The origins of this repo are in Stephen Grider's Udemy course on React and Redux.
It has begun as a clone of this repo and will evolve as I continue reviewing the course.
Checkout that repo, install dependencies, then start the gulp process with the following:
> git clone https://github.com/StephenGrider/ReduxSimpleStarter.git
> cd ReduxSimpleStarter
> npm install
> npm start
I'm relying on Stephen Grider's tutorial as I revisit React in 2018. The commits I make to this repo are meant to document my learning and review process. The motivation for this repo is similar to the motivation for this Django repo; that is, I want to write a handy study journal (a log) that my future self can read when she revisits this moment in time.
React is a JS library that produces HTML, and React code is written in the form of individual components (i.e., views). The legibility of React code depends largely on the usage of JSX, which allows us to write JS functions that incorporate HTML syntax. (NB: JS variable references within JSX should be surrounded with curly braces, e.g., {this.state.term}.)
Our app incorporates ES6 conventions, although neither JSX nor ES6 are currently interpretable by the browser. We make it browser-ready thanks to webpack, babel, and bundle.js.
/index.html has a script tag that references bundle.js, which represents the sum of all of the JS in the app. webpack and babel are the libraries responsible for compiling All The JS into bundle.js. It's not yet clear to me exactly how webpack and babel work with each other and exactly where bundle.js lives, but the webpack config file seems to lend clues.
We rely on babel to transpile our ES6 to vanilla JS (i.e., browser-readable ES5). Try playing around in babel's in-browser REPL to see just how illegible React code can become (if written in plain ES5 script).
Unlike a functional component, a class-based component has an "intelligent" awareness of itself and its own state, i.e., what has happened to itself once it's been rendered in the DOM. Class-based components are capable of introspection. It's sufficient to use functional components (or, "dumb" components) when we only need to render JSX and don't need a component to maintain an internal record of its state.
A class-based React component is also an ES6 class, replete with properties and methods. Note that every React class must include a render function that returns JSX.
The tutorial introduces the concept of state in Sections 1.17 and 1.18. State is a plain JS object that's used to record and react to user events. Functional components don't have state (because they're dumb), but class-based components do.
Whenever a class-based component's state changes, the component re-renders. A component's state change triggers all children components to re-render, as well.
In order to initialize a component's state, be sure to declare a class constructor method, e.g.,
class SearchBar extends Component {
constructor(props) {
super(props);
this.state = {
property1: 'value1',
property2: 'value2',
property3: 'value3',
};
}
In order to update a component's state, be sure to use this.setState(), e.g.,
render() {
return <input onChange={event => this.setState({ property1: 'newvalue1' })} />;
}
(Do not attempt to update state with something like: this.state.property1 = ...)
In Section 1.18, we can see the state-change and component-render cycle at work with:
render() {
return (
<div>
<input onChange={event => this.setState({ term: event.target.value })} />
VALUE OF THE INPUT: {this.state.term}
</div>
);
}
The component is first instantiated and then rendered with state in its initial state. Whenever a user modifies input in the search bar, state gets updated with this.setState(), which then triggers the render function to run anew. State is then retrieved again with this.state.term and rendered on the page, alongside VALUE OF THE INPUT.
State change and component re-rendering at work in the browser
React employs a declarative flow of data, whereas a library like jQuery employs an imperative flow. The concept of controlled components is an example of this declarative flow, in that its value is set by state and its value changes only when its state changes. Here's a version of SearchBar's render function that demonstrates this at work.
render() {
return (
<div>
<input
value = {this.state.term}
onChange={event => this.setState({ term: event.target.value })} />
</div>
);
}
In sum, when a user enters or re-enters a value into a controlled form element like our SearchBar, they are not actually setting the value of the element. Instead, they are setting into motion this series of events:
- they trigger a change event on the form element
- the change event triggers a state change
- the state change triggers a re-rendering of the component
- the re-rendering of the component sets the value of the element
This is the tutorial's first version of SearchBar's event handler (as seen in Section 1.16):
class SearchBar extends Component {
render() {
return <input onChange={this.handleInputChange} />;
}
handleInputChange(event) {
console.log(event.target.value);
}
}
In the render function's return statement, we are passing a property-value pair to the input element in the form of onChange={this.handleInputChange}.
(Note that onChange is a recognized, protected React-defined property.)
Since our handleInputChange() function contains only a console.log() statement, we can simplify our code by passing the event handling directly to onChange. Here's some ES6 syntactic sugar at work:
class SearchBar extends Component {
render() {
return <input onChange={(event) => console.log(event.target.value)} />;
}
}
And since our event handler takes only one argument, we can simplify further by removing the parentheses around event:
class SearchBar extends Component {
render() {
return <input onChange={event => console.log(event.target.value)} />;
}
}
Console-logging searchbar input upon change event
The first app I'm making is a video app that makes use of the YouTube Data API. It will have a search bar input at the top of the page, above a section that includes the video player and details for the currently-playing video (title and description).
On the right side of the page, there'll be a list of video preview items. This list will be populated according to the search results returned by the API in response to the search request sent via the search bar input.
To access Google APIs, go here.
You can find the YouTube Data API by searching in Google's API library. Be sure to enable the API, create API credentials, and add the API key to index.js.
Then, install the youtube-api-search package with npm install --save youtube-api-search. (--save adds the package to our package.json file).