WebR Opaque Nodes — Design Spec

Date: 2026-04-22 Milestone: M6 enabler (Session 2 of WebR follow-up sessions) Predecessor: 2026-04-20 WebR Integration (Session 1 — typed framework + lm_robust, merged)

1. Context

Session 1 landed the WebR framework plus one typed marshaler (lm_robust). The worker protocol scaffolded dispatch-opaque but nothing on the TS side emits or consumes it. This session wires the opaque path end-to-end, restructures the recognizer around a binding-level walk, and adds a statement-block fallback for parser failures.

Data from the 2026-04-22 opaque inventory (REPLICATION-AUDIT-OPAQUE.md, 83 packages, 10,753 unsupported-node occurrences):

~70 unique functions are load-bearing (assigned and consumed). The long tail is paper-specific custom functions — outcomes_shares, get_collapsed_df, run_rob_rd, etc. — where no pre-written typed marshaler is possible.
Consumer histograms show opaque outputs flowing overwhelmingly into Dataset ports (data-filter:data, data-mutate:data, linear-model:data, webr-typed:data). Auto-marshaling opaque outputs back to TS Dataset when is.data.frame(result) unlocks the downstream chain.
readRDS alone blocks 46 models across 2 papers (principally qje-voluntary-minimum-wages with 38). A single paper’s custom function (get_collapsed_df) blocks 20 models. These are the headline wins for opaque.
Prerequisite: the inliner currently surfaces return(x) from inlined function bodies as a top-level unsupported node (490 occurrences, 25 papers). Fix this first so opaque metrics aren’t drowned in noise.

Framework goal: every assignment whose RHS is call-like produces a pipeline node — typed when recognized, opaque when not. Scalar-literal, simple-vector, and evaluator-computable RHS (e.g., x <- 5, threshold <- 0.05, names <- c("a","b","c"), dir <- "/path") continue to update the recognizer’s scope map without emitting a node. The parser’s pattern table becomes a sub-dispatch inside the walk, not the primary traversal.

2. Scope

In

Prerequisite: return() unwrapping in the inliner.
New PipelineNode variant: WebROpaqueNode with dynamic per-instance input ports.
Recognizer restructured as a binding-level walk (assignment-driven primary loop; pattern table becomes sub-dispatch).
Statement-block opaque fallback for parser failures.
Free-variable extraction (scope-aware) for input port wiring.
Mapper: webr-opaque AnalysisCall → WebROpaqueNode.
Worker-side probe-and-marshal bridge: if is.data.frame(result) → marshal as Dataset; else return opaque-binding handle.
Executor branch: dispatch opaque nodes, resolve upstream Dataset-vs-opaque inputs, attach results, error downstream when auto-marshal fails and consumer expects Dataset.
React Flow rendering: dashed border, amber “R?” badge, dynamic port labels.
Unit, integration, validation, and E2E tests.
Audit regression: rerun audit-opaque.ts, assert opaque-candidate bucket shrinks to zero (all such nodes are now webr-opaque, not unsupported).

Out (future sessions)

Sticky-opaque / auto-promotion of downstream to WebR when probe fails (session 3 — alongside broom auto-typing bridge; non-Dataset opaque outputs are the long tail, out of scope here).
Broom auto-typing bridge (session 3) — run broom::tidy(binding) to promote opaque to typed regression.
Native-alias backlog from the opaque inventory (data.frame, as.data.frame, cbind, distinct, fixef, etc.) — separate Wave 1/2 work, tracked but not in this session.
WebR-typed marshalers from the inventory (readRDS, excel readers, sf::*) — per-function 15–30 min additions, deferred until the opaque path is live and we can A/B against it.
UI “cast opaque to regression” inspector (Tier 4, future).
Cancellation / AbortSignal on opaque dispatches.
Multi-assignment (list[a, b] <- ...) — rare; emit as opaque if observed, no special handling.

