Planet Mozilla

The Machine Learning team at Mozilla Research continues to work on an automatic speech recognition engine as part of Project DeepSpeech, which aims to make speech technologies and trained models openly available to developers. We’re hard at work improving performance and ease-of-use for our open source speech-to-text engine. The upcoming 0.2 release will include a much-requested feature: the ability to do speech recognition live, as the audio is being recorded. This blog post describes how we changed the STT engine’s architecture to allow for this, achieving real-time transcription performance. Soon, you’ll be able to transcribe audio at least as fast as it’s coming in.

When applying neural networks to sequential data like audio or text, it’s important to capture patterns that emerge over time. Recurrent neural networks (RNNs) are neural networks that “remember” — they take as input not just the next element in the data, but also a state that evolves over time, and use this state to capture time-dependent patterns. Sometimes, you may want to capture patterns that depend on future data as well. One of the ways to solve this is by using two RNNs, one that goes forward in time and one that goes backward, starting from the last element in the data and going to the first element. You can learn more about RNNs (and about the specific type of RNN used in DeepSpeech) in this article by Chris Olah.

Using a bidirectional RNN

The current release of DeepSpeech (previously covered on Hacks) uses a bidirectional RNN implemented with TensorFlow, which means it needs to have the entire input available before it can begin to do any useful work. One way to improve this situation is by implementing a streaming model: Do the work in chunks, as the data is arriving, so when the end of the input is reached, the model is already working on it and can give you results more quickly. You could also try to look at partial results midway through the input.

This animation shows how the data flows through the network. Data flows from the audio input to feature computation, through three fully connected layers. Then it goes through a bidirectional RNN layer, and finally through a final fully connected layer, where a prediction is made for a single time step.

In order to do this, you need to have a model that lets you do the work in chunks. Here’s the diagram of the current model, showing how data flows through it.

As you can see, on the bidirectional RNN layer, the data for the very last step is required for the computation of the second-to-last step, which is required for the computation of the third-to-last step, and so on. These are the red arrows in the diagram that go from right to left.

We could implement partial streaming in this model by doing the computation up to layer three as the data is fed in. The problem with this approach is that it wouldn’t gain us much in terms of latency: Layers four and five are responsible for almost half of the computational cost of the model.

Using a unidirectional RNN for streaming

Instead, we can replace the bidirectional layer with a unidirectional layer, which does not have a dependency on future time steps. That lets us do the computation all the way to the final layer as soon as we have enough audio input.

With a unidirectional model, instead of feeding the entire input in at once and getting the entire output, you can feed the input piecewise. Meaning, you can input 100ms of audio at a time, get those outputs right away, and save the final state so you can use it as the initial state for the next 100ms of audio.

An alternative architecture that uses a unidirectional RNN in which each time step only depends on the input at that time and the state from the previous step.

Here’s code for creating an inference graph that can keep track of the state between each input window:

import tensorflow as tf

def create_inference_graph(batch_size=1, n_steps=16, n_features=26, width=64):
    input_ph = tf.placeholder(dtype=tf.float32,
                              shape=[batch_size, n_steps, n_features],
                              name='input')
    sequence_lengths = tf.placeholder(dtype=tf.int32,
                                      shape=[batch_size],
                                      name='input_lengths')
    previous_state_c = tf.get_variable(dtype=tf.float32,
                                       shape=[batch_size, width],
                                       name='previous_state_c')
    previous_state_h = tf.get_variable(dtype=tf.float32,
                                       shape=[batch_size, width],
                                       name='previous_state_h')
    previous_state = tf.contrib.rnn.LSTMStateTuple(previous_state_c, previous_state_h)

    # Transpose from batch major to time major
    input_ = tf.transpose(input_ph, [1, 0, 2])

    # Flatten time and batch dimensions for feed forward layers
    input_ = tf.reshape(input_, [batch_size*n_steps, n_features])

    # Three ReLU hidden layers
    layer1 = tf.contrib.layers.fully_connected(input_, width)
    layer2 = tf.contrib.layers.fully_connected(layer1, width)
    layer3 = tf.contrib.layers.fully_connected(layer2, width)

    # Unidirectional LSTM
    rnn_cell = tf.contrib.rnn.LSTMBlockFusedCell(width)
    rnn, new_state = rnn_cell(layer3, initial_state=previous_state)
    new_state_c, new_state_h = new_state

    # Final hidden layer
    layer5 = tf.contrib.layers.fully_connected(rnn, width)

    # Output layer
    output = tf.contrib.layers.fully_connected(layer5, ALPHABET_SIZE+1, activation_fn=None)

    # Automatically update previous state with new state
    state_update_ops = [
        tf.assign(previous_state_c, new_state_c),
        tf.assign(previous_state_h, new_state_h)
    ]
    with tf.control_dependencies(state_update_ops):
        logits = tf.identity(logits, name='logits')

    # Create state initialization operations
    zero_state = tf.zeros([batch_size, n_cell_dim], tf.float32)
    initialize_c = tf.assign(previous_state_c, zero_state)
    initialize_h = tf.assign(previous_state_h, zero_state)
    initialize_state = tf.group(initialize_c, initialize_h, name='initialize_state')

    return {
        'inputs': {
            'input': input_ph,
            'input_lengths': sequence_lengths,
        },
        'outputs': {
            'output': logits,
            'initialize_state': initialize_state,
        }
    }

The graph created by the code above has two inputs and two outputs. The inputs are the sequences and their lengths. The outputs are the logits and a special “initialize_state” node that needs to be run at the beginning of a new sequence. When freezing the graph, make sure you don’t freeze the state variables previous_state_h and previous_state_c.

Here’s code for freezing the graph:

from tensorflow.python.tools import freeze_graph

freeze_graph.freeze_graph_with_def_protos(
        input_graph_def=session.graph_def,
        input_saver_def=saver.as_saver_def(),
        input_checkpoint=checkpoint_path,
        output_node_names='logits,initialize_state',
        restore_op_name=None,
        filename_tensor_name=None,
        output_graph=output_graph_path,
        initializer_nodes='',
        variable_names_blacklist='previous_state_c,previous_state_h')

With these changes to the model, we can use the following approach on the client side:

1. Run the “initialize_state” node.
2. Accumulate audio samples until there’s enough data to feed to the model (16 time steps in our case, or 320ms).
3. Feed through the model, accumulate outputs somewhere.
4. Repeat 2 and 3 until data is over.

