Planet Mozilla

Introducing Coil

In the coming weeks, Mozilla will roll out a Web Monetization experiment using Coil to support payments to creators in the Firefox Reality ecosystem. Web Monetization is an alternative approach to payments that doesn’t rely on advertising or stealing your data and attention. We wrote about Web Monetization for game developers back in the autumn, and now we’re excited to invite more of you to participate, first as creators and soon as consumers of all kinds of digital and virtual content.

Problem: Now more than ever, digital content creators need new options for earning money from their work in a fast-changing world. Solution: Mozilla is testing Coil as an alternative to credit card or Paypal payments for authors and independent content creators.

If you’ve developed a 3D experience, a game, a 360 video, or if you’re thinking of building something new, you’re invited to participate in this experiment. I encourage you as well to contact us directly at creator_payments at mozilla dot com to showcase your work in the Firefox Reality content feed.

You’ll find details on how to participate below. I will also share answers and observations, from my own perspective as an implementer and investigator on the Mixed Reality team.

A note about timing

Tangentially, the COVID-19 pandemic is dominating our attention. Just to be clear: This project is not a promise to create revenue for you during a planetary crisis. We support people where they are emotionally in their lives at this time and we do feel that real-world concerns are far more important. Also, we send thanks to everybody at Coil and Mozilla and all of you who are supporting this work when we’re all juggling family, chores, and our own lives.

In closing

We know that many of you are looking for solutions to make money from your creative work online. We are here for you and we want you to create, share, and thrive on the net. Take a look the details on how to participate below. I will also share answers to other questions and observations from my own perspective as an implementer and investigator on the Mixed Reality team. Please let us know how this works for you!

FAQ: How to participate

How do I participate as a Creator?

Do you have a piece of content—a blog post, an interactive experience, a 360 video, a WebXR game—that you want to share with people in Firefox Reality? Here’s how you can web monetize this content:

The first step is to add a meta tag to the top of your site which will define a payment pointer (an email address for money). This article walks you through the process in detail:

From js13kGames to MozFest Arcade: A game dev Web Monetization story

Alternatively, this article is also good:
Web Monetization: Quick Start Guide

If you have a WordPress blog here’s another way to add a payment pointer.

The second step is to simply please let us know! You can message us at creator_payments@mozilla.com and we’ll make sure that your work is showcased in the Firefox Reality Content feed.

What is this Coil thing anyway?

Coil is a for-profit membership service that charges users $5.00 a month and streams micropayments to creators based on member attention. Coil uses the Interledger network to move money, allowing creators to work in any currency they like.

Effectively you get paid for user attention—assuming those users are set up with web monetization. Web Monetization consists of an HTML tag, a JavaScript API, and uses the Interledger protocol for actually moving the money and enabling payments in many different currencies.

And just to be clear, Interledger is not a blockchain and there is no “Interledger token”. Interledger functions more like the Internet, in that it routes packets. Except the packets also represent money instead of just carrying data. You can find out more about how it works on interledger.org.

Why Coil?

Coil is an example of how open standards help foster healthy ecosystems. Coil can be thought of as a user-facing appliance running on top of the emerging Web Monetization and Payment Pointers standard. As Coil succeeds, the possibilities for other payment services to succeed also increases. Once creators set up a payment pointer, they themselves are not tied to Coil. Anybody or any new service can send money to that creator—without using Coil itself. By lowering the “activation energy” this opens up the door for new payment services. Also, at the same time, we at Mozilla stay true to our values—fostering open standards, working internationally, and protecting user privacy.

From a user perspective, if I install Coil how do I know it is working?

On a desktop browser, if you have a Coil subscription you can visit Hubs by Mozilla right now, and by clicking on the Coil plugin you can see that it is being monetized.

For testing Coil in Firefox Reality, you can visit this test site to see if you are Coil enabled. (Note: Personally, I’m not a big fan of the depiction of gender and the rags to riches narrative at that URL. But the site works for testing.)

From a creator perspective if I install Coil how do I know it is working?

If you visit this Coil Checker site and enter the URL of your own site, it will report if your Coil implementation is working.

Can I offer different content based on if patrons are paying or not?

As a creator, you can detect if patrons are Coil-enabled using javaScript. The recommended practice is called the “100+20” rule: offer special content for visitors who are paying, but do not disable the site or user experience for other guests. Please see the following links:

Web Monetization: Exclusive Content

The 100+20 Rule for Premium Content

Can I share revenue with other creators?

Ben has a great article on Probabilistic Revenue Sharing and Sabine has another one about a Web Monetized Image Gallery, showing how you can change where revenue is flowing based on which content is being examined.

If I enable Coil on my sites how do I get cash out of the system?

If you are in the United States you can get an account at Stronghold. There are other web wallets that support Interledger and can convert payments to local currencies. This varies depending on which country you are in. Note that in the U.S, the Securities and Exchange Commission (SEC) has important Know Your Customer (KYC) requirements, which means you’ll need to provide a driver’s license or passport.

Of course, Web Monetization will work better once it is adopted by a large number of users, built into most browsers, and so on, but the goal of this phase is less to generate a cash-out for you today and more about gathering data and feedback. So please keep in mind that this is an experiment! Also, again, we are especially interested in hearing how this works for you. Please make sure to contact us at creator_payments at mozilla dot com once you set this up.

