| name | playwright-interactive |
| description | Persistent browser and Electron interaction through `js_repl` for fast iterative UI debugging. |
Playwright Interactive Skill
Use a persistent js_repl Playwright session to debug local web or Electron
apps, keep the same handles alive across iterations, and run functional plus
visual QA without restarting the whole toolchain unless the process ownership
changed.
Preconditions
js_repl must be enabled for this skill.
- If
js_repl is missing, enable it in ~/.codex/config.toml:
[features]
js_repl = true
- You can also start a new session with
--enable js_repl (equivalent to
-c features.js_repl=true).
- After enabling
js_repl, start a new Codex session so the tool list
refreshes.
- For now, run this workflow with sandboxing disabled: start Codex with
--sandbox danger-full-access (or the equivalent config for
sandbox_mode=danger-full-access). This is a temporary requirement while
js_repl + Playwright support inside the sandbox is still being completed.
- Run setup from the same project directory you need to debug.
- Treat
js_repl_reset as a recovery tool, not routine cleanup. Resetting the
kernel destroys your Playwright handles.
One-time setup
test -f package.json || npm init -y
npm install playwright
node -e "import('playwright').then(() => console.log('playwright import ok')).catch((error) => { console.error(error); process.exit(1); })"
If you switch to a different workspace later, repeat setup there.
Core Workflow
- Write a brief QA inventory before testing:
- Build the inventory from three sources: the user's requested requirements,
the user-visible features or behaviors you actually implemented, and the
claims you expect to make in the final response.
- Anything that appears in any of those three sources must map to at least
one QA check before signoff.
- List the user-visible claims you intend to sign off on.
- List every meaningful user-facing control, mode switch, or implemented
interactive behavior.
- List the state changes or view changes each control or implemented behavior
can cause.
- Use this as the shared coverage list for both functional QA and visual QA.
- For each claim or control-state pair, note the intended functional check,
the specific state where the visual check must happen, and the evidence you
expect to capture.
- If a requirement is visually central but subjective, convert it into an
observable QA check instead of leaving it implicit.
- Add at least 2 exploratory or off-happy-path scenarios that could expose
fragile behavior.
- Run the bootstrap cell once.
- Start or confirm any required dev server in a persistent TTY session.
- Launch the correct runtime and keep reusing the same Playwright handles.
- After each code change, reload for renderer-only changes or relaunch for
main-process/startup changes.
- Run functional QA with normal user input.
- Run a separate visual QA pass.
- Verify viewport fit and capture the screenshots needed to support your
claims.
- Clean up the Playwright session only when the task is actually finished.
Bootstrap (Run Once)
var chromium;
var electronLauncher;
var browser;
var context;
var page;
var mobileContext;
var mobilePage;
var electronApp;
var appWindow;
try {
({ chromium, _electron: electronLauncher } = await import("playwright"));
console.log("Playwright loaded");
} catch (error) {
throw new Error(
`Could not load playwright from the current js_repl cwd. Run the setup commands from this workspace first. Original error: ${error}`,
);
}
Binding rules:
- Use
var for the shared top-level Playwright handles because later js_repl
cells reuse them.
- The setup cells below are intentionally short happy paths. If a handle looks
stale, set that binding to
undefined and rerun the cell instead of adding
recovery logic everywhere.
- Prefer one named handle per surface you care about (
page, mobilePage,
appWindow) over repeatedly rediscovering pages from the context.
Shared web helpers:
var resetWebHandles = function () {
context = undefined;
page = undefined;
mobileContext = undefined;
mobilePage = undefined;
};
var ensureWebBrowser = async function () {
if (browser && !browser.isConnected()) {
browser = undefined;
resetWebHandles();
}
browser ??= await chromium.launch({ headless: false });
return browser;
};
var reloadWebContexts = async function () {
for (const currentContext of [context, mobileContext]) {
if (!currentContext) continue;
for (const p of currentContext.pages()) {
await p.reload({ waitUntil: "domcontentloaded" });
}
}
console.log("Reloaded existing web tabs");
};
Choose Session Mode
For web apps, use an explicit viewport by default and treat native-window mode
as a separate validation pass.