It wouldn’t make sense to drown readers with hundreds of lines of the client-side code here, but if you’re interested, it’s all MPL 2.0 licensed and available on GitHub. We actually have two different implementations, one in Python that we use for generating test reports, and one in C++ which is behind our official client API.

Performance improvements

What does this all mean for our STT engine? Well, here are some numbers, compared with our current stable release:

• Model size down from 468MB to 180MB
• Time to transcribe: 3s file on a laptop CPU, down from 9s to 1.5s
• Peak heap usage down from 4GB to 20MB (model is now memory-mapped)
• Total heap allocations down from 12GB to 264MB

Of particular importance to me is that we’re now faster than real time without using a GPU, which, together with streaming inference, opens up lots of new usage possibilities like live captioning of radio programs, Twitch streams, and keynote presentations; home automation; voice-based UIs; and so on. If you’re looking to integrate speech recognition in your next project, consider using our engine!

Here’s a small Python program that demonstrates how to use libSoX to record from the microphone and feed it into the engine as the audio is being recorded.

import argparse
import deepspeech as ds
import numpy as np
import shlex
import subprocess
import sys

parser = argparse.ArgumentParser(description='DeepSpeech speech-to-text from microphone')
parser.add_argument('--model', required=True,
                    help='Path to the model (protocol buffer binary file)')
parser.add_argument('--alphabet', required=True,
                    help='Path to the configuration file specifying the alphabet used by the network')
parser.add_argument('--lm', nargs='?',
                    help='Path to the language model binary file')
parser.add_argument('--trie', nargs='?',
                    help='Path to the language model trie file created with native_client/generate_trie')
args = parser.parse_args()

LM_WEIGHT = 1.50
VALID_WORD_COUNT_WEIGHT = 2.25
N_FEATURES = 26
N_CONTEXT = 9
BEAM_WIDTH = 512

print('Initializing model...')

model = ds.Model(args.model, N_FEATURES, N_CONTEXT, args.alphabet, BEAM_WIDTH)
if args.lm and args.trie:
    model.enableDecoderWithLM(args.alphabet,
                              args.lm,
                              args.trie,
                              LM_WEIGHT,
                              VALID_WORD_COUNT_WEIGHT)
sctx = model.setupStream()

subproc = subprocess.Popen(shlex.split('rec -q -V0 -e signed -L -c 1 -b 16 -r 16k -t raw - gain -2'),
                           stdout=subprocess.PIPE,
                           bufsize=0)
print('You can start speaking now. Press Control-C to stop recording.')

try:
    while True:
        data = subproc.stdout.read(512)
        model.feedAudioContent(sctx, np.frombuffer(data, np.int16))
except KeyboardInterrupt:
    print('Transcription:', model.finishStream(sctx))
    subproc.terminate()
    subproc.wait()

Finally, if you’re looking to contribute to Project DeepSpeech itself, we have plenty of opportunities. The codebase is written in Python and C++, and we would love to add iOS and Windows support, for example. Reach out to us via our IRC channel or our Discourse forum.

The post Streaming RNNs in TensorFlow appeared first on Mozilla Hacks - the Web developer blog.

Here’s what happened in August to the code, data, and tools that support MDN Web Docs:

• Migrated 95% of compatibility data
• Improved performance and experience
• Maintained the platform
• Shipped tweaks and fixes by merging 400 pull requests, including 78 pull requests from 55 new contributors

Here’s the plan for September:

• Hack on Accessibility
• Ship more performance improvements

Done in August

Migrated 95% of compatibility data

The MDN content team prioritized reviewing and merging Browser Compatibility Data pull requests (PRs) in August, and met their goal of getting the open PRs to less than 50. The team reviewed and merged 85 PRs that were open at the start of the month, including a schema change to catch duplicate identifiers (PR 1415) from Dominique Hazael-Massieux. The team also merged 123 PRs that were opened during the month, including Visual Studio Code configurations for BCD editing (PR 2498) from ExE Boss.

A lot of these were migration PRs, and the migration is now 95% complete, with 10,000 features over 6,300 pages. Some of the remaining migration work will be straightforward. Other data sources will require strategy and format discussions, such as Event support and summary pages. These discussions will be easier with the experience of migrating thousands of simpler features.

Existing data also got some love. Contributors fixed incorrect data, clarified if and when a browser supported a feature, and celebrated support in new browser releases. We expect a steady stream of maintenance PRs as the project transitions from migration to ongoing maintenance.

Florian Scholz has worked to make this a community project, organizing the effort with spreadsheets and transitioning to issues as the remaining work becomes manageable. This has been a successful effort, and GitHub insights shows that most contributions were not from MDN staff.

Top BCD contributors for August 2018

Thanks to ExE Boss (24 PRs), Connor Shea (23 PRs), Claas Augner (18 PRs), David Ross (17 PRs), Lucian Condrea (13 PRs), Joe Medley (8 PRs), and all our contributors, and thanks to the staff and tool builders that keep the review queue moving!

Improved performance and experience

Tim Kadlec audited MDN in July, and created performance metrics and goals, as well as recommending changes. In August, we started implementing these changes. Schalk Neethling improved the load time for the homepage by optimizing the hero image (PR 4903) and removing a section with an image (PR 4912). Ryan Johnson automated recording deployments and re-calculating metrics with Speedcurve (PR 4902). We’ll continue working on performance in the coming months.

Previously, if you wanted to link to a section in a page, such as MDN’s advice on why you should use labels for <input> elements, you had to use the Developer Tools to get the section ID. Schalk added section-level anchor links (PR 4901), so that you can quickly grab the link and paste it into a code review:

The new section links on MDN

Maintained the platform

Anthony Maton is switching Kuma to Python 3. Our memcached library hasn’t been updated for Python 3, and instead of a library swap, Anthony simplified the caching configuration and switched to Redis (PR 4870). He continues to make incremental changes (PR 4899) to get to a shared Python 2 / Python 3 codebase, with a goal of switching to Python 3 by the end of the year.

I completed the ElasticSearch 5.6 update, which was harder than expected. The update from 1.7 to 2.4 only required updating the servers (PR 4192), and didn’t even merit a mention in the April 2017 report. ElasticSearch no longer provides libraries that span major versions. The upgrade from 2.5 to 5.6 required updating the client libraries, the Kuma code that uses them (PR 4906), and the server (PR 4904), all at the same time. This update included some minor fixes, and search with 5.x appears faster, but site search still needs a lot of work. The next update, to ElasticSearch 6.x, will be in March 2019.