3. Architecture

3.1 Module changes

src/core/parsers/r/recognizer.ts             [restructured]
                                              Binding-level walk as primary loop;
                                              pattern table becomes sub-dispatch

src/core/parsers/r/recognize-opaque.ts       [new]
                                              Free-variable extraction,
                                              opaque AnalysisCall construction

src/core/parsers/r/inliner.ts                [modified]
                                              Unwrap trailing return(x) → x

src/core/parsers/shared/analysis-call.ts     [modified]
                                              Add 'webr-opaque' to AnalysisKind

src/core/pipeline/types.ts                   [modified]
                                              Add WebROpaqueNode; add 'any' dataType;
                                              extend getPortsFor() for dynamic ports

src/core/pipeline/mapper.ts                  [modified]
                                              webr-opaque AnalysisCall → WebROpaqueNode

src/core/pipeline/executor.ts                [modified]
                                              Opaque executor branch; probe-result
                                              handling; downstream error propagation

src/core/webr/protocol.ts                    [modified]
                                              Extend dispatch-opaque response with
                                              probe-result discriminated union

src/workers/webr-worker.ts                   [modified]
                                              handleDispatchOpaque probes result,
                                              marshals Dataset or returns binding

src/workers/worker-manager.ts                [modified]
                                              Route webr-opaque nodes to dispatchOpaque

src/ui/components/pipeline-node.tsx          [modified]
                                              webr-opaque rendering variant

3.2 Node type and ports

// src/core/pipeline/types.ts
export interface WebROpaqueParams {
  rSource: string;         // RHS sliced from original source
  resultBinding: string;   // R name the output lives under (`.n_<id>`)
  inputBindings: string[]; // ordered R identifiers this node depends on
  origin: 'assignment' | 'statement-fallback';
  unassigned: boolean;     // true for top-level side-effect calls (no LHS)
}

export type OpaqueResult =
  | { kind: 'dataset'; dataset: Dataset }
  | { kind: 'opaque-binding'; binding: string }
  | { kind: 'side-effect'; capturedText?: string };

export interface WebROpaqueNode extends PipelineNodeBase {
  type: 'webr-opaque';
  params: WebROpaqueParams;
  result?: OpaqueResult;
}

Ports are per-instance and computed dynamically:

// src/core/pipeline/types.ts — extend getPortsFor()
if (node.type === 'webr-opaque') {
  return {
    inputs: node.params.inputBindings.map(name => ({ name, dataType: 'any' })),
    outputs: [{ name: 'out', dataType: 'any' }],
  };
}

New 'any' dataType is added to PortDataType. Port validation treats it as bidirectionally compatible with 'dataset' and 'model'. No existing port uses 'any' — it’s reserved for opaque edges.

3.3 Rendering (UI)

pipeline-node.tsx adds a variant for webr-opaque:

Dashed border (distinct from webr-typed’s solid).
Amber “R?” badge in the corner (vs. webr-typed’s solid “R”).
Port handles render from node.params.inputBindings with the identifier name as the label.
Tooltip on the node shows node.params.rSource so the user can see the exact R expression.

webr-opaque is selectable, inspectable in the properties panel, and shows execution state (idle / running / dataset-marshaled / opaque-binding-only / side-effect-captured / error).

Results-panel rendering by result kind:

`result.kind`	Panel content
`dataset`	Dataset table viewer (same as native data-nodes)
`opaque-binding`	Badge: “R value kept in WebR env (binding: `<name>`)” + source echo
`side-effect` + `capturedText`	Preformatted text block (stdout/stderr from `captureR`)
`side-effect` without `capturedText`	Empty-state: “This node ran with no captured output. If it produced a plot, image capture is coming in session 3.”

4. Inliner `return()` unwrap — prerequisite

Current bug: inline(f) where f <- function(x) { body; return(x) } emits AnalysisCalls for the body statements plus a top-level return(x) that the recognizer then flags as unsupported.

Fix: in tryInline() (src/core/parsers/r/inliner.ts), after argument substitution, inspect the final body statement:

If it’s a FunctionCallNode with name return and exactly one argument → replace it with that argument as a bare expression statement.
If it’s assigned (y <- return(x)), unwrap the RHS: y <- x.
return() anywhere else in the body (early exits, conditionals) is unreachable under our single-level inlining model — already excluded by the “no control flow in body” guard. No change needed there.

Test coverage: add inliner-return.test.ts with five cases — single tail return, assigned tail return, no return (unchanged), early return (should fall through guard), named return value (return(value = x) → x).

Success metric: audit-opaque.ts rerun shows return drops from 490 unsupported occurrences to ≤ 5 (tolerates residual edge cases).

