Planet Mozilla

Happy Things Thursday! Today we are releasing WebThings Gateway 0.10. If you have a gateway using our Raspberry Pi builds then it should already have automatically updated itself.

This new release comes with support for thermostats and smart locks, as well as an updated add-ons system including extension add-ons, which enable developers to extend the gateway user interface. We’ve also added localisation settings so that you can choose your country, language, time zone and unit preferences. From today you’ll be able to use the gateway in American English or Italian, but we’re already receiving contributions of translations in different languages!

Thermostats

Version 0.10 comes with support for smart thermostats like the Zigbee Zen Thermostat, the Centralite HA 3156105 and the Z-Wave Honeywell TH8320ZW1000.

You can view the current temperature of your home remotely, set a heating or cooling target temperature and set the current heating mode. You can also create rules which react to temperature or control your heating/cooling via the rules engine. In this way, you could set the heating to come on at a particular time of day or change the colour of lights based on how warm it is, for example.

Smart Locks

Ever wonder if you’ve forgotten to lock your front door? Now you can check when you get to work, and even lock or unlock the doors remotely. With the help of the rules engine, you can also set rules to lock doors at a particular time of day or notify you when they are unlocked.

So far we have support for Zigbee and Z-Wave smart locks like the Yale YRD226 Deadbolt and Yale YRD110 Deadbolt.

Extension Add-ons

Version 0.10 also comes with a revamped add-ons system which includes a new type of add-on called extensions. Like a browser extension, an extension add-on can be used to augment the gateway’s user interface.

For example, an extension can add its own entry in the gateway’s main menu and display its own dedicated screen with new functionality.

Together with a new mechanism for add-on developers to extend the gateway’s REST API, this opens up a whole new world of possibilities for add-on developers to customise the gateway.

Note that the updated add-ons system comes with a new manifest format inspired by Web Extensions. Stand by for a blog post next week which will explain in more depth how to use the new add-ons system. We’ll walk you through building your own extension add-on.

Localisation Settings

Many add-ons use location-specific data like weather, sunrise/sunset and tide times, but it’s no fun to have to configure your location for each add-on. It’s now possible to choose your country, time zone and language via the gateway’s web interface.

With time zone support, time-based rules should now correctly adjust for daylight savings time in your region. Since the gateway is configured to use Greenwich Mean Time by default, your rules may show times you didn’t expect at first. To fix this, you’ll need to set your time zone appropriately and adjust your rule times. You can also set your preference of unit used to display temperature, to either degrees Celsius or Fahrenheit.

And finally, many of you have asked for the user interface to support multiple languages. We are shipping with an Italian translation in this release thanks to our resident Italian speaker Kathy. We already have French, Dutch and Polish translations in the pipeline thanks to our wonderful community. Stand by for more information on how to contribute to translations in your language!

API Changes & Standardisation

For developers, in addition to the new add-ons system, it’s now possible to communicate with all the gateway’s web things via a single WebSocket connection. Previously it was necessary to open a WebSocket per device, so this is a significant enhancement.

We’ve recently started the Web Thing Protocol Community Group at the W3C with the intention of standardising this WebSocket sub-protocol in order to further improve interoperability on the Web of Things. We welcome developers to join this group to contribute to the standardisation process.

Coming Soon

Coming up next, expect Mycroft voice controls, translations into more languages and new ways to install and use WebThings Gateway.

As always, you can head over to the forums for support. And we welcome your contributions on GitHub.

The post Thermostats, Locks and Extension Add-ons – WebThings Gateway 0.10 appeared first on Mozilla Hacks - the Web developer blog.

Notifications. Can you keep count of how many websites or services prompt you daily for permission to send notifications? Can you remember the last time you were thrilled to get one?

Earlier this year we decided to reduce the amount of unsolicited notification permission prompts people receive as they move around the web using the Firefox browser. We see this as an intrinsic part of Mozilla’s commitment to putting people first when they are online.

In preparation, we ran a series of studies and experiments. We wanted to understand how to improve the user experience and reduce annoyance. In response, we’re now making some changes to the workflow for how sites ask users for permission to send them notifications. Firefox will require explicit user interaction on all notification permission prompts, starting in Firefox 72.

For the full background story, and details of our analysis and experimentation, please read Restricting Notification Permission Prompts in Firefox. Today, we want to be sure web developers are aware of the upcoming changes and share best practices for these two key scenarios:

1. How to guide the user toward the prompt.
2. How to acknowledge the user changing the permission.

We anticipate that some sites will be impacted by changes to the user flow. We suspect that many sites do not yet deal with the latter in their UX design. Let’s briefly walk through these two scenarios:

How to guide the user toward the prompt

Ideally, sites that want permission to notify or alert a user already guide them through this process. For example, they ask if the person would like to enable notifications for the site and offer a clickable button.

document.getElementById("notifications-button").addEventListener("click", () => {
  Notification.requestPermission().then(setupNotifications);
});

Starting with Firefox 72, the notification permission prompt is gated behind a user gesture. We will not deliver prompts on behalf of sites that do not follow the guidance above. Firefox will instantly reject the promise returned by Notification.requestPermission() and PushManager.subscribe(). However, the user will see a small notification permission icon in the address bar.

Note that because PushManager.subscribe() requires a ServiceWorkerRegistration, Firefox will carry user-interaction flags through promises that return ServiceWorkerRegistration objects. This enables popular examples to continue to work when called from an event handler.

Firefox shows the notification permission icon after a successful prompt. The user can select this icon to make changes to the notification permission. For instance, if they decide to grant the site the permission, or change their preference to no longer receive notifications.

How to acknowledge the user changing the permission

When the user changes the notification permission through the notification permission icon, this is exposed via the Permissions API:

navigator.permissions.query({ name: "notifications" }).then(status => {
  status.onchange = () => potentiallyUpdateNotificationPermission(status.state);
  potentiallyUpdateNotificationPermission(status.state);
}

We believe this improves the user experience and makes it more consistent. And allows to align the site interface with the notification permission. Please note that the code above works in earlier versions of Firefox as well. However, users are unlikely to change the notification permission dynamically in earlier Firefox releases. Why? Because there was no notification permission icon in the address bar.

Our studies show that users are more likely to engage with prompts that they’ve interacted with explicitly. We’ve seen that through pre-prompting in the user interface, websites can inform the user of the choice they are making before presenting a prompt. Otherwise, unsolicited prompts are denied in over 99% of cases.

We hope these changes will lead to a better user experience for all and better and healthier engagement with notifications.

The post Upcoming notification permission changes in Firefox 72 appeared first on Mozilla Hacks - the Web developer blog.

Today we announce the formation of the Bytecode Alliance, a new industry partnership coming together to forge WebAssembly’s outside-the-browser future by collaborating on implementing standards and proposing new ones. Our founding members are Mozilla, Fastly, Intel, and Red Hat, and we’re looking forward to welcoming many more.

