000, ]) — requires [[/[ RHS subscript parser work (partially addressed M5d, still incomplete). Falls through to UnsupportedNode in spike.
• Non-typed inline data expressions (e.g., data = my_custom_func(df)) — needs the opaque path to lift to a webr-opaque pre-node. Deferred with opaque support.
• Multi-dataset inline expressions (e.g., data = merge(df1, df2, by = 'id')) — rare in practice; defer.
• Transferable-backed zero-copy postMessage (optimization).
• LocalStorage/OPFS-backed package cache across sessions.
• Cancellation / AbortSignal for in-flight dispatches.

3. Architecture

3.1 Module layout

src/core/webr/                       [new — framework-free, worker-portable]
├── protocol.ts                      Message types (WebRRequest, WebRResponse)
├── transport.ts                     WebRTransport interface (post + subscribe)
├── dispatch.ts                      createWebRDispatcher(transport) — pure factory
├── dataset-marshal.ts               TS Dataset ↔ MarshaledDataset
└── marshalers/
    ├── registry.ts                  registerMarshaler(name, fn); lookupMarshaler(name)
    └── lm-robust.ts                 First typed marshaler

src/workers/webr-worker.ts           [new — second Web Worker]
                                     Lifecycle, WebR init, package install, dispatch

src/workers/worker-manager.ts        [modified]
                                     Construct WebRTransport over a real Worker;
                                     instantiate dispatcher via createWebRDispatcher;
                                     expose webrDispatchTyped() to executor

src/core/pipeline/types.ts           [modified]
                                     Add WebRTypedNode to PipelineNode union
                                     Add getPortsFor(node) helper (falls through to NODE_PORTS
                                     for static types; consults marshaler registry for webr-typed)

src/core/pipeline/executor.ts        [modified]
                                     Branch on WebRTypedNode → workerManager.webrDispatchTyped()

src/core/parsers/r/recognizer.ts     [modified]
                                     Add recognizeLmRobust pattern

src/core/pipeline/mapper.ts          [modified]
                                     Add webr-typed AnalysisCall → WebRTypedNode mapping

3.2 Two runtime workers

The existing TS worker stays untouched and instant. The WebR worker is spawned lazily (§5.1), holds ~30MB WASM + installed packages for the session, processes dispatches serially.

3.3 Framework-free via transport injection

src/core/webr/dispatch.ts never references a Worker directly. It exposes a pure factory:

export interface WebRTransport {
  post(msg: WebRRequest): void;
  subscribe(handler: (msg: WebRResponse) => void): () => void;  // returns unsubscribe
}

export function createWebRDispatcher(transport: WebRTransport) { /* ... */ }

The boundary layer (src/workers/worker-manager.ts) constructs the transport wrapping a real Worker and passes it in. This keeps all of src/core/webr/ — dispatcher, protocol types, marshalers, dataset marshaler — fully worker-portable and testable with in-memory transport mocks (no jsdom Worker polyfill needed).

The same pattern makes future transports (TCP to an R sidecar, shared-memory IPC, Node worker_threads) substitutable without core changes.

3.4 Data flow (mixed pipeline example)

 [TS worker]                [WebR worker]
     |                           |
     | execute filter()          |
     | produces Dataset          |
     |                           |
     | ── webr dispatch ──────→  | marshal dataset → R data.frame
     |     (dataset, R src)      | install estimatr (first time)
     |                           | execute lm_robust(...)
     |                           | marshal R result → RegressionResult
     | ← RegressionResult ────── |
     | store on node             |
     | continue pipeline         |

4. Node type & recognizer

4.1 New PipelineNode variant

type WebRTypedNode = {
  type: 'webr-typed';
  id: string;
  span: Span;
  params: {
    rFunction: string;            // 'lm_robust' — drives marshaler + package lookup
    rSource: string;              // reconstructed R snippet with data arg named explicitly
    dataBinding: string;          // R variable name used for the data argument
    resultSchema: 'regression';   // discriminates marshaler family
  };
  result?: RegressionResult;
};

4.2 rSource construction — reconstruct, not pass-through

The recognizer extracts structured params (formula, se_type, clusters, weights, etc.) from the AST and reconstructs rSource as a canonical single call. Chosen over pass-through because:

• Pipe forms (df %>% lm_robust(y ~ x)) are desugared at recognition time anyway, so the call at dispatch is always in canonical form.
• The user-visible properties panel can show the reconstructed call as an editable surface.
• The reconstruction logic is contained — we emit only calls whose argument shapes we fully understand.