- Use an explicit viewport for routine iteration, breakpoint checks,
reproducible screenshots, snapshot diffs, and model-assisted localization.
This is the default because it is stable across machines and avoids host
window-manager variability.
- When you need deterministic high-DPI behavior, keep the explicit viewport and
add
deviceScaleFactor rather than switching straight to native-window mode.
- Use native-window mode (
viewport: null) for a separate headed pass when you
need to validate launched window size, OS-level DPI behavior, browser chrome
interactions, or bugs that may depend on the host display configuration.
- For Electron, assume native-window behavior all the time. Electron launches
through Playwright with
noDefaultViewport, so treat it like a real desktop
window and check the as-launched size and layout before resizing anything.
- When signoff depends on both layout breakpoints and real desktop behavior, do
both passes: explicit viewport first for deterministic QA, then native-window
validation for final environment-specific checks.
- Treat switching modes as a context reset. Do not reuse a viewport-emulated
context for a native-window pass or vice versa; close the old page and
context, then create a new one for the new mode.
Start or Reuse Web Session
Desktop and mobile web sessions share the same browser, helpers, and QA flow.
The main difference is which context and page pair you create.
Desktop Web Context
Set TARGET_URL to the app you are debugging. For local servers, prefer
127.0.0.1 over localhost.
var TARGET_URL = "http://127.0.0.1:3000";
if (page?.isClosed()) page = undefined;
await ensureWebBrowser();
context ??= await browser.newContext({
viewport: { width: 1600, height: 900 },
});
page ??= await context.newPage();
await page.goto(TARGET_URL, { waitUntil: "domcontentloaded" });
console.log("Loaded:", await page.title());
If context or page is stale, set context = page = undefined and rerun the
cell.
Mobile Web Context
Reuse TARGET_URL when it already exists; otherwise set a mobile target
directly.
var MOBILE_TARGET_URL = typeof TARGET_URL === "string"
? TARGET_URL
: "http://127.0.0.1:3000";
if (mobilePage?.isClosed()) mobilePage = undefined;
await ensureWebBrowser();
mobileContext ??= await browser.newContext({
viewport: { width: 390, height: 844 },
isMobile: true,
hasTouch: true,
});
mobilePage ??= await mobileContext.newPage();
await mobilePage.goto(MOBILE_TARGET_URL, { waitUntil: "domcontentloaded" });
console.log("Loaded mobile:", await mobilePage.title());
If mobileContext or mobilePage is stale, set
mobileContext = mobilePage = undefined and rerun the cell.
Native-Window Web Pass
var TARGET_URL = "http://127.0.0.1:3000";
await ensureWebBrowser();
await page?.close().catch(() => {});
await context?.close().catch(() => {});
page = undefined;
context = undefined;
browser ??= await chromium.launch({ headless: false });
context = await browser.newContext({ viewport: null });
page = await context.newPage();
await page.goto(TARGET_URL, { waitUntil: "domcontentloaded" });
console.log("Loaded native window:", await page.title());
Start or Reuse Electron Session
Set ELECTRON_ENTRY to . when the current workspace is the Electron app and
package.json points main to the right entry file. If you need to target a
specific main-process file directly, use a path such as ./main.js instead.
var ELECTRON_ENTRY = ".";
if (appWindow?.isClosed()) appWindow = undefined;
if (!appWindow && electronApp) {
await electronApp.close().catch(() => {});
electronApp = undefined;
}
electronApp ??= await electronLauncher.launch({
args: [ELECTRON_ENTRY],
});
appWindow ??= await electronApp.firstWindow();
console.log("Loaded Electron window:", await appWindow.title());
If js_repl is not already running from the Electron app workspace, pass cwd
explicitly when launching.
