soukai-solid
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This library allows you to store and read data from a Solid POD using Soukai. Before going into Solid specifics, you should be familiar with Soukai basics so make sure to read the Soukai documentation first.

There are two extensions to the core Soukai library, a Solid engine and a some Solid models (with their respective relationships). To get started, you can install both packages as npm dependencies:

npm install soukai soukai-solid

Managing the authentication is outside the scope of this package, so you'll need to provide a fetch method to perform network requests. If you want to learn how to handle authentication, you can check out this simple application: Ramen.

To get started, initialize the engine and make sure to call bootSolidModels to boot models that are provided by this library:

import { bootSolidModels, SolidEngine, SolidModel } from 'soukai-solid';
import { bootModels, setEngine } from 'soukai';

class Person extends SolidModel {}

bootSolidModels();
bootModels({ Person });

// If you want to make authenticated requests, you should pass the fetch method from an authentication library.
setEngine(new SolidEngine());

// You would normally get the url dynamically, we're hard-coding it here as an example.
Person.at('https://example.org/people/').create({ name: 'John Doe' });

Warning This example is just illustrative to get you started; in a real application you would define static properties in the Person model to configure the mapping to RDF. You can read the rest of this documentation to learn how.

Solid Models vs Solid Documents

Soukai is a library designed to work with document databases using the Active Record pattern. This usually means that a Soukai model maps to a database document, and documents are stored within collections in the database.

In Solid, however, things work a little different. A Solid container is the equivalent of a collection, but Solid documents don't map directly to Soukai models. Instead, Soukai models represent RDF resources. This is an irrelevant distinction when a Solid document only contains a single RDF resource, but that's rarely the case. Proper RDF modeling often results in documents containing information about multiple resources.

All of this complexity is dealt with under the hood, but it is important to be aware of the distinction. There are also some practical implications that you'll see in the following sections dealing with collections. Internally, SolidModel is serialized to a JSON-LD graph and different models can end up modifying the same document.

The way that models are stored in documents can be configured with relations, and there are some methods to get document information. getDocumentUrl() returns the document url inferred from the resource id, whilst getSourceDocumentUrl() returns the document url where the resource is actually stored. Most of the time, both should be the same document, but there is nothing in Solid that prevents doing otherwise.

Defining Solid Models

All standard model definition rules apply, with some extra things to keep in mind.

Primary keys

By default, the attribute that serves as the primary key for a SolidModel is url instead of id. As its name suggests, this is the url of the RDF resource that represents the model.

Collections

The concept of collections in Solid is represented with Solid containers. Given the dynamic nature of Solid, collection names should not be hard-coded in the model class. Instead, they will be inferred from the model url. Since the url of a model is not always available, there are a couple of helper methods in the SolidModel class to make this easier.

You can use both from and at, which are only syntactic sugar to set the static collection property of a model at runtime:

// This is something you would obtain at runtime from other models or libraries.
const containerUrl = 'https://example.org/people/';

// Get persons from the container.
const persons = await Person.from(containerUrl).all();

// Create a new person in the container.
const person = await Person.at(containerUrl).create({ name: 'Amy Doe' });

The find, delete and save methods infer the container url from the model url, so calling from or at is not necessary. However, the save method accepts the container url as a first argument. This can be ignored if the model url has been minted before by calling mintUrl or setting the url attribute:

const person = new Person({ name: 'Amy Doe' });

// You can either do this...
await person.save('https://example.org/people/');

// or this...
person.mintUrl('https://example.org/people/amy');

await person.save();

// or this.
person.url = 'https://example.org/people/amy#it';

await person.save();

RDF definitions

When working with Solid entities, there are a couple of things that have to be defined for a model to be serialized properly as an RDF resource.

You can indicate the resource types using the rdfsClasses static property (these will be serialized as http://www.w3.org/1999/02/22-rdf-syntax-ns#type RDF properties).

Property names can be defined using the rdfProperty key within the field definition.

Here's an example illustrating both:

class Person extends SolidModel {

    static rdfsClasses = ['http://xmlns.com/foaf/0.1/Person'];

    static fields = {
        name: {
            type: FieldType.String,
            rdfProperty: 'http://xmlns.com/foaf/0.1/name',
        },
    };

}

Doing this all the time can become cumbersome, given that the same namespaces will probably be used multiple times. You can define reusable prefixes using the rdfContexts static property.

Here's a definition equivalent to the previous snippet:

class Person extends SolidModel {

    static rdfContexts = {
        'foaf': 'http://xmlns.com/foaf/0.1/',
    };

    static rdfsClasses = ['foaf:Person'];

    static fields = {
        name: {
            type: FieldType.String,
            rdfProperty: 'foaf:name',
        },
    };

}

As we've seen in the first example, those properties are optional. Here's their default values:

  • rdfContexts has the following prefixes included out of the box. If you define your own, these will be merged and not overridden:

    Prefix Url
    solid http://www.w3.org/ns/solid/terms#
    rdfs http://www.w3.org/2000/01/rdf-schema#
    rdf http://www.w3.org/1999/02/22-rdf-syntax-ns#
    ldp http://www.w3.org/ns/ldp#
    purl http://purl.org/dc/terms/
  • rdfsClasses is an empty array by default, but this should rarely be left empty for proper RDF modeling. Values that are not urls or short-hand definitions using contexts will use the default context (the first one defined in rdfContexts).