Calls with inline-expression data arguments (e.g., data = df %>% filter(year > 2000)) are handled in-scope via Strategy 1 — the inline expression is recursively recognized and emitted as upstream TS pipeline nodes, with the outer WebR-typed node referencing a synthetic lifted binding. See §4.3.1. When the inline expression isn’t recognizable (base-R bracket subset, unknown function call), the outer call falls back to UnsupportedNode.

4.3 Recognizer pattern

recognizeLmRobust added to the per-function table in src/core/parsers/r/recognizer.ts. Extracts:

• formula via existing parseFormulaFromArg
• data argument via recognizeDataArgExpression (see §4.3.1 below)
• se_type string literal (default "HC2" per estimatr)
• clusters formula (~var form)
• weights expression (bare identifier only)
• ci_level number literal

Produces 1 or more AnalysisCalls: zero or more lifted TS-pipeline calls (from inline data-arg expressions) followed by one { kind: 'webr-typed', rFunction: 'lm_robust', dataBinding: <bare or synthetic>, ... }.

4.3.1 recognizeDataArgExpression — inline data arg lifting

New shared helper used by every WebR-typed recognizer (starts with lm_robust, reusable for all future marshalers):

type DataArgResult =
  | { kind: 'binding'; name: string }                 // data = df
  | { kind: 'lifted'; binding: string;
      liftedCalls: AnalysisCall[] }                    // data = df %>% filter(...) or data = filter(df, ...)
  | { kind: 'unsupported' };                           // falls back to UnsupportedNode

function recognizeDataArgExpression(
  expr: AstNode,
  scope: RecognizerScope,
): DataArgResult;

Supported shapes (by AST pattern):

Synthetic binding IDs: __lift_<nodeId>_<stage> where nodeId is the outer call’s recognized id and stage is the pipe-chain position. Deterministic and unique per outer call — re-recognition of the same source produces identical bindings (idempotent).

Span semantics: Each lifted call’s sourceSpan points at the corresponding AST node in the original source (filter(...) subexpression’s span, not the whole outer call). This preserves error messages and the properties panel showing the right source fragment for each lifted node.

Lifted vs user bindings: The mapper treats synthetic __lift_* bindings identically to user bindings — looks them up in the binding-name → node-id map. No special case.

4.3.2 Failure isolation

If recognizeDataArgExpression returns { kind: 'unsupported' }, the outer lm_robust call becomes an UnsupportedNode — same as if the whole call were unrecognized. No partial pipeline is emitted. This guarantees we never run a WebR-typed node with a synthesized data binding that doesn’t correspond to a real upstream node.

4.4 Mapper

core/pipeline/mapper.ts translates each AnalysisCall into a PipelineNode:

1. Lifted TS-transform calls (from inline data args) map through the existing transform mappers — no new mapper code needed.
2. webr-typed calls produce WebRTypedNode:
   • Reconstruct rSource: lm_robust(${formulaText}, data = ${dataBinding}${seTypeArg}${clustersArg}${weightsArg}${ciLevelArg}). dataBinding is either a user binding (df) or a synthetic lifted one (__lift_17_0) — the reconstruction is identical.
   • Edge from upstream node (data-load, transform, or lifted transform) → data port.
   • Output port model produces RegressionResult.

4.5 Port definitions — dynamic, per marshaler

Port shape is intrinsic to each R function: lm_robust takes data in → produces a model; pivot_longer takes data → produces data; predict takes model + newdata → produces data; rbindlist is variadic over datasets; etc. A static NODE_PORTS['webr-typed'] entry can’t cover all of these.

Resolution: ports live on the marshaler spec (§6.5), not on NODE_PORTS. The spec introduces one lookup helper:

// src/core/pipeline/types.ts
export function getPortsFor(node: PipelineNode): NodePortDef {
  if (node.type === 'webr-typed') {
    const spec = lookupMarshaler(node.params.rFunction);
    return spec?.ports ?? { inputs: {}, outputs: {} };
  }
  return NODE_PORTS[node.type];
}

All existing sites that reference NODE_PORTS[node.type] for port discovery go through getPortsFor(node) instead. For every non-WebR node type, behavior is unchanged (static lookup). For webr-typed, the registry is the source of truth.

