Last month we announced that UK users can access apps for the Google Assistant on Google Home and their phones—and starting today, we're bringing Actions on Google to Australia. From Perth to Sydney, developers can start building apps for the Google Assistant, giving their users even more ways to get things done.
Similar to our launch in the UK, your English apps will appear in the local directory automatically. With that said, there are a few things to help make your app a true blue Aussie:
Our developer tools, documentation and simulator have all been updated to make it easy for you to create, test and deploy your app. So what are you waiting for?
UK and Aussie users are just the start, we'll continue to make the Actions on Google platform available in more languages over the coming year. If you have questions about internationalization, please reach out to us on Stackoverflow and Google+.
TensorFlow 1.3 introduces two important features that you should try out:
Below you can see how they fit in the TensorFlow architecture. Combined, they offer an easy way to create TensorFlow models and to feed data to them:
To explore these features we're going to build a model and show you relevant code snippets. The complete code is available here, including instructions for getting the training and test files. Note that the code was written to demonstrate how Datasets and Estimators work functionally, and was not optimized for maximum performance.
The trained model categorizes Iris flowers based on four botanical features (sepal length, sepal width, petal length, and petal width). So, during inference, you can provide values for those four features and the model will predict that the flower is one of the following three beautiful variants:
We're going to train a Deep Neural Network Classifier with the below structure. All input and output values will be float32, and the sum of the output values will be 1 (as we are predicting the probability for each individual Iris type):
float32
For example, an output result might be 0.05 for Iris Setosa, 0.9 for Iris Versicolor, and 0.05 for Iris Virginica, which indicates a 90% probability that this is an Iris Versicolor.
Alright! Now that we have defined the model, let's look at how we can use Datasets and Estimators to train it and make predictions.
Datasets is a new way to create input pipelines to TensorFlow models. This API is much more performant than using feed_dict or the queue-based pipelines, and it's cleaner and easier to use. Although Datasets still resides in tf.contrib.data at 1.3, we expect to move this API to core at 1.4, so it's high time to take it for a test drive.
At a high-level, the Datasets consists of the following classes:
Where:
To get started, let's first look at the dataset we will use to feed our model. We'll read data from a CSV file, where each row will contain five values-the four input values, plus the label:
The label will be:
To describe our dataset, we first create a list of our features:
feature_names = [ 'SepalLength', 'SepalWidth', 'PetalLength', 'PetalWidth']
When we train our model, we'll need a function that reads the input file and returns the feature and label data. Estimators requires that you create a function of the following format:
def input_fn(): ...<code>... return ({ 'SepalLength':[values], ..<etc>.., 'PetalWidth':[values] }, [IrisFlowerType])
The return value must be a two-element tuple organized as follows: :
Since we are returning a batch of input features and training labels, it means that all lists in the return statement will have equal lengths. Technically speaking, whenever we referred to "list" here, we actually mean a 1-d TensorFlow tensor.
To allow simple reuse of the input_fn we're going to add some arguments to it. This allows us to build input functions with different settings. The arguments are pretty straightforward:
input_fn
file_path
perform_shuffle
repeat_count
Here's how we can implement this function using the Dataset API. We will wrap this in an "input function" that is suitable when feeding our Estimator model later on:
def my_input_fn(file_path, perform_shuffle=False, repeat_count=1): def decode_csv(line): parsed_line = tf.decode_csv(line, [[0.], [0.], [0.], [0.], [0]]) label = parsed_line[-1:] # Last element is the label del parsed_line[-1] # Delete last element features = parsed_line # Everything (but last element) are the features d = dict(zip(feature_names, features)), label return d dataset = (tf.contrib.data.TextLineDataset(file_path) # Read text file .skip(1) # Skip header row .map(decode_csv)) # Transform each elem by applying decode_csv fn if perform_shuffle: # Randomizes input using a window of 256 elements (read into memory) dataset = dataset.shuffle(buffer_size=256) dataset = dataset.repeat(repeat_count) # Repeats dataset this # times dataset = dataset.batch(32) # Batch size to use iterator = dataset.make_one_shot_iterator() batch_features, batch_labels = iterator.get_next() return batch_features, batch_labels
Note the following: :
TextLineDataset
shuffle
map
decode_csv
That's an introduction to Datasets! Just for fun, we can now use this function to print the first batch:
next_batch = my_input_fn(FILE, True) # Will return 32 random elements # Now let's try it out, retrieving and printing one batch of data. # Although this code looks strange, you don't need to understand # the details. with tf.Session() as sess: first_batch = sess.run(next_batch) print(first_batch) # Output ({'SepalLength': array([ 5.4000001, ...<repeat to 32 elems>], dtype=float32), 'PetalWidth': array([ 0.40000001, ...<repeat to 32 elems>], dtype=float32), ... }, [array([[2], ...<repeat to 32 elems>], dtype=int32) # Labels )
That's actually all we need from the Dataset API to implement our model. Datasets have a lot more capabilities though; please see the end of this post where we have collected more resources.