Ryan Johnson is continuing the work of migrating from MozMEAO to Mozilla IT support. Ed Lim provisioned the new Kubernetes cluster (PR 24) and backing services (PR 31), with support from Dave Parfitt and Josh Mize. Ryan configured the new Jenkins server to run parallel tests and deployments (PR 4931), and to publish Docker images to a new repository (PR 4933). We’re now deploying to both the MozMEAO staging environment and the MozIT staging environment.

We’ll continue with production and disaster-recovery environments in September, and prioritize the infrastructure issues. The goal is to switch traffic in October.

Shipped tweaks and fixes

There were 400 PRs merged in August:

• 208 mdn/browser-compat-data PRs
• 53 mozilla/kuma PRs
• 34 mdn/bob PRs
• 34 mdn/interactive-examples PRs
• 29 mdn/kumascript PRs
• 17 mdn/data PRs
• 16 mdn/infra PRs
• 4 mdn/css-examples PRs
• 2 mdn/learning-area PRs
• 1 mdn/webextensions-examples PR
• 1 mdn/sw-test PR
• 1 mdn/webaudio-examples PR

This includes some important changes and fixes:

• Fix the survey banner on standard DPI displays (Kuma PR 4907), from Schalk Neethling.
• Avoid “remember this preference” dialog if the language preference is already set (Kuma PR 4890), from Safwan Rahman.
• Add Discourse field to user profiles (Kuma PR 4930), from Mihir Karbelkar.
• Improve document purging (Kuma PR 4934), from me.
• Improve reliability of Interactive Example performance metrics (Kuma PR 4935), from Schalk Neethling.
• Replace KUMA_WIKI_IFRAME_ALLOWED_HOSTS with ALLOWED_IFRAME_PATTERNS (Kuma PR 4940), from me.
• Replace the survey banner with a Firefox Development banner (Kuma PR 4938), from Schalk Neethling.
• On mobile, show the browser name instead of an icon in compatibility table (Kuma PR 4948), from Schalk Neethling.

78 pull requests were from first-time contributors:

• Add Service Worker support in Safari 11.1 (BCD PR 1881), from Abdón Rodríguez Davila.
• Correct SMIL compatibility information (BCD PR 1956), from Robert Longson.
• Add compat data for Element (BCD PR 2316), from Bobu aka Sébastien.
• Add compat data for PositionError. (BCD PR 2398), from Deepraj Pandey.
• Fix Mobile Edge support for gap, row-gap and column-gap (BCD PR 2500), from Kumar Harsh.
• Update setIcon to include Edge notes (BCD PR 2513), from Morgan Gangwere.
• Add missing <input type="password"> description (BCD PR 2543), from weary-adventurer.
• Update datalist, not supported by Android WebView. (BCD PR 2544), from Valentin.
• Rename “ExperimentalCanvasFeatures” to “Experimental Web Platform Features” (BCD PR 2547), from Indi Kernick.
• Remove Safari support for href from SVG <use> (BCD PR 2548), from Michal Miky Jankovský.
• Remove support fort proxy.settings from Firefox Android (PR 2550), from Martin Giger (first contribution to BCD).
• Remove support for chrome_url_overrides from Edge (BCD PR 2556), from Lucas Everett.
• Add support for Upgrade-Insecure-Requests in Edge 17 (PR 2561), and Add support for :matches() in Edge (PR 2578), to BCD from Eric Eggert.
• Add support for Request.destination in Chrome, Opera and Edge (BCD PR 2562), from Nicolas Hoizey.
• Add support for InputEvent.getTargetRanges() in Safari 10.1 (PR 2565), and Add support for Asynchronous Clipboard API in Opera 53 and Chrome 66 (PR 2703), to BCD from Makoto Kato.
• Add support for onbeforeunload in Edge (BCD PR 2566), from Sumit Chahal.
• Update support for -webkit-overflow-scrolling, not supported (BCD PR 2577), from Summon528.
• Update X-Frame-Options compatibility for Safari and Edge (PR 2579), and Fix Navigator.share compatibility for Chrome and Opera (PR 2595), to BCD from Nick Zahn.
• Migrate compat data for Coordinates (BCD PR 2587), from Omar Boukli-Hacene.
• Update window.open support IE and Edge (BCD PR 2594), from David Patterson.
• Use correct name for menus permission (PR 2612), and Use correct name for contextMenus permission (PR 2613), to BCD from Jay Linski.
• Remove Mobile Safari support for href from SVG <use> (BCD PR 2616), from Erno.
• Add support for numeric font weights in Chrome 62 (PR 2619), and Move support for RGBA hex notation to Chrome 62 from 63 (PR 2630), to BCD from Kasper Isager.
• Add Promise.finally support in Safari 11.1 (PR 2623), and Add Safari 11 support for Performance APIs (PR 2645), to BCD from jakub-g.
• Update support for NetworkInformation.effectiveType (BCD PR 2656), from Seul-gi Choi(Chase).
• Add support forxml:space in SVG in Firefox 3 and 4 (BCD PR 2670), from linkmauve.
• Add support for location.origin and .toString in IE 11 (BCD PR 2672), from Nik Rolls.
• Add support for Document.hasFocus in Opera (BCD PR 2678), from Mass Carl.
• Migrate note on Firefox 3.5 support for the Geolocation API (BCD PR 2680), from Mingye Wang.
• <details> is not in development in Edge (PR 2688), from Kagami Sascha Rosylight (first contribution to BCD).
• Update support for NetworkInformation for Firefox and Edge (PR 2689), and Add support for Document.exitFullscreen (PR 2699), to BCD from Thomas den Hollander.
• Add Edge 15 support version for Element.closest (BCD PR 2702), from Randall Leeds.
• Add support for word-break for Edge (BCD PR 2704), from k-utsumi.
• Fix typo of “user-agent” in console.error() calls (Kuma PR 4916), from Stephen Donner.
• Remove reference to incorrect restart command (Kuma PR 4922), from James Hobin.
• Add examples for async iterators and generators. (PR 1036), from Joe Medley (first contribution to Interactive Examples).
• Add String concat, ends/startswith, padend/start live examples (Interactive Examples PR 1068), from Melissa.
• Add method for String[@@iterator]() (PR 1069), Create an example for the String.raw() method (PR 1070), and 4 more PRs from Irene Smith (first contributions to Interactive Examples).
• Make variable names consistent (Interactive Examples PR 1090), from Roy Revelt.
• Improve example code (Interactive Examples PR 1111), from Arjan Einbu.
• Add Japanese Translation for CompatibilityTable.ejs (KumaScript PR 692), from hmatrjp.
• Add data for XPath specifications (PR 726), Correct broken <a> and <strong> DOM hierarchy in AddonSidebar (PR 771), and Add the overheadIndicator class to SeeCompatTable (PR 788), from ExE Boss (first contributions to KumaScript).
• Update CSS4 Text specification (PR 735), from Jakob Krigovsky (first contribution to KumaScript).
• Add CSS Environment Variables spec (KumaScript PR 748), from Nicolas Hoizey.
• Localize WebExtensions Sidebar (KumaScript PR 755), from Etienne Wan.
• Add Japanese translation (KumaScript PR 763), from WhiteHawk.
• Mark a couple of scroll-snap properties as obsolete (PR 251), from Dominique Hazael-Massieux (first contribution to Data).
• Add place-items property. (PR 252), from Connor Shea (first contribution to Data).
• Add MDN URLs to CSS properties data (PR 256), Add MDN URLs to at-rules data (PR 258), and 3 more PRs from Daniel D. Beck (first contributions to Data).
• Add initial value auto to min-width and min-height (PR 263), and Rename the offset- logical properties to inset- (PR 273), from Rachel Andrew (first contributions to Data).
• Add media-document(<string>) to @document (PR 268), from Estelle Weyl (first contribution to Data).
• Create code examples for Variable Fonts Guide (PR 4), Update widths and spacing (PR 5), and 2 more PRs to css-examples from Jason Pamental.
• Fix spelling error (learning-area PR 74), from Utkarsh Nag.
• Fix spelling error (learning-area PR 91), from LittleMang.
• Make minor adjustments to the setup instructions (sw-test PR 28), from Zunino.
• Add audio analyser (webaudio-examples PR 7), from peterchang.