For this spike’s single marshaler (lm_robust):

inputs:  { data: { dataType: 'dataset' } }
outputs: { model: { dataType: 'model' } }  // RegressionResult includes residuals/fitted as fields

Why one model output, not separate model/residuals/fittedValues ports: matches our native lm / feols / glm nodes, which produce a single result carrying residuals as fields. Consistency means downstream consumers (spec explorer, comparison tables) treat WebR-produced models and native models identically. Users who want residuals or fitted values as standalone vectors add a post-estimation extraction node (a future marshaler for residuals(m) or fitted(m)).

Future marshalers that will exercise other shapes: - pivot_longer / pivot_wider / distinct: { data → data } - readRDS: { (no inputs, filename param) → data } - rbindlist, cbind: { datasets: variadic → data } - fixef: { model → vector } - predict: { model, newdata? → data }

Each is one registerMarshaler(spec) call when added.

5. Worker lifecycle

5.1 Triggers

Spawn is eager (background) so cold-start overhead happens while the user is examining the DAG, not after clicking Run. Debounce prevents thrashing during rapid code edits.

5.2 Init state machine

Init is one-shot per session. Package install is a separate, independently-triggered pipeline that runs asynchronously whenever the DAG changes — it does not block on Run, and Run does not trigger it (only awaits it if in flight).

WORKER INIT (once per session)

  not-spawned → downloading → booting → ready (terminal)
                                 │
                                 ↓
                              (failed) — surfaced as user error; Run attempts retry

PACKAGE INSTALL (many per session, async, triggered by DAG change)

  DAG update event
        │
        ↓ (500ms debounce)
  collectRequiredPackages(currentPipeline)
        │
        ↓
  diff against installedPackages cache
        │
        ├─ diff empty      → no-op
        └─ diff non-empty  → post install-packages(delta)
                              ↓
                           (worker runs webR.installPackages)
                              ↓
                           install-complete → cache updated

RUN (user clicks)

  Run
   ├─ await ensureWebRWorker()         (usually no-op: already ready)
   ├─ await any in-flight install      (usually no-op: already complete)
   └─ dispatch WebR nodes

Singleton Promise<void> on WorkerManager for worker init; install promises are keyed by request id and chained so Run can await “whatever’s currently installing.”

5.3 Message protocol

type WebRRequest =
  | { type: 'init' }
  | { type: 'install-packages'; id: string; packages: string[] }
  | {
      type: 'dispatch-typed';
      id: string;
      rSource: string;
      inputs: Record<string, MarshaledDataset>;
      marshalerName: string;
      marshalerContext: MarshalerContext;   // e.g., { vcovType: 'HC1' }
    }
  | {
      type: 'dispatch-opaque';          // scaffolded; no TS caller this session
      id: string;
      rSource: string;
      inputs: Record<string, MarshaledDataset>;
      resultBinding: string;
    };

type WebRResponse =
  | { type: 'init-progress'; phase: 'downloading' | 'booting'; bytesLoaded?: number }
  | { type: 'init-ready' }
  | { type: 'init-error'; error: string }
  | { type: 'install-complete'; id: string; installed: string[] }
  | { type: 'install-error'; id: string; error: string; failedPackage: string }
  | { type: 'dispatch-result'; id: string; result: MarshaledRegression | { kind: 'opaque'; binding: string } }
  | { type: 'dispatch-error'; id: string; stage: 'bind-inputs' | 'eval' | 'marshal'; error: string };

Every message is a discriminated union on type — matches the existing TS worker protocol.

5.4 Dispatch concurrency

Serial within the worker. R is single-threaded, and — crucially — the worker’s promise chain serializes the full dispatch cycle as one atomic unit: bind-inputs → eval → marshal → post result → pop queue. Dispatch N+1 does not start its bind-inputs stage until dispatch N’s marshal has returned its result message.

