client.md

Frontend Client

This document aims to describe the current LIT frontend system, including conventions, best practices, and gotchas.

High Level Overview

LIT is powered by two central pieces of tech - lit-element for components and HTML rendering, and mobx for observable-oriented state management.

Lit-element is a simple, web-component based library for building small, self-contained pieces of web functionality. It uses a template-string based output to declaratively render small, isolated pieces of UI.

Mobx is a tool centered around observable data, and it makes managing state simple and scalable.

We highly recommend reading the docs for both projects - they both have fairly simple APIs and are easy to digest in comparison to some heavier-weight toolkits like Angular.

LIT Application Architecture

The LIT client frontend is roughly divided into three conceptual groups - Modules (which render visualizations), Services (which manage data), and the App itself (which coordinates initialization of services and determines which modules to render).

Bootstrapping

The LIT app bootstrapping takes place in two steps: First, the served index.html page contains a single web component for the <lit-app>. This component is responsible for the overall layout of the app, including the toolbar, footer, and the <lit-modules> component. The <lit-modules> component is responsible for actually laying out and rendering the various LitModule components, a process about which we'll go into greater detail later.

The JS bundle entry point is main.ts, which first imports the loaded, the <lit-app> web component is declared, and attaches itself to the DOM, waiting for the app to be initialized.

The second step is kicking off app initialization. The LitApp singleton class is provided with a layout declaring which LitModule components to use, then builds the app services and kicks off app initialization and loading data.

Layout

A layout is defined by a structure of LitModule classes, and includes a set of main components that are always visible, (designated in the object by the "main" key) and a set of tabs that each contain a group other components.

A simplified version for a classifier model might look like:

const layout: LitComponentLayout = {
  components : {
    'Main': [DataTableModule, DatapointEditorModule],

    'Classifiers': [
      ConfusionMatrixModule,
    ],
    'Counterfactuals': [GeneratorModule],
    'Predictions': [
      ScalarModule,
      ClassificationModule,
    ],
    'Explanations': [
      ClassificationModule,
      SalienceMapModule,
      AttentionModule,
    ]
  }
};

The full layouts are defined in layout.ts. To use a specific layout for a given LIT instance, pass the key (e.g., "simple" or "mlm") in as a server flag when initializing LIT(--layout=<layout>). The layout can be set on-the-fly a URL param (the url param overrides the server flag).

The actual layout of components in <lit-modules> can be different than the simple declared layout, since the visibility of modules depends on a number of factors, including the user-chosen visibility and whether or not specific modules show multiple copies per selected model. This actual layout is computed in modules_service.

Initialization

Finally, the LIT App initializes by building the various service classes and starting the initial load of data from the server. This process consists of:

1. Parsing the URL query params to get the url configuration
2. Fetching the app metadata, which includes what models/datasets are available to use.
3. Determining which models/datasets to load and then loding them.

LIT Modules

The LitModule is the base class from which all module components derive. It provides a number of convenience methods for handling common update / data loading patterns. Each LIT Module also requires a few static methods by convention, responsible for specifying Module display and behavior. These helpers and conventions are outlined below:

/**
 * A dummy module that responds to changes in selected data by making a request
 * to an API service to get the pig latin translation.
 */
@customElement('demo-module')                                                   // (0)
export class DemoTextModule extends LitModule {
  static title = 'Demo Module';                                                 // (1)
  static template = (model = '') => {                                           // (2)
    return html`<demo-module model=${model}></demo-module>`;
  };
  static duplicateForModelComparison = true;                                    // (3)

  static get styles() {
    return [styles];                                                            // (4)
  }

  private readonly colorService = app.getService(ColorService);                 // (5)

  @observable private pigLatin: string = '';                                    // (6)

  firstUpdated() {
    this.reactImmediately(() => this.selectionService.primarySelectedInputData, // (7)
      primarySelectedInputData => {
        this.getTranslation(primarySelectedInputData);
      });
  }

  private async getTranslation(primarySelectedInputData: IndexedInput) {
    if (primarySelectedInputData === null) return;

    const promise = this.apiService.getPigLatin(primarySelectedInputData);      // (8)
    const results = await this.loadLatest('pigLatin', promise);                 // (9)
    if (results === null) return;

    this.pigLatin = results;
  }

  render() {                                                                    // (10)
    const color = this.colorService.getDatapointColor(
        this.selectionService.primarySelectedInputData);
    return html`
      <div class="results" style=${styleMap({'color': color})}>
        ${this.pigLatin}
      </div>
    `;
  }

  static checkModule(modelSpecs: ModelsMap, datasetSpec: Spec): boolean {       // (11)
    return true;
  }
}

declare global {                                                                // (12)
  interface HTMLElementTagNameMap {
    'demo-module': DemoTextModule;
  }
}

The above LitModule, while just a dummy example, illustrates all of the necessary static properties and many of the most common patterns found in the LIT app.