5. Recognizer — binding-level walk

5.1 Current structure

recognizeR today walks each top-level statement, and for AssignmentNode tries a fixed pattern table of function-name matches (tryRecognizeLm, tryRecognizeFeols, …). If no pattern matches, emits { kind: 'unsupported', ... }.

5.2 New structure

The primary loop iterates top-level statements in source order. For each, it dispatches through a sequence of sub-recognizers:

for (const stmt of program.body) {
  if (isIgnorableCall(stmt)) continue;              // library(), setwd(), etc.
  if (stmt.type === 'for' || stmt.type === 'control-flow') {
    handleLoopOrControlFlow(stmt); continue;
  }
  if (stmt.type === 'function-def') {
    registerFunctionDef(stmt); continue;
  }

  const result = tryRecognizeStatement(stmt, scope);
  //  ^ returns: typed AnalysisCall(s) | opaque AnalysisCall | 'evaluated-in-scope' | 'ignored'

  for (const call of result.calls) {
    if (call.assignedTo) scope.set(call.assignedTo, call);
    emit(call);
  }
}

tryRecognizeStatement is the new dispatch:

function tryRecognizeStatement(stmt, scope):
  1. Try typed patterns by RHS function name (existing tryRecognizeLm, tryRecognizeFeols, ...)
     → If one matches, return { calls: [typedCall] }
  2. Try scope-eval for evaluable RHS (existing mutate-column-arithmetic path)
     → If it's a scalar/vector the evaluator can handle, update scope and return { calls: [] }
  3. Try inline expansion (existing tryInline for user-defined function calls)
     → If successful, recurse on inlined body statements
  4. Try loop/apply expansion (existing tryExpandLoop, tryExpandApply)
     → If successful, flush expansion result
  5. **Opaque fallback (NEW):** construct a webr-opaque AnalysisCall from the assignment
     → Return { calls: [opaqueCall] }

Step 5 is the new insertion. Steps 1–4 are the existing logic refactored into a dispatch sequence. Pattern match still fires first — the only semantic change is that step 5 emits webr-opaque instead of unsupported.

5.3 Opaque AnalysisCall construction (`recognize-opaque.ts`)

function recognizeOpaqueAssignment(
  assignment: AssignmentNode,
  scope: Map<string, AnalysisCall>,
  source: string,
): AnalysisCall {
  const rhs = assignment.value;
  const rhsSource = source.slice(rhs.span.start, rhs.span.end);
  const freeVars = extractFreeIdentifiers(rhs);
  const inputBindings = freeVars.filter(v => scope.has(v));

  return {
    kind: 'webr-opaque',
    args: {
      rSource: rhsSource,
      inputBindings,
      origin: 'assignment',
    },
    assignedTo: assignment.target.name,
    sourceSpan: assignment.span,
  };
}

For unassigned top-level calls (plot(x), print(summary(m))) that the pattern table doesn’t recognize and aren’t in the ignorable-call list:

function recognizeOpaqueSideEffect(call: FunctionCallNode, scope, source): AnalysisCall {
  return {
    kind: 'webr-opaque',
    args: {
      rSource: source.slice(call.span.start, call.span.end),
      inputBindings: extractFreeIdentifiers(call).filter(v => scope.has(v)),
      origin: 'assignment',  // treated identically; result kind will be 'side-effect' at execute
    },
    sourceSpan: call.span,
    // No assignedTo → mapper emits a terminal node (no outgoing edges)
  };
}

5.4 Free-variable extraction

extractFreeIdentifiers(node) walks the AST and returns identifiers that are referenced but not bound within the expression. Filters out:

Function names — the identifier in the callee position of FunctionCallNode (e.g., my_cleanup in my_cleanup(df)) is a function reference, not a binding we track.
Named-argument keywords — in f(threshold = 0.5), threshold is a keyword, not a reference.
Formula variables — in y ~ x + z, y/x/z are column names, not bindings. (Caveat: column names can collide with binding names; we conservatively do not edge them, matching current behavior.)
dplyr NSE column references — inside filter(df, year > 2000), year is a column not a binding. Existing recognize-data-arg.ts already has this logic.
Locals from function definitions inside the expression — lambdas, anonymous functions. If the RHS contains function(a) a + 1, a is not free. (Rare in RHS expressions; handled conservatively — if detected, emit a diagnostic and don’t attempt free-var extraction, which makes the opaque node edge-less.)

