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ember-orbit (or "EO") is a library that integrates orbit.js with ember.js to provide flexibility and control in your application's data layer.

Highlights

Relationship to Orbit

EO provides a thin "Emberified" layer over the top of some core primitives from Orbit, including Store, Cache, and Model classes. Most common developer interactions with Orbit will be through these classes.

EO does not attempt to wrap every base class from Orbit. For instance, you'll need to use Orbit's Coordinator and coordination strategies to define relationships between Orbit sources. In this way, you can install any Orbit Source or Bucket library and wire them together in your EO application.

Important: It's strongly recommended that you read the Orbit guides at orbitjs.com before using EO, since an understanding of Orbit is vital to making the most of EO.

Compatibility

Status

EO obeys semver and thus should not be considered to have a stable API until 1.0. Until then, any breaking changes in APIs or Orbit dependencies should be accompanied by a minor version bump of EO.

Demo

todomvc-ember-orbit is a simple TodoMVC example that uses EO to illustrate a number of possible configurations and application patterns.

Installation

Install EO in your project with:

ember install ember-orbit

The generators for orbit sources and buckets will attempt to install any additional orbit-related dependencies.

Usage

EO creates the following directories by default:

Note that "factories" are simply objects with a create method that serves to instantiate an object. The factory interface conforms with the expectations of Ember's DI system.

EO installs the following services by default:

All the directories and services configured by EO can be customized for your app, as described in the "Customizing EO" section below.

Defining models

Models are used to access the underlying data in an EO Store. They provide a proxy to get and set attributes and relationships. In addition, models are used to define the schema that's shared by the sources in your Orbit application.

The easiest way to create a Model class is with the data-model generator:

ember g data-model planet

This will create the following module in app/data-models/planet.js:

import { Model } from 'ember-orbit';

export default class Planet extends Model {}

You can then extend your model to include keys, attributes, and relationships:

import { Model, attr, hasOne, hasMany, key } from 'ember-orbit';

export default class Planet extends Model {
  @key() remoteId;
  @attr('string') name;
  @hasMany('moon', { inverse: 'planet' }) moons;
  @hasOne('star') sun;
}

You can create polymorphic relationships by passing in an array of types:

import { Model, attr, hasOne, hasMany } from 'ember-orbit';

export default class PlanetarySystem extends Model {
  @attr('string') name;
  @hasMany(['moon', 'planet']) bodies;
  @hasOne(['star', 'binaryStar']) star;
}

Stores and Caches

EO's Store class is a thin wrapper around Orbit's MemorySource, while EO's Cache class wraps Orbit's MemoryCache. The difference between memory sources and caches is explained extensively in Orbit's docs.

The essential difference between EO's Store and Cache and the underlying Orbit classes is that EO is model-aware. Unlike plain Orbit, in which results are returned as static POJOS, every query and update result in EO is translated into Model instances, or simply "records". When changes occur to the underlying Orbit sources and caches, they will be reflected immediately in EO's records.

Every EO record is connected to a cache, which in turn belongs to a store. When stores or caches provide results in the form of records, they are always instantiated by, and belong to, a Cache. For a given identity (type / id pair), there is only ever one record instance per cache. These are maintained in what is fittingly called an "identity map".

Records, including all their attributes and relationships, will stay in sync with the underlying data in their associated cache.

Querying Data

There are three primary methods available to query records:

All of these query methods take the same arguments as any other queryable Orbit source - see the Orbit guides for details.

The following liveQuery immediately returns a live resultset that will stay updated with the "terrestrial" planets in the store:

let planets = store.cache.liveQuery((qb) =>
  qb
    .findRecords('planet')
    .filter({ attribute: 'classification', value: 'terrestrial' })
);

The EO Store also supports findRecord and findRecords methods. These methods are async and call query internally:

// find all records of a type
let planets = await store.findRecords('planet');

// find a specific record by type and id
let planet = await store.findRecord('planet', 'abc123');

These methods are also available on the EO Cache, but are synchronous:

// find all records of a type
let planets = store.cache.findRecords('planet');

