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Introduction

Cell is an API-less framework that creates a self-contained & self-driving DOM.

  • No API : Remember that Cell is all about how you structure your logic and NOT about learning how to use some proprietary API. This document will walk you through this.
  • Self contained : Each element is its own universe (context) with its own variables and functions.
  • Self driving : Each element communicates with outside world via stateless function calls. This means each cell can survive on its own and plug into anything with zero overhead/footprint.

How to use this document

Because of the unique traits mentioned above, learning Cell is mostly about understanding how Cell works, and not about how to use and memorize some API methods, because there is no API.

In fact, you don't even need to read this tutorial if you just understand the 3 rules.

Here's my suggestion:

  1. First go ahead and head over to the homepage where it explains the 3 rules.
  2. Head over to the demo page and play around with it.
  3. Come back to this document to learn more advanced topics.

Concepts

Building a dynamic web app with Cell can be summarized into the following 3 steps:

1. How to create HTML elements from scratch.

2. How to store data and run programs on elements.

3. How to make elements communicate with one another.


1. How to create HTML elements from scratch

Cell creates HTML elements (Cell calls a created element a "Phenotype") from a blueprint (called "Genotype") written in JSON. "Blueprint" sounds like some serious piece of technology but it's nothing more than just an ordinary javascript variable that describes how each HTML element should look and behave.

All you need to do is declare a variable following a simple naming convention. And then Cell takes care of the rest to turn it into an actual HTML element.

Let's start wit 6 special attributes (The only keywords you need to remember when using Cell, ever) you can use to define an element's structure.

Keyword Explanation
$cell A marker to indicate that this is a Cell element and not just a normal Javascript object
$type Dom Element type (Example: div, span, textarea, etc., and "text" for plain text node)
$text Text content inside the element
$components Array of child Genotypes
$init The function that runs automatically after the element is created
$update The function that runs automatically whenever some data stored on the element updates.

First, let's take a look at $cell, $type and $text.


a. Creating a simple element

When defining a Genotype variable, it really doesn't matter what you name it. To demonstrate this, we'll name it ಠᴥಠ.

ಠᴥಠ = {
	$cell: true,
	$type: "span",
	$text: "Hello"
}

Creates:

<span>Hello</span>
  • $cell: true indicates that this object desribes an HTML element. (If excluded, it will be treated as just an ordinary object and nothing will render)
  • $type describes the type of a node--in this case span.
  • $text describes the text content of a node--in this case Hello.

As we already mentioned, the variable name doesn't matter. The only thing that matters is that you include the $cell key, and Cell will turn that variable into an HTML element.


NOTE: To create a plain text node, you can use $type: "text". For example,

<div class='row'>
  <img src="http://localhost/img.jpg"> Plain text
</div>

You would write

Row = {
  class: "row",
  $components: [{
    $type: "img",
    src: "http://localhost/img.jpg"
  }, {
    $type: "text",
    $text: "Plain Text"
  }]
}


b. Creating nested elements

This time let's take a look at $components.

$components is an array that contains genotypes of child elements. We will take the span we created above and nest it inside a div element.

ಠᴥಠ = {
	$cell: true,
	$type: "div",
	$components: [
		{ $type: "span", $text: "Hello" },
		{ $type: "span", $text: "World" }
	]
}

Creates:

<div>
	<span>Hello</span>
	<span>World</span>
</div>

c. Setting DOM attributes

DOM attributes are first class citizens in Cell.

This means that by default all the attributes will map 1:1 to DOM element attributes (unless you're using the 6 special "$"-prefixed keywords from above). Here's an example:

$el = {
	$type: "div",
	class: "container",
	$components: [{
		$type: "a",
		$text: "Google",
		href: "https://www.google.com"
	}]
}

Becomes:

<div class='container'>
  <a href="https://www.google.com">Google</a>
</div>

d. Setting event handlers

Setting DOM properties is not limited to string attributes, you can even attach native DOM event handlers. Here's an example:

ಠᴥಠ = {
  $cell: true,
  $type: "button",
  $text: "Button",
  onclick: function(e){
    alert("clicked!");
  }
}

creates a button like this:

<button>Button</button>

and attach the onclick event handler, so it will display an alert "clicked!" when you click.

e. Injecting a Cell into an exsiting DOM tree

By default all Cell elements get appended to the document <body> tag in the order they were declared.