If the app process looks stale, set electronApp = appWindow = undefined and
rerun the cell.
If you already have an Electron session but need a fresh process after a
main-process, preload, or startup change, use the restart cell in the next
section instead of rerunning this one.
Reuse Sessions During Iteration
Keep the same session alive whenever you can.
Web renderer reload:
await reloadWebContexts();
Electron renderer-only reload:
await appWindow.reload({ waitUntil: "domcontentloaded" });
console.log("Reloaded Electron window");
Electron restart after main-process, preload, or startup changes:
await electronApp.close().catch(() => {});
electronApp = undefined;
appWindow = undefined;
electronApp = await electronLauncher.launch({
args: [ELECTRON_ENTRY],
});
appWindow = await electronApp.firstWindow();
console.log("Relaunched Electron window:", await appWindow.title());
If your launch requires an explicit cwd, include the same cwd here.
Default posture:
- Keep each
js_repl cell short and focused on one interaction burst.
- Reuse the existing top-level bindings (
browser, context, page,
electronApp, appWindow) instead of redeclaring them.
- If you need isolation, create a new page or a new context inside the same
browser.
- For Electron, use
electronApp.evaluate(...) only for main-process inspection
or purpose-built diagnostics.
- Fix helper mistakes in place; do not reset the REPL unless the kernel is
actually broken.
Checklists
Session Loop
- Bootstrap
js_repl once, then keep the same Playwright handles alive across
iterations.
- Launch the target runtime from the current workspace.
- Make the code change.
- Reload or relaunch using the correct path for that change.
- Update the shared QA inventory if exploration reveals an additional control,
state, or visible claim.
- Re-run functional QA.
- Re-run visual QA.
- Capture final artifacts only after the current state is the one you are
evaluating.
Reload Decision
- Renderer-only change: reload the existing page or Electron window.
- Main-process, preload, or startup change: relaunch Electron.
- New uncertainty about process ownership or startup code: relaunch instead of
guessing.
Functional QA
- Use real user controls for signoff: keyboard, mouse, click, touch, or
equivalent Playwright input APIs.
- Verify at least one end-to-end critical flow.
- Confirm the visible result of that flow, not just internal state.
- For realtime or animation-heavy apps, verify behavior under actual interaction
timing.
- Work through the shared QA inventory rather than ad hoc spot checks.
- Cover every obvious visible control at least once before signoff, not only the
main happy path.
- For reversible controls or stateful toggles in the inventory, test the full
cycle: initial state, changed state, and return to the initial state.
- After the scripted checks pass, do a short exploratory pass using normal input
for 30-90 seconds instead of following only the intended path.
- If the exploratory pass reveals a new state, control, or claim, add it to the
shared QA inventory and cover it before signoff.
page.evaluate(...) and electronApp.evaluate(...) may inspect or stage
state, but they do not count as signoff input.
Visual QA
- Treat visual QA as separate from functional QA.
- Use the same shared QA inventory defined before testing and updated during QA;
do not start visual coverage from a different implicit list.
- Restate the user-visible claims and verify each one explicitly; do not assume
a functional pass proves a visual claim.
- A user-visible claim is not signed off until it has been inspected in the
specific state where it is meant to be perceived.
- Inspect the initial viewport before scrolling.
- Confirm that the initial view visibly supports the interface's primary claims;
if a core promised element is not clearly perceptible there, treat that as a
bug.
- Inspect all required visible regions, not just the main interaction surface.
- Inspect the states and modes already enumerated in the shared QA inventory,
including at least one meaningful post-interaction state when the task is
interactive.
- If motion or transitions are part of the experience, inspect at least one
in-transition state in addition to the settled endpoints.
- If labels, overlays, annotations, guides, or highlights are meant to track
changing content, verify that relationship after the relevant state change.
- For dynamic or interaction-dependent visuals, inspect long enough to judge
stability, layering, and readability; do not rely on a single screenshot for
signoff.