How will Mozilla encourage users to participate in this experiment?

Stay tuned for a follow-up announcement in the not too distant future. In broad strokes, we will issue free Coil memberships to qualified users in the Firefox Reality ecosystem.

How does this experiment with Coil differ from Mozilla’s partnership with Scroll.com?

Astute observers will notice that Mozilla recently partnered with Scroll, a new ad-free subscription service. So how is this different from Scroll and why do we need both things?

The main difference today is that our collaboration with Coil today is to test adoption.

These two membership services are aimed at different use cases. Coil lets anybody be a content creator and get paid out of user attention. Because the payout rate is something like $0.36 per hour per user, Coil becomes useful if you have hundreds of people looking at your site. In contrast, Scroll partners with specific and often larger organizations such as publishers and media outlets with reporters, editors, and higher overheads. Their fees reflect the value of news in terms of quality and reputation.

Notably there are also other services such as Comixology, (also described here), Flattr, and Unlock. Each of these caters to different audience needs.

We can even imagine future services that have much higher payment rates, such as charging $30.00 an hour to allow a foreign language teacher in a virtual Hubs room to teach a small class of students and have a sustainable business. There will never be a single silver bullet that covers all consumer needs.

Does “Grant for the Web” relate to this?

Grant for the Web is a separate series of grants that are definitely worth applying for. This initiative plans to distribute 100 million dollars to support creators on the web. This is especially suitable for web projects that require up-front funding.

Payment Challenges and Solutions

Why are we looking at payment solutions?

Last year we interviewed web developers and creatives, asking them about how they monetized content on the web. They reported several challenges. These are two of the largest issues:

• Payment Frictions: Many developers reported that they simply didn’t have good ways to charge money—especially small amounts of money. Solutions were fragmented and complex. Their patrons didn’t have a way to pay even if they wanted to.
• Funding Up Front: Beyond payments, there was a specific issue around simply needing more money before starting development. Historically, smaller web developers were often able to incrementally grow their revenue. Yet because the web is becoming more powerful there are now higher up-front costs to build compelling experiences.

Note that there were many other related issues such as discoverability of content, consumer trust in content, defending intellectual property, better tools for building content and so on. But payments is one area that seems to require a known and trusted neutral third-party. And so, we believe that Mozilla is uniquely qualified to help with this.

A look at the digital content ecosystem

If we step back and look beyond the web, digital content ecosystems are exploding. Social apps such as Facebook are a $50 billion dollar a year industry, driven by advertising. Mobile app subscription revenue is $4 billion dollars a year. Mobile native games were forecast to capture over $70 billion dollars in 2019.

Experiences on app stores such as Google Play or the Apple App Store can capture up to 30% of that energy in transaction fees. (Admittedly, they provide other valuable services mentioned above, such as quality, trust, discovery, and recourse).

Although the boundary between native and web is somewhat porous, some developers we spoke to were packaging their web apps as native apps and releasing them into app stores such as itch.io just to get cash out of the system for their labor.

However, the web is unique. The web is open and accessible to all parties, not owned or controlled by any one party. Content can be shared with a URL. Because of this, the web has become the place of the “great conversation” – where we can all talk freely about issues all over the world.

Thanks to the work of many engineers, the web has many of the rich visual capabilities of native apps delivered via open standards. Technologies like WebAssembly and high-performance languages such as Rust make it possible for a game like Candy Crush Saga to become a web experience.

And yet, even though you can share a web experience with somebody halfway around the planet, there’s no way for them to tip you a quarter if they like their experience. If money is a form of communication, then it makes sense to fix money as well—in an open, scalable way that is fair, and that discourages bad actors.

Why not just stick with advertising?

Right now advertising dominates on the web as a revenue model. Ads are important and valuable as a form of social signaling in a noisy landscape. However, this means creators may be beholden to advertisers more so than to their patrons.

There are strong market incentives today to profile, segment, and target users. Targeting can even become a vector for bad actors, such as we saw with Cambridge Analytica. Cross-site tracking in particular is a concern. As a result, browser vendors such as Apple, Microsoft and Mozilla are working to reduce cross-site tracking. This is reducing the effectiveness of advertising as a whole.

But nature abhors a vacuum. We need to do more. From an ecosystem perspective, if we can support alternative revenue options and protect user privacy this feels like a win.

Don’t users expect content on the web to be free?

There is some argument that services like Patreon and Kickstarter exist because people who enjoy online content want to think of themselves as patrons of the arts; not merely consumers. We are doing this experiment in part to test that idea.

Why not invent some other digital currency or wallet solution?

Payments on the web is a complex topic. There are creator needs, user and patron needs, privacy concerns, international boundaries, payment frictions and costs, regulatory issues and so on. Consider even just the issue of people who don’t have credit cards; or artists, story-tellers, and creators around the world who don’t have bank accounts at all—especially women.

We’ve seen ideas over the years ranging from Beenz (now defunct) to Libra, and every imaginable point system and scheme. We see Brave and Puma providing browser-bound solutions. Industry-wide, we have working methods for purchases online for adults with credit cards such as through Stripe or Paypal. But there aren’t widely available solutions for smaller low-friction payments that hit all our criteria.