Planned for September

In September, we’ll continue working on new and improved interactive examples, converting compatibility data, migrating MDN services, and other long-term projects.

Hack on accessibility

We’re happy with the results of the Paris Hack on MDN event in March, and are doing it again in September. MDN staff will meet in London for a week of meetings and 2019 planning, and then have the fourth Hack on MDN event, focusing on accessibility. We plan to write docs, build tools, and explore ways to help web developers make the internet more accessible for all users.

Ship more performance improvements

We’ll continue working on the suggested performance improvements, to meet the performance goals for the year.

One area for improvement is optimizing MDN’s use of custom web fonts. These fonts often need to be downloaded, increasing page load time. Some plugins and clients, like Firefox Focus, improve the mobile experience by blocking these by default. Our goal is to improve the experience for desktop users by downloading optimized fonts after the initial page load, and avoiding required custom fonts like FontAwesome for icons.

Another focus is Interactive Examples, which are useful but have a large impact on page load time. James Hobin is working through the requirements to load the examples directly into the page, rather than via an <iframe>. Schalk is improving the asset builder for new features and for optimized asset building.

The post MDN Changelog for August 2018 appeared first on Mozilla Hacks - the Web developer blog.

Firefox Focus is private browsing as an app: It automatically blocks ads and trackers, so you can surf the web in peace. When you’re done, a single tap completely erases your history, cookies, and other local data.

Protecting you from invasive tracking is part of Mozilla’s non-profit mission, and Focus’s built-in tracking protection helps keep you safe. It also makes websites load faster!

With Focus, you don’t have to worry about your browsing history coming back to haunt you in retargeted ads on other websites.

Bringing Gecko to Focus

In the next weeks, we’ll release a new version of Focus for Android, and for the first time, Focus will come bundled with Gecko, the browser engine that powers Firefox Quantum. This is a major architectural change, so while every copy of Focus will include Gecko—hence the larger download size—we plan on enabling it gradually to ensure a smooth transition. You can help us test Gecko in Focus today by installing the Focus Beta.

Note: At time of publishing, Focus Beta is conducting an A/B test between the old and new engines. Look for “Gecko/62.0” in your User-Agent String to determine if your copy is using Gecko or not.

Up until this point, Focus has been powered exclusively by Android’s built-in WebView. This made sense for initial development, since WebView was already on every Android device, but we quickly ran into limitations. Foremost, it isn’t designed for building browsers. Despite being based on Chromium, WebView only supports a subset of web standards, as Google expects app developers to use native Android APIs, and not the Web, for advanced functionality. Instead, we’d prefer if apps had access to the entirety of the open, standards-based web platform.

In Focus’s case, we can only build next-generation privacy features if we have deep access to the browser internals, and that means we need our own engine. We need Gecko. Fortunately, Firefox for Android already uses Gecko, just not in a way that’s easy to reuse in other applications. That’s where GeckoView comes in.

GeckoView: Making Gecko Reusable

GeckoView is Gecko packaged as a reusable Android library. We’ve worked to decouple the engine itself from its user interface, and made it easy to embed in other applications. Thanks to GeckoView’s clean architecture, our initial benchmarks of the new Focus show a median page load improvement of 20% compared to Firefox for Android, making GeckoView our fastest version of Gecko on Android yet.

We first put GeckoView into production last year, powering both Progressive Web Apps (PWAs) and Custom Tabs in Firefox for Android. These minimal, self-contained features were good initial projects, but with Focus we’re going much further. Focus will be our first time using GeckoView to completely power an existing, successful, and standalone product.

We’re also using GeckoView in entirely new products like Firefox Reality, a browser designed exclusively for virtual and augmented reality headsets. We’ll be sharing more about it later this year.

Building Browsers with Android Components

To build a web browser, you need more than just an engine. You also need common functionality like tabs, auto-complete, search suggestions, and so on. To avoid unnecessary duplication of effort, we’ve also created Android Components, a collection of independent, ready-to-use libraries for building browsers and browser-like applications on Android.

For Mozilla, GeckoView means we can leverage all of our Firefox expertise in building more compelling, safe, and robust online experiences, while Android Components ensures that we can continue experimenting with new projects (like Focus and Firefox Reality) without reinventing wheels. In many ways, these projects set the stage for the next generation of the Firefox family of browsers on Android.

For Android developers, GeckoView means control. It’s a production-grade engine with a stable and expansive API, usable either on its own or through Android Components. Because GeckoView is a self-contained library, you don’t have to compile it yourself. Furthermore, powering your app with GeckoView gives you a specific web engine version you can work with. Compare that to WebView, which tends to have quite a bit of variance between versions depending on the OS and Chrome version available on the device. With GeckoView, you always know what you’re getting — and you benefit from Gecko’s excellent, cross-platform support for web standards.