- For interfaces that can become denser after loading or interaction, inspect
the densest realistic state you can reach during QA, not only the empty,
loading, or collapsed state.
- If the product has a defined minimum supported viewport or window size, run a
separate visual QA pass there; otherwise, choose a smaller but still realistic
size and inspect it explicitly.
- Distinguish presence from implementation: if an intended affordance is
technically there but not clearly perceptible because of weak contrast,
occlusion, clipping, or instability, treat that as a visual failure.
- If any required visible region is clipped, cut off, obscured, or pushed
outside the viewport in the state you are evaluating, treat that as a bug even
if page-level scroll metrics appear acceptable.
- Look for clipping, overflow, distortion, layout imbalance, inconsistent
spacing, alignment problems, illegible text, weak contrast, broken layering,
and awkward motion states.
- Judge aesthetic quality as well as correctness. The UI should feel
intentional, coherent, and visually pleasing for the task.
- Prefer viewport screenshots for signoff. Use full-page captures only as
secondary debugging artifacts, and capture a focused screenshot when a region
needs closer inspection.
- If motion makes a screenshot ambiguous, wait briefly for the UI to settle,
then capture the image you are actually evaluating.
- Before signoff, explicitly ask: what visible part of this interface have I not
yet inspected closely?
- Before signoff, explicitly ask: what visible defect would most likely
embarrass this result if the user looked closely?
Signoff
- The functional path passed with normal user input.
- Coverage is explicit against the shared QA inventory: note which requirements,
implemented features, controls, states, and claims were exercised, and call
out any intentional exclusions.
- The visual QA pass covered the whole relevant interface.
- Each user-visible claim has a matching visual check and reviewed screenshot
artifact from the state and viewport or window size where that claim matters.
- The viewport-fit checks passed for the intended initial view and any required
minimum supported viewport or window size.
- If the product launches in a window, the as-launched size, placement, and
initial layout were checked before any manual resize or repositioning.
- The UI is not just functional; it is visually coherent and not aesthetically
weak for the task.
- Functional correctness, viewport fit, and visual quality must each pass on
their own; one does not imply the others.
- A short exploratory pass was completed for interactive products, and the
response mentions what that pass covered.
- If screenshot review and numeric checks disagreed at any point, the
discrepancy was investigated before signoff; visible clipping in screenshots
is a failure to resolve, not something metrics can overrule.
- Include a brief negative confirmation of the main defect classes you checked
for and did not find.
- Cleanup was executed, or you intentionally kept the session alive for further
work.
Screenshot Examples
If you plan to emit a screenshot through codex.emitImage(...), use the
CSS-normalized paths in the next section by default. Those are the canonical
examples for screenshots that will be interpreted by the model or used for
coordinate-based follow-up actions. Keep raw captures as an exception for
fidelity-sensitive debugging only; the raw exception examples appear after the
normalization guidance.
Model-bound screenshots (default)
If you will emit a screenshot with codex.emitImage(...) for model
interpretation, normalize it to CSS pixels for the exact region you captured
before emitting. This keeps returned coordinates aligned with Playwright CSS
pixels if the reply is later used for clicking, and it also reduces image
payload size and model token cost.
Do not emit raw native-window screenshots by default. Skip normalization only
when you explicitly need device-pixel fidelity, such as Retina or DPI artifact
debugging, pixel-accurate rendering inspection, or another fidelity-sensitive
case where raw pixels matter more than payload size. For local-only inspection
that will not be emitted to the model, raw capture is fine.
Do not assume page.screenshot({ scale: "css" }) is enough in native-window
mode (viewport: null). In Chromium on macOS Retina displays, headed
native-window screenshots can still come back at device-pixel size even when
scale: "css" is requested. The same caveat applies to Electron windows
launched through Playwright because Electron runs with noDefaultViewport, and
appWindow.screenshot({ scale: "css" }) may still return device-pixel output.