We will continue to explore a variety of options, but we want options like Web Monetization that are available today. We value options that have low activation energy; are transparent and easy to test; don’t require industry changes; handle small transactions; work over international boundaries; are abuse-resistant; help the unbanked; and protect user privacy.

Doesn’t Web Payments solve this problem?

We’re all familiar with the Error code 404 – page not found warning on the web. But probably not a single one of us has seen an “Error code 402 – payment required” warning. Payments are not something we as consumers use yet or encounter routinely in the wild.

Until we see “402 Payment Required” on the web it’s probably likely that we have not solved web payments.

Yes, we have W3C Web Payments—and this may become the right answer. There are some options from Paypal for micropayments, as well as a bewildering number of cryptocurrency solutions. Still, we have our work cut out for us.

Long-Term Trajectories: A Vision

Welcome to the future. It is August 1st, 2022. You’re surfing the web and you come across an amazing recipe site or blog post you really like, perhaps a kid-friendly indie game or photos of the northern lights, captured and shared by somebody in a different country. Or perhaps you’ve been watching a campaign to protect forests in Romania and you want to donate. Now imagine being able to easily send them money as a token of your appreciation.

Maybe you’ve become a fan of a new virtual reality interactive journalism site. Rather than subscribing to them specifically you use a service that streams background micropayments while you are on their site. As you and your friends join in, the authors get more and more support over time. The creator is directly supported in their work, and directly responsive to you, rather than having to chase grants. They’re able to vet their sources better and extend their reach.

This is the kind of vision that we want to support. Let’s get there together. If you have any other questions or comments please reach out!

The post Innovating on Web Monetization: Coil and Firefox Reality appeared first on Mozilla Hacks - the Web developer blog.

Lots of kids around the world are learning from home right now. In this post, I introduce free resources based on web technologies that will help them explore and learn from the safety of their living rooms. VR headsets and high-end graphics cards aren’t necessary. Really, all you need is a web browser!

Create a secret hideout

Hubs by Mozilla lets you share a virtual room with friends right in your browser. You can watch videos, play with 3D objects, or just hang out. Then, once you get the hang of Hubs, you can build almost anything imaginable with Spoke: a clubhouse, adventure island, or magic castle . . . . In Hubs, your little world becomes a place to spend time with friends (and show off your skills).

Try It Out

Play with the CSS Coloring Book

When kids (or adults) want to color, you have some options besides pulp paper booklets of princesses and sea creatures, thanks to Lubna, a front-end developer from the UK. Just click the “Edit On Codepen” button, and start playing. (The CSS color guide on MDN is a helpful reference). Young and old can learn by experimenting with this fun little toy.

Bring Bright Colors Into A Gray Day

Learn CSS Grid and Flexbox

The seasons are changing around the world—toward spring and toward fall. It feels like time to get into the garden and meet the frogs hopping from plant to plant. The Grid Garden that is, and Flexbox Froggy, to be precise. Educational software vendor Codepip created these attractive online learning experiences. They’re a great place for the young—and the young at heart—to get started with CSS.

Enter the Garden
Meet Flexbox Froggy

Fly to Jupiter

You don’t need a bus, car, submarine, or rocketship to go on a field trip. Educator Kai has created a variety of free VR experiences for kids and adults over at KaiXR. No headset is needed. Visit the planets of the solar system, Martin Luther King Memorial, the Mayan city of Chichen Itza, and the Taj Mahal in India. See dinosaurs, explore the human body, dive under the sea . . . and much, much more.

Go Exploring

It’s great to share resources!

Have other suggestions to share, or favorite learning resources? Tell us about them in the comments. They may be included in a future edition of our developer newsletter, where a portion of this content has already appeared.

The post Learn web technology at “sofa school” appeared first on Mozilla Hacks - the Web developer blog.

Today sees the release of Firefox number 74. The most significant new features we’ve got for you this time are security enhancements: Feature Policy, the Cross-Origin-Resource-Policy header, and removal of TLS 1.0/1.1 support. We’ve also got some new CSS text property features, the JS optional chaining operator, and additional 2D canvas text metric features, along with the usual wealth of DevTools enhancements and bug fixes.

As always, read on for the highlights, or find the full list of additions in the following articles:

• Firefox 74 for developers
• Site compatibility for Firefox 74
• Firefox 74 end-user release notes

Note: In the Security enhancements section below, we detail the removal of TLS 1.0/1.1 in Firefox 74, however we reverted this change for an undetermined amount of time, to better enable access to critical government sites sharing COVID19 information. We are keeping the infomation below intact because it is still useful to give you an idea of future intents. (Updated Monday, 30 March.)

Security enhancements

Let’s look at the security enhancement we’ve got in 74.

Feature Policy

We’ve finally enabled Feature Policy by default. You can now use the <iframe> allow attribute and the Feature-Policy HTTP header to set feature permissions for your top level documents and IFrames. Syntax examples follow:

<iframe src="https://example.com" allow="fullscreen"></iframe>

Feature-Policy: microphone 'none'; geolocation 'none'

CORP

We’ve also enabled support for the Cross-Origin-Resource-Policy (CORP) header, which allows web sites and applications to opt in to protection against certain cross-origin requests (such as those coming from <script> and <img> elements). This can help to mitigate speculative side-channel attacks (like Spectre and Meltdown) as well as Cross-Site Script Inclusion attacks.