Get Involved

We’re really excited about what GeckoView means for the future of browsers on Android, and we’d love for you to get involved:

• Consider installing the Focus Beta and reporting any issues you find.
• If you’re a Web Developer, start testing your mobile experience in Gecko, either via Focus Beta, Firefox for Android, or Firefox’s built-in responsive design mode.
• If you’re an Android Developer, consider GeckoView for your next project, or contribute directly by helping us fix bugs in Focus and Components.

Let us know what you think of GeckoView and the new Focus in the comments below!

The post Firefox Focus with GeckoView appeared first on Mozilla Hacks - the Web developer blog.

A couple months ago I ported the Pathfinder demo app to WebVR. It was an interesting experience, and I feel like I learned a bunch of things about porting WebGL applications to WebVR that would be generally useful to folks, especially folks coming to WebVR from non-web programming backgrounds.

Pathfinder is a GPU-based font rasterizer in Rust, and it comes with a demo app that runs the Rust code on the server side but does all the GPU work in WebGL in a TypeScript website.

We had a 3D demo showing a representation of the Mozilla Monument as a way to demo text rasterization in 3D. What I was hoping to do was to convert this to a WebVR application that would let you view the monument by moving your head instead of using arrow keys.

I started working on this problem with a decent understanding of OpenGL and WebGL, but almost zero background in VR or WebVR. I’d written an Android Cardboard app three years previously and that was about it.

I’m hoping this article may be useful for others from similar backgrounds.

The converted triangle demo running in WebVR

What is WebVR?

WebVR is a set of APIs for writing VR applications on the web. It lets us request jumping into VR mode, at which point we can render things directly to the eyes of a VR display, rather than rendering to a flat surface browser within the display. When the user is on a device like the Cardboard or Daydream where a regular phone substitutes for the VR display, this is the point where the user puts their phone within the headset.

WebVR APIs help with transitioning to/from VR mode, obtaining pose information, rendering in VR, and dealing with device input. Some of these things are being improved in the work in progress on the new WebXR Device API specification.

Do I need any devices to work with WebVR?

Ideally, a good VR device will make it easier to test your work in progress, but depending on how much resolution you need, a Daydream or Cardboard (where you use your phone in a headset casing) is enough. You can even test stuff without the headset casing, though stuff will look weird and distorted.

For local testing Chrome has a WebVR API emulation extension that’s pretty useful. You can use the devtools panel in it to tweak the pose, and you get a non-distorted display of what the eyes see.

Firefox supports WebVR, and Chrome Canary supports it if you enable some flags. There’s also a polyfill which should work for more browsers.

How does it work under the hood?

I think not understanding this part was the source of a lot of confusion and bugs for me when I was getting started. The core of the API is basically “render something to a canvas and then magic happens”, and I had trouble figuring how that magic worked.

Essentially, there’s a bunch of work we’re supposed to do, and then there’s extra work the browser (or polyfill) does.

Once we enter VR mode, there’s a callback triggered whenever the device requests a frame. Within this callback we have access to pose information.

Using this pose information, we can figure out what each eye should see, and provide this to the WebVR API in some form.

What the WebVR API expects is that we render each eye’s view to a canvas, split horizontally (this canvas will have been passed to the API when we initialize it).

That’s it from our side, the browser (or polyfill) does the rest. It uses our rendered canvas as a texture, and for each eye, it distorts the rendered half to appropriately work with the lenses used in your device. For example, the distortion for Daydream and Cardboard follows this code in the polyfill.

It’s important to note that, as application developers, we don’t have to worry about this — the WebVR API is handling it for us! We need to render undistorted views from each eye to the canvas — the left view on the left half and the right view on the right half, and the browser handles the rest!

Porting WebGL applications

I’m going to try and keep this self contained, however I’ll mention off the bat that some really good resources for learning this stuff can be found at webvr.info and MDN. webvr.info has a bunch of neat samples if, like me, you learn better by looking at code and playing around with it.

Entering VR mode

First up, we need to be able to get access to a VR display and enter VR mode.

let vrDisplay;
navigator.getVRDisplays().then(displays => {
    if (displays.length === 0) {
        return;
    }
    vrDisplay = displays[displays.length - 1];

    // optional, but recommended
    vrDisplay.depthNear = /* near clip plane distance */;
    vrDisplay.depthFar = /* far clip plane distance */;
}

We need to add an event handler for when we enter/exit VR:

let canvas = document.getElementById(/* canvas id */);
let inVR = false;

window.addEventListener('vrdisplaypresentchange', () => {
  // no VR display, exit
  if (vrDisplay == null)
      return;

  // are we entering or exiting VR?
  if (vrDisplay.isPresenting) {
    // We should make our canvas the size expected
    // by WebVR
    const eye = vrDisplay.getEyeParameters("left");
    // multiply by two since we're rendering both eyes side
    // by side
    canvas.width = eye.renderWidth * 2;
    canvas.height = eye.renderHeight;

    const vrCallback = () => {
        if (vrDisplay == null || !inVR) {
            return;
        }
        // reregister callback if we're still in VR
        vrDisplay.requestAnimationFrame(vrCallback);

        // render scene
        render();
    };
    // register callback
    vrDisplay.requestAnimationFrame(vrCallback);
  } else {
    inVR = false;
    // resize canvas to regular non-VR size if necessary
  }
});

And, to enter VR itself:

if (vrDisplay != null) {
    inVR = true;
    // hand the canvas to the WebVR API
    vrDisplay.requestPresent([{ source: canvas }]);

    // requestPresent() will request permission to enter VR mode,
    // and once the user has done this our `vrdisplaypresentchange`
    // callback will be triggered
}

Rendering in VR

Well, we’ve entered VR, now what? In the above code snippets we had a render() call which was doing most of the hard work.