We have a vision of a WebAssembly ecosystem that is secure by default, fixing cracks in today’s software foundations. And based on advances rapidly emerging in the WebAssembly community, we believe we can make this vision real.

We’re already putting these solutions to work on real world problems, and those are moving towards production. But as an Alliance, we’re aiming for something even bigger…

Why

As an industry, we’re putting our users at risk more and more every day. We’re building massively modular applications, where 80% of the code base comes from package registries like npm, PyPI, and crates.io.

Making use of these flourishing ecosystems isn’t bad. In fact, it’s good!

The problem is that current software architectures weren’t built to make this safe, and bad guys are taking advantage of that… at a dramatically increasing rate.

What the bad guys are exploiting here is that we’ve gotten our users to trust us. When the user starts up your application, it’s like the user’s giving your code the keys to their house. They’re saying “I trust you”.

But then you invite all of your dependencies, giving each one of them a full set of keys to the house. These dependencies are written by people who you don’t know, and have no reason to trust.

As a community, we have a choice. The WebAssembly ecosystem could provide a solution here… at least, if we choose to design it in a way that’s secure by default. But if we don’t, WebAssembly could make the problem even worse.

As the WebAssembly ecosystem grows, we need to solve this problem. And it’s a problem that’s too big to solve alone. That’s where the Bytecode Alliance comes in.

What

The Bytecode Alliance is a group of companies and individuals, coming together to form an industry partnership.

Together, we’re putting in solid, secure foundations that can make it safe to use untrusted code, no matter where you’re running it—whether on the cloud, natively on someone’s desktop, or even on a tiny IoT device.

With this, developers can be as productive as they are today, using open source in the same way, but without putting their users at risk.

This common, reusable set of foundations can be used on their own, or embedded in other libraries and applications.

Currently, we’re collaborating on:

Runtimes:

• Wasmtime is a stand-alone WebAssembly runtime that can be used as a CLI tool or embedded into other systems. It’s very configurable and scalable so that it can serve as the base for many use-case specific runtimes, from small IoT devices all the way up to cloud data centers.
• Lucet is an example of a use-case specific runtime. It’s ideal for fast CDNs and Edge Compute, using AOT compilation and other techniques to provide low-latency and high-concurrency. We are refactoring it to use Wasmtime at its core.
• WebAssembly Micro Runtime (WAMR) is another use-case specific runtime. It’s ideal for small embedded devices that have extremely limited resources. It provides a small footprint and uses an interpreter to keep memory overhead low.

Runtime components:

• Cranelift is emerging as a state-of-the-art code generator. It is designed to generate optimized machine code very quickly because it parallelizes compilation on a function-by-function level.
• WASI common is a standalone implementation of the WebAssembly System Interface that runtimes can use.

Language tooling

• cargo-wasi is a lightweight Cargo subcommand that compiles Rust code to target WebAssembly and the WebAssembly System Interface for outside-the-browser use.
• wat and wasmparser parse WebAssembly. wat parses the text format, and wasmparser is an event-driven library for parsing the binary format.

And we expect this set of projects to expand as we grow the Alliance.

Our members are also leading the WASI standards effort itself, as well as the Rust to WebAssembly working group.

Who

The founding members of the Bytecode Alliance are Mozilla, Fastly, Intel, and Red Hat.

We’re starting with a lightweight governance structure. We intend to formalize this structure gradually over time. You can read more about this our FAQ.

As we said before, this is too big to go it alone. That’s why we’re happy to welcome new members to the Alliance. If you want to join, please email us at hello@bytecodealliance.org.

Here’s why we think this is important:

WebAssembly is changing the web, but we believe WebAssembly can play an even bigger role in the software ecosystem as it continues to expand beyond browsers. This is a unique moment in time at the dawn of a new technology, where we have the opportunity to fix what’s broken and build new, secure-by-default foundations for native development that are portable and scalable. But we need to take deliberate, cross-industry action to ensure this happens in the right way. Together with our partners in the Bytecode Alliance, Mozilla is building these new secure foundations—for everything from small, embedded devices to large, computing clouds.

— Luke Wagner, Distinguished Engineer at Mozilla and co-creator of WebAssembly

Fastly is very happy to help bring the Bytecode Alliance to the community. Lucet and Cranelift have been developed together for years, and we’re excited to formalize their relationship and help them grow faster together. This is an important moment in computing history, marking our chance to redefine how software will be built across clients, origins, and the edge. The Bytecode Alliance is our way of contributing to and working with the community, to create the foundations that the future of the internet will be built on.

Tyler McMullen, CTO at Fastly

Intel is joining the Bytecode Alliance as a founding member to help extend WebAssembly’s performance and security benefits beyond the browser to a wide range of applications and servers. Bytecode Alliance technologies can help developers extend software using a wide selection of languages, building upon the full capabilities of leading-edge compute platforms
— Mark Skarpness; VP, Intel Architecture, Graphics, and Software; Director, Data-Centric System Stacks

Red Hat believes deeply in the role open source technologies play in helping provide the foundation for computing from the operating system to the browser to the open hybrid cloud. Wasmtime is an exciting development that helps move WebAssembly out of the browser into the server space where we are experimenting with it to change the trust model for applications, and we are happy to be involved in helping it grow into a mature, community-based project.

— Chris Wright, senior vice president and Chief Technology Officer at Red Hat

So that’s the big news!

To learn more about what we’re building together, read on.

The problem

The way that we architect software has radically changed over the past 20 years. In 2003, companies had a hard time getting developers to reuse code.

Now 80% of your average code base is built with modules downloaded from registries like JavaScript’s npm, Python’s PyPI, Rust’s crates.io, and others. Even C++ is moving towards enabling an ecosystem of composable modules.

This new way of developing applications has made us much more productive as an industry. But it has also introduced gaping wide holes in our security. And as I talked about above, the bad guys are using those holes to attack our users.

The user is entrusting us with the keys to their house and we’re giving that access away like candy… and that’s not because we’re irresponsible. It’s because there’s huge value in these packages, but no easy way to mitigate the security risks that come from using them.

More than this, it’s not just our own dependencies that come along for the ride. It’s also any modules that they depend on—the indirect dependencies.

What do these developers get access to?

1. resources on the machine—things like files and memory
2. APIs and syscalls—tools that they can use to do things to those resources

This means that these modules can do a lot of damage. This could either be on purpose, as with malicious code, or completely accidentally, as with vulnerable code.

Let’s look at how these attacks work.

Malicious code

Malicious code is written by the attacker themselves.

Attackers often use social engineering to get their package into applications. They create a package that has useful features, and then sneak in some malicious code. Once the code is in the app and the user starts up the app, the code can attack the user.