However sometimes you may not want to build an entire web page with Cell. You may just want to generate a small component with Cell and inject it into an existing DOM tree. Here's how:

1. Set an id on the element you would like to inject into.

<html>
<body>
  <h1>Widget</h1>
  <div id='widget'></div>
</body>
</html>

2. Include the same id in your Cell definition.

ಠᴥಠ = {
  $cell: true,
  id: "widget",
  $init: function(){
    // some initialization
  }
}

THis will replace the original <div id='widget'></div> with your new Cell element.

You can create and inject as many of these components as you want. Just remember to specify a unique id everytime.


2. How to store data and run programs on elements

Concepts


A. Application Context

Every element created with Cell is completely self-contained and can survive on its own. In fact, the only thing Cell (the library) does is create this "smart DOM" at the beginning and then goes away. There's no need for a central structure to maintain all the bindings and event handling.

This is possible because each element functions as its own app execution context, by storing its own data and functions under its own context.

Let's look at an example:

ಠᴥಠ = {
  $cell: true,
  $type: "input",
  class: "textfield",
  onchange: function(e){
    alert("The value is " + this.value + " and the class name is " + this.class);
  }
}

This will turn into a textfield that looks like:

<input class="textfield">

The important part here is what's going on inside the onchange handler.

Notice we're using this.value to access the textfield's native value attribute, and this.class to access the class attribute we just defined right above.

TLDR: Cell binds all the variable and function's context to the element they're defined on, so you can directly manipulate them by using the this context.

B. Containerizing Data and Functions

Now for the most important part: We know how to express the looks, but how do we store data and application directly on the HTML element?

We've seen from above that:

  1. to define cell's structure we use the 6 reserved attributes
  2. to define native DOM attributes, we just define them directly (with no prefix).

Now here's the third and the last part to this rule:

To define a data on an element, you use the _ prefix.

Here's an example:

ಠᴥಠ = {
  $type: "button",
  $text: "Click me",
  _index: 0,
  _items: ["Coffee", "Tea", "Sparkling Water", "Soft Drink"]
}

We have successfully defined _index and _items on the button element. This is all! There is no special method to call in order to store data. You simply define it directly, just like you would define an ordinary attribute. Just remember to prefix your variable with _.

So how do we use it?

Let's try shuffling through this _items array by incrementing the _index attribute whenever you click the button. Just remember, all attributes are bound to the element's context, so you can use the this context to access them.

ಠᴥಠ = {
  $type: "button",
  $text: "Click me",
  _index: 0,
  _items: ["Coffee", "Tea", "Sparkling Water", "Soft Drink"],
  onclick: function(){
    this._index++;
    this.$text = this._items[this._index];
  }
}

C. Creating Self-Driving Cells

So far we have looked at how each element can be self-contained by storing data and functions on its own context.

But just storing all those data and logic won't do anything on its own. To make each element truly autonomous (Start its own lifecycle and keep running on its own), we need ways to describe how each cell:

  1. Kickstarts its lifecycle ($init)
  2. Reacts to internal and external changes to sustain itself. ($update)

1. $init

The $init function, when defined, gets automatically executed right after the element gets created.

This is useful if you need to apply some dynamic logic on your element at initialization.

For example you can use $init to apply some 3rd party library, such as jQuery, Select2, Bootstrap, CodeMirror, etc.