The available values are same-origin and same-site. same-origin only allows requests that share the same scheme, host, and port to read the relevant resource. This provides an additional level of protection beyond the web’s default same-origin policy. same-site only allows requests that share the same site.

To use CORP, set the header to one of these values, for example:

Cross-Origin-Resource-Policy: same-site

TLS 1.0/1.1 removal

Last but not least, Firefox 74 sees the removal of TLS 1.0/1.1 support, to help raise the overall level of security of the web platform. This is vital for moving the TLS ecosystem forward, and getting rid of a number of vulnerabilities that existed as a result of TLS 1.0/1.1 not being as robust as we’d really like — they’re in need of retirement.

The change was first announced in October 2018 as a shared initiative of Mozilla, Google, Microsoft, and Apple. Now in March 2020 we are all acting on our promises (with the exception of Apple, who will be making the change slightly later on).

The upshot is that you’ll need to make sure your web server supports TLS 1.2 or 1.3 going forward. Read TLS 1.0 and 1.1 Removal Update to find out how to test and update your TLS/SSL configuration. From now on, Firefox will return a Secure Connection Failed error when connecting to servers using the older TLS versions. Upgrade now, if you haven’t already!

Note: For a couple of release cycles (and longer for Firefox ESR), the Secure Connection Failed error page will feature an override button allowing you to Enable TLS 1.0 and 1.1 in cases where a server is not yet upgraded, but you won’t be able to rely on it for too long.

To find out more about TLS 1.0/1.1 removal and the background behind it, read It’s the Boot for TLS 1.0 and TLS 1.1.

Other web platform additions

We’ve got a host of other web platform additions for you in 74.

New CSS text features

For a start, the text-underline-position property is enabled by default. This is useful for positioning underlines set on your text in certain contexts to achieve specific typographic effects.

For example, if your text is in a horizontal writing mode, you can use text-underline-position: under; to put the underline below all the descenders, which is useful for ensuring legibility with chemical and mathematical formulas, which make frequent use of subscripts.

.horizontal {
  text-underline-position: under;
}

In text with a vertical writing-mode set, we can use values of left or right to make the underline appear to the left or right of the text as required.

.vertical {
  writing-mode: vertical-rl;
  text-underline-position: left;
}

In addition, the text-underline-offset and text-decoration-thickness properties now accept percentage values, for example:

text-decoration-thickness: 10%;

For these properties, this is a percentage of 1em in the current font’s size.

Optional chaining in JavaScript

We now have the JavaScript optional chaining operator (?.) available. When you are trying to access an object deep in a chain, this allows for implicit testing of the existence of the objects higher up in the chain, avoiding errors and the need to explicitly write testing code.

let nestedProp = obj.first?.second;

New 2D canvas text metrics

The TextMetrics interface (retrieved using the CanvasRenderingContext2D.measureText() method) has been extended to contain four more properties measuring the actual bounding box — actualBoundingBoxLeft, actualBoundingBoxRight, actualBoundingBoxAscent, and actualBoundingBoxDescent.

For example:

const canvas = document.createElement('canvas');
const ctx = canvas.getContext('2d');
const text = ctx.measureText('Hello world');

text.width;                    // 56.08333206176758
text.actualBoundingBoxAscent;  // 8
text.actualBoundingBoxDescent; // 0
text.actualBoundingBoxLeft;    // 0
text.actualBoundingBoxRight;   // 55.733333333333334

DevTools additions

Next up, DevTools additions.

Device-like rendering in Responsive Design Mode

While Firefox for Android is being relaunched with GeckoView to be faster and more private, the DevTools need to stay ahead. Testing on mobile should be as frictionless as possible, both when using Responsive Design Mode on your desktop and on-device with Remote Debugging.

Correctness is important for Responsive Design Mode, so developers can trust the output without a device at hand. Over the past releases, we rolled out major improvements that ensure meta viewport is correctly applied with Touch Simulation. This ties in with improved device presets, which automatically enable touch simulation for mobile devices.

Fun fact: The team managed to make this simulation so accurate that it has already helped to identify and fix rendering bugs for Firefox on Android.

DevTools Tip: Open Responsive Design Mode without DevTools via the tools menu or Ctrl + Shift + M on Windows/Cmd + Opt + M on macOS.

We’d love to hear about your experiences when giving your site a spin in RDM or on your Android phone with Firefox Nightly for Developers.

CSS tools that work for you

The Page Inspector’s new in-context warnings for inactive CSS rules have received a lot of positive feedback. They help you solve gnarly CSS issues while teaching you about the intricate interdependencies of CSS rules.

Since its launch, we have continued to tweak and add rules, often based on user feedback. One highlight for 74 is a new detection setting that warns you when properties depend on positioned elements – namely z-index, top, left, bottom, and right.

Your feedback will help to further refine and expand the rules. Say hi to the team in the DevTools chat on Mozilla’s Matrix instance or follow our work via @FirefoxDevTools.