This is how a hacker stole $1.5 million worth of cryptocurrency (and almost $13 million more) from users, starting in March of this year.

• Day 0 (March 6): The attacker published a module to npm: electron-native-notify. This seemed useful—it helped Electron apps fire off native notifications in a way that worked across platforms. It didn’t have any malicious code in it, yet.
• Day 2: To pull of the heist, the attacker has to get this module into the cryptocurrency app. The vector they choose is a dependency in an application that helps users manage their cryptocurrency, the Agama Wallet.
• Day 17: The attacker adds the malicious payload.
• Day 41-66: The app is rebuilt, pulling in the most recent version of the dependency, and electron-native-notify with it. At this point, it starts sending user’s “seeds” (username/password combos) to a server. The attacker can then use these seeds to empty users’ wallets.
• Day 90: A user alerts npm to suspicious behavior in electron-native-notify, and they notify the cryptocurrency platform, which moved funds from vulnerable wallets to a secure one.

Let’s look at what access this malicious code needed to pull off the attack.

It needed the seed. To do this, it got access to memory holding the seed.

Then it needed to send the seed to a server. For this it needed access to a socket, and access to an API or syscall for opening that socket.

Malicious code attacks are on the rise as more and more attackers realize how vulnerable our systems of trust are. For example, the number of malicious modules published to npm more than doubled from 2017 to 2019. And npm’s VP of security points out that these attacks are getting more serious.

In 2019, we’re seeing more financially motivated attacks. Early attacks were focused on shenanigans—deleting files and trying to steal some credentials. Real basic attacks, kind of smash and grab style. Now end users are the target. And [the attackers] are trying hard to be patient, to be sneaky, to really have a well planned out attack.

Vulnerable code

Vulnerabilities are different. The module maintainer isn’t trying to do anything bad.

The module maintainer just has a bug in their code. But attackers can use that bug to trick their code into doing something that shouldn’t do.

For an example of this, let’s look at ZipSlip.

ZipSlip is a vulnerability found in modules in many ecosystems: JavaScript, Java, .NET, Go,Ruby, C++, Python… the list goes on. And it affected thousands of projects, including ones from HP, Amazon, Apache, Pivotal, and many more.

If a module had this vulnerability, attackers could use it to replace files anywhere in the file system. For example, the attacker could use it to replace .js files in the node_modules directory. Then, when the .js file was required, the attacker’s code would run.

So how did this work?

The attacker would create a file, and give it a filename that included ‘../’, building up a relative file path. When the vulnerable code unzipped it, it wouldn’t sanitize the filename. So it would call the write syscall with the relative path, placing the file wherever the attacker wanted it to go in the file system.

So what access did the vulnerable code need for the attacker to pull this off?

It needed access to the directory with the sensitive files.

It also needed access to the write syscall.

Vulnerabilities are on the rise, as well, with an 88% increase in the last two years. As Snyk reported in their 2019 State of Open Source Security Report:

In 2018, vulnerabilities for npm grew by 47%. Maven Central and PHP Packagist disclosures grew by 27% and 56% respectively.

With these risks, you would think that patching vulnerabilities would be a high priority. But as Snyk found, only 59% of packages have known fixes for disclosed vulnerabilities, because many maintainers don’t have the time or the security know-how to fix these vulnerabilities.

This leads to widespread vulnerability, as these vulnerable modules are depended on by other modules. For example, a study of npm modules found that up to 40% of packages depend on code with at least one publicly known vulnerability.

How can we protect users today?

So how can you protect your users against these threats in today’s software ecosystem?

• You can run scanners that detect fishy coding patterns in your code and that of your dependencies. But there are many things these automated tools can’t catch.
• You could subscribe to a monitoring service that alerts you when a vulnerability is found one of your dependencies. But this only works for those that have been found. And even once a vulnerability has been found, there’s a good chance the maintainer won’t be able to fix it quickly. For example, Snyk found in the npm ecosystem that for the top 6 packages, the median time-to-fix (measured starting at the vulnerability’s inclusion) was 2.5 years.
• You could try and do manual code review. Whenever there’s an update in a dependency, you’d review the changed lines. But if you have hundreds of modules in your dependency tree, that could easily be 100,000 lines of code to review every few weeks.
• You could pin your dependencies, so that malicious code can’t get in until you’ve had a chance to review. But then fixes for vulnerabilities would be stalled, leaving your app vulnerable longer.

This all makes for a kind of no-win scenario, which makes you want to throw up your hands and just hope for the best. But as an industry, we simply can’t do that. There’s too much at stake for our users.

All of these solutions try to catch malicious and vulnerable code. But what if we look at this a different way?

Part of the problem was the access that these modules had. What if we took away that access?

We’ve faced this kind of challenge as an industry before… just at a different granularity.

When you have two programs running on a computer at the same time, how do you know that one won’t mess with the other? Do you have to trust the programs to behave?

No, because protection is built into the operating system. The tool that OSs use to protect programs from each other is the process.

When you start a program, the OS fires up a new process. Each process gets its own chunk of memory to use, and it can’t access memory in other processes.

If it wants to get data from the other process, it has to ask. Then the data is sent across the process boundary. This makes sure each program is in control of its own data in memory.

This memory isolation does make it much safer to run two programs at the same time. But this isn’t perfect security. A malicious program can still mess with certain other resources, like files in the file system.

VMs and containers were developed to fix this. They ensure that something running in one VM or container can’t access the file system of another. And with sandboxing, it’s possible to take away access to APIs and syscalls.

So could we put each package in its own little isolated unit? Its own little sandboxed process?

That would solve our problem. But it would also introduce a new problem.

All of these techniques are relatively heavyweight. If we wrap hundreds of packages into their own sandboxed process, we’d quickly run out of memory. We’d also make the function calls between the different packages much slower and more complicated.

But it turns out that new technologies are giving us new options.

As we’re building out the WebAssembly ecosystem, we can design how the pieces fit together in a way that gives you the kind of isolation that you get with processes or containers, but without the downsides.

Tomorrow’s solution: WebAssembly “nanoprocesses”

WebAssembly can provide the kind of isolation that makes it safe to run untrusted code. We can have an architecture that’s like Unix’s many small processes, or like containers and microservices.

But this isolation is much lighter weight, and the communication between them isn’t much slower than a regular function call.

This means you can use them to wrap a single WebAssembly module instance, or a small collection of module instances that want to share things like memory among themselves.

Plus, you don’t have to give up the nice programming language affordances—like function signatures and static type checking.

So how does this work? What about WebAssembly makes this possible?

First, there’s the fact that each WebAssembly module is sandboxed by default.

By default, the module doesn’t have access to APIs and system calls. If you want the module to be able to interact with anything outside of the module, you have to explicitly provide the module with the function or syscall. Then the module can call it.

Second, there’s the memory model.