LitModule Setup

First, a LitModule must declare a static title string (1) and template function (2). The template function determines how the modules layout renders the component template and passes in module properties, such as the name of the model this should respond to. (3) specified behavior in model comparison mode; if duplicate is set to true, the layout engine will create two (or more) instances of this module, each responsible for a different model.

Note: there are additional static attributes which control module behavior; see the LitModule base class for full definitions.

Styles are also declared with a static get method (4), following the lit-element convention. These styles can be built using the lit-element css template function, or by importing a separate .css file. Styles can be shared between components by importing a shared styles .css file (for instance, shared_styles.css)

Services are used by requesting them from the LitApp app singleton class (5). This can be thought of as a super-simple dependency injection system, and allows for much easier stubbing / mocking of services in testing. We request the colorService here, but the base LitModule class initializes the most common services (apiService, appState, and selectionService) for us automatically.

The LitModule must also provide a static checkModule (11) method, which determines if this module should display for the given model(s) and dataset.

Finally, the @customElement('demo-module') decorator (0) defines this class as a custom HTML element <demo-module>, and (12) ensures this is accessible to other TypeScript files in different build units.

LitModule functionality

The above module has a very simple task - When the user selects input data, it makes a request to an API service to fetch and display a pig latin translation of the data. Since we're using mobx observables to store and compute our state, we do this all in a reactive way.

First, since the LitModule base class derives from MobxLitElement, any observable data that we use in the render method automatically triggers a rerener when updated. This is excellent for simple use cases, but what about when we want to trigger more complex behavior, such as the asynchronous request outlined above?

The pattern that we leverage across the app is as follows: The render method (10) accesses a private observable pigLatin property (6) that, when updated, will rerender the template and show the results of the translation automatically. In order to update the pigLatin observable, we need to set up a bit of machinery. In the lit-element lifecycle method firstUpdated, we use a helper method reactImmediately (7) to set up an explicit reaction to the user selecting data. Whatever is returned by the first function (in this case this.selectionService.primarySelectedInputData) is observed and passed to the second function immediately and whenever it changes, allowing us to do something whenever the selection changes. Note, another helper method react is used in the same way as reactImmediately, in instances where you don't want to immediately invoke the reaction.

We pass the selction to the getTranslation method to fetch the data from our API service. However rather than awaiting our API request directly, we pass the request promise (8) to another helper method loadLatest (9). This ensures that we won't have any race conditions if, for instance, the user selects different data rapidly - the function returns null when the request being fetched has been superseded by a more recent call to the same endpoint. Finally, we set the private pigLatin observable with the results of our API request and the template is automatically rerendered, displaying our data.

This may seem like a bit of work for a simple module, but the pattern of using purely observable data to declaratively specify what gets rendered is very powerful for simpligying the logic around building larger, more complex components.

LitModule Escape Hatches

Finally, it's worth noting that the declarative template-based rendering setup, while effective for handling most component render logic, is sometimes inadequate for more advanced visualizations. In particular, the template approach is not well suited for animations, rapidly changing data, or things that MUST be done imperatively (such as drawing to a canvas). Fortunately, it's very easy to "bridge" from declarative to imperative code by leveraging the lit-element lifecycle methods.

In particular, the updated and firstUpdated methods are useful for explicitly doing work after the component has rendered. You can use normal querySelector methods to select elements and update their properties imperatively (note that you must make selections using the shadow root, not the document, since we're using isolated web components).

One important caveat is that messing with the actual structure of the rendered DOM output (such as removing/reordering DOM nodes) will cause issues with lit-element, since it relies on a consistent template output to do its reconciliation of what needs to be updated per render.

// An example of a LITModule imperative "escape hatch"
  updated() {
    const canvas = this.shadowRoot!.querySelector('canvas');
    this.drawCanvas(canvas);
  }

  render() {
    return html`<canvas></canvas>`;
  }