Debugging for Nested Workers

Firefox’s JavaScript Debugger team has been focused on optimizing Web Workers over the past few releases to make them easier to inspect and debug. The more developers and frameworks that use workers to move processing off the main thread, the easier it will be for browsers to prioritize running code that is fired as a result of user input actions.

Nested web workers, which allow workers to spawn and control their own worker instances, are now displayed in the Debugger:

Improved React DevTools integration

The React Developer Tools add-on is one of many developer add-ons that integrate tightly with Firefox DevTools. Thanks to the WebExtensions API, developers can create and publish add-ons for all browsers from the same codebase.

In collaboration with the React add-on maintainers, we worked to re-enable and improve the context menus in the add-on, including Go to definition. This action lets developers jump from React Components directly to their source files in the Debugger. The same functionality has already been enabled for jumping to elements in the Inspector. We want to build this out further, to make framework workflows seamless with the rest of the tools.

Early-access DevTools features in Developer Edition

Developer Edition is Firefox’s pre-release channel which gets early access to tooling and platform features. Its settings also enable more functionality for developers by default. We like to bring new features quickly to Developer Edition to gather your feedback, including the following highlights.

Instant evaluation for Console expressions

Exploring JavaScript objects, functions, and the DOM feels like magic with instant evaluation. As long as expressions typed into the Web Console are side-effect free, their results will be previewed while you type, allowing you to identify and fix errors more rapidly than before.

Async Stack Traces for Debugger & Console

Modern JavaScript code depends heavily upon stacking async/await on top of other async operations like events, promises, and timeouts. Thanks to better integration with the JavaScript engine, async execution is now captured to give a more complete picture.

Async call stacks in the Debugger let you step through events, timeouts, and promise-based function calls that are executed over time. In the Console, async stacks make it easier to find the root causes of errors.

Sneak-peek Service Worker Debugging

This one has been in Nightly for a while, and we are more than excited to get it into your hands soon. Expect it in Firefox 76, which will become Developer Edition in 4 weeks.

The post Security means more with Firefox 74 appeared first on Mozilla Hacks - the Web developer blog.

Or: The Implementation of the SpiderMonkey Debugger (and its cleanup)

We’ve made major improvements to JavaScript debugging in Firefox DevTools over the past two years. Developer feedback has informed and validated our work on performance, source maps, stepping reliability, pretty printing, and more types of breakpoints. Thank you. If you haven’t tried Firefox for debugging modern JavaScript in a while, now is the time.

Many of the aforementioned efforts focused on the Debugger frontend (written in React and Redux). We were able to make steady progress. The integration with SpiderMonkey, Firefox’s JavaScript engine, was where work went more slowly. To tackle larger features like proper asynchronous call stacks (available now in DevEdition), we needed to do a major cleanup. Here’s how we did that.

Background: A Brief History of the JS Debugger

The JavaScript debugger in Firefox is based on the SpiderMonkey engine’s Debugger API. This API was added in 2011. Since then, it has survived the addition of four JIT compilers, the retirement of two of them, and the addition of a WebAssembly compiler. All that, without needing to make substantial changes to the API’s users. Debugger imposes a performance penalty only temporarily, while the developer is closely observing the debuggee’s execution. As soon as the developer looks away, the program can return to its optimized paths.

A few key decisions (some ours, others imposed by the situation) influenced the Debugger‘s implementation:

• For better or worse, it is a central tenet of Firefox’s architecture that JavaScript code of different privilege levels can share a single heap. Object edges and function calls cross privilege boundaries as needed. SpiderMonkey’s compartments ensure the necessary security checks get performed in this free-wheeling environment. The API must work seamlessly across compartment boundaries.
• Debugger is an intra-thread debugging API: events in the debuggee are handled on the same thread that triggered them. This keeps the implementation free of threading concerns, but invites other sorts of complications.
• Debuggers must interact naturally with garbage collection. If an object won’t be missed, it should be possible for the garbage collector to recycle it, whether it’s a Debugger, a debuggee, or otherwise.
• A Debugger should observe only activity that occurs within the scope of a given set of JavaScript global objects (say, a window or a sandbox). It should have no effect on activity elsewhere in the browser. But it should also be possible for multiple Debuggers to observe the same global, without too much interference.

Garbage Collection

People usually explain garbage collectors by saying that they recycle objects that are “unreachable”, but this is not quite correct. For example, suppose we write:

fetch("https://www.example.com/")
  .then(res => {
    res.body.getReader().closed.then(() => console.log("stream closed!"))
  });

Once we’re done executing this statement, none of the objects it constructed are reachable by the rest of the program. Nonetheless, the WHATWG specification forbids the browser from garbage collecting everything and terminating the fetch. If it were to do so, the message would not be logged to the console, and the user would know the garbage collection had occurred.

Garbage collectors obey an interesting principle: an object may be recycled only if it never would be missed. That is, an object’s memory may be recycled only if doing so would have no observable effect on the program’s future execution—beyond, of course, making more memory available for further use.