Unlike a normal binary compiled directly to something like x86, a WebAssembly module doesn’t have access to all of the memory in its process. It only has access to the chunk of memory that has been assigned to it.

In theory, scripting languages would also provide this kind of isolation. Code in scripting languages can’t directly access the memory in the process. It can only access memory through the variables it has in scope.

But in most scripting language ecosystems, code makes a lot of use of a shared global object. That’s effectively the same as shared memory. So the conventions in the ecosystem make memory isolation a problem for scripting languages as well.

WebAssembly could have had this problem. In the early days, some wanted to establish a convention of passing a shared memory in to every module. But the community group opted for the more secure convention of keeping memory encapsulated by default.

This gives us memory isolation between the two modules. That means that a malicious module can’t mess with the memory of its parent module.

But how do we share data from our module? You have to pass it in or out as the values of a function call.

There’s a problem here, though. By default, WebAssembly only has a handful of numeric types, which means you can only pass single digits across.

Here’s where the third feature comes in—the interface type proposal which we demoed in August. With interface types, modules can communicate using more complex values—things like like strings, sequences, records, variants, and nested combinations of these.

That makes it easy for two modules to exchange data, but in a way that’s secure and fast. The WebAssembly engine can do direct copies between the caller and the callee’s memories, without having to serialize and deserialize the data. And this works even if the two modules aren’t compiled from the same language.

So that’s how we ensure that a malicious module can’t mess with the memory of other modules in the application.

But we don’t just need to take precautions around how memory is handled between these modules. Because if the application is actually going to be able to do anything with that data, it is going to need to call APIs or system calls. And those APIs or system calls might have access to shared resources, like the file system. And as we talked about in a previous post, the way that most operating systems handle access to the file system really falls down in providing the security we need here.

So we need APIs and system calls that actually have the concept of permissions baked into them, so that they can give different modules different permissions to different resources.

This is where the fourth feature comes in: WASI, the WebAssembly system interface.

That gives us a way to isolate these different modules from each other and give them fine-grained permissions to particular parts of the file system and other resources, and also fine grained permissions for different system calls.

So with this, we’ve taken control of the keys.

What’s missing?

Right now, we don’t have a way to pass these keys down through the dependency tree. We need a way for parent modules to give these keys to their dependencies. This way, they can give their dependencies exactly the keys they need and no other ones. And then, those dependencies can do the same thing for their children, all the way down through the tree.

That’s what we’ll be working on next. In technical terms, we’re planning to use a fine grained form of per-module virtualization. This is an idea that researchers have demonstrated in research contexts, and we’re working on bringing this to WebAssembly.

Taken all together, these features make it possible for us to have similar isolation to that of a process, but with much lower overhead. This pattern of usage is what we’re calling a WebAssembly nanoprocess.

It’s still just WebAssembly, but it follows a particular pattern. And if we build this pattern into the tools and conventions we use, we can make third-party code reuse safe in WebAssembly in a way it hasn’t been in other ecosystems to date.

Sidenote: At the moment, every nanoprocess is made up of exactly one wasm module. In the future, we’ll focus on toolchain support for creating nanoprocesses containing multiple wasm modules, allowing native-style dynamic linking while preserving the memory isolation of nanoprocesses

With these foundations in place, developers will be able to build dependency trees of isolated packages, each with their own tiny little nanoprocess around them.

How do nanoprocesses protect users?

So how does this help us keep users safe?

In both of these cases, it’s the fact that we’re following the principle of least authority that’s keeping us secure. Let’s walk through how this helps.

Malicious code

In order to carry out an attack, a module often needs access to resources and APIs that it wouldn’t otherwise need access to. With our approach, the module has to declare that it needs access to these things. That makes it easy to see when it’s asking to do things it shouldn’t.

For example, the wallet stealing module needed access to both a socket pointing to the server that it was sending the seed to, and the ability to open a network connection.

But this module was just supposed to take the text that was passed in to it and hand it off to the system, so that the system could display it. Why would the module need to open a network connection to a remote server to do that?

If electron-native-notify had asked for these permissions from the start, that would’ve been a serious red flag. The maintainers of EasyDEX-GUI probably wouldn’t have accepted it into their dependency tree.

If the malicious maintainer had tried to slip these access requests in later, sometime after it was already in EasyDEX-GUI, then that would’ve been a breaking change. The module’s signature would have changed, and WebAssembly throws an error when the calling code doesn’t provide the imports or parameters that a module expects.

This means there’s no way to sneak in access to a new resource or system call under the radar.

So it’s unlikely that the maintainer could get the basic access they needed to communicate with the server. But even if this maintainer were somehow able to trick the app developer into granting them this access, they still would have an extremely hard time getting the seed.

That’s because the seed would be in another module’s memory. There are two ways for a module to get access to something from some other module’s memory. And neither of them allow the malicious module to be sneaky about it.

1. The module that has the seed exports the seed variable, making it automatically visible to all other modules in the app.
2. The module that has the seed passes it directly to a function in the malicious module as a parameter.

Both seem incredibly unlikely for a variable this sensitive.

There is unfortunately one less straightforward way that attackers can access another module’s memory—side-channel attacks like Spectre. OS processes attempt to provide something called time protection, and this helps protect against these attacks. Unfortunately, CPUs and OSes don’t offer finer-than-process granularity time protection features.

There’s a good chance you’ve never thought about using processes to protect your code. Why don’t most people have to care? Because hosting providers take care of it, sometimes using complex techniques.

If you are architecting your code with isolated process now, you may still need to. Making a shift to nanoprocesses here would take careful analysis.

But there are lots of situations where timing protection isn’t needed, or where people aren’t using processes at all right now. These are good candidates for nanoprocesses.

Plus, as CPUs evolve to provide cheaper time protection features, WebAssembly nanoprocesses will be in a good position to quickly take advantage of these features, at which point you won’t need to use OS processes for this.

Vulnerable code

How does this protect against attackers exploiting vulnerabilities?

Just as with malicious modules, it’s less likely that a vulnerable module legitimately needs the combination of access rights that the attacker needs.

In our ZipSlip example, even for legitimate uses, the vulnerable module does need access to a dangerous syscall—the write syscall which allows it to write files.

But it doesn’t need access to the node_modules directory for any legitimate use. It would only have access to the directory that its parent passes to it, which would be some directory that zip files can be unarchived into.

That makes it impossible for the vulnerable module to carry out the attackers wishes (unless the parent knowingly passes a very sensitive directory into to the vulnerable module).

As noted in the caveat above, it is possible that the application developer would pass in a sensitive directory, like the root directory. But for this to work, this mistake would have to be made in the top level package. It can’t happen in a transitive dependency. By making all of these accesses explict, it makes it much easier to catch those kinds of sloppy mistakes in review.

Other benefits of nanoprocesses

With nanoprocesses, we can continue to build massively modular applications… we can keep the developer productivity gains while also ensuring that our users are safe.