Reuses isNSEContext() and related helpers from recognize-data-arg.ts rather than reimplementing.

5.5 Recognizer API — unchanged externally

recognizeR(ast, source, scope) → { calls, diagnostics, loadedPackages } signature stays identical. Only the internal structure changes. Existing callers (FileRegistry, audit, direct recognizer tests) need no modifications.

6. Statement-block opaque fallback

6.1 Parser error-recovery gap

The R parser uses Chevrotain with error recovery. When a statement fails to parse (e.g., a syntax the lexer doesn’t handle, an unrecognized construct), the parser skips to the next statement boundary. Today, the failed span is lost — no AnalysisCall is emitted for it, and no diagnostic carries its source.

Representative parse-failure cases observed in the corpus (17 files with errors across 15 papers; one file alone has 356 errors):

Shape	Example	Today	With fallback
R 4.1 lambda shorthand	`map(xs, \(x) x * 2)`	lexer drops statement	opaque node evals in WebR
Complex `felm` multi-`\\|` formula	`felm(y ~ x \\| fe1 + fe2 \\| z ~ w \\| cluster, data=df)`	recovery skips the assignment, downstream `m` undefined	opaque node with `resultBinding = .n_<id>` that downstream can reference
S4 slot access cascade	`val <- tree@data`	`@` trips recovery, following statements also dropped	one opaque node per skipped statement
Large swath in one file	`qje-do-financial-concerns/.../Figure_1.R` — 183 parse errors	~180 silently-dropped statements; pipeline looks artificially small	surfaces as opaque nodes so the user can see what got routed to WebR

6.2 Extension

parseR is extended to return an additional field unparsedRanges: Span[] — spans in the source that the parser skipped due to recovery. The recognizer receives these and emits one webr-opaque AnalysisCall per span:

for (const span of ast.unparsedRanges) {
  const rSource = source.slice(span.start, span.end);
  calls.push({
    kind: 'webr-opaque',
    args: {
      rSource,
      inputBindings: scanIdentifiersAgainstScope(rSource, scope),
      origin: 'statement-fallback',
    },
    sourceSpan: span,
    // No assignedTo → terminal node (best-effort evaluation; if the R side
    // assigns to user bindings, those are picked up by subsequent opaque
    // nodes via scope through worker-side R env persistence)
  });
}

6.3 `scanIdentifiersAgainstScope` — best-effort input inference

No AST means no proper free-variable extraction, but the recognizer already maintains a source-order scope map. A regex-based token scan intersected with scope is sufficient for the common case:

const R_RESERVED = new Set([
  'function', 'if', 'else', 'for', 'while', 'repeat', 'break', 'next',
  'return', 'TRUE', 'FALSE', 'NULL', 'NA', 'NA_integer_', 'NA_real_',
  'NA_character_', 'NaN', 'Inf', 'in',
]);

function scanIdentifiersAgainstScope(
  source: string,
  scope: Map<string, AnalysisCall>,
): string[] {
  const tokens = source.match(/\b[a-zA-Z.][a-zA-Z0-9._]*\b/g) ?? [];
  const seen = new Set<string>();
  for (const tok of tokens) {
    if (R_RESERVED.has(tok)) continue;
    if (scope.has(tok)) seen.add(tok);
  }
  return [...seen];
}

Example — m <- felm(y ~ x1 + x2 | fe1 + fe2 | z1 + z2 ~ w1 | cluster, data = df) where the parser trips on the multi-| formula and emits a fallback span covering the whole assignment:

Regex tokens: m, felm, y, x1, x2, fe1, fe2, z1, z2, w1, cluster, data, df
After reserved-word filter: same set
Intersect with scope (say scope has only df as a user binding): { df }
inputBindings = ['df'] → mapper adds edge from upstream data-node → fallback opaque’s df port → worker binds df as Dataset in R env → felm(..., data = df) resolves.

Trade-offs:

Over-approximation is safe. If scope has a single-letter binding like y and the fallback source uses y as a formula column, we’d bind the y Dataset into R env unnecessarily. R’s felm uses its data = df argument for column resolution, not the top-level y. Costs extra marshaling bytes; no correctness impact.
Under-approximation is possible. A fallback that references a name only through a dynamically-constructed string (paste0("d", "f") to build "df") won’t match. The user sees the R error and can refactor. Documented limitation.
Shadowing collisions (top-level y binding + y as a formula column) are theoretically ambiguous but vanishingly rare in applied-econ code; we accept the false positive.