Why full-cycle serialization matters: the R env is shared state. If dispatch B’s bind-inputs began while dispatch A was still in the marshal stage, B could overwrite a binding (e.g., df) that A’s marshaler is implicitly relying on. (The result binding __n_A would be safe — R’s copy-on-write semantics snapshot it — but any evalR("some_expr_referencing_df") during A’s marshal would see a mutated df.) Treating bind+eval+marshal as indivisible eliminates the class.

Parallelism is out of scope. Running two WebR dispatches truly concurrently would require a second WebR worker with its own R env. Could be added later (e.g., for large pipelines with many independent regressions), but forces a significant design shift — multi-worker coordination, per-dispatch env isolation, higher memory cost. For the spike and M6, one worker processing serially is the model.

TS-side concurrent executePipeline: the existing executionGeneration counter already guards superseded runs. A second Run-click while WebR dispatches from the first are still in flight increments the generation; callbacks from dispatch N see generation !== executionGeneration and skip their set(). Dispatches continue to completion (can’t cancel in-flight WebR work without the cancellation story, deferred) but their results are dropped on the floor — same protection as native results.

5.5 Package install

Package install is eager and async, triggered by DAG updates (not by Run). Run just awaits whatever’s in flight.

TS-side state: - installedPackages: Set<string> — mirrors the worker’s installed set. Only updated on install-complete from the worker. - pendingInstall: Promise<void> | null — the current in-flight install, if any. Serialized: if a new DAG update fires while an install is running, the next install chains onto the current one’s completion.

Triggered by DAG update (store subscriber in src/workers/worker-manager.ts or equivalent hook):

onPipelineChange(pipeline => {
  const required = collectRequiredPackages(pipeline);   // uses lookupMarshaler
  const delta = setDifference(required, installedPackages);
  if (delta.size === 0) return;                          // no-op

  pendingInstall = (pendingInstall ?? Promise.resolve()).then(async () => {
    await ensureWebRWorker();
    const { installed } = await postAndAwait({ type: 'install-packages', packages: [...delta] });
    installed.forEach(p => installedPackages.add(p));
  });
});

Debounced by 500ms against rapid successive DAG updates. Errors on this path surface as toast notifications (not blocking the UI) and leave installedPackages unchanged — next install attempt retries the failed delta.

Triggered by Run (inside executePipeline):

if (pipelineHasWebRNodes) {
  await ensureWebRWorker();                              // usually no-op
  await (pendingInstall ?? Promise.resolve());           // usually no-op
  const stillMissing = difference(collectRequiredPackages(pipeline), installedPackages);
  if (stillMissing.size > 0) {
    // belt-and-suspenders: DAG update hook may not have fired yet, or prior install failed
    await installPackages([...stillMissing]);
  }
  dispatchWebRNodes();
}

Run’s install step is a safety net. In the common case — DAG settled > 500ms before Run is clicked — nothing to do. Handles the edge where Run is clicked immediately after a DAG edit.

Package requirements live on the marshaler spec (§6.5) — one source of truth. Adding a new WebR-typed function never requires touching a separate static map.

5.6 Termination

No auto-termination. Worker lives for the tab’s lifetime. WorkerManager.shutdown() (on page unload) calls worker.terminate(). Session-level caching justifies holding ~30MB.

5.7 Error modes

Pipeline-level behavior on WebR node error matches existing UnsupportedNode handling — node marked error, downstream dependents skipped, independent branches continue.

6. Data marshaling

6.1 Wire format

type MarshaledDataset = {
  nrows: number;
  columns: Array<
    | { name: string; kind: 'numeric'; values: Float64Array }        // NaN = NA
    | { name: string; kind: 'categorical'; codes: Uint32Array; levels: string[] }  // 0xFFFFFFFF = NA
  >;
};

Traverses postMessage via structured clone (copy). Transferable-backed zero-copy is a future optimization.

6.2 Direction 1: TS Dataset → R data.frame

src/core/webr/dataset-marshal.ts:

export function toMarshaled(ds: Dataset): MarshaledDataset;

Pulls underlying typed arrays by reference — no allocation or copy in this function.

Worker side:

async function bindDatasetToR(marshaled: MarshaledDataset, rName: string): Promise<void>;

Per column: - Numeric → new webR.RObject.Double(column.values). - Categorical → factor from levels[codes] with NA for sentinel codes.