But what else can nanoprocesses help with?

Isolation that fits anywhere

These nanoprocesses—these little container-like things—can fit in all sorts of places that regular processes and containers and VMs can’t go.

This is what makes it possible for us to wrap each package or groups of packages into these tiny little micro processes. Because they’re so small, they won’t blow up the size of your application. But dependency trees aren’t the only places where you would use these nanoprocesses.

Here are just a couple of other use cases we see for them, and which partners in the Alliance are working on:

Handling requests for tens of thousands of customers on the same machine

Fastly serves 13% of the Internet’s traffic. That means responding to millions of requests, and trying to do it with as little overhead as possible while keeping customers secure.

They’ve come up with an innovative architecture using WebAssembly nanoprocesses which makes it possible to securely host tens of thousands of simultaneously running programs in the same process. Their approach completely isolates the request from previous requests, ensuring full VM isolation. It has the added advantage of having cold start that’s orders of magnitude faster.

Software fault isolation for individual libraries in native applications

In some applications, most of your code is written in-house, and only a few libraries are written by untrusted developers outside of the organization.

In these cases, you can use a nanoprocess to create a lightweight, in-process sandbox for a single library, rather than having your full dependency tree wrapped in nanoprocesses.

We’ve started building this kind of sandboxing in Firefox to protect users from bugs in third party libraries, like font rendering engines, and image and audio decoders.

Improved software composability

For decades, software development best practices have been driving towards more and more componentized architectures, built out of small, Lego-like pieces.

This started with libraries and modules described above, running in the same process in the same language. More recently, there’s been a progression towards services, and then microservices, which give you the security benefits of isolation.

But beyond security, the isolation services provide also makes software more composable. It means that you can plug together services that are written in different languages, or different versions of the same language. That gives you a much larger set of lego blocks to play with.

But these services can’t go all the places that libraries can go because they’re too big. They are often running inside a process, which is running inside of a container, which is running on a server. This means that you often have to use a coarse-grained approach when breaking your app apart into these services.

With wasm, we can replace microservices with nanoprocesses and get the same security and language independence benefits. It gives us the composability of microservices without the weight. This means we can use a microservices-style architecture and the language interoperability that provides, but with a finer-grained approach to defining the component services.

Join us

So that’s the vision we have for a safer future for our users. We believe that WebAssembly doesn’t just have the opportunity but the responsibility to provide this kind of safety.

And we hope that you’ll join us!

The post Announcing the Bytecode Alliance: Building a secure by default, composable future for WebAssembly appeared first on Mozilla Hacks - the Web developer blog.

Since its debut in Firefox 61, the Accessibility Inspector in the Firefox Developer Tools has evolved from a low-level tool showing the accessibility structure of a page. In Firefox 70, the Inspector has become an auditing facility to help identify and fix many common mistakes and practices that reduce site accessibility. In this post, I will offer an overview of what is available in this latest release.

Inspecting the Accessibility Tree

First, select the Accessibility Inspector from the Developer Toolbox. Turn on the accessibility engine by clicking “Turn On Accessibility Features.” You’ll see a full representation of the current foreground tab as assistive technologies see it. The left pane shows the hierarchy of accessible objects. When you select an element there, the right pane fills to show the common properties of the selected object such as name, role, states, description, and more. To learn more about how the accessibility tree informs assistive technologies, read this post by Hidde de Vries.

The DOM Node property is a special case. You can double-click or press ENTER to jump straight to the element in the Page Inspector that generates a specific accessible object. Likewise, when the accessibility engine is enabled, open the context menu of any HTML element in the Page Inspector to inspect any associated accessible object. Note that not all DOM elements have an accessible object. Firefox will filter out elements that assistive technologies do not need. Thus, the accessibility tree is always a subset of the DOM tree.

In addition to the above functionality, the inspector will also display any issues that the selected object might have. We will discuss these in more detail below.

The accessibility tree refers to the full tree generated from the HTML, JavaScript, and certain bits of CSS from the web site or application. However, to find issues more easily, you can filter the left pane to only show elements with current accessibility issues.

Finding Accessibility Problems

To filter the tree, select one of the auditing filters from the “Check for issues” drop-down in the toolbar at the top of the inspector window. Firefox will then reduce the left pane to the problems in your selected category or categories. The items in the drop-down are check boxes — you can check for both text labels and focus issues. Alternatively, you can run all the checks at once if you wish. Or, return the tree to its full state by selecting None.

Once you select an item from the list of problems, the right pane fills with more detailed information. This includes an MDN link to explain more about the issue, along with suggestions for fixing the problem. You can go into the page inspector and apply changes temporarily to see immediate results in the accessibility inspector. Firefox will update Accessibility information dynamically as you make changes in the page inspector. You gain instant feedback on whether your approach will solve the problem.

Text labels

Since Firefox 69, you have the ability to filter the list of accessibility objectss to only display those that are not properly labeled. In accessibility jargon, these are items that have no names. The name is the primary source of information that assistive technologies, such as screen readers, use to inform a user about what a particular element does. For example, a proper button label informs the user what action will occur when the button is activated.

The check for text labels goes through the whole document and flags all the issues it knows about. Among other things, it finds missing alt-text (alternative text) on images, missing titles on iframes or embeds, missing labels for form elements such as inputs or selects, and missing text in a heading element.

Check for Keyboard issues

Keyboard navigation and visual focus are common sources of accessibility issues for various types of users. To help debug these more easily, Firefox 70 contains a checker for many common keyboard and focus problems. This auditing tool detects elements that are actionable or have interactive semantics. It can also detect if focus styling has been applied. However, there is high variability in the way controls are styled. In some cases, this results in false positives. If possible, we would like to hear from you about these false positives, with an example that we can reproduce.

For more information about focus problems and how to fix them, don’t miss Hidde’s post on indicating focus.

Contrast

Firefox includes a full-page color contrast checker that checks for all three types of color contrast issues identified by the Web Content Accessibility Guidelines 2.1 (WCAG 2.1):

• Does normal text on background meet the minimum requirement of 4.5:1 contrast ratio?
• Does the heading, or more generally, does large-scale, text on background meet the 3:1 contrast ratio requirement?
• Will interactive elements and graphical elements meet a minimum ratio of 3:1 (added in WCAG 2.1)?

In addition, the color contrast checker provides information on the triple-A success criteria contrast ratio. You can see immediately whether your page meets this advanced standard.

Are you using a gradient background or a background with other forms of varying colors? In this case, the contrast checker (and accessibility element picker) indicates which parts of the gradient meet the minimum requirements for color contrast ratios.