The Principle in Action

Consider the following code:

// Create a new JavaScript global object, in its own compartment.
var global = newGlobal({ newCompartment: true });

// Create a new Debugger, and use its `onEnterFrame` hook to report function
// calls in `global`.
new Debugger(global).onEnterFrame = (frame) => {
  if (frame.callee) {
    console.log(`called function ${frame.callee.name}`);
  }
};

global.eval(`
  function f() { }
  function g() { f(); }
  g();
`);

When run in SpiderMonkey’s JavaScript shell (in which Debugger constructor and the newGlobal function are immediately available), this prints:

called function g
called function f

Just as in the fetch example, the new Debugger becomes unreachable by the program as soon as we are done setting its onEnterFrame hook. However, since all future function calls within the scope of global will produce console output, it would be incorrect for the garbage collector to remove the Debugger. Its absence would be observable as soon as global made a function call.

A similar line of reasoning applies for many other Debugger facilities. The onNewScript hook reports the introduction of new code into a debuggee global’s scope, whether by calling eval, loading a <script> element, setting an onclick handler, or the like. Or, setting a breakpoint arranges to call its handler function each time control reaches the designated point in the code. In all these cases, debuggee activity calls functions registered with a Debugger, which can do anything the developer likes, and thus have observable effects.

This case, however, is different:

var global = newGlobal({ newCompartment: true });

new Debugger(global);

global.eval(`
  function f() { }
  function g() { f(); }
  g();
`);

Here, the new Debugger is created, but is dropped without any hooks being set. If this Debugger were disposed of, no one would ever be the wiser. It should be eligible to be recycled by the garbage collector. Going further, in the onEnterFrame example above, if global becomes unnecessary, with no timers or event handlers or pending fetches to run code in it ever again, then global, its Debugger, and its handler function must all be eligible for collection.

The principle is that Debugger objects are not anything special to the GC. They’re simply objects that let us observe the execution of a JavaScript program, and otherwise follow the same rules as everyone else. JavaScript developers appreciate knowing that, if they simply avoid unnecessary entanglements, the system will take care of cleaning up memory for them as soon as it’s safe to do so. And this convenience extends to code using the Debugger API.

The Implementation

Looking through the description above, it seems clear that when a Debugger has an onEnterFrame hook, an onNewScript hook, or something else like that, its debuggee globals hold an owning reference to it. As long as those globals are alive, the Debugger must be retained as well. Clearing all those hooks should remove that owning reference. Thus, the liveness of the global no longer guarantees that the Debugger will survive. (References from elsewhere in the system might, of course.)

And that’s pretty much how it’s done. At the C++ level, each JavaScript global has an associated JS::Realm object, which owns a table of DebuggerLink objects, one for each Debugger of which it is a debuggee. Each DebuggerLink object holds an optional strong reference to its Debugger. This is set when the Debugger has interesting hooks, and cleared otherwise. Hence, whenever the Debugger has hooks set, there is a strong path, via the DebuggerLink intermediary, from its debuggee globals to the Debugger. In contrast, when the hooks are clear, there is no such path.

A breakpoint set in a script behaves similarly. It acts like an owning reference from that script to the breakpoint’s handler function and the Debugger to which it belongs. As long as the script is live, the handler and Debugger must remain alive, too. Or, if the script is recycled, certainly that breakpoint will never be hit again, so the handler might as well go, too. And if all the Debugger‘s breakpoints’ scripts get recycled, then the scripts no longer protect the Debugger from collection.

However, things were not always so straightforward.

What’s Changed

Originally, Debugger objects had an enabled flag, which, when set to false, immediately disabled all the Debugger‘s hooks and breakpoints. The intent was to provide a single point of control. In this way, the Firefox Developer Tools server could neutralize a Debugger (say, when the toolbox is closed), ensuring that it would have no further impact on the system. Of course, simply clearing out the Debugger‘s set of debuggee globals—a capability we needed for other purposes anyway—has almost exactly the same effect. So this meant the enabled flag was redundant. But, we reasoned, how much trouble could a simple boolean flag really cause?

What we did not anticipate was that the presence of the enabled flag made the straightforward implementation described above seem impractical. Should setting enabled to false really go and clear out all the breakpoints in the debuggee’s scripts? And should setting it back to true go and put them all back in? That seemed ridiculous.

So, rather than treating globals and scripts as if they owned references to their interested Debuggers, we added a new phase to the garbage collection process. Once the collector had found as many objects as possible to retain, we would loop over all the Debuggers in the system. We would ask each one: Are any of your debuggees sure to be retained? Do you have any hooks or breakpoints set? And, are you enabled? If so, we marked the Debugger itself for retention.

Naturally, once we decided to retain a Debugger, we alsohad to retain any objects it or its handler functions could possibly use. Thus, we would restart the garbage collection process, let it run to exhaustion a second time, and repeat the scan of all Debuggers.

Cleaning up Garbage Collection

In the fall of 2019, Logan Smyth, Jason Laster, and I undertook a series of debugger cleanups. This code, named Debugger::markIteratively, was one of our targets. We deleted the enabled flag, introduced the owning edges described above (among others), and shrunk Debugger::markIteratively down to the point that it could be safely removed. This work was filed as bug 1592158: “Remove Debugger::hasAnyLiveFrames and its vile henchmen”. (In fact, in a sneak attack, Logan removed it as part of a patch for a blocker, bug 1592116.)