// find a specific record by type and id
let planet = store.cache.findRecord('planet', 'abc123');

Updating Data

There are two primary approaches to update data in EO:

Direct Updates to the Store

The Store exposes several async methods to update data:

Here are some examples of each:

// add a new record (returned as a Model instance)
let planet = await store.addRecord({ type: 'planet', id: '1', name: 'Earth' });
console.log(planet.name); // Earth

// update one or more fields of the record
await store.updateRecord({ type: 'planet', id: '1', name: 'Mother Earth' });
console.log(planet.name); // Mother Earth

// remove the record
await store.removeRecord({ type: 'planet', id: '1' });
// or alternatively: await store.removeRecord(planet);

// add more planets in a single `Transform`
let [mars, venus] = await store.update((t) => [
  t.addRecord({ type: 'planet', name: 'Mars' }),
  t.addRecord({ type: 'planet', name: 'Venus' })
]);

Updates via Forking / Merging

EO stores can be forked and merged, just as described in the Orbit guides.

Once you have forked a store, you can proceed to make synchronous changes to the fork's associated Cache and/or Model instances. These changes will be tracked and can then be merged back to the base store.

Here's an example:

  // (async) start by adding two planets and a moon to the store
  await store.update(t => [
    t.addRecord(earth),
    t.addRecord(venus),
    t.addRecord(theMoon)
  ]);

  // (async) query the planets in the store
  let planets = await store.query(q => q.findRecords('planet').sort('name')));
  console.log('original planets', planets);

  // (sync) fork the store
  forkedStore = store.fork();
  let forkedCache = forkedStore.cache;

  // (sync) add a planet and moons to the fork's cache
  forkedCache.update(t => [
    t.addRecord(jupiter),
    t.addRecord(io),
    t.addRecord(europa)
  ]);

  // (sync) query the planets in the forked cache
  planets = forkedCache.query(q => q.findRecords('planet').sort('name')));
  console.log('planets in fork', planets);

  // (async) merge the forked store back into the original store
  await store.merge(forkedStore);

  // (async) query the planets in the original store
  planets = await store.query(q => q.findRecords('planet').sort('name')));
  console.log('merged planets', planets);

Some notes about forking / merging:

Important - One additional concern to be aware of is that EO will generate new records for each store. Care should be taken to not mix records between stores, since the underlying data in each store can diverge. If you need to access a record in a store's fork, just query the forked store or cache for that record.

Sync Updates via the Cache

The Cache exposes sync versions of the Store's async update methods:

By default, only forked caches are able to be updated directly. This provides protection against data loss, since changes to caches do not participate in Orbit's data flows. An exception is made for forks because the changes are tracked and applied back to stores via merge.

If you want to override these protections and update a non-forked cache, you can set cache.allowUpdates = true, but know that those updates won't leave the cache.

Sync Updates via Model instances

Each Model exposes all of its fields, including attributes and relationships, as properties that stay updated.

Attributes and has-one relationships are also directly editable. For instance:

let jupiter = forkedCache.findRecord('planet', 'jupiter');
let sun = forkedCache.findRecord('star', 'theSun');

console.log(jupiter.name); // 'Jupiter'

// update attribute
jupiter.name = 'Jupiter!';
console.log(jupiter.name); // 'Jupiter!'

// update has-one relationship
jupiter.sun = theSun;

In order to not conflict with user-defined fields, all standard methods on Model are prefixed with a $. The following synchronous methods are available:

let jupiter = forkedCache.findRecord('planet', 'jupiter');
let io = forkedCache.findRecord('moon', 'io');
let europa = forkedCache.findRecord('moon', 'europa');
let sun = forkedCache.findRecord('star', 'theSun');

jupiter.$replaceAttribute('name', 'JUPITER!');
jupiter.$addToRelatedRecords('moons', io);
jupiter.$removeFromRelatedRecords('moons', europa);
jupiter.$replaceRelatedRecord('sun', sun);

console.log(jupiter.name); // 'JUPITER!'
console.log(jupiter.moons.includes(io)); // true
console.log(jupiter.moons.includes(europa)); // false
console.log(jupiter.sun.id); // 'theSun'