Estimators is a high-level API that reduces much of the boilerplate code you previously needed to write when training a TensorFlow model. Estimators are also very flexible, allowing you to override the default behavior if you have specific requirements for your model.
There are two possible ways you can build your model using Estimators:
Here is the class diagram for Estimators:
We hope to add more pre-made Estimators in future releases.
As you can see, all estimators make use of input_fn that provides the estimator with input data. In our case, we will reuse my_input_fn, which we defined for this purpose.
my_input_fn
The following code instantiates the estimator that predicts the Iris flower type:
# Create the feature_columns, which specifies the input to our model. # All our input features are numeric, so use numeric_column for each one. feature_columns = [tf.feature_column.numeric_column(k) for k in feature_names] # Create a deep neural network regression classifier. # Use the DNNClassifier pre-made estimator classifier = tf.estimator.DNNClassifier( feature_columns=feature_columns, # The input features to our model hidden_units=[10, 10], # Two layers, each with 10 neurons n_classes=3, model_dir=PATH) # Path to where checkpoints etc are stored
We now have a estimator that we can start to train.
Training is performed using a single line of TensorFlow code:
# Train our model, use the previously function my_input_fn # Input to training is a file with training example # Stop training after 8 iterations of train data (epochs) classifier.train( input_fn=lambda: my_input_fn(FILE_TRAIN, True, 8))
But wait a minute... what is this "lambda: my_input_fn(FILE_TRAIN, True, 8)" stuff? That is where we hook up Datasets with the Estimators! Estimators needs data to perform training, evaluation, and prediction, and it uses the input_fn to fetch the data. Estimators require an input_fn with no arguments, so we create a function with no arguments using lambda, which calls our input_fn with the desired arguments: the file_path, shuffle setting, and repeat_count. In our case, we use our my_input_fn, passing it:
lambda: my_input_fn(FILE_TRAIN, True, 8)
lambda
file_path, shuffle setting,
my_input_fn,
FILE_TRAIN
True
8
Ok, so now we have a trained model. How can we evaluate how well it's performing? Fortunately, every Estimator contains an evaluate method:
evaluate
# Evaluate our model using the examples contained in FILE_TEST # Return value will contain evaluation_metrics such as: loss & average_loss evaluate_result = estimator.evaluate( input_fn=lambda: my_input_fn(FILE_TEST, False, 4) print("Evaluation results") for key in evaluate_result: print(" {}, was: {}".format(key, evaluate_result[key]))
In our case, we reach an accuracy of about ~93%. There are various ways of improving this accuracy, of course. One way is to simply run the program over and over. Since the state of the model is persisted (in model_dir=PATH above), the model will improve the more iterations you train it, until it settles. Another way would be to adjust the number of hidden layers or the number of nodes in each hidden layer. Feel free to experiment with this; please note, however, that when you make a change, you need to remove the directory specified in model_dir=PATH, since you are changing the structure of the DNNClassifier.