The SpiderMonkey team members responsible for the garbage collector also appreciated our cleanup. It removed a hairy special case from the garbage collector. The replacement is code that looks and behaves much more like everything else in SpiderMonkey. The idea that “this points to that; thus if we’re keeping this, we’d better keep that, too” is the standard path for a garbage collector. And so, this work turned Debugger from a headache into (almost) just another kind of object.

Compartments

The Debugger API presented the garbage collector maintainers with other headaches as well, in its interactions with SpiderMonkey compartments and zones.

In Firefox, the JavaScript heap generally includes a mix of objects from different privilege levels and origins. Chrome objects can refer to content objects, and vice versa. Naturally, Firefox must enforce certain rules on how these objects interact. For example, content code might only be permitted to call certain methods on a chrome object. Or, chrome code might want to see only an object’s original, web-standard-specified methods, regardless of how content has toyed with its prototype or reconfigured its properties.

(Note that Firefox’s ongoing ‘Fission’ project will segregate web content from different origins into different processes, so inter-origin edges will become much less common. But even after Fission, there will still be interaction between chrome and content JavaScript code.)

Runtimes, Zones, and Realms

To implement these checks, to support garbage collection, and to support the web as specified, Firefox divides up the JavaScript world as follows:

• A complete world of JavaScript objects that might interact with each other is called a runtime.
• A runtime’s objects are divided into zones, which are the units of garbage collection. Every garbage collection processes a certain set of zones. Typically there is one zone per browser tab.
• Each zone is divided into compartments, which are units of origin or privilege. All the objects in a given compartment have the same origin and privilege level.
• A compartment is divided into realms, corresponding to JavaScript window objects, or other sorts of global objects like sandboxes or JSMs.

Each script is assigned to a particular realm, depending on how it was loaded. And each object is assigned a realm, depending on the script that creates it.

Scripts and objects may only refer directly to objects in their own compartment. For inter-compartment references, each compartment keeps a collection of specialized proxies, called cross-compartment wrappers. Each of these wrappers represents a specific object in another compartment. These wrappers intercept all property accesses and function calls and apply security checks. This is done to decide whether they should proceed, based on the relative privilege levels and origins of the wrapper’s compartment and its referent’s compartment. Rather than passing or returning an object from one compartment to another, SpiderMonkey looks up that object’s wrapper in the destination compartment (creating it if none exists). Then it hands over the wrapper instead of the object.

Wrapping Compartments

An extensive system of assertions, in the garbage collector but also throughout the rest of SpiderMonkey, verify that no direct inter-compartment edges are ever created. Furthermore, scripts must only directly touch objects in their own compartments.

But since every inter-compartment reference must be intercepted by a wrapper, the compartments’ wrapper tables form a convenient registry of all inter-zone references as well. This is exactly the information that the garbage collector needs to collect one set of zones separately from the rest. If an object has no wrappers representing it in compartments outside its own zone, then the collector knows. All without having to examine the entire runtime. No other zone would miss that object if it were recycled.

Inter-Compartment Debugging

The Debugger API’s Debugger.Object objects throw a wrench into this neat machinery. Since the debugger server is privileged chrome code, and the debuggee is usually content code, these fall into separate compartments. This means that a Debugger.Object‘s pointer to its reference is an inter-compartment reference.

But the Debugger.Objects cannot be cross-compartment wrappers. A compartment may have many Debugger objects, each of which has its own flock of Debugger.Objects, so there may be many Debugger.Objects referring to the same debuggee object in a single compartment. (The same is true of Debugger.Script and other API objects. We’ll focus on Debugger.Object here for simplicity.)

Previously, SpiderMonkey coped with this by requiring that each Debugger.Object be paired with a special entry to the compartment’s wrapper table. The table’s lookup key was not simply a foreign object, but a (Debugger, foreign object) pair. This preserved the invariant that the compartments’ wrapper tables had a record of all inter-compartment references.

Unfortunately, these entries required special treatment. An ordinary cross-compartment wrapper can be dropped if its compartment’s objects no longer point there, since an equivalent wrapper can be constructed on demand. But a Debugger.Object must be retained for as long as its Debugger and referent are alive. A user might place a custom property on a Debugger.Object or use it as a key in a weak map. That user might expect to find the property or weak map entry when encountering the corresponding debuggee object again. Also, special care is required to ensure that the wrapper table entries are reliably created and removed in sync with Debugger.Object creation, even if out-of-memory errors or other interruptions arise.

Cleaning up Compartments

As part of our Fall 2019 code cleanup, we removed the special wrapper table entries. By simply consulting the Debugger API’s own tables of Debugger.Objects, we changed the garbage collector find cross-compartment references. This is Debugger-specific code, which we would, of course, prefer to avoid, but the prior arrangement was also Debugger-specific. The present approach is more direct. It looks more like ordinary garbage collector tracing code. This removes the need for careful synchronization between two tables.

Forced Returns and Exceptions

When SpiderMonkey calls a Debugger API hook to report some sort of activity in the debuggee, most hooks can return a resumption value to say how the debuggee should continue execution:

• undefined means that the debuggee should proceed normally, as if nothing had happened.
• Returning an object of the form { throw: EXN } means that the debuggee should proceed as if the value EXN were thrown as an exception.
• Returning an object of the form { return: RETVAL } means that the debuggee should return immediately from whatever function is running now, with RETVAL as the return value.
• null means that the debuggee should be terminated, as if by the slow script dialog.