Behind the scenes, these changes each result in a call to forkedCache.update. Of course, this method could also be called directly instead of issuing updates through the model:

forkedCache.update((t) => [
  t.replaceAttribute(jupiter, 'name', 'JUPITER!');
  t.addToRelatedRecords(jupiter, 'moons', io);
  t.removeFromRelatedRecords(jupiter, 'moons', europa);
  t.replaceRelatedRecord(jupiter, 'sun', sun);
]);

Adding a "backup" source

The store's contents exist only in memory and will be cleared every time your app restarts. Let's try adding another source and use the dataCoordinator service to keep it in sync with the store.

We can use the data-source generator to create a backup source:

ember g data-source backup --from=@orbit/indexeddb

This will generate a source factory in app/data-sources/backup.js:

import SourceClass from '@orbit/indexeddb';
import { applyStandardSourceInjections } from 'ember-orbit';

export default {
  create(injections = {}) {
    applyStandardSourceInjections(injections);
    injections.name = 'backup';
    return new SourceClass(injections);
  }
};

Note that injections should include both a Schema and a KeyMap, which are injected by default for every EO application. We're also adding a name to uniquely identify the source within the coordinator. You could optionally specify a namespace to be used to name the IndexedDB database.

Every source that's defined in app/data-sources will be discovered automatically by EO and added to the dataCoordinator service.

Next let's define some strategies to synchronize data between sources.

Defining coordination strategies

There are four different types of coordination strategies that can be generated by default using the standard data-strategy generator:

Let's define a sync strategy to backup changes made to the store into our new backup source.

ember g data-strategy store-backup-sync --type=sync

This should create a SyncStrategy factory in app/data-strategies/store-backup-sync.js as follows:

import { SyncStrategy } from '@orbit/coordinator';

export default {
  create() {
    return new SyncStrategy({
      name: 'store-backup-sync',

      /**
       * The name of the source which will have its `transform` event observed.
       */
      source: 'store',

      /**
       * The name of the source which will be acted upon.
       *
       * When the source receives the `transform` event, the `sync` method
       * will be invoked on the target.
       */
      target: 'backup',

      /**
       * A handler for any errors thrown as a result of invoking `sync` on the
       * target.
       */
      // catch(e) {},

      /**
       * A filter function that returns `true` if `sync` should be performed.
       *
       * `filter` will be invoked in the context of this strategy (and thus will
       * have access to both `this.source` and `this.target`).
       */
      // filter(...args) {};

      /**
       * Should resolution of the target's `sync` block the completion of the
       * source's `transform`?
       *
       * Can be specified as a boolean or a function which which will be
       * invoked in the context of this strategy (and thus will have access to
       * both `this.source` and `this.target`).
       */
      blocking: true
    });
  }
};

You should also consider adding an event logging strategy to log events emitted from your sources to the browser console:

ember g data-strategy event-logging

Sources have another kind of log as well: a transform log, which tracks transforms that are applied. A log truncation strategy will keep the size of transform logs in check. It observes the sources associated with the strategy and truncates their transform logs when a common transform has been applied to them all. Let's add a log truncation strategy as well:

ember g data-strategy log-truncation

Activating the coordinator

Next we'll need to activate our coordinator as part of our app's boot process. The coordinator requires an explicit activation step because the process is async and we may want to allow developers to do work beforehand.

In our case, we want to restore our store from the backup source before we enable the coordinator. Let's do this in our application route's beforeModel hook (in app/routes/application.js):

import Route from '@ember/routing/route';
import { inject as service } from '@ember/service';

export default class ApplicationRoute extends Route {
  @service dataCoordinator;
  @service store;

  async beforeModel() {
    // Populate the store from backup prior to activating the coordinator
    const backup = this.dataCoordinator.getSource('backup');
    const records = await backup.query((q) => q.findRecords());
    await this.store.sync((t) => records.map((r) => t.addRecord(r)));

    await this.dataCoordinator.activate();
  }
}

This code first pulls all the records from backup and then syncs them with the main store before activating the coordinator. In this way, the coordination strategy that backs up the store won't be enabled until after the restore is complete.