6.3 Span collection in `parseR`

The Chevrotain parser’s error recovery already computes the skip range internally. Extracting it requires hooking the SKIP_TOKEN recovery path in the CST visitor and recording { start, end } pairs. Implementation: a small skipListener attached to the parser instance, populating a per-parse unparsedRanges array.

7. Mapper

mapper.ts gets one new case:

case 'webr-opaque': {
  return {
    id: freshId(call),
    type: 'webr-opaque',
    label: formatOpaqueLabel(call.args.rSource),  // first ~40 chars of rSource
    span: call.sourceSpan,
    params: {
      rSource: call.args.rSource,
      resultBinding: `.n_${freshId(call).replace(/[^a-z0-9]/gi, '_')}`,
      inputBindings: call.args.inputBindings,
      origin: call.args.origin,
      unassigned: !call.assignedTo,
    },
  };
}

Edges to the opaque node are added by the existing binding-resolution pass: for each name in inputBindings, look up the upstream node in the binding map and add an edge upstream.out → opaque.<name>.

8. Executor and worker protocol

8.1 Worker protocol extension

WebRResponse’s dispatch-result discriminated union gains a probe-aware opaque result:

type OpaquePayload =
  | { kind: 'dataset'; dataset: MarshaledDataset }
  | { kind: 'opaque-binding'; binding: string }
  | { kind: 'side-effect' };

type DispatchResult =
  | { kind: 'typed'; payload: unknown }
  | { kind: 'opaque'; payload: OpaquePayload };

8.2 Worker `handleDispatchOpaque` extended

The worker branches on req.unassigned before bindAndEval so side-effect calls don’t double-execute (running both as assignment and again under capture would redraw plots, re-write files, etc.).

Assignment path (default):

const rName = req.resultBinding;
const ok = await bindAndEval(req, rName);   // binds `rName <- rSource`
if (!ok) { /* post dispatch-error */ return; }

Side-effect path (unassigned):

if (req.unassigned) {
  // bindInputs first (no eval) so captureR can reference inputs
  await bindInputsOnly(req.inputs);

  const captured = await webR.captureR(req.rSource, { captureStreams: true });
  const capturedText = captured.output
    .filter(o => o.type === 'stdout' || o.type === 'stderr')
    .map(o => o.data)
    .join('\n');
  post({ type: 'dispatch-result', id, result: {
    kind: 'opaque',
    payload: { kind: 'side-effect', capturedText: capturedText || undefined },
  } });
  return;
}

const isDataFrame = await webR.evalR(`is.data.frame(${rName})`).then(r => r.toBoolean());
if (isDataFrame) {
  const marshaled = await marshalDatasetFromR(rName);  // reuse toMarshaled pattern in reverse
  post({ type: 'dispatch-result', id, result: { kind: 'opaque', payload: { kind: 'dataset', dataset: marshaled } } });
  // Keep rName in R env — downstream opaque/typed nodes may reference it
} else {
  post({ type: 'dispatch-result', id, result: { kind: 'opaque', payload: { kind: 'opaque-binding', binding: rName } } });
}

marshalDatasetFromR(rName) is a new helper — mirror of bindDatasetToR:

ncol <- ncol(rName); nrow <- nrow(rName); colnames <- colnames(rName)
For each column: col <- rName[[i]]; if (is.numeric(col)) typedArray else if (is.factor(col)) levels+codes else coerce to character
Assemble MarshaledDataset with columns in original order.

Numeric: as.numeric then toTypedArray(). Factor: as.integer(col) - 1L for codes, levels(col) for levels. Character: as.factor(col) then marshal as categorical. Logical: coerce to numeric 0/1 (documented lossiness).