Wrap as data.frame(list(...)) and assign to the R global env under rName.

6.3 NA semantics

NumericColumn collapses R’s NA and NaN into a single NaN. Documented known lossiness; has not bitten any applied-econ replication to date. If ever needed, extend NumericColumn with a separate missing bitmap.

6.4 Direction 2: R lm_robust result → RegressionResult

Produces a RegressionResult conforming to src/core/stats/types.ts — same shape as our native OLS results. No new fields; comparison tables, spec curves, and all other typed consumers work out of the box.

src/core/webr/marshalers/lm-robust.ts:

import type { RegressionResult, CoefficientRow, VcovType } from '../../stats/types';

export async function marshalLmRobust(
  webR: WebR,
  binding: string,
  ctx: { vcovType: VcovType },
): Promise<RegressionResult> {
  const terms = await webR.evalR(`names(coef(${binding}))`).then(r => r.toArray() as string[]);

  const [coefArr, seArr, tArr, pArr, dfRes, r2, adjR2, fstat, fp, rse, resids, fitted] =
    await Promise.all([
      webR.evalR(`unname(coef(${binding}))`).then(r => r.toTypedArray()),
      webR.evalR(`unname(${binding}$std.error)`).then(r => r.toTypedArray()),
      webR.evalR(`unname(${binding}$statistic)`).then(r => r.toTypedArray()),
      webR.evalR(`unname(${binding}$p.value)`).then(r => r.toTypedArray()),
      webR.evalR(`${binding}$df.residual`).then(r => r.toNumber()),
      webR.evalR(`${binding}$r.squared`).then(r => r.toNumber()),
      webR.evalR(`${binding}$adj.r.squared`).then(r => r.toNumber()),
      webR.evalR(`${binding}$fstatistic$value`).then(r => r.toNumber()),
      webR.evalR(`${binding}$fstatistic$p.value`).then(r => r.toNumber()),
      webR.evalR(`sqrt(sum(${binding}$res^2) / ${binding}$df.residual)`).then(r => r.toNumber()),
      webR.evalR(`unname(${binding}$res)`).then(r => Array.from(r.toTypedArray() as Float64Array)),
      webR.evalR(`unname(${binding}$fitted.values)`).then(r => Array.from(r.toTypedArray() as Float64Array)),
    ]);

  const hasIntercept = terms.includes('(Intercept)');

  const coefficients: CoefficientRow[] = terms.map((name, i) => ({
    name,
    estimate: coefArr[i],
    standardError: seArr[i],
    tStatistic: tArr[i],
    pValue: pArr[i],
  }));

  return {
    type: 'regression',
    coefficients,
    rSquared: r2,
    adjustedRSquared: adjR2,
    fStatistic: fstat,
    fPValue: fp,
    dfModel: terms.length - (hasIntercept ? 1 : 0),
    dfResidual: dfRes,
    residualStandardError: rse,
    residuals: resids,
    fittedValues: fitted,
    vcovType: ctx.vcovType,
  };
}

Notes on extraction:

• unname() before toTypedArray() — R’s coef() returns a named numeric vector; toTypedArray wants a plain numeric. Names are reattached on the TS side from the separately-extracted terms.
• Promise.all parallelizes ~12 round-trips — microsecond-scale, cheap.
• fstatistic$value / fstatistic$p.value — estimatr’s lm_robust stores these differently from base lm (which uses a named vector); the marshaler assumes estimatr’s layout.
• residuals / fittedValues are required by RegressionResult. Extracted as full N-vectors; ~N×16 bytes marshaled per dispatch. Negligible for typical applied econ datasets (<50K rows).
• No vcov matrix field — RegressionResult doesn’t carry one in the native path either (the vcov local in regression.ts is discarded after computing per-coefficient SEs). Post-estim coeftest/vcov flows work today by modifying upstream model params, not by re-using a stored vcov matrix. If that changes, the marshaler can gain a vcovMatrix?: number[][] field — same pattern as native regression would.
• ctx.vcovType — passed in by the dispatcher, sourced from the recognizer’s extracted se_type arg. Marshaler doesn’t re-parse the rSource.

6.5 Marshaler registry — single source of truth per R function

Each R function we route through WebR-typed has a single registration entry that carries everything the framework needs to integrate it: input/output ports, required R packages, and the marshal function.