In SpiderMonkey’s C++ code, there was an enumerated type named ResumeMode, which had values Continue, Throw, Return, and Terminate, representing each of these possibilities. Each site in SpiderMonkey that needed to report an event to Debugger and then respect a resumption value needed to have a switch statement for each of these cases. For example, the code in the bytecode interpreter for entering a function call looked like this:

switch (DebugAPI::onEnterFrame(cx, activation.entryFrame())) {
  case ResumeMode::Continue:
    break;
  case ResumeMode::Return:
    if (!ForcedReturn(cx, REGS)) {
      goto error;
    }
    goto successful_return_continuation;
  case ResumeMode::Throw:
  case ResumeMode::Terminate:
    goto error;
  default:
    MOZ_CRASH("bad DebugAPI::onEnterFrame resume mode");
}

Discovering Relevant SpiderMonkey Conventions

However, Logan Smyth noticed that, except for ResumeMode::Return, all of these cases were already covered by SpiderMonkey’s convention for ‘fallible operations’. According to this convention, a C++ function that might fail should accept a JSContext* argument, and return a bool value. If the operation succeeds, it should return true; otherwise, it should return false and set the state of the given JSContext to indicate a thrown exception or a termination.

For example, given that JavaScript objects can be proxies or have getter properties, fetching a property from an object is a fallible operation. So SpiderMonkey’s js::GetProperty function has the signature:

bool js::GetProperty(JSContext* cx,
                     HandleValue v, HandlePropertyName name,
                     MutableHandleValue vp);

The value v is the object, and name is the name of the property we wish to fetch from it. On success, GetProperty stores the value in vp and returns true. On failure, it tells cx what went wrong, and returns false. Code that calls this function might look like:

if (!GetProperty(cx, obj, id, &value)) {
  return false; // propagate failure to our caller
}

All sorts of functions in SpiderMonkey follow this convention. They can be as complex as evaluating a script, or as simple as allocating an object. (Some functions return a nullptr instead of a bool, but the principle is the same.)

This convention subsumes three of the four ResumeMode values:

• ResumeMode::Continue is equivalent to returning true.
• ResumeMode::Throw is equivalent to returning false and setting an exception on the JSContext.
• ResumeMode::Terminate is equivalent to returning false but setting no exception on the JSContext.

The only case this doesn’t support is ResumeMode::Return.

Building on SpiderMonkey Conventions

Next, Logan observed that SpiderMonkey is already responsible for reporting all stack frame pops to the DebugAPI::onLeaveFrame function, so that Debugger can call frame onPop handlers and perform other bookkeeping. So, in principle, to force an immediate return, we could:

• stash the desired return value somewhere;
• return false without setting an exception to force termination;
• wait for the termination to propagate through the current function call, at which point SpiderMonkey will call DebugAPI::onLeaveFrame;
• recover our stashed return value, and store it in the right place in the stack frame; and finally
• return true as if nothing had happened, emulating an ordinary return.

With this approach, there would be no need for the ResumeMode enum or special handling at DebugAPI call sites. SpiderMonkey’s ordinary rules for raising and propagating exceptions are already very familiar to any SpiderMonkey developer. Those rules do all the work for us.

As it turns out, the machinery for stashing the return value and recognizing the need for intervention in DebugAPI::onLeaveFrame already existed in SpiderMonkey. Shu-Yu Guo had implemented it years ago to handle a rare case involving slow script timeouts and single-stepping.

With this collection of insights, Logan was able to turn the call sites at which SpiderMonkey reports activity to Debugger into call sites just like those of any other fallible function. The call to DebugAPI::onEnterFrame shown above now reads, simply:

if (!DebugAPI::onEnterFrame(cx, activation.entryFrame())) {
  goto error;
}

Other Cleanups

We carried out a number of other minor cleanups as part of our Fall 2019 effort:

• We split the file js/src/vm/Debugger.cpp, originally 14k lines long and containing the entire Debugger implementation, into eight separate source files, and moved them to the directory js/src/debugger. Phabricator no longer refuses to colorize the file because of its length.
• Each Debugger API object type, Debugger.Object, Debugger.Frame, Debugger.Environment, Debugger.Script, and Debugger.Source, is now represented by its own C++ subclass of js::NativeObject. This lets us use the organizational tools C++ provides to structure and scope their implementation code. We can also replace dynamic type checks in the C++ code with types. The compiler can check those at compile time.
• The code that lets Debugger.Script and Debugger.Source refer to both JavaScript and WebAssembly code was simplified so that Debugger::wrapVariantReferent, rather than requiring five template parameters, requires only one–and one that could be inferred by the C++ compiler, to boot.

I believe this work has resulted in a substantial improvement to the quality of life of engineers who have to deal with Debugger‘s implementation. I hope it is able to continue to serve Firefox effectively in the years to come.

The post Future-proofing Firefox’s JavaScript Debugger Implementation appeared first on Mozilla Hacks - the Web developer blog.