model_dir=PATH
DNNClassifier
And that's it! We now have a trained model, and if we are happy with the evaluation results, we can use it to predict an Iris flower based on some input. As with training, and evaluation, we make predictions using a single function call:
# Predict the type of some Iris flowers. # Let's predict the examples in FILE_TEST, repeat only once. predict_results = classifier.predict( input_fn=lambda: my_input_fn(FILE_TEST, False, 1)) print("Predictions on test file") for prediction in predict_results: # Will print the predicted class, i.e: 0, 1, or 2 if the prediction # is Iris Sentosa, Vericolor, Virginica, respectively. print prediction["class_ids"][0]
The preceding code specified FILE_TEST to make predictions on data stored in a file, but how could we make predictions on data residing in other sources, for example, in memory? As you may guess, this does not actually require a change to our predict call. Instead, we configure the Dataset API to use a memory structure as follows:
FILE_TEST
predict
# Let create a memory dataset for prediction. # We've taken the first 3 examples in FILE_TEST. prediction_input = [[5.9, 3.0, 4.2, 1.5], # -> 1, Iris Versicolor [6.9, 3.1, 5.4, 2.1], # -> 2, Iris Virginica [5.1, 3.3, 1.7, 0.5]] # -> 0, Iris Sentosa def new_input_fn(): def decode(x): x = tf.split(x, 4) # Need to split into our 4 features # When predicting, we don't need (or have) any labels return dict(zip(feature_names, x)) # Then build a dict from them # The from_tensor_slices function will use a memory structure as input dataset = tf.contrib.data.Dataset.from_tensor_slices(prediction_input) dataset = dataset.map(decode) iterator = dataset.make_one_shot_iterator() next_feature_batch = iterator.get_next() return next_feature_batch, None # In prediction, we have no labels # Predict all our prediction_input predict_results = classifier.predict(input_fn=new_input_fn) # Print results print("Predictions on memory data") for idx, prediction in enumerate(predict_results): type = prediction["class_ids"][0] # Get the predicted class (index) if type == 0: print("I think: {}, is Iris Sentosa".format(prediction_input[idx])) elif type == 1: print("I think: {}, is Iris Versicolor".format(prediction_input[idx])) else: print("I think: {}, is Iris Virginica".format(prediction_input[idx])
Dataset.from_tensor_slides() is designed for small datasets that fit in memory. When using TextLineDataset as we did for training and evaluation, you can have arbitrarily large files, as long as your memory can manage the shuffle buffer and batch sizes.
Dataset.from_tensor_slides()
Using a pre-made Estimator like DNNClassifier provides a lot of value. In addition to being easy to use, pre-made Estimators also provide built-in evaluation metrics, and create summaries you can see in TensorBoard. To see this reporting, start TensorBoard from your command-line as follows:
# Replace PATH with the actual path passed as model_dir argument when the # DNNRegressor estimator was created. tensorboard --logdir=PATH
The following diagrams show some of the data that TensorBoard will provide:
In this this blogpost, we explored Datasets and Estimators. These are important APIs for defining input data streams and creating models, so investing time to learn them is definitely worthwhile!
For more details, be sure to check out
But it doesn't stop here. We will shortly publish more posts that describe how these APIs work, so stay tuned for that!
Until then, Happy TensorFlow coding!
You can now use our developer-documentation style guide for open source documentation projects.
For some years now, our technical writers at Google have used an internal-only editorial style guide for most of our developer documentation. In order to better support external contributors to our open source projects, such as Kubernetes, AMP, or Dart, and to allow for more consistency across developer documentation, we're now making that style guide public.
If you contribute documentation to projects like those, you now have direct access to useful guidance about voice, tone, word choice, and other style considerations. It can be useful for general issues, like reminders to use second person, present tense, active voice, and the serial comma; it can also be great for checking very specific issues, like whether to write "app" or "application" when you want to be consistent with the Google Developers style.
The style guide is a reference document, so instead of reading through it in linear order, you can use it to look things up as needed. For matters of punctuation, grammar, and formatting, you can do a search-in-page to find items like "Commas," "Lists," and "Link text" in the left nav. For specific terms and phrases, you can look at the word list.
Keep an eye on the guide's release notes page for updates and developments, and send us your comments and suggestions via the Send Feedback link on each page of the guide—we want to hear from you as we continue to evolve the style guide.
For a virtual scene to be truly immersive, stunning visuals need to be accompanied by true spatial audio to create a realistic and believable experience. Spatial audio tools allow developers to include sounds that can come from any direction, and that are associated in 3D space with audio sources, thus completely enveloping the user in 360-degree sound.
Spatial audio helps draw the user into a scene and creates the illusion of entering an entirely new world. To make this possible, the Chrome Media team has created Songbird, an open source, spatial audio encoding engine that works in any web browser by using the Web Audio API.