Since we’re starting with an existing WebGL application, we’ll have some function like this already.

let width = canvas.width;
let height = canvas.height;

function render() {
    let gl = canvas.getContext("gl");
    gl.viewport(0, 0, width, height);
    gl.clearColor(/* .. */);
    gl.clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT);

    gl.useProgram(program);
    gl.bindBuffer(/* .. */);
    // ...
    let uProjection = gl.getUniformLocation(program, "uProjection");
    let uModelView = gl.getUniformLocation(program, "uModelview");
    gl.uniformMatrix4fv(uProjection, false, /* .. */);
    gl.uniformMatrix4fv(uModelView, false, /* .. */);
    // set more parameters
    // run gl.drawElements()
}

So first we’re going to have to split this up a bit further, to handle rendering the two eyes:

// entry point for WebVR, called by vrCallback()
function renderVR() {
    let gl = canvas.getContext("gl");
    // set clearColor and call gl.clear()
    clear(gl);

    renderEye(true);
    renderEye(false);
    vrDisplay.submitFrame(); // Send the rendered frame over to the VR display
}

// entry point for non-WebVR rendering
// called by whatever mechanism (likely keyboard/mouse events)
// you used before to trigger redraws
function render() {
    let gl = canvas.getContext("gl");
    // set clearColor and call gl.clear()
    clear(gl);
    renderSceneOnce();
}

function renderEye(isLeft) {
    // choose which half of the canvas to draw on
    if (isLeft) {
        gl.viewport(0, 0, width / 2, height);
    } else {
        gl.viewport(width / 2, 0, width / 2, height);
    }
    renderSceneOnce();
}

function renderSceneOnce() {
    // the actual GL program and draw calls go here
}

This looks like a good step forward, but notice that we’re rendering the same thing to both eyes, and not handling movement of the head at all.

To implement this we need to use the perspective and view matrices provided by WebVR from the VRFrameData object.

The VRFrameData object contains a pose member with all of the head pose information (its position, orientation, and even velocity and acceleration for devices that support these). However, for the purpose of correctly positioning the camera whilst rendering, VRFrameData provides projection and view matrices which we can directly use.

We can do this like so:

let frameData = new VRFrameData();
vrDisplay.getFrameData(frameData);

// use frameData.leftViewMatrix / framedata.leftProjectionMatrix
// for the left eye, and
// frameData.rightViewMatrix / framedata.rightProjectionMatrix for the right

In graphics, we often find ourselves dealing with the model, view, and projection matrices. The model matrix defines the position of the object we wish to render in the coordinates of our space, the view matrix defines the transformation between the camera space and the world space, and the projection matrix handles the transformation between clip space and camera space (also potentially dealing with perspective). Sometimes we’ll deal with the combination of some of these, like the “model-view” matrix.

One can see these matrices in use in the cubesea code in the stereo rendering example from webvr.info.

There’s a good chance our application has some concept of a model/view/projection matrix already. If not, we can pre-multiply our positions with the view matrix in our vertex shaders.

So now our code will look something like this:

// entry point for non-WebVR rendering
// called by whatever mechanism (likely keyboard/mouse events)
// we used before to trigger redraws
function render() {
    let gl = canvas.getContext("gl");
    // set clearColor and call gl.clear()
    clear(gl);
    let projection = /*
        calculate projection using something
        like glmatrix.mat4.perspective()
        (we should be doing this already in the normal WebGL app)
    */;
    let view = /*
        use our view matrix if we have one,
        or an identity matrix
    */;
    renderSceneOnce(projection, view);
}

function renderEye(isLeft) {
    // choose which half of the canvas to draw on
    let projection, view;
    let frameData = new VRFrameData();
    vrDisplay.getFrameData(frameData);
    if (isLeft) {
        gl.viewport(0, 0, width / 2, height);
        projection = frameData.leftProjectionMatrix;
        view = frameData.leftViewMatrix;
    } else {
        gl.viewport(width / 2, 0, width / 2, height);
        projection = frameData.rightProjectionMatrix;
        view = frameData.rightViewMatrix;
    }
    renderSceneOnce(projection, view);
}

function renderSceneOnce(projection, view) {
    let model = /* obtain model matrix if we have one */;
    let modelview = glmatrix.mat4.create();
    glmatrix.mat4.mul(modelview, view, model);

    gl.useProgram(program);
    gl.bindBuffer(/* .. */);
    // ...

    let uProjection = gl.getUniformLocation(program, "uProjection");
    let uModelView = gl.getUniformLocation(program, "uModelview");
    gl.uniformMatrix4fv(uProjection, false, projection);
    gl.uniformMatrix4fv(uModelView, false, modelview);
    // set more parameters
    // run gl.drawElements()
}

This should be it! Moving your head around should now trigger movement in the scene to match it! You can see the code at work in this demo app that takes a spinning triangle WebGL application and turns it into a WebVR-capable triangle-viewing application using the techniques from this blog post.

If we had further input we might need to use the Gamepad API to design a good VR interface that works with typical VR controllers, but that’s out of scope for this post.

The post Converting a WebGL application to WebVR appeared first on Mozilla Hacks - the Web developer blog.

We’re entering a new phase of work on JavaScript APIs here at Mozilla, that will help everyone create and share virtual reality (VR) and augmented reality (AR) projects on the open web.

As you might know, we formally launched this work last year with the release of Firefox desktop support for the WebVR 1.1 API. Using that draft API, early adopters like WITHIN were able to distribute 3D experiences on the web and have them work well on a range of devices, from mobile phones and cardboard viewers to full-fledged, immersive VR headsets.

The Expansion of WebVR

WebVR has been instrumental in democratizing VR, so more people can experience 3D content without expensive headsets. It’s also been a huge time-saver for content creators, who need to test and verify that their work renders well on every viewing platform. Having a stable API to work with means 3D content can find a wider audience, and it cuts down on the rework creators have to do to deliver great web experiences to a range of devices.

Mozilla has been pushing the boundaries of VR in the browser, getting people together across the industry to support a standard way of rendering 3D content. That work has created a fast lane for artists and programmers to share web-based VR experiences with a growing user base. And with WebVR support in browsers like Firefox, we’ve started the work of liberating VR and AR content from silos and headset stores, and making them accessible on the open web.

The Promise of Mixed Reality

Mixed Reality is going to be a powerful platform, bringing highly engaging and emotionally evocative immersive content to the web. Like any new creative medium, we want it to be widely accessible, so curious viewers can experience the next generation of digital media without having to shell out hundreds of dollars for a high-end viewer.

Today, the industry is taking another step toward these goals. We have ambitions to broaden the number of platforms and devices that can display VR and AR content. For instance, the camera on most mobile phones can be used to overlay information on physical reality – if it has a set of instructions on how to do that.

Experimentation continues with a new JavaScript API called the WebXR Device API. We expect this specification will replace WebVR in time and offer a smooth path forward for folks using WebVR today.

What’s New in WebXR

The new WebXR Device API has two new goals that differentiate it from WebVR. They are:

• To support a wider variety of user inputs, such as voice and gestures, giving users options for navigating and interacting in virtual spaces
• To establish a technical foundation for development of AR experiences, letting creators integrate real-world media with contextual overlays that elevate the experience.