Color Vision Deficiency Simulator

Firefox 70 contains a new tool that simulates seven types of color vision deficiencies, a.k.a. color blindness. It shows a close approximation of how a person with one of these conditions would see your page. In addition, it informs you if you’ve colored something that would not be viewable by a colorblind user. Have you provided an alternative? For example, someone who has Protanomaly (low red) or Protanopia (no red) color perception would be unable to view an error message colored in red.

As with all vision deficiencies, no two users have exactly the same perception. The low red, low green, low blue, no red, no green, and no blue deficiencies are genetic and affect about 8 percent of men, and 0.5 percent of women worldwide. However, contrast sensitivity loss is usually caused by other kinds of mutations to the retina. These may be age-related, caused by an injury, or via genetic predisposition.

Note: The color vision deficiency simulator is only available if you have WebRender enabled. If it isn’t enabled by default, you can toggle the gfx.webrender.all property to True in about:config.

Quick auditing with the accessibility picker

As a mouse user, you can also quickly audit elements on your page using the accessibility picker. Like the DOM element picker, it highlights the element you selected and displays its properties. Additionally, as you hover the mouse over elements, Firefox displays an information bar that shows the name, role, and states, as well as color contrast ratio for the element you picked.

First, click the Accessibility Picker icon. Then click on an element to show its properties. Want to quickly check multiple elements in rapid succession? Click the picker, then hold the shift key to click on multiple items one after another to view their properties.

In Conclusion

Since its release back in June 2018, the Accessibility Inspector has become a valuable helper in identifying many common accessibility issues. You can rely on it to assist in designing your color palette. Use it to ensure you always offer good contrast and color choices. We build a11y features into the DevTools that you’ve come to depend on, so you do not need to download or search for external services or extensions first.

The post Auditing For Accessibility Problems With Firefox Developer Tools appeared first on Mozilla Hacks - the Web developer blog.

This is a short story of how js13kGames, an online “code golf” competition for web game developers, tried out Web Monetization this year. And ended up at the Mozilla Festival, happening this week in London, where we’re showcasing some of our winning entries.

A brief history of js13kGames

The js13kGames online competition for HTML5 game developers is constantly evolving. We started in 2012, and we run every year from August 13th to September 13th. In 2017, we added a new A-Frame category.

You still had to build web games that would fit within the 13 kilobytes zipped package as before, but the new category added the A-Frame framework “for free”, so it wasn’t counted towards the size limit. The new category resulted in some really cool entries.

Fast forward twelve months to 2018 – the category changed its name to WebXR. We added Babylon.js as a second option. In 2019, the VR category was extended again, with Three.js as the third library of choice. Thanks to the Mozilla Mixed Reality team we were able to give away three Oculus Quest devices to the winning entries.

The evolution of judging mechanics

The process for judging js13kGames entries has also evolved. At the beginning, about 60 games were submitted each year. Judges could play all the games to judge them fairly. In recent years, we’ve received nearly 250 entries. It’s really hard to play all of them, especially since judges tend to be busy people. And then, how can you be sure you scored fairly?

That’s why we introduced a new voting system. The role of judges changed: they became experts focused on giving constructive feedback, rather than scoring. Expert feedback is valued highly by participants, as one of the most important benefits in the competition.

At the same time, Community Awards became the official results. We upgraded the voting system with the new mechanism of “1 on 1 battles.” By comparing two games at once, you can focus and judge them fairly, and then move on to vote on another pair.

Voters compared the games based on consistent criteria: gameplay, graphics, theme, etc. This made “Community” votes valuable to developers as a feedback mechanism also. Developers could learn what their game was good at, and where they could improve. Many voting participants also wrote in constructive feedback, similar to what the experts provided. This feedback was accurate and eventually valuable for future improvements.

Web Monetization in the world of indie games

This year we introduced the Web Monetization category in partnership with Coil. The challenge to developers was to integrate Web Monetization API concepts within their js13kGames entries. Out of 245 games submitted overall, 48 entries (including WebXR ones) had implemented the Web Monetization API. It wasn’t that difficult.

Basically, you add a special monetization meta tag to index.html:

<!DOCTYPE HTML>
<html>
<head>
  <meta charset="utf-8">
  <title>Flood Escape</title>
  <meta name="monetization" content="your_payment_pointer">
  // ...
</head>

And then you need to add code to detect if a visitor is a paid subscriber (to Coil or any other similar service available in the future):

if(document.monetization && document.monetization.state === 'started') {
  // do something
}

You can do this detection via an event too:

function startEventHandler(event){
  // do something
}
document.monetization.addEventListener('monetizationstart', startEventHandler);

If the monetization event starts, that means the visitor has been identified as a paying subscriber. Then they can receive extra or special content: be it more coins, better weapons, shorter cooldown, extra level, or any other perk for the player.

It’s that simple to implement web monetization! No more bloated, ever changing SDKs to place advertisements into the games. No more waiting months for reports to see if spending time on this was even worth it.

The Web Monetization API gives game developers and content creators a way to monetize their creative work, without compromising their values or the user experience. As developers, we don’t have to depend on annoying in-game ads that interrupt the player. We can get rid of tracking scripts invading player privacy. That’s why Enclave Games creations never have any ads. Instead, we’ve implemented the Web Monetization API. We now offer extra content and bonuses to subscribers.

See you at MozFest

This all leads to London for the 2019 Mozilla Festival. Working with Grant for the Web, we’ve prepared something special: MozFest Arcade.

If you’re attending Mozfest, check out our special booth with game stations, gamepads, virtual reality headsets, and more. You will be able to play Enclave Games creations and js13kGames entries that are web-monetized! You can see for yourself how it all works under the hood.

Grant for the Web is a $100M fund to boost open, fair, and inclusive standards and innovation in web monetization. It is funded and led by Coil, working in collaboration with founding collaborators Mozilla and Creative Commons. (Additional collaborators may be added in the future.) A program team, led by Loup Design & Innovation, manages the day-to-day operations of the program.

It aims to distribute grants to web creators who would like to try web monetization as their business model, to earn revenue, and offer real competition to intrusive advertising, paywalls, and closed marketplaces.

If you’re in London, please join us at the Friday’s Science Fair at MozFest House. You can learn more about Web Monetization, Grant for the Web, while playing cool games. Also, you can get a free Coil subscription in the process. Join us through the weekend at the Indie Games Arcade at Ravensbourne University!

The post From js13kGames to MozFest Arcade: A game dev Web Monetization story appeared first on Mozilla Hacks - the Web developer blog.

If you like to read release notes, then you may have spotted in the Firefox 70 notes a line about the implementation of the two-value syntax of the display CSS property. Or maybe you saw a mention in yesterday’s Firefox 70 roundup post. Today I’ll explain what this means, and why understanding this two-value syntax is important despite only having an implementation in Firefox right now.

The display property

The display property is how we change the formatting context of an element and its children. In CSS some elements are block by default, and others are inline. This is one of the first things you learn about CSS.