The Songbird library takes in any number of mono audio streams and allows developers to programmatically place them in 3D space around the user. Songbird allows you to create immersive soundscapes, realistically reproducing reflection and reverb for the space you describe. Sounds bounce off walls and reflect off materials just as they would in real-life, capturing truly 360-degree sound. Songbird creates an ambisonic soundfield that can then be rendered in real-time for use in your application. We've partnered with the Omnitone project, which we blogged about last year, to add higher-order ambisonic support to Omnitone's binaural renderer to produce far more accurate sounding audio than ever before.
Songbird encapsulates Omnitone and with it, developers can now add interactive, full-sphere audio to any web based application. Songbird can scale to any order ambisonics, thereby creating a more realistic sound and higher performance than what is achievable through standard Web Audio API.
The implementation of Songbird is based on the Google spatial media specification. It expects mono input and outputs ambisonic (multichannel) ACN channel layout with SN3D normalization. Detailed documentation may be found here.
As the web emerges as an important VR platform for delivering content, spatial audio will play a vital role in users' embrace of this new medium. Songbird and Omnitone are key tools in enabling spatial audio on the web platform and establishing it as a preeminent platform for compelling VR experiences. Combining these audio experiences with 3D JavaScript libraries like three.js gives a glimpse into the future on the web.
This project was made possible through close collaboration with Google's Daydream and Web Audio teams. This collaboration allowed us to deliver similar audio capabilities to the web as are available to developers creating Daydream applications.
We look forward to seeing what people do with Songbird now that it's open source. Check out the code on GitHub and let us know what you think. Also available are a number of demos on creating full spherical audio with Songbird.
Launchpad Accelerator gives us an opportunity to work with and empower amazing developers, who are solving major challenges all around the world -- whether it's streamlining digital commerce across Africa, providing access to multimedia tools that support special needs education, or using AI to simplify business operations.
That's why we're doubling down on our efforts and opening up applications for the next class of the program to more countries for the first time starting today. Here's the full list of the new additions:
They'll be joined by our larger list of countries that are already part of the program, including: Argentina, Brazil, Chile, Colombia, Czech Republic, Hungary, India, Indonesia, Kenya, Malaysia, Mexico, Nigeria, Philippines, Poland, South Africa, Thailand, and Vietnam.
The application process for the equity-free program will end on October 2, 2017 at 9AM PST. Later in the year, the list of selected developers will be invited to the Google Developers Launchpad Space in San Francisco for 2 weeks of all-expense-paid training.
The training at Google HQ includes intensive mentoring from 20+ Google teams, and expert mentors from top technology companies and VCs in Silicon Valley. Participants receive equity-free support, credits for Google products, PR support and continue to work closely with Google back in their home country during the 6-month program. Hear from some alumnus about their experiences here.
Each startup that applies to the Launchpad Accelerator is considered holistically and with great care. Below are general guidelines behind our process to help you understand what we look for in our candidates.
All startups in the program must:
Additionally, we are interested in what kind of startup you are. We also consider:
We can't wait to hear from you and see how we can work together to improve your business.
We'd like to share with you some good news about an improvement in the data available via the Google Play Developer API. Starting Monday Aug 28, the API for Purchases.products and Purchases.subscriptions will be returning a couple of new values:
This additional data will be automatically returned to you in the JSON responses to your API calls. Please double check your integration to make sure this new field and value will not cause any problems for you.
To view all of the values returned by the APIs, check Purchases.products and Purchases.subscriptions reference pages.
Posted by Billy Rutledge, Director, AIY Projects
Makers are hands-on when it comes to making change. We're explorers, hackers and problem solvers who build devices, ecosystems, art (sometimes a combination of the three) on the basis of our own (often unconventional) ideas. So when my team first sought out to empower makers of all types and ages with the AI technology we've honed at Google, we knew whatever we built had to be open and accessible. We stayed clear of limitations that come from platform and software stack requirements, high cost and complex set up, and fixed our focus on the curiosity and inventiveness that inspire makers around the world.
When we launched our Voice Kit with help from our partner Raspberry Pi in May and sold out globally in just a few hours, we got the message loud and clear. There is a genuine demand among do-it-yourselfers for artificial intelligence that makes human-to-machine interaction more like natural human interaction.
Last week we announced the Speech Commands Dataset, a collaboration between the TensorFlow and AIY teams. The dataset has 65,000 one-second long utterances of 30 short words by thousands of different contributors of the AIY website and allows you to build simple voice interfaces for applications. We're currently in the process of integrating the dataset with the next release of the Voice Kit, so makers could build devices that respond to simple voice commands without the press of a button or an internet connection.