Let's first take a static example without $init.

var Model = [ {value: "AL", caption: "Alabama"}, {value: "WY", caption: "Wyoming"} ]
var Option = function(m){
  return { $type: "option", value: m.value, $text: m.caption }
}
var selector = {
  $cell: true,
  $type: "select",
  class: "js-example-basic-single",
  $components: Model.map(Option)
}

This will create the following HTML:

<select class="js-example-basic-single">
  <option value="AL">Alabama</option>
  <option value="WY">Wyoming</option>
</select>

Now let's use $init to turn this into a select2 component. Just include an $init function that looks like this:

$init: function(){
  $(this).select2()
}

Here's the full code:

var Model = [ {value: "AL", caption: "Alabama"}, {value: "WY", caption: "Wyoming"} ]
var Option = function(m){
  return { $type: "option", value: m.value, $text: m.caption }
}
var selector2 = {
  $type: "select",
  class: "js-example-basic-single",
  $init: function(){
    $(this).select2()   // $init function turns this into Select2!
  },
  $components: Model.map(Option)
}

2. $update

The $update function, when defined, gets executed automatically when any data stored on the element gets updated.

To explain this concept, let's try building an app that:

  1. Fetches a remote API (Github API)
  2. Store the data under an element when we get the API response.
  3. Let that "storing" event automatically trigger $update, where we render it.
var GithubApp = {
  $cell: true,
  _items: [],
  $init: function(){
    this._github();
  },
  _github: function(){
    fetch("https://api.github.com/search/repositories?q=javascript").then(function(res){
      return res.json();
    }).then(function(res){
      this._refresh(res.items);
    }.bind(this)); 
  },
  _refresh: function(result){
    this._items = result;
  },
  _template: function(item){
    return {
      $components: [{
        $text: item.full_name
      }, {
        content: item.description ? item.description : ""
      }]
    };
  },
  $update: function(){
    this.$components = this._items.map(this._template);
  }
}

Let's walk through the code step by step.

  1. $cell: true : We declare the $cell attribute to declare that this is a cell object. Cell will turn this into an HTML element.
  2. _items: [] : All variables MUST be declared on the object initially if you want to track them. For example, if you want $update() to auto trigger whenever _items updates, you need to declare the _items key on the object, like we did here.
  3. $init() : When this element gets created, this function will auto-execute. What we want to do is fetch the Github API when this element gets created, so we call this._github() here.
  4. _github() : This function's job is to fetch from the Github API. We use the browser's fetch API to make a request to Github Trending search API to search for "javascript" (https://api.github.com/search/repositories?q=javascript) When we get the return value, we turn it into JSON (return res.json()), and then we call this._refresh().
  5. _refresh() : This function simply takes the result from the _github() function and stores it on the _items array.
  6. $update() : Here's the good stuff happens. $update() is triggered automatically when _items gets updated, because we declared _items on the object at the beginning. We want to update $components with what we got from Github, so we run a map on this.__items with this._template and our Github app is updated.

Important!

To auto-trigger $update() when a "_ variable" updates, you MUST declare it on the object to indicate that this variable needs to be tracked.

Take a look at this code for example:

{
  _items: [],
  _counter: 0,
  _increment: function(){
    this._dirty = true;
    this._items.push(this._counter++);
  },
  $update: function(){
    this.$components = this._items.map(function(item){ return {$text: item} })
  }
}

In this example, we make use of 3 non-function _ variables: _items, _counter, and _dirty.

However since only _items and _counter are defined on the object, they are the only variables that will trigger the $update() function when their values change.

On the other hand, setting this._dirty = true; won't trigger the $update() since it's not explicitly declared in the definition therefore not tracked.



D. Summary

Here's the summary of all the attribute types:

Starts with Explanation Example
"$" DOM construction metadata Special properties used to construct the node. Updating them directly modifies the DOM. $cell, $type, $text, $components, $init, $update
"_" Custom Variables Declare variables local to your node and use from your app logic. Modifying them doesn't have direct effect on the DOM _model, _request, etc. Name them whatever you want as long as they start with "_".
Default Everything else, by default gets mapped 1:1 to DOM Attributes. Updating them directly modifies the DOM. style, class, href, onclick, onkeyup, etc.