  • rdfProperty within field definitions will use the field name with the default context (the first one defined in rdfContexts).

The Person class we defined before can be defined more concisely like this:

class Person extends SolidModel {

    static rdfContexts = {
        // This will be the default context, because it is defined first.
        'foaf': 'http://xmlns.com/foaf/0.1/',
    };

    // Because "Person" is not a url or short-hand definition using contexts,
    // the default context will be used. This will be interpreted as "foaf:Person".
    static rdfsClasses = ['Person'];

    static fields = {
        // Because "foaf" is the default context and "name" is the name of the field,
        // the rdfProperty will be interpreted as "foaf:name".
        name: FieldType.String,
    };

}

And if you're using TypeScript, you can use the defineSolidModelSchema method to take advantage of TypeScript inference.

There is also a SolidContainer class that should be used to declare container models. In addition to everything from a SolidModel, it has the following built-in definitions:

  • The rdfsClasses array contains the ldp:Container type, it'll be merged with definitions in the model. So it actually makes sense to leave rdfsClasses undefined for container models.
  • The resourceUrls field is defined as an array mapped from the ldp:contains RDF property.
  • The relationship documents is defined as a belongsToMany relation with SolidDocument models, using the resourceUrls property as the foreign key. It also provides a special contains multi-model relationship (read more about relationships below).
  • Minted urls will use the name field if it exists to generate a slug instead of a UUID, and they won't use a hash at the end (read more about url minting below).

Url minting

The default behavior when creating new models is that the url will be minted in the client side, using the container url and generating a UUID. It will also add a hash at the end which can be configured defining the defaultResourceHash static property in the model (it'll be defined as "it" by default).

If the model is a SolidContainer and has a name attribute, this will be used to create a slug instead. Container models don't use a hash in the url and end with a trailing slash.

Url minting is useful in order to perform operations with a new model before the server request has been resolved, but it can be disabled by setting the mintsUrls property to false. You can also mint it manually calling the mintUrl method or setting the url attribute:

class Person extends SolidModel {
    static mintsUrls = false;
}

// You can do this...
const person = new Person({ name: 'Amy Doe' });

person.mintUrl();

await person.save();

// Or you could set the url yourself.
const person = new Person({
    url: 'http://example.org/amy#it',
    name: 'Amy Doe',
});

await person.save();

Warning Keep in mind that disabling this may break some relationships' initialization, when they rely on foreign keys existing. If you're disabling this and you're using such relationships, make sure to always provide an url when you're creating models.

Relations

In addition to the relations included with the core library, other relations are provided in this package and some are extended with more functionality.

hasMany

This relation comes with some helper methods.

create, save and attach can be used to associate models, setting foreign keys. Models that are stored in the same document of a related model will be saved automatically when the parent model (the one who defines the relationship) is created if it didn't exist before. This can be configured with the usingSameDocument method.

When related models are stored in the same document, the hash of those models will be a UUID instead of the one defined in their defaultResourceHash static property.

For example, let's say that we want to model a Music Band with all their members, and we want to store all the RDF resources in the same document:

class Band extends SolidModel {

    static rdfContexts = {
        'schema': 'https://schema.org/',
    };

    static rdfsClasses = ['MusicGroup'];

    static fields = {
        name: FieldType.String,
    };

    membersRelationship() {
        return this.hasMany(Person, 'bandUrl').usingSameDocument(true);
    }

}
class Person extends SolidModel {

    static rdfContexts = {
        'schema': 'https://schema.org/',
    };

    static rdfsClasses = ['Person'];

    static fields = {
        name: FieldType.String,
        bandUrl: {
            type: FieldType.Key,
            rdfProperty: 'schema:memberOf',
        },
    };

}

And here's an example using those models:

const acdc = await Band.find('https://example.org/bands/ac-dc');

// You can create the model yourself, and it'll be stored when the parent is saved.
acdc.relatedMembers.attach(new Person({ name: 'Bon Scott' }));

await acdc.save();

// Or you can use the create method.
// Notice how we're not specifying the bandUrl in either scenario.
await acdc.relatedMembers.create({ name: 'Angus Young' });

Note Given the nature of Solid, related models defined with hasMany will only be loaded if they can be found in the same document as the parent model (the one who defines the relationship). This also works if the foreign key is the only attribute found in the document.

contains and isContainedBy

There is a couple of relationships that are helpful to work with Solid containers: contains and isContainedBy.