Today, you can pre-order your Voice Kit, which will be available for purchase in stores and online through Micro Center.
Or you may have to resort to the hack that maker Shivasiddarth created when Voice Kit with MagPi #57 sold out in May, and then again (within 17 minutes) earlier this month.
Martin Mander created a retro-inspired intercom that he calls 1986 Google Pi Intercom. He describes it as "a wall-mounted Google voice assistant using a Raspberry PI 3 and the Google AIY (Artificial Intelligence Yourself) [voice] kit." He used a mid-80s intercom that he bought on sale for £4. It cleaned up well!
Get the full story from Martin and see what Slashgear had to say about the project.
(This one's for Dr. Who fans) Tom Minnich created a Dalek-voiced assistant.
He offers a tutorial on how you can modify the Voice Kit to do something similar — perhaps create a Drogon-voiced assistant?
Victor Van Hee used the Voice Kit to create a voice-activated internet streaming radio that can play other types of audio files as well. He provides instructions, so you can do the same.
The Voice Kit is currently available in the U.S. We'll be expanding globally by the end of this year. Stay tuned here, where we'll share the latest updates. The strong demand for the Voice Kit drives us to keep the momentum going on AIY Projects.
What we build next will include vision and motion detection and will go hand in hand with our existing Voice Kit. AIY Project kits will soon offer makers the "eyes," "ears," "voice" and sense of "balance" to allow simple yet powerful device interfaces.
We'd love to bake your input into our next releases. Go to hackster.io or leave a comment to start up a conversation with us. Show us and the maker community what you're working on by using hashtag #AIYprojects on social media.
Automatic speech recognition (ASR) has seen widespread adoption due to the recent proliferation of virtual personal assistants and advances in word recognition accuracy from the application of deep learning algorithms. Many speech recognition teams rely on Kaldi, a popular open-source speech recognition toolkit. We're announcing today that Kaldi now offers TensorFlow integration.
With this integration, speech recognition researchers and developers using Kaldi will be able to use TensorFlow to explore and deploy deep learning models in their Kaldi speech recognition pipelines. This will allow the Kaldi community to build even better and more powerful ASR systems as well as providing TensorFlow users with a path to explore ASR while drawing upon the experience of the large community of Kaldi developers.
Building an ASR system that can understand human speech in every language, accent, environment, and type of conversation is an extremely complex undertaking. A traditional ASR system can be seen as a processing pipeline with many separate modules, where each module operates on the output from the previous one. Raw audio data enters the pipeline at one end and a transcription of recognized speech emerges from the other. In the case of Kaldi, these ASR transcriptions are post processed in a variety of ways to support an increasing array of end-user applications.
Yishay Carmiel and Hainan Xu of Seattle-based IntelligentWire, who led the development of the integration between Kaldi and TensorFlow with support from the two teams, know this complexity first-hand. Their company has developed cloud software to bridge the gap between live phone conversations and business applications. Their goal is to let businesses analyze and act on the contents of the thousands of conversations their representatives have with customers in real-time and automatically handle tasks like data entry or responding to requests. IntelligentWire is currently focused on the contact center market, in which more than 22 million agents throughout the world spend 50 billion hours a year on the phone and about 25 billion hours interfacing with and operating various business applications.
For an ASR system to be useful in this context, it must not only deliver an accurate transcription but do so with very low latency in a way that can be scaled to support many thousands of concurrent conversations efficiently. In situations like this, recent advances in deep learning can help push technical limits, and TensorFlow can be very useful.
In the last few years, deep neural networks have been used to replace many existing ASR modules, resulting in significant gains in word recognition accuracy. These deep learning models typically require processing vast amounts of data at scale, which TensorFlow simplifies. However, several major challenges must still be overcome when developing production-grade ASR systems:
One of the ASR system modules that exemplifies these challenges is the language model. Language models are a key part of most state-of-the-art ASR systems; they provide linguistic context that helps predict the proper sequence of words and distinguish between words that sound similar. With recent machine learning breakthroughs, speech recognition developers are now using language models based on deep learning, known as neural language models. In particular, recurrent neural language models have shown superior results over classic statistical approaches.