Use separate normalization paths for web pages and Electron windows:
- Web: prefer
page.screenshot({ scale: "css" }) directly. If native-window
Chromium still returns device-pixel output, resize inside the current page
with canvas; no scratch page is required.
- Electron: do not use
appWindow.context().newPage() or
electronApp.context().newPage() as a scratch page. Electron contexts do not
support that path reliably. Capture in the main process with
BrowserWindow.capturePage(...), resize with nativeImage.resize(...), and
emit those bytes directly.
Shared helpers and conventions:
var emitJpeg = async function (bytes) {
await codex.emitImage({
bytes,
mimeType: "image/jpeg",
detail: "original",
});
};
var emitWebJpeg = async function (surface, options = {}) {
await emitJpeg(
await surface.screenshot({
type: "jpeg",
quality: 85,
scale: "css",
...options,
}),
);
};
var clickCssPoint = async function ({ surface, x, y, clip }) {
await surface.mouse.click(
clip ? clip.x + x : x,
clip ? clip.y + y : y,
);
};
var tapCssPoint = async function ({ page, x, y, clip }) {
await page.touchscreen.tap(
clip ? clip.x + x : x,
clip ? clip.y + y : y,
);
};
- Use
page or mobilePage for web, or appWindow for Electron, as the
surface.
- Treat
clip as CSS pixels from getBoundingClientRect() in the renderer.
- Prefer JPEG at
quality: 85 unless lossless fidelity is specifically
required.
- For full-image captures, use returned
{ x, y } directly.
- For clipped captures, add the clip origin back when clicking.
Web CSS normalization
Preferred web path for explicit-viewport contexts, and often for web in general:
await emitWebJpeg(page);
Mobile web uses the same path; substitute mobilePage for page:
await emitWebJpeg(mobilePage);
If the model returns { x, y }, click it directly:
await clickCssPoint({ surface: page, x, y });
Mobile web click path:
await tapCssPoint({ page: mobilePage, x, y });
For web clip screenshots or element screenshots in this normal path,
scale: "css" usually works directly. Add the region origin back when clicking.
await emitWebJpeg(page, { clip })
await emitWebJpeg(mobilePage, { clip })
await clickCssPoint({ surface: page, clip, x, y })
await tapCssPoint({ page: mobilePage, clip, x, y })
await clickCssPoint({ surface: page, clip: box, x, y }) after
const box = await locator.boundingBox()
Web native-window fallback when scale: "css" still comes back at device-pixel
size:
var emitWebScreenshotCssScaled = async function (
{ page, clip, quality = 0.85 } = {},
) {
var NodeBuffer = (await import("node:buffer")).Buffer;
const target = clip
? { width: clip.width, height: clip.height }
: await page.evaluate(() => ({
width: window.innerWidth,
height: window.innerHeight,
}));
const screenshotBuffer = await page.screenshot({
type: "png",
...(clip ? { clip } : {}),
});
const bytes = await page.evaluate(
async ({ imageBase64, targetWidth, targetHeight, quality }) => {
const image = new Image();
image.src = `data:image/png;base64,${imageBase64}`;
await image.decode();
const canvas = document.createElement("canvas");
canvas.width = targetWidth;
canvas.height = targetHeight;
const ctx = canvas.getContext("2d");
ctx.imageSmoothingEnabled = true;
ctx.drawImage(image, 0, 0, targetWidth, targetHeight);
const blob = await new Promise((resolve) =>
canvas.toBlob(resolve, "image/jpeg", quality)
);
return new Uint8Array(await blob.arrayBuffer());
},
{
imageBase64: NodeBuffer.from(screenshotBuffer).toString("base64"),
targetWidth: target.width,
targetHeight: target.height,
quality,
},
);
await emitJpeg(bytes);
};
For a full viewport fallback capture, treat returned { x, y } as direct CSS
coordinates:
await emitWebScreenshotCssScaled({ page });
await clickCssPoint({ surface: page, x, y });
For a clipped fallback capture, add the clip origin back:
await emitWebScreenshotCssScaled({ page, clip });
await clickCssPoint({ surface: page, clip, x, y });
Electron CSS normalization
For Electron, normalize in the main process instead of opening a scratch
Playwright page. The helper below returns CSS-scaled bytes for the full content
area or for a clipped CSS-pixel region. Treat clip as content-area CSS pixels,
for example values taken from getBoundingClientRect() in the renderer.