8.3 Executor branch

src/core/pipeline/executor.ts adds a case for webr-opaque:

case 'webr-opaque': {
  // Resolve upstream inputs — each inputBinding either comes from a Dataset-producing
  // node (native or opaque-probe-succeeded) or from an opaque-binding handle.
  const inputs: Record<string, MarshaledDataset> = {};
  const carriedBindings: string[] = [];  // R names already live in env

  for (const name of node.params.inputBindings) {
    const upstream = findUpstreamNode(node, name);
    const result = upstream.result;
    if (result?.kind === 'dataset') {
      inputs[name] = toMarshaled(result.dataset);
    } else if (result?.kind === 'opaque-binding') {
      carriedBindings.push(result.binding);  // already bound under result.binding name
      // Re-alias if binding name differs from input port name
      if (result.binding !== name) rebind(name, result.binding);
    } else {
      throw new Error(`Cannot resolve input "${name}" for opaque node ${node.id}`);
    }
  }

  const payload = await workerManager.webrDispatchOpaque({
    nodeId: node.id,
    rSource: node.params.rSource,
    resultBinding: node.params.resultBinding,
    inputs,
    unassigned: node.params.unassigned,   // threaded from the AnalysisCall (no assignedTo)
  });

  node.result = payload;  // { kind: 'dataset', ... } | { kind: 'opaque-binding', ... } | { kind: 'side-effect' }
}

8.4 Downstream consumer handling

When a TS-native node’s data input comes from an opaque upstream:

Upstream result.kind === 'dataset' → Dataset is available; consumer runs natively. No change.
Upstream result.kind === 'opaque-binding' → Dataset not available; consumer errors with: "Cannot use opaque R value as input — downstream node expects a Dataset but upstream '<label>' returned a non-data.frame R object. Session 3 will add broom-bridge support."
Upstream result.kind === 'side-effect' → shouldn’t happen (side-effect nodes have no outgoing edges by construction); defensive error.

Consumer port validation is done once, per-pipeline-run, before dispatch. All impacted model/transform nodes are marked error before the executor starts so the user sees the whole affected region at once.

8.5 Sticky handling deferred

Session 3 will implement automatic promotion of downstream TS-native nodes to WebR (re-dispatch lm as webr-typed lm when its data arg is an opaque-binding). That requires both the broom bridge and lm/glm marshalers. Out of scope here — this session errors clearly instead.

9. Worker protocol — full request/response

Request (unchanged shape, new unassigned flag):

{
  type: 'dispatch-opaque';
  id: string;
  rSource: string;
  resultBinding: string;         // e.g., '.n_abc123'
  inputs: Record<string, MarshaledDataset>;
  unassigned?: boolean;          // true for side-effect calls
}

Response (extended):

{
  type: 'dispatch-result';
  id: string;
  result: { kind: 'opaque'; payload: OpaquePayload };
}
// or
{
  type: 'dispatch-error';
  id: string;
  stage: 'bind-inputs' | 'eval' | 'probe' | 'marshal';
  error: string;
}

New probe stage covers is.data.frame failures (e.g., result is an unevaluated promise, a missing value, or an error object). marshal covers marshalDatasetFromR failures (e.g., unsupported column type like complex numbers — documented failure mode).

10. CLAUDE.md No-Go List additions

Opaque 'any' port dataType is single-consumer-checked — port validation treats 'any' as compatible with 'dataset'/'model', but runtime consumer compatibility is resolved by inspecting node.result.kind. Never rely on port typing alone for opaque edges.
Opaque inputBindings are the only edge-creation source for opaque nodes — statement-fallback opaque nodes have empty inputBindings by design. Adding edges requires AST-derived free variables; never infer edges from rSource text.
Opaque probe-marshal is worker-only — the TS side never executes R; the probe decision (is.data.frame) happens in the worker and returns a discriminated union. Don’t add TS-side heuristics.
return() trailing unwrap is single-tail-only — the inliner unwraps return(x) when it’s the final statement of an inlined body, not at arbitrary positions. Control-flow returns stay excluded by the existing no-control-flow guard.
Statement-fallback opaque nodes use regex-based identifier scan + scope intersection for input inference — best-effort, may over-approximate (extra marshaling is safe) and may miss dynamically-constructed identifiers (paste0("d","f")). Never promote this to an AST-quality guarantee; call sites that need reliable input inference must use an assignment opaque node with a parsed AST.