However, the training and deployment of neural language models is complicated and highly time-consuming. For IntelligentWire, the integration of TensorFlow into Kaldi has reduced the ASR development cycle by an order of magnitude. If a language model already exists in TensorFlow, then going from model to proof of concept can take days rather than weeks; for new models, the development time can be reduced from months to weeks. Deploying new TensorFlow models into production Kaldi pipelines is straightforward as well, providing big gains for anyone working directly with Kaldi as well as the promise of more intelligent ASR systems for everyone in the future.
Similarly, this integration provides TensorFlow developers with easy access to a robust ASR platform and the ability to incorporate existing speech processing pipelines, such as Kaldi's powerful acoustic model, into their machine learning applications. Kaldi modules that feed the training of a TensorFlow deep learning model can be swapped cleanly, facilitating exploration, and the same pipeline that is used in production can be reused to evaluate the quality of the model.
We hope this Kaldi-TensorFlow integration will bring these two vibrant open-source communities closer together and support a wide variety of new speech-based products and related research breakthroughs. To get started using Kaldi with TensorFlow, please check out the Kaldi repo and also take a look at an example for Kaldi setup running with TensorFlow.
Whether it's opening night for a Broadway musical or launch day for your app, both are thrilling times for everyone involved. Our agency, Posse, collaborated with Hamilton to design, build, and launch the official Hamilton app... in only three short months.
We decided to use Firebase, Google's mobile development platform, for our backend and infrastructure, while we used Flutter, a new UI toolkit for iOS and Android, for our front-end. In this post, we share how we did it.
We love to spend time designing beautiful UIs, testing new interactions, and iterating with clients, and we don't want to be distracted by setting up and maintaining servers. To stay focused on the app and our users, we implemented a full serverless architecture and made heavy use of Firebase.
A key feature of the app is the ticket lottery, which offers fans a chance to get tickets to the constantly sold-out Hamilton show. We used Cloud Functions for Firebase, and a data flow architecture we learned about at Google I/O, to coordinate the lottery workflow between the mobile app, custom business logic, and partner services.
For example, when someone enters the lottery, the app first writes data to specific nodes in Realtime Database and the database's security rules help to ensure that the data is valid. The write triggers a Cloud Function, which runs business logic and stores its result to a new node in the Realtime Database. The newly written result data is then pushed automatically to the app.
Because of Hamilton's intense fan following, we wanted to make sure that app users could get news the instant it was published. So we built a custom, web-based Content Management System (CMS) for the Hamilton team that used Firebase Realtime Database to store and retrieve data. The Realtime Database eliminated the need for a "pull to refresh" feature of the app. When new content is published via the CMS, the update is stored in Firebase Realtime Database and every app user automatically sees the update. No refresh, reload, or pull required!
Besides powering our lottery integration, Cloud Functions was also extremely valuable in the creation of user profiles, sending push notifications, and our #HamCam — a custom Hamilton selfie and photo-taking experience. Cloud Functions resized the images, saved them in Cloud Storage, and then updated the database. By taking care of the infrastructure work of storing and managing the photos, Firebase freed us up to focus on making the camera fun and full of Hamilton style.
With only three months to design and deliver the app, we knew we needed to iterate quickly on the UX and UI. Flutter's hot reload development cycle meant we could make a change in our UI code and, in about a second, see the change reflected on our simulators and phones. No rebuilding, recompiling, or multi-second pauses required! Even the state of the app was preserved between hot reloads, making it very fast for us to iterate on the UI with our designers.
We used Flutter's reactive UI framework to implement Hamilton's iconic brand with custom UI elements. Flutter's "everything is a widget" approach made it easy for us to compose custom UIs from a rich set of building blocks provided by the framework. And, because Flutter runs on both iOS and Android, we were able to spend our time creating beautiful designs instead of porting the UI.
The FlutterFire project helped us access Firebase Analytics, Firebase Authentication, and Realtime Database from the app code. And because Flutter is open source, and easy to extend, we even built a custom router library that helped us organize the app's UI code.
We enjoyed building the Hamilton app (find it on the Play Store or the App Store) in a way that allowed us to focus on our users and experiment with new app ideas and experiences. And based on our experience, we'd happily recommend serverless architectures with Firebase and customized UI designs with Flutter as powerful ways for you to save time building your app.
For us, we already have plans how to continue and develop Hamilton app in new ways, and can't wait to release those soon!
If you want to learn more about Firebase or Flutter, we recommend the Firebase docs, the Firebase channel on YouTube, and the Flutter website.