var emitElectronScreenshotCssScaled = async function (
{ electronApp, clip, quality = 85 } = {},
) {
const bytes = await electronApp.evaluate(
async ({ BrowserWindow }, { clip, quality }) => {
const win = BrowserWindow.getAllWindows()[0];
const image = clip
? await win.capturePage(clip)
: await win.capturePage();
const target = clip
? { width: clip.width, height: clip.height }
: (() => {
const [width, height] = win.getContentSize();
return { width, height };
})();
const resized = image.resize({
width: target.width,
height: target.height,
quality: "best",
});
return resized.toJPEG(quality);
},
{ clip, quality },
);
await emitJpeg(bytes);
};
Full Electron window:
await emitElectronScreenshotCssScaled({ electronApp });
await clickCssPoint({ surface: appWindow, x, y });
Clipped Electron region using CSS pixels from the renderer:
var clip = await appWindow.evaluate(() => {
const rect = document.getElementById("board").getBoundingClientRect();
return {
x: Math.round(rect.x),
y: Math.round(rect.y),
width: Math.round(rect.width),
height: Math.round(rect.height),
};
});
await emitElectronScreenshotCssScaled({ electronApp, clip });
await clickCssPoint({ surface: appWindow, clip, x, y });
Raw Screenshot Exception Examples
Use these only when raw pixels matter more than CSS-coordinate alignment, such
as Retina or DPI artifact debugging, pixel-accurate rendering inspection, or
other fidelity-sensitive review.
Web desktop raw emit:
await codex.emitImage({
bytes: await page.screenshot({ type: "jpeg", quality: 85 }),
mimeType: "image/jpeg",
detail: "original",
});
Electron raw emit:
await codex.emitImage({
bytes: await appWindow.screenshot({ type: "jpeg", quality: 85 }),
mimeType: "image/jpeg",
detail: "original",
});
Mobile raw emit after the mobile web context is already running:
await codex.emitImage({
bytes: await mobilePage.screenshot({ type: "jpeg", quality: 85 }),
mimeType: "image/jpeg",
detail: "original",
});
Viewport Fit Checks (Required)
Do not assume a screenshot is acceptable just because the main widget is
visible. Before signoff, explicitly verify that the intended initial view
matches the product requirement, using both screenshot review and numeric
checks.
- Define the intended initial view before signoff. For scrollable pages, this is
the above-the-fold experience. For app-like shells, games, editors,
dashboards, or tools, this is the full interactive surface plus the controls
and status needed to use it.
- Use screenshots as the primary evidence for fit. Numeric checks support the
screenshots; they do not overrule visible clipping.
- Signoff fails if any required visible region is clipped, cut off, obscured, or
pushed outside the viewport in the intended initial view, even if page-level
scroll metrics appear acceptable.
- Scrolling is acceptable when the product is designed to scroll and the initial
view still communicates the core experience and exposes the primary call to
action or required starting context.
- For fixed-shell interfaces, scrolling is not an acceptable workaround if it is
needed to reach part of the primary interactive surface or essential controls.
- Do not rely on document scroll metrics alone. Fixed-height shells, internal
panes, and hidden-overflow containers can clip required UI while page-level
scroll checks still look clean.
- Check region bounds, not just document bounds. Verify that each required
visible region fits within the viewport in the startup state.
- For Electron or desktop apps, verify both the launched window size and
placement and the renderer's initial visible layout before any manual resize
or repositioning.