You can find details about WebXR Device API by visiting the Immersive Web Community Group. We expect that many of the same crew that worked on WebVR – talented engineers from Mozilla, Google, Samsung, Amazon and other companies – will continue to work on the WebXR Device API, along with new contributors like Magic Leap.

AR Comes to the Web

AR and VR both are at the cutting edge of creative expression. Some museums offer AR experiences to give depth and context to exhibits. Other projects include educational content, from geology lessons to what it’s like to walk the streets in war-torn Syria.

What can augmented reality do on the web? Already there are examples that demonstrate powerful use cases. For instance, want to know how that new sofa will fit in your living room, before you buy it? Or how an espresso machine would look in your kitchen? Augmented reality can make online shopping a more sensory experience, so you can test-drive new products in your home in a way that preserves size and scale. It’s a great complement to online shopping, especially as companies start offering online visualizations of physical products.

Mozilla has some key tenets for how we’d like this next-generation media to work on behalf of users.

• We want to ensure user privacy. You shouldn’t have to give an art store website access to pictures of your home and everything in it in order to see how a poster would look on your wall.
• We want to make AR and VR accessible to the widest possible audience. We’re committed to removing barriers for people.
• We want to help creators make content that works on all devices, so users can access mixed reality experiences with the device they have, or want to use.
• We want to enable the long tail of creators, not just big studios and well-known brands. Everyone who wants to should be able to augment the world, not just those who can get an app into a store.

The WebXR community is working on draft specifications that target some of the constraints of today’s wireless devices. For instance, creating a skybox setting you can use to can change the background image of a web page. We’re also working on a way to expose the world-sensing capabilities of early AR platforms to the web, so developers can determine where surfaces are without needing to run complex computer vision code on a battery-powered device.

Support in Firefox

We’re proud that Firefox supports WebVR today, so people can use current technology while we’re working to implement the next-generation specification. We have begun work to add WebXR support to Firefox. An early implementation will be available in Firefox Nightly in the coming months, so developers and early adopters can turn it on and give it a test-drive.

Some parts of the WebXR specification are still in motion. Rather than waiting for a final version of the spec, we’re going to move forward with what we have now and adjust to any changes along the way. The roadmap for the upcoming Firefox Reality browser will be similar to the Firefox desktop version, with initial support for immersive browsing using WebVR, and WebXR support to follow.

In time, we plan to support WebXR everywhere that we support WebVR currently, including Windows, Linux, macOS, and Android/GeckoView platforms. We will continue supporting WebVR until most popular sites and engines have completed the transition to WebXR. Want more technical details? Check out this WebXR explainer.

Today’s AR Experiments

If you can’t wait to dive into augmented reality, here’s something you can try today: Mozilla’s WebXR Viewer for iOS. It’s a way you can get a glimpse of the future right on your iPhone (6s or newer) or iPad. To be clear: this app is an experiment based on a proposed interim API we created last year. We are currently converting it to use the WebXR Device API.

We created this app as a way to experiment with AR and to find out how easy it was to get it working on iOS using Apple’s ARKit.  If you want to have a look at the code for the iOS app, it’s posted on GitHub. For Android users, Google has a similar experiment going with early support for the immersive web.

Want to keep up with the progress of WebXR and the new WebXR Device API? Follow @mozillareality on twitter, or subscribe to the Mozilla Mixed Reality blog for our weekly roundup of XR news.

The post New API to Bring Augmented Reality to the Web appeared first on Mozilla Hacks - the Web developer blog.

Hello there! It’s been six-odd weeks, and the march of progress continues to, uh… march… progressingly. That means we have a brand new Firefox to share, with an abundance of bug fixes, performance improvements, and (in particular) sweet developer tool treats! So tuck in your napkin and enjoy this tasting menu of some of what’s new in Firefox 62.

Shape Up Your Floats

CSS Shapes lets a floated element sculpt the flow of content around it beyond the classic rectangular bounding box we’ve been constrained to. For instance, in the above screenshot and linked demo, the text is wrapping to the shape of the grapes vs the image’s border. There are properties for basic shapes all the way up to complex polygons. There are of course great docs on all of this, but Firefox 62 also includes new tooling to both inspect and visually manipulate CSS Shapes values.

You can learn more in Josh Marinacci’s post on the new CSS Shapes tooling from yesterday.

Variable Fonts Are Here!

No punny title, I’m just excited! OpenType Font Variations allow a single font file to contain multiple instances of the same font, encoding the differences between instances. In addition to being in one file, font creators can expose any number of variation axes that give developers fine-grained control on how a font is rendered. These can be standard variations like font weight (font weight 536 looks right? no problem!) or things that were never previously available via CSS (x-height! serif-size!). In addition to the candy-store possibilities for typography nerds, being able to serve a single file with multiple variants is a major page weight savings. Dan Callahan goes much deeper on the grooviness to be found and how Firefox makes it easy to tweak these new custom values.

Devtools Commands

The Developer Toolbar was an alternate command repl input in the Firefox Developer tools, apart from the Web Console. I say “was” because as of Firefox 62, it has been removed. It was always a bit hard to find and not as well-advertised as it could be, but did encapsulate some powerful commands. Most of these commands have been progressively migrated elsewhere in the devtools, and this is wrapped up in Firefox 62, so we’ve removed the toolbar altogether.

One of the last commands to be migrated is screenshot, which is a power-user version of the “take a screenshot” button available in the devtools UI. The screenshot command is now available as :screenshot in the Web Console! For example, have you ever needed a high-res screenshot of a page for print? You can specify a higher pixel density for a screenshot via the command:

:screenshot --dpr 4

There are a bunch of other options as well, such as specifying output filenames, capture delays, and selector-cropped screenshots. Eric Meyer wrote a great primer on the power of :screenshot on his blog, and it will change your page capture game!

Did You Know: In addition to :screenshot, there are a bunch of other helpful commands and magic variables available from within the Web Console? You can learn about them on MDN Web Docs.

Mo’ Pixels, Mo’ Panels

Do you have a 4k monitor? Do your browser windows bathe in a wash of ample screen real-estate? Let your devtools stretch their legs with a new 3-column mode in the Page Inspector. You can now pop the CSS Rules view into its own column, to let you view style information and the excellent Grid tooling or Animations panel side-by-side.