11. Testing

11.1 Unit (Vitest)

inliner-return.test.ts — 5 cases for trailing return unwrap.
recognize-opaque.test.ts — free-variable extraction over representative RHS shapes (call, pipe, named args, formula, nested lambda).
recognizer.opaque.test.ts — binding-level walk emits opaque for unrecognized RHS; typed patterns still match first.
mapper.opaque.test.ts — AnalysisCall → WebROpaqueNode shape + edges from inputBindings.
webr-worker.opaque.test.ts — probe branch: is.data.frame true → dataset payload; false → opaque-binding payload.
executor.opaque.test.ts — Dataset upstream, opaque-binding upstream, error on opaque-binding → TS-native consumer.

11.2 Integration

webr-worker.integration.opaque.test.ts — real WebR worker, bind Dataset, run df2 <- some_r_expr(df), assert marshal-back Dataset matches.
recognizer.statement-fallback.test.ts — feed source with a known parser-failure construct, assert opaque node with the right span is emitted.

11.3 Audit regression

audit-opaque.ts is rerun after implementation. Expected deltas:

Metric	Before	After
`return` occurrences	490	≤ 5
Total unsupported nodes	10,753	≤ 3,000 (most become `webr-opaque`; the rest are ignorable scalars/side-effects)
`webr-opaque` nodes (new metric)	0	≥ 500
Models blocked (existing audit)	154	≤ 100

Regression criterion: webr-opaque nodes appear in ≥ 30 of 83 packages (≥ 36% coverage for the opaque path).

11.4 E2E (Playwright)

e2e/webr-opaque.spec.ts:

Upload a synthetic replication package where one data-prep call is intentionally unknown (e.g., a toy my_cleanup() user-defined function).
Wait for DAG containing a webr-opaque node (dashed border, “R?” badge).
Click Run.
Verify the opaque node runs, auto-marshals to Dataset, and downstream lm produces coefficients.

11.5 Validation — golden comparison

Paired with session 1’s validation pattern: pick one opaque path (readRDS of a CSV-equivalent .rds fixture) and assert the loaded Dataset matches a TS-native read_csv of the same content.

12. Shipping criteria

All unit and integration tests pass.
return audit count drops to ≤ 5.
Audit regression thresholds met (§11.3).
E2E test passes in Chromium.
npm run build && npm test && npm run lint && npm run test:e2e green.
Manual smoke: upload a replication package containing an unknown R function that returns a data.frame, verify opaque node renders with dashed border, Run completes, downstream lm shows coefficients.

13. Follow-up sessions

Session	Item	Rationale
3	Broom auto-typing bridge	Run `broom::tidy(binding)` on opaque results to auto-promote to typed regression — covers ~200 model classes via one generic path.
3	Sticky-opaque / auto-WebR promotion of downstream	When auto-marshal fails (opaque result is a list/model), re-dispatch downstream TS-native nodes as `webr-typed`. Requires `lm`/`glm` marshalers beyond the existing `lm_robust`.
3	Plot/SVG capture for side-effect opaque nodes	`captureR` with `captureGraphics: true` returns SVG for `plot()`/`ggplot()`. Needs a UI renderer (canvas or SVG embed), scaling, download. This session only captures stdout/stderr text.
3	UI “cast opaque to regression”	User-triggered broom extraction for nodes the probe couldn’t auto-type.
3+	Virtual FS artifact download	Files written by `ggsave()`, `write.csv()`, etc. currently die with the worker. Surface a “Download artifacts” panel that enumerates new files in a designated output dir.
M6	Native-alias + native-implement bucket work	`data.frame`, `as.data.frame`, `cbind`, `distinct`, `fixef`, etc. — tracked on the opaque-inventory report as Wave 1/2 backlog.
Any	Per-function typed marshalers	`readRDS`, excel readers, `sf::*` — each is a ~15–30 min `registerMarshaler()` call with a known output shape. Follow the `lm_robust` pattern.

14. Open questions

Opaque result caching across Run clicks. If the user edits code downstream but the opaque upstream didn’t change, should we skip re-executing the opaque node? Current execution model re-runs everything; opaque execution is expensive (R round-trip), so caching is tempting. Defer to M6 performance work.
Binding lifecycle in R env across runs. Session 1 leaves .n_<id> bindings alive between runs (free-form chaining); opaque inherits this. If a node is deleted from the DAG, its binding leaks in the R env until the worker is terminated. Low-impact for normal use; track as a cleanup item.