The display property enables switching between these states. For example, this means that an h1, usually a block element, can be displayed inline. Or a span, initially an inline element, can be displayed as a block.

More recently we have gained CSS Grid Layout and Flexbox. To access these we also use values of the display property — display: grid and display: flex. Only when the value of display is changed do the children become flex or grid items and begin to respond to the other properties in the grid or flexbox specifications.

Two-value display – span with display: flex

What grid and flexbox demonstrate, however, is that an element has both an outer and an inner display type. When we use display: flex we create a block-level element, with flex children. The children are described as participating in a flex formatting context. You can see this if you take a span and apply display: flex to it — the span is now block-level. It behaves as block-level things do in relationship to other boxes in the layout. It’s as if you had applied display: block to the span, however we also get the changed behavior of the children. In the CodePen below you can see that the string of text and the em have become two flex items.

See the Pen
Mozilla Hacks two-value Display: span with display: flex by rachelandrew (@rachelandrew)
on CodePen.

Two-value display – span with display: grid

Grid layout behaves in the same way. If we use display: grid we create a block-level element and a grid formatting context for the children. We also have methods to create an inline-level box with flex or grid children with display: inline-flex and display: inline-grid. The next example shows a div, normally a block-level element, behaving as an inline element with grid item children.

As an inline element, the box does not take up all the space in the inline dimension, and the following string of text displays next to it. The children however are still grid items.

See the Pen
Mozilla Hacks two-value display: inline-grid by rachelandrew (@rachelandrew)
on CodePen.

Refactoring display

As the above examples show, the outer display type of an element is always block or inline, and dictates how the box behaves in the normal flow of the document. The inner display type then changes the formatting context of the children.

To better describe this behavior, the CSS Display specification has been refactored to allow for display to accept two values. The first describes whether the outer display type is block or inline, whereas the second value describes the formatting of the children. This table shows how some of these new values map to the single values – now referred to as legacy values – in the spec.

There are more values of display, including lists and tables; to see the full set of values visit the CSS Display Specification.

We can see how this would work for Flexbox. If I want to have a block-level element with flex children I use display: block flex, and if I want an inline-level element with flex children I use display: inline flex. The below example will work in Firefox 70.

See the Pen
Mozilla Hacks two-value Display: two value flex values by rachelandrew (@rachelandrew)
on CodePen.

Our trusty display: block and display: inline don’t remain untouched either, display: block becomes display: block flow – that is a block element with children participating in normal flow. A display: inline element becomes display: inline flow.

display: inline-block and display: flow-root

This all becomes more interesting if we look at a couple of values of display – one new, one which dates back to CSS2. Inline boxes in CSS are designed to sit inside a line box, the anonymous box which wraps each line of text in a sentence. This means that they behave in certain ways: If you add padding to all of the edges of an inline box, such as in the example below where I have given the inline element a background color, the padding applies. And yet, it does not push the line boxes in the block direction away. In addition, inline boxes do not respect width or height (or inline-size and block-size).

Using display: inline-block causes the inline element to contain this padding, and to accept the width and height properties. It remains an inline thing however; it continues to sit in the flow of text.

In this next CodePen I have two span elements, one regular inline and the other inline-block, so that you can see the difference in layout that this value causes.

See the Pen
Mozilla Hacks two-value display: inline-block by rachelandrew (@rachelandrew)
on CodePen.

We can then take a look at the newer value of display, flow-root. If you give an element display: flow-root it becomes a new block formatting context, becoming the root element for a new normal flow. Essentially, this causes floats to be contained. Also, margins on child elements stay inside the container rather than collapsing with the margin of the parent.

In the next CodePen, you can compare the first example without display: flow-root and the second with display: flow-root. The image in the first example pokes out of the bottom of the box, as it has been taken out of normal flow. Floated items are taken out of flow and shorten the line boxes of the content that follows. However, the actual box does not contain the element, unless that box creates a new block formatting context.

The second example does have flow-root and you can see how the box with the grey background now contains the float, leaving a gap underneath the text. If you have ever contained floats by setting overflow to auto, then you were achieving the same thing, as overflow values other than the default visible create a new block formatting context. However, there can be some additional unwanted effects such as clipping of shadows or unexpected scrollbars. Using flow-root gives you the creation of a block formatting context (BFC) without anything else happening.

See the Pen
Mozilla Hacks two-value display: flow-root by rachelandrew (@rachelandrew)
on CodePen.

The reason to highlight display: inline-block and display: flow-root is that these two things are essentially the same. The well-known value of inline-block, creates an inline flow-root which is why the new two-value version of display: inline-block is display: inline flow-root. It does exactly the same job as the flow-root property which, in a two-value world, becomes display: block flow-root.

You can see both of these values used in this last example, using Firefox 70.

See the Pen
Mozilla Hacks two-value display: inline flow-root and block flow-root by rachelandrew (@rachelandrew)
on CodePen.

Can we use these two value properties?

With support currently available only in Firefox 70, it is too early to start using these two-value properties in production. Currently, other browsers will not support them. Asking for display: block flex will be treated as invalid except in Firefox. Since you can access all of the functionality using the one-value syntax, which will remain as aliases of the new syntax, there is no reason to suddenly jump to these.

However, they are important to be aware of, in terms of what they mean for CSS. They properly explain the interaction of boxes with other boxes, in terms of whether they are block or inline, plus the behavior of the children. For understanding what display is and does, I think they make for a very useful clarification. As a result, I’ve started to teach display using these two values to help explain what is going on when you change formatting contexts.

It is always exciting to see new features being implemented, I hope that other browsers will also implement these two-value versions soon. And then, in the not too distant future we’ll be able to write CSS in the same way as we now explain it, clearly demonstrating the relationship between boxes and the behavior of their children.

The post The two-value syntax of the CSS Display property appeared first on Mozilla Hacks - the Web developer blog.

Firefox 70 is released today, and includes great new features such as secure password generation with Lockwise and the new Firefox Privacy Protection Report; you can read the full details in the Firefox 70 Release Notes.

Amazing user features and protections aside, we’ve also got plenty of cool additions for developers in this release. These include DOM mutation breakpoints and inactive CSS rule indicators in the DevTools, several new CSS text properties, two-value display syntax, and JS numeric separators. In this article, we’ll take a closer look at some of the highlights!

For all the details, check out the following:

• Firefox 70 for developers
• Site compatibility for Firefox 70

Note that the new Mozilla Developer YouTube channel will have videos covering many of the features mentioned below. Why not subscribe, so you can get them when they come out?

HTML forms and secure passwords

To enable the generation of secure passwords (as mentioned above) we’ve updated HTML <input> elements; any <input> element of type password will have an option to generate a secure password available in the context menu, which can then be stored in Lockwise.