- Passing viewport-fit checks only proves that the intended initial view is
visible without unintended clipping or scrolling. It does not prove that the
UI is visually correct or aesthetically successful.
Web or renderer check:
console.log(
await page.evaluate(() => ({
innerWidth: window.innerWidth,
innerHeight: window.innerHeight,
clientWidth: document.documentElement.clientWidth,
clientHeight: document.documentElement.clientHeight,
scrollWidth: document.documentElement.scrollWidth,
scrollHeight: document.documentElement.scrollHeight,
canScrollX: document.documentElement.scrollWidth >
document.documentElement.clientWidth,
canScrollY: document.documentElement.scrollHeight >
document.documentElement.clientHeight,
})),
);
Electron check:
console.log(
await appWindow.evaluate(() => ({
innerWidth: window.innerWidth,
innerHeight: window.innerHeight,
clientWidth: document.documentElement.clientWidth,
clientHeight: document.documentElement.clientHeight,
scrollWidth: document.documentElement.scrollWidth,
scrollHeight: document.documentElement.scrollHeight,
canScrollX: document.documentElement.scrollWidth >
document.documentElement.clientWidth,
canScrollY: document.documentElement.scrollHeight >
document.documentElement.clientHeight,
})),
);
Augment the numeric check with getBoundingClientRect() checks for the required
visible regions in your specific UI when clipping is a realistic failure mode;
document-level metrics alone are not sufficient for fixed shells.
Dev Server
For local web debugging, keep the app running in a persistent TTY session. Do
not rely on one-shot background commands from a short-lived shell.
Use the project's normal start command, for example:
npm start
Before page.goto(...), verify the chosen port is listening and the app
responds.
For Electron debugging, launch the app from js_repl through
_electron.launch(...) so the same session owns the process. If the Electron
renderer depends on a separate dev server (for example Vite or Next), keep that
server running in a persistent TTY session and then relaunch or reload the
Electron app from js_repl.
Cleanup
Only run cleanup when the task is actually finished:
- This cleanup is manual. Exiting Codex, closing the terminal, or losing the
js_repl session does not implicitly run electronApp.close(),
context.close(), or browser.close().
- For Electron specifically, assume the app may keep running if you leave the
session without executing the cleanup cell first.
if (electronApp) {
await electronApp.close().catch(() => {});
}
if (mobileContext) {
await mobileContext.close().catch(() => {});
}
if (context) {
await context.close().catch(() => {});
}
if (browser) {
await browser.close().catch(() => {});
}
browser = undefined;
context = undefined;
page = undefined;
mobileContext = undefined;
mobilePage = undefined;
electronApp = undefined;
appWindow = undefined;
console.log("Playwright session closed");
If you plan to exit Codex immediately after debugging, run the cleanup cell
first and wait for the "Playwright session closed" log before quitting.
Common Failure Modes
Cannot find module 'playwright': run the one-time setup in the current
workspace and verify the import before using js_repl.
- Playwright package is installed but the browser executable is missing: run
npx playwright install chromium.
page.goto: net::ERR_CONNECTION_REFUSED: make sure the dev server is still
running in a persistent TTY session, recheck the port, and prefer
http://127.0.0.1:<port>.
electron.launch hangs, times out, or exits immediately: verify the local
electron dependency, confirm the args target, and make sure any renderer
dev server is already running before launch.
Identifier has already been declared: reuse the existing top-level bindings,
choose a new name, or wrap the code in { ... }. Use js_repl_reset only
when the kernel is genuinely stuck.
browserContext.newPage: Protocol error (Target.createTarget): Not supported
while working with Electron: do not use appWindow.context().newPage() or
electronApp.context().newPage() as a scratch page; use the Electron-specific
screenshot normalization flow in the model-bound screenshots section.
js_repl timed out or reset: rerun the bootstrap cell and recreate the
session with shorter, more focused cells.
- Browser launch or network operations fail immediately: confirm the session was
started with
--sandbox danger-full-access and restart that way if needed.