// src/core/webr/marshalers/registry.ts
export interface MarshalerContext {
  vcovType?: VcovType;        // lm_robust
  // Extend per future marshaler needs
}

export type Marshaler = (
  webR: WebR,
  binding: string,
  ctx: MarshalerContext,
) => Promise<unknown>;

export interface MarshalerSpec {
  rFunction: string;                                 // 'lm_robust'
  packages: string[];                                // ['estimatr']
  ports: {
    inputs:  Record<string, PortDefinition>;
    outputs: Record<string, PortDefinition>;
  };
  marshal: Marshaler;
}

const registry = new Map<string, MarshalerSpec>();
export function registerMarshaler(spec: MarshalerSpec): void;
export function lookupMarshaler(rFunction: string): MarshalerSpec | undefined;

First and only registration in this spike:

// src/core/webr/marshalers/lm-robust.ts (registration block)
registerMarshaler({
  rFunction: 'lm_robust',
  packages: ['estimatr'],
  ports: {
    inputs:  { data:  { dataType: 'dataset' } },
    outputs: { model: { dataType: 'model' } },
  },
  marshal: marshalLmRobust,
});

Adding a new WebR-typed function later is one registerMarshaler({ ... }) call. Framework code is untouched: port discovery, package collection, and dispatch all consult the registry.

6.6 Package collection flows through the registry

What previously would have been a separate WEBR_PACKAGES: Record<string, string[]> static map now comes from the marshaler spec. collectRequiredPackages(pipeline) (§5.5) walks WebR nodes and calls lookupMarshaler(node.params.rFunction).packages for each — a single source of truth avoids the drift of forgetting to update one side when adding a new marshaler.

7. End-to-end dispatch lifecycle

7.1 Happy path

executor: reaches node N (type=webr-typed, rFunction=lm_robust)
  │
  ├─ upstream Dataset already computed on TS side
  │
  ├─ workerManager.webrDispatchTyped({
  │     nodeId, rSource, inputs: { [dataBinding]: toMarshaled(ds) },
  │     marshalerName: 'lm_robust',
  │     marshalerContext: { vcovType: <from recognizer params> },
  │   })
  │
  ↓
webr-worker:
  ├─ stage=bind-inputs: bindDatasetToR(marshaled, dataBinding)
  ├─ stage=eval: webR.evalR(`__n${id} <- ${rSource}`)
  ├─ stage=marshal: lookupMarshaler('lm_robust')(webR, `__n${id}`)
  └─ postMessage({ type: 'dispatch-result', id, result })
  │
  ↓
workerManager: resolves pending promise
  │
  ↓
executor: sets node.result, marks complete
  │
  ↓
pipeline store: set() with executionGeneration guard
  │
  ↓
UI: re-render, "R" badge on node, comparison table picks up coefficient

7.2 Binding persistence

__n${id} remains in WebR’s env after dispatch. Enables future opaque chaining (session 2). For typed-only spike, it’s future-proofing and allows post-hoc field queries from the UI.

7.3 Concurrent executePipeline

Existing executionGeneration counter in pipeline.ts already guards async callbacks from superseded runs; WebR dispatches participate identically.

7.4 Cancellation

Not supported in this spike. Hard termination via workerManager.terminateWebR() is the only interrupt. Soft cancellation via AbortSignal deferred.

7.5 No automatic engine fallback

If lm_robust fails in WebR (e.g., collinear X), we do not silently retry in the native OLS path. The user asked for lm_robust; if it can’t run, node shows error. A future UI affordance could offer “fall back to TS OLS” manually.

8. Testing & validation

8.1 Unit (Vitest)

Colocated next to source:

• dataset-marshal.test.ts — round-trip, NA/NaN, categorical levels
• dispatch.test.ts — protocol, id correlation, error propagation (transport mocked with an in-memory implementation — no Worker polyfill needed)
• marshalers/lm-robust.test.ts — extractors against mocked webR.evalR(...) returns
• marshalers/registry.test.ts — register, lookup, collision; packages and ports fields carried through
• recognizer/lm-robust-inline-data.test.ts — inline-expression data args: data = df %>% filter(...), data = filter(df, ...), multi-stage pipes, fallback to UnsupportedNode on data = df[cond, ] and data = my_func(df). Asserts the emitted AnalysisCall sequence and synthetic binding names.

