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@fluidframework/aqueduct
Advanced tools
The Aqueduct is a library for building Fluid objects and Fluid containers within the Fluid Framework. Its goal is to provide a thin base layer over the existing Fluid Framework interfaces that allows developers to get started quickly.
Fluid object development consists of developing the data object and the corresponding data object factory. The data object defines the logic of your Fluid object, whereas the data object factory defines how to initialize your object.
DataObject
and PureDataObject
are the two base classes provided by the library.
DataObject
The DataObject
class extends PureDataObject
and provides the following additional functionality:
root
SharedDirectory that makes creating and storing distributed data structures and objects easy.Note: Most developers will want to use the
DataObject
as their base class to extend.
PureDataObject
PureDataObject
provides the following functionality:
initializingFirstTime(props: S)
- called only the first time a Fluid object is initialized and only on the first client on which it loads.initializingFromExisting()
- called every time except the first time a Fluid object is initialized; that is, every time an instance is loaded from a previously created instance.hasInitialized()
- called every time after initializingFirstTime
or initializingFromExisting
executesNote: You probably don't want to inherit from this data object directly unless you are creating another base data object class. If you have a data object that doesn't use dDistributed data structures you should use Container Services to manage your object.
In the below example we have a simple data object, Clicker, that will render a value alongside a button the the page. Every time the button is pressed the value will increment. Because this data object renders to the DOM it also extends IFluidHTMLView
.
export class Clicker extends DataObject implements IFluidHTMLView {
public static get Name() { return "clicker"; }
public get IFluidHTMLView() { return this; }
private _counter: SharedCounter | undefined;
protected async initializingFirstTime() {
const counter = SharedCounter.create(this.runtime);
this.root.set("clicks", counter.handle);
}
protected async hasInitialized() {
const counterHandle = this.root.get<IFluidHandle<SharedCounter>>("clicks");
this._counter = await counterHandle.get();
}
public render(div: HTMLElement) {
ReactDOM.render(
<CounterReactView counter={this.counter} />,
div,
);
return div;
}
private get counter() {
if (this._counter === undefined) {
throw new Error("SharedCounter not initialized");
}
return this._counter;
}
}
The DataObjectFactory
is used to create a Fluid object and to initialize a data object within the context of a Container. The factory can live alongside a data object or within a different package. The DataObjectFactory
defines the distributed data structures used within the data object as well as any Fluid objects it depends on.
The Aqueduct offers a factory for each of the data objects provided.
In the below example we build a DataObjectFactory
for the Clicker
example above. In the above example we use this.root
to store our "clicks"
. The DataObject
comes with the SharedDirectory
already initialized so we do not need to add additional distributed data structures.
export const ClickerInstantiationFactory = new DataObjectFactory(
Clicker.Name,
Clicker,
[SharedCounter.getFactory()], // distributed data structures
{}, // Provider Symbols see below
);
This factory can then create Clickers when provided a creating instance context.
const myClicker = ClickerInstantiationFactory.createInstance(this.context) as Clicker;
The this.providers
object on PureDataObject
is initialized in the constructor and is generated based on Providers provided by the Container. To access a specific provider you need to:
PureDataObject
/DataObject
In the below example we have an IFluidUserInfo
interface that looks like this:
interface IFluidUserInfo {
readonly userCount: number;
}
On our example we want to declare that we want the IFluidUserInfo
Provider and get the userCount
if the Container provides the IFluidUserInfo
provider.
export class MyExample extends DataObject<IFluidUserInfo> {
protected async initializingFirstTime() {
const userInfo = await this.providers.IFluidUserInfo;
if(userInfo) {
console.log(userInfo.userCount);
}
}
}
// Note: we have to define the symbol to the IFluidUserInfo that we declared above. This is compile time checked.
export const ClickerInstantiationFactory = new DataObjectFactory(
Clicker.Name
Clicker,
[], // distributed data structures
{IFluidUserInfo}, // Provider Symbols see below
);
A Container is a collection of data objects and functionality that produce an experience. Containers hold the instances of data objects as well as defining the data objects that can be created within the Container. Because of this data objects cannot be consumed except for when they are within a Container.
The Aqueduct library provides the ContainerRuntimeFactoryWithDataStore
that enables you as a container developer to:
In the below example we will write a Container that exposes the above Clicker
using the Clicker Factory
. You will notice below that the Container developer defines the registry name (data object type) of the Fluid object. We also pass in the type of data object we want to be the default. The default data object is created the first time the Container is created.
export fluidExport = new ContainerRuntimeFactoryWithDataStore(
ClickerInstantiationFactory.type, // Default data object type
ClickerInstantiationFactory.registryEntry, // Fluid object registry
[], // Provider Entries
[], // Request Handler Routes
);
The container developer can optionally provide a registry of ProviderEntry objects into the container. A ProviderEntry is defined as follows:
interface ProviderEntry<T extends keyof IFluidObject> {
type: T;
provider: FluidProvider<T>
}
The type
must be a keyof IFluidObject
. This basically means that it needs to be the name of an interfaces that extends off of IFluidObject
. The provider
must be something that provides the interface defined in type
. The DependencyContainer
we use in the @fluidframework/synthesize
package defines the following FluidObjectProvider
types:
type FluidObjectProvider<T extends keyof IFluidObject> =
IFluidObject[T]
| Promise<IFluidObject[T]>
| ((dependencyContainer: DependencyContainer) => IFluidObject[T])
| ((dependencyContainer: DependencyContainer) => Promise<IFluidObject[T]>);
IFluidObject[T]
An object that implements the interface.
Promise<IFluidObject[T]>
A Promise to an object that implements the interface
(dependencyContainer: DependencyContainer) => IFluidObject[T]
A factory that will return the object.
(dependencyContainer: DependencyContainer) => Promise<IFluidObject[T]>
A factory that will return a Promise to the object.
You can provide custom request handlers to the container. These request handlers are injected after system handlers but before the DataObject
get function. Request handlers allow you to intercept requests made to the container and return custom responses.
Consider a scenario where you want to create a random color generator. I could create a RequestHandler that when someone makes a request to the Container for {url:"color"}
will intercept and return a custom IResponse
of { status:200, type:"text/plain", value:"blue"}
.
We use custom handlers to build the Container Services pattern.
FAQs
A set of implementations for Fluid Framework interfaces.
The npm package @fluidframework/aqueduct receives a total of 5,106 weekly downloads. As such, @fluidframework/aqueduct popularity was classified as popular.
We found that @fluidframework/aqueduct demonstrated a healthy version release cadence and project activity because the last version was released less than a year ago. It has 0 open source maintainers collaborating on the project.
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