For example, take the following:

<input type=”password”>

In the Firefox UI, you’ll then be able to generate a secure password like so:

In addition, any type="password" field with autocomplete=”new-password” set on it will have an autocomplete UI to generate a new password in-context.

Note: It is advisable to use autocomplete=”new-password” on password change and registration forms as a strong signal to password managers that a field expects a new password, not an existing one.

CSS

Let’s turn our attention to the new CSS features in Firefox 70.

New options for styling underlines!

Firefox 70 introduces three new properties related to text decoration/underline:

• text-decoration-thickness: sets the thickness of lines added via text-decoration.
• text-underline-offset: sets the distance between a text decoration and the text it is set on. Bear in mind that this only works on underlines.
• text-decoration-skip-ink: sets whether underlines and overlines are drawn if they cross descenders and ascenders. The default value, auto, causes them to only be drawn where they do not cross over a glyph. To allow underlines to cross glyphs, set the value to none.

So, for example, the following code:

h1 {
  text-decoration: underline red;
  text-decoration-thickness: 3px;
  text-underline-offset: 6px;
}

will give you this kind of effect:

Two-keyword display values

For years, the humble display property has taken a single value, whether we are talking about simple display choices like block, inline, or none, or newer display modes like flex or grid.

However, as Rachel explains, the boxes on your page have an outer display type, which determines how the box is laid out in relation to other boxes on the page, and an inner display type, which determines how the box’s children will behave. Browsers have done this for a while, but it has only been specified recently. The new set of two-keyword values allow you to explicitly specify the outer and inner display values.

In supporting browsers (just Firefox at the time of writing), the single keyword values we know and love will map to new two-keyword values, for example:

• display: flex; is equivalent to display: block flex;
• display: inline-flex; is equivalent to display: inline flex;

Rachel will explain this in more detail in an upcoming blog post. For now, watch this space!

JavaScript

Now let’s move on to the JavaScript.

Numeric separators

Numeric separators are now supported in JavaScript — underscores can now be used as separators in large numbers, so that they are more readable. For example:

let myNumber = 1_000_000_000_000;
console.log(myNumber); // Logs 1000000000000

let myHex = 0xA0_B0_C0
console.log(myHex); // Logs 10531008

Numeric separators are usable with any kind of numeric literal, including BigInts.

Intl improvements

We’ve improved JavaScript i18n (internationalization), starting with the implementation of the Intl.RelativeTimeFormat.formatToParts() method. This is a special version of Intl.RelativeTimeFormat.format() that returns an array of objects, each one representing a part of the value, rather than returning a string of the localized time value.

const rtf = new Intl.RelativeTimeFormat("en", { numeric: "auto" });

rtf.format(-2, "day"); // Returns "2 days ago"

rtf.formatToParts(-2, "day");
/*
Returns

[
​  { type: "integer", value: "2", unit: "day" },
​  { type: "literal", value: " days ago" }
​]
*/

This is useful because it allows you to easily isolate the numeric value out of the string, for example.

In addition, Intl.NumberFormat.format() and Intl.NumberFormat.formatToParts() now accept BigInt values.

Performance improvements

JavaScript has got generally faster thanks to our new baseline interpreter! You can learn more by reading The Baseline Interpreter: a faster JS interpreter in Firefox 70.

Developer tools

There is a whole host of awesome new things going on with Firefox 70 developer tools. Let’s find out what they are!

Inactive CSS rules indicator in rules panel

Inactive CSS properties in the Rules view of the Page Inspector are now colored gray and have an information icon displayed next to them. The properties are technically valid, but won’t have any effect on the element. When you hover over the info icon, you’ll see a useful message about why the CSS is not being applied, including a hint about how to fix the problem and a “Learn more” link for more information.

For example, in this case our grid-auto-columns property is inactive because we are trying to apply it to an element that is not a grid container:

And in this case, our flex property is inactive because we are trying to apply it to an element that is not a flex item. (Its parent is not a flex container.):

To fix this second issue, we can go into the inspector, find the element’s parent (a <div> in this case), and apply display: flex; to it:

Our fix is shown in the Changes panel, and from there can be copied and put into our code base. Sorted!

Pause on DOM Mutation in Debugger

In complex dynamic web apps it is sometimes hard to tell which script changed the page and caused the issue when you run into a problem. DOM Mutation Breakpoints (aka DOM Change Breakpoints) let you pause scripts that add, remove, or change specific elements.

Try inspecting any element on your page. When you /ctrl + click it in the HTML inspector, you’ll see a new context menu item “Break on…”, with the following sub-items:

• Subtree modification
• Attribute modification
• Node removal

Once a DOM mutation breakpoint is set, you’ll see it listed under “DOM Mutation Breakpoints” in the right-hand pane of the Debugger; this is also where you’ll see breaks reported.

For more details, see Break on DOM mutation. If you find them useful for your work, you might find Event Listener Breakpoints and XHR Breakpoints useful too!

Color contrast information in the color picker!

In the CSS Rules view, you can click foreground colors with the color picker to determine if their contrast with the background color meets accessibility guidelines.

Accessibility inspector: keyboard checks

The Accessibility inspector‘s Check for issues dropdown now includes keyboard accessibility checks:

Selecting this option causes Firefox to go through each node in the accessibility tree and highlight all that have a keyboard accessibility issue:

Hovering over or clicking each one will reveal information about what the issue is, along with a “Learn more” link for more details on how to fix it.

Try it now, on a web page near you!

Web socket inspector

In Firefox DevEdition, the Network monitor now has a new “Messages” panel, which appears when you are monitoring a web socket connection (i.e. a 101 response). This can be used to inspect web socket frames sent and received through the connection.

Read Firefox’s New WebSocket Inspector to find out more. Note that this functionality was originally supposed to be in Firefox 70 general release, but we had a few more bugs to iron out, so expect it in Firefox 71! For now, you can use it in DevEdition — please share your constructive feedback!

The post Firefox 70 — a bountiful release for all appeared first on Mozilla Hacks - the Web developer blog.

Fonts and typography are at the heart of design on the web. We now have powerful tools to inspect, understand, and design our typography in the browser. For instance, have you ever landed on a web page and wondered what fonts are being used? Then, have you asked yourself where those fonts come from or why a particular font isn’t loading?

The font editor in Firefox provides answers and insights. You gain the ability to make font changes directly, with a live preview. As for me, I use the editor for understanding variable fonts, how they work, and the options they expose.

Get started with a quick overview by Jen Simmons:

I’ve been using Firefox font tools since they were first released. And yet, I wasn’t aware of all the things the editor can do. Start using the built-in unit-conversion feature, which quickly exposes relative units like em, rem, as well as percents along with computed px values. Interested in more detail? Check out the follow-up video:

Enjoy styling type on the web!

The post Quickly Alter Typography with Firefox Font Editor appeared first on Mozilla Hacks - the Web developer blog.