Defining a data bucket

Data buckets are used by sources and key maps to load and persist state. You will probably want to use a bucket if you plan to support any offline or optimistic UX.

To create a new bucket, run the generator:

ember g data-bucket main

By default this will create a new bucket factory based on @orbit/indexeddb-bucket. It will also create an initializer that injects this bucket into all your sources and key maps.

Customizing EO

The types, collections, and services used by EO can all be customized for your application via settings under the orbit key in config/environment:

module.exports = function (environment) {
  let ENV = {
    // ... other settings here

    // Default Orbit settings (any of which can be overridden)
    orbit: {
      schemaVersion: undefined,
      types: {
        bucket: 'data-bucket',
        model: 'data-model',
        source: 'data-source',
        strategy: 'data-strategy'
      },
      collections: {
        buckets: 'data-buckets',
        models: 'data-models',
        sources: 'data-sources',
        strategies: 'data-strategies'
      },
      services: {
        store: 'store',
        bucket: 'data-bucket',
        coordinator: 'data-coordinator',
        schema: 'data-schema',
        keyMap: 'data-key-map',
        normalizer: 'data-normalizer',
        validator: 'data-validator'
      },
      skipStoreService: false,
      skipBucketService: false,
      skipCoordinatorService: false,
      skipSchemaService: false,
      skipKeyMapService: false,
      skipNormalizerService: false,
      skipValidatorService: false
    }
  };

  return ENV;
};

Note that schemaVersion should be set if you're using any Orbit sources, such as IndexedDBSource, that track schema version. By default, Orbit's schema version will start at 1. This value should be bumped to a a higher number with each significant change that requires a schema migration. Migrations themselves must be handled in each individual source.

Conditionally include strategies and sources

Sources and strategies may be conditionally included in your app's coordinator by customizing the default export of the source / strategy factory. A valid factory is an object with the interface { create: () => {} }. If a valid factory is not the default export for your module, it will be ignored.

For example, the following strategy will be conditionally included for all non-production builds:

// app/data-strategies/event-logging.js

import { EventLoggingStrategy } from '@orbit/coordinator';
import config from 'example/config/environment';

const factory = {
  create() {
    return new EventLoggingStrategy();
  }
};

// Conditionally include this strategy
export default config.environment !== 'production' ? factory : null;

Customizing validators

Like Orbit itself, EO enables validators by default in all sources. EO provides the same set of validators to all sources by building a single data-validator service that is injected into all sources.

Validators are useful to ensure that your data matches its type expectations and that operations and query expressions are well formed. Of course, they also add some extra code and processing, which you may want to eliminate (or perhaps only for production environments). You can disable validators across all sources by setting Orbit's skipValidatorService environment flag to false in config/environment, as described above.

If you want to use validators but extend them to include custom validators, you can override the standard validator service by generating your own data-validator service that passes custom arguments to buildRecordValidatorFor.

For instance, in order to provide a custom validator for an address type:

// app/services/data-validator.js

import { buildRecordValidatorFor } from '@orbit/records';

const validators = {
  address: (input) => {
    if (typeof input?.country !== 'string') {
      return [
        {
          validator: 'address',
          validation: 'country',
          description: 'is not a string',
          ref: input,
        },
      ];
    }
  },
};

export default {
  create() {
    return buildRecordValidatorFor({ validators });
  },
};

This custom validator service will be injected into all your orbit sources via applyStandardSourceInjections, as described above.

Contributing to EO

Installation

Running Tests

Acknowledgments

EO owes a great deal to Ember Data, which has influenced the design of many of EO's interfaces. Many thanks to the Ember Data Core Team, including Yehuda Katz, Tom Dale, and Igor Terzic, for their work.

It is hoped that, by tracking Ember Data's features and interfaces where possible, EO will also be able to contribute back to Ember Data.

License

Copyright 2014-2021 Cerebris Corporation. MIT License (see LICENSE for details).