8.2 Integration (Vitest, Node @r-wasm/webr)

src/workers/webr-worker.integration.test.ts:

• Spawn real WebR worker.
• Install estimatr.
• Round-trip small Dataset → R data.frame → extract back.
• Evaluate lm_robust on synthetic data.
• Assert RegressionResult shape + field types.

Marked test.slow — ~15s first run (download/install), cached via r-wasm.org CDN on CI.

8.3 Validation — golden comparison

src/core/webr/marshalers/lm-robust.validation.test.ts:

Four variants (HC0, HC1, HC2, HC3) on synthetic heteroskedastic data (N=500, K=3, seed=42):

• Path A: native TS OLS + applyRobustSE (existing repo code).
• Path B: WebR lm_robust(y ~ x1 + x2 + x3, data = ds, se_type = 'HC[0-3]').
• Assert coefficients, SEs, F-statistics match CLAUDE.md statistic tolerance (<5e-5); p-values match CLAUDE.md p-value tolerance (<1e-5).
• Assert nobs, dfResidual exactly equal.

Passing this proves marshaling bijectivity, formula parity, and result extraction correctness end-to-end.

8.4 E2E (Playwright)

e2e/webr-lm-robust.spec.ts:

• Navigate to /.
• Upload examples/synthetic-webr.zip (new fixture: 50-row CSV + .R with lm_robust call).
• Wait for DAG with webr-typed node.
• Wait for toolbar “R runtime ready” indicator.
• Click Run.
• Wait for comparison table.
• Assert expected coefficient value.

8.5 Feature flag

No user-facing flag. Lazy architecture gives free opt-out.

Dev-only kill switch:

// src/ui/workers/worker-manager.ts
private webrEnabled = !import.meta.env.VITE_DISABLE_WEBR;

VITE_DISABLE_WEBR=1 npm run dev makes webr-typed nodes behave like UnsupportedNode.

8.6 Shipping criteria

1. All unit tests pass.
2. All four HC variants of the validation test pass.
3. E2E test passes in Chromium.
4. npm run build && npm test && npm run lint && npm run test:e2e green.
5. Manual smoke: upload a lm_robust example, verify execution and comparison table.

9. Follow-up sessions

Items captured during brainstorming, not in spike scope:

10. Architectural invariants introduced

Appends to the CLAUDE.md No-Go List:

• WebR worker is session-scoped — never auto-terminate. Holds ~30MB + package state that’s expensive to rebuild.
• WebR dispatches are atomic end-to-end — bind-inputs → eval → marshal → post result runs as one indivisible unit before the next dispatch begins. The shared R env is never touched by two in-flight dispatches simultaneously.
• Package install is async on DAG change, not Run-triggered — Run awaits the in-flight install promise but does not initiate install as its primary mechanism (only as a belt-and-suspenders safety net if the DAG-hook debounce hasn’t yet fired).
• installedPackages TS-side mirror must stay consistent with worker state — only the worker’s install-complete response may update it. Never pre-populate.
• No pass-through of user R source to WebR — always reconstruct from AST-extracted params. Pass-through would silently drop arguments the recognizer missed.
• Port shapes for webr-typed nodes come from the marshaler spec — use getPortsFor(node), never NODE_PORTS['webr-typed'] directly. Adding a new WebR-typed function is one registerMarshaler({ ... }) call with packages + ports + marshal.
• Synthetic lifted bindings are derived from the outer call’s node id — __lift_<outerId>_<stage>. Must be deterministic so re-recognition of the same source is idempotent and the mapper resolves edges to the same upstream nodes.
• Marshalers must unname() vectors before toTypedArray() — names are attached on the TS side from a separately-queried terms array.
• Pipeline-level executionGeneration guard must wrap WebR result handlers — same stale-execution protection as native results.

11. Open questions

None blocking. One note on package-version pinning: the spike uses whatever r-wasm.org serves for estimatr (latest at install time). If a future version of estimatr changes a result field (e.g., p.value.adjusted rename), the marshaler breaks and the validation test catches it. Pinning versions is an M6 concern tied to renv.lock support.