Here's an example:

class MoviesContainer extends SolidModel {

    static fields = {
        name: {
            type: FieldType.String,
            rdfProperty: 'rdfs:label',
        },
    };

    moviesRelationship() {
        return this.contains(Movie);
    }

}
class Movie extends SolidModel {

    static rdfContexts = {
        'schema': 'https://schema.org/',
    };

    static rdfsClasses = ['Movie'];

    static fields = {
        title: {
            type: FieldType.String,
            rdfProperty: 'schema:name',
        },
    };

    moviesContainerRelationship() {
        return this.isContainedBy(MoviesContainer);
    }

}

These methods don't take foreign and local keys because they rely on the url of the models to resolve collections and model ids.

Automatic Timestamps

Declaring automatic timestamps works the same way as in the core library, but there are some important differences to keep in mind.

Initially, timestamps were declared as model fields and would produce the following RDF on serialization:

@prefix foaf: <http://xmlns.com/foaf/0.1/>.
@prefix terms: <http://purl.org/dc/terms/>.
@prefix xsd: <http://www.w3.org/2001/XMLSchema#>.

<#it>
    a foaf:Person ;
    foaf:name "Alice" ;
    terms:created "2021-01-30T11:47:24Z"^^xsd:dateTime ;
    terms:modified "2021-01-30T11:47:24Z"^^xsd:dateTime .

This is, however, incorrect. The RDF above implies that the person "Alice" was created on January 2021. Instead, what has been created on January 2021 is this record in the Solid POD.

Because of this, timestamps are now declared as fields in a separate Metadata model, which is accessible through the built-in metadata relationship. You can still use setters and getters in the main model, but keep in mind that it's just syntactic sugar but they are different models under the hood.

This is the RDF that will be generated:

@prefix foaf: <http://xmlns.com/foaf/0.1/>.
@prefix crdt: <https://vocab.noeldemartin.com/crdt/>.
@prefix xsd: <http://www.w3.org/2001/XMLSchema#>.

<#it>
    a foaf:Person ;
    foaf:name "Alice" .

<#it-metadata>
    a crdt:Metadata ;
    crdt:resource <#it> ;
    crdt:createdAt "2021-01-30T11:47:24Z"^^xsd:dateTime ;
    crdt:updatedAt "2021-01-30T11:47:24Z"^^xsd:dateTime .

History Tracking

In some situations, it is desirable to keep track of changes made to a model over time. History tracking is disabled by default, but you can enable it in the model declaration:

class Person extends SolidModel {

    static history = true;

}

Once this is enabled, any changes that are made to the model will create new operations using the built-in operations relationship:

const alice = await Person.create({ name: 'Alice' });

await alice.update({ name: 'Alice Doe' });

console.log(alice.operations.length);
// console output: 2

The code above will generate the following operations:

  • Set name to "Alice"
  • Set name to "Alice Doe"

This is a trivial example, but this allows implementing a crude CRDT mechanism that uses the Solid POD as mediator. This can be demonstrated by creating two instances of a model, updating them separately, and synchronizing them afterwards using the synchronize method.

There are also other use-cases supported, such as soft-deletes (marking a resource as deleted even though it still exists), and tombstones (leaving a crdt:Tombstone resource behind instead of deleting the entire document).

Due to the complexity and experimental nature of the feature though, this documentation is brief on purpose. It will be documented further in the future, but for now if you're interested you can learn more from the following resources:

  • CRDTs for Mortals (20min talk introducing CRDTs).
  • Local-first software (Technical article explaining CRDTs motivations and use-cases).
  • Umai (An offline-first application using Soukai Solid to synchronize changes across devices).

Authorization

In order to manage documents' permissions, you can take advantage of the built-in authorizations relationship. There are also some helpers such as the isPublic and isPrivate getters; and the fetchPublicPermissions and updatePublicPermissions methods.

At the moment, authorization support is limited to WAC resources.

Interoperability

In order to improve interoperability between apps, you can make use of Type Indexes. There are some utilities built in the library to read and write type registrations:

// Read containers and documents registered in the type index
const movieContainers = await SolidContainer.fromTypeIndex(typeIndexUrl, Movie);
const movieDocuments = await SolidDocument.fromTypeIndex(typeIndexUrl, Movie);

// Register documents in the type index
await movie.registerInTypeIndex(typeIndexUrl);

// Register containers in the type index
const movies = new SolidContainer({ url: moviesContainerUrl });

await movies.register(typeIndexUrl, Movie);

You should be able to obtain the typeIndexUrl from user profiles, and in case they don't exist you can create them as well:

await SolidTypeIndex.createPublic(userProfile);
await SolidTypeIndex.createPrivate(userProfile);

You can obtain the user profile using fetchLoginUserProfile from @noeldemartin/solid-utils.

Caveats and limitations

Given the nature of Solid and RDF, there are some things that don't work the same way as the core library:

  • null and undefined attributes will be treated the same way (casted to undefined).
  • In array fields, an empty array will also be treated the same way as null and undefined (casted to an empty array).
  • FieldType.Object cannot be used (use relationships instead), neither can nested FieldType.Array.
  • Arrays cannot have duplicated entries.

Going Further

If you want to see more examples, you can find some models defined under src/testing/lib/stubs and files ending with .test.ts throughout the source code.

If you want to see some real-life application using this library, check out one of these:

/soukai-solid/

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