Streamlining MediaStream

If you’ve worked with WebRTC’s getUserMedia API, you may be familiar with a bit of branching logic when attaching a MediaStream object to a <video> or <audio> tag:

navigator.mediaDevices.getUserMedia({ audio: true, video: true })
.then(function(stream) {
  if ("srcObject" in video) {
    videoEl.srcObject = stream;
  } else {
    videoEl.src = URL.createObjectURL(stream);
  }
});

It’s true that earlier support for WebRTC required the use of the URL API, but this was non-standard and is no longer necessary. Firefox 62 removes support for passing a MediaStream to createObjectURL, so be sure you’re using a proper capability check as above.

Why stop here?

I’ve shown you a glimpse of what’s new and exciting in Firefox 62, but there’s more to learn and love! Be sure to check out the product release notes for user-facing features as well as a more complete list of developer facing changes on MDN.

Happy building!

The post Firefox 62 – Tools Cool for School! appeared first on Mozilla Hacks - the Web developer blog.

The web doesn’t have to be boxy. Historically, every element in a page is rendered as a rectangle of some kind, but it doesn’t have to be this way. With CSS Shapes you can create web layouts every bit as stylish as print magazines, but with all of the advantages of the web.

CSS Shapes let your web designs break out of the rectangular grid. All of those classic magazine design elements like non-rectangular text flow and shaped images can be yours, for the low low price of using a new CSS standard. Text can flow, images can be rounded, even just a few non-parallel lines can make your site stand out and make your brand distinctive. Standing out is the biggest challenge most sites face today. Shapes can help!

Image by Sara Soueidan

The Standard

The shape of your elements can be controlled with just two CSS properties: shape-outside and clip-path.

The shape-outside property changes the way content flows outside of a floated DOM element. It affects layout, not drawing. The clip-path property changes the clipping boundary of how the DOM element is drawn. It affects drawing, not layout.

The clip-path and shape-outside properties.

Because these two properties are separate, you can use one, or both, or none — to get just exactly the effect you are looking for. The good news is that both of these use the same basic-shape syntax.

Want to clip your image to be in a circle? Just use clip-path: circle(50%). Want to make text wrap around your image as if it were a circle, just use shape-outside: circle(50%). The shape syntax supports rectangles, circles, ellipses, and full polygons. Of course, manually positioning polygons with numbers is slow and painful. Fortunately there is a better way.

The Shape Path Editor

With the Shape Path Editor in Firefox 62, you can visually edit the shape directly from the CSS inspector. Open your page in Firefox, and use Firefox Developer Tools to select the element whose shape you want to modify. Once you select the element there will be a little icon next to the shape-outside and clip-path properties if you have used one of them. If not, add shape-outside and clip-path to that element first. Click on that little icon to start the visual editor. Then you can directly manipulate the shape with your mouse.

Image courtesy of placekitten, text courtesy of catipsum.

Open the Inspector and select the element you want to modify:

Click the icon next to clip-path or shape-outside. If the element doesn’t have one of these properties, add it, then select it.

Edit the clip path:

Edit the outside shape:

Check out this live demo on glitch.

To learn more about how to use the CSS Shape Editor read the full documentation.

Progressive Enhancement

CSS shapes are here and they work today in most browsers, and most importantly they degrade gracefully. Readers with current browsers will get a beautiful experience and readers with non-compliant browsers will never know they are missing anything.

Stunning Examples

Here are just a few examples of the amazing layouts you can do with CSS Shapes:

Page layout text effects with clip-path:

via Mandy Michael

Plants and background effect using clip-path:

via Aga Naplocha

Minion using shape-outside:

via Nicholas Evans

Break out of the Box

Shapes on the web are here today, thanks to shape-outside and clip-path. Using the Firefox Shape Path Editor makes them even easier to use.

How will you make your website break out of the box? Let us know how you’re using Shapes.

The post Make your web layouts bust out of the rectangle with the Firefox Shape Path Editor appeared first on Mozilla Hacks - the Web developer blog.

Firefox 62, which lands in general release this week, adds support for Variable Fonts, an exciting new technology that makes it possible to create beautiful typography with a single font file. Variable fonts are now supported in all major browsers.

What are Variable Fonts?

Font families can have dozens of variations: different weights, expanded or condensed widths, italics, etc. Traditionally, each variant required its own separate font file, which meant that Web designers had to balance typographic nuance with pragmatic concerns around page weight and network performance.

Compared to traditional fonts, variable fonts contain additional data, which make it possible to generate different styles of the font on demand. For one example, consider Jost*, an open-source, Futura-inspired typeface from indestructible type*. Jost* comes in nine weights, each with regular and italic styles, for a total of eighteen files.

Jost* also comes as a single variable font file which is able to generate not only those same eighteen variations, but also any intermediate weight at any degree of italicization.

Design Axes

Jost* is an example of a “two-axis” variable font: it can vary in both weight and italics. Variable fonts can have any number of axes, and each axis can control any aspect of the design. Weight is the most common axis, but typographers are free to invent their own.

One typeface that invented its own axis is Slovic. Slovic is a Cyrillic variable font with a single axis, style, that effectively varies history. At one extreme, characters are drawn similarly to how they appear in 9th century manuscripts, while at the other, they adopt modern sans-serif forms. In between are several intermediate styles. Variable font technology allows the design to adapt and morph smoothly across the entire range of the axis.

The sky’s the limit! To see other examples of variable fonts, check out v-fonts.com and Axis Praxis.

Better Tools for Better Typography on the Web

Great features deserve great tools, and that’s why we’re hard at work building an all new Font Editor into the Firefox DevTools. Here’s a sneak peek:

You can find the Font Editor as a panel inside the Page Inspector in the Dev Tools. If you have enough space on your screen, it’s helpful to enable 3-pane mode so you can see the DOM tree, CSS Rules, and Font Editor all side-by-side.

When you click on an element in the DOM tree, the Font Editor updates to show information about the selected element’s font, as well as tools for editing its properties. The Font Editor works on all fonts, but really shines with variable ones. For instance, the weight control subtly changes from stepped slider to continuous one in the presence of a variable font with a weight axis.

Similarly, each design axis in a variable font gets its own widget in the editor, allowing you to directly customize the font’s appearance and immediately see the results on your page.

The new Font Editor will arrive with Firefox 63 in October, but you can use it today by downloading Firefox Nightly. Let us know what you think! Your feedback is an essential guide as we continue to build and refine Firefox’s design tools.

Editor’s note: Attention MacOS users — variable fonts require MacOS 10.13+

The post Variable Fonts Arrive in Firefox 62 appeared first on Mozilla Hacks - the Web developer blog.