3. Inter-Cellular Communication

So far we know how to create elements and how to bring them to life by storing data and running app logic dierctly on them.

Now let's take a look at how to let these cells communicate with one another to create a truly decentralized DOM.

Normally this would be the most confusing part in web app frameworks, but for Cell this is the easiest part, because all we need to do to let cells communicate is:

  1. Select an element (Simply using native HTML selectors!)
  2. Call its function

Let's look at how we can get a handle on an element.

A. HTML Selectors

Cell creates vanilla HTML elements. This means we can use the browser's own native API, such as getElementById, querySelector, querySelectorAll, etc.

Here's an example:

ಠᴥಠ = {
  $components: [{
    $type: "div",
    id: "console",
    $text: "",
    _refresh: function(text){
      this.$text = text;
    }
  }, {
    $type: "input",
    onkeyup: function(e){
      if(e.keyCode === 13) {
        document.querySelector("#console")._refresh(this.value);
      }
    }
  }]
}

Notice how we're simply using document.querySelector("#console") to select the first component, and then calling its _refresh function. Simple as that. So whatever you type into the input created by Cell will appear in the #console created by Cell.

B. Context Inheritance and Polymorphism

Earlier we discussed how all variables and functions are bound to their container element's context, allowing us to refer to them simply through this.

This is the default behavior. But there's a second behavior I haven't mentioned yet:

The this context gets inherited down the DOM tree.

Let me explain what it means.


1. Quick Object Oriented Programming Analogy

Here's an analogy using a typical object oriented programming example:

public class Animal
{
  public int age;
  public string gender;
}
public class Human extends Animal
{
  public string firstName;
  public string lastName;
}

var tom = new Human();
tom.age = 1;
tom.gender = "male";

Here we take an Animal class, and extend it to create a subclass Human. Because it inherits its parent attributes, we can simply create a Human instance and access the attributes inherited from the Animal class (age and gender).


2. How Cell implements "context inheritance"

Well, Cell doesn't have any of these classes and objects. Instead you operate by calling stateless functions. So how does Cell implement this type of behavior?

Cell has a concept called "context inheritance". The underlying premise is the same as class inheritance but the implementation is different, and is designed specifically for HTML DOM. Let's look at an example:

{
  $cell: true,
  $type: "div",
  id: "container",
  _items: [],
  $components: [
    {
      $type: "input",
      onkeyup: function(e){
        if(e.keyCode === 13){
          this._items.push(this.value);
        }
      }
    }  		
  ]
}

Notice how we have _items declared on the root element (div#container), but we are able to access it from the onkeyup() handler of one of its descendants (the input element).

Basically whenever you refer to an attribute, the element first looks for the variable on itself. If it doesn't find one, it traverses up the DOM tree until it finds the closest ancestor that has that attribute.

This way you can store a model at any level on the DOM tree and retrieve & manipulate it from any of its descendants.

So for example, we can implement the $update() function on the div#container and handle all synchronization there, like this:

{
  $cell: true,
  $type: "div",
  id: "container",
  _items: [],
  $update: function(){
    this.querySelector(".list")._refresh();
  },
  $components: [
    {
      $type: "input",
      onkeyup: function(e){
        if(e.keyCode === 13){
          this._items.push(this.value);
          this.value = "";
        }
      }
    },
    {
      class: "list",
      _refresh: function(){
        this.$components = this._items.map(function(item){
          return { class: "row", $text: item };
        })
      }
    }  		
  ]
}

Here's what's going on:

  1. onkeyup() inside the input element: It checks to see if the keyCode is 13 (enter key), and when the user presses enter, it tries to push its value into this._items array (this._items.push(this.value)). Cell searches for the _items attribute on the input, but it can't find one so it traverses the DOM tree upwards until it finds one at div#container (the root element).
  2. Once the _items array is found, we push the value into it. This triggers an $update() function on the div#container because one of its data variables has changed.
  3. The $update() function searches for one of its descendants with the selector .list, and calls _refresh() function on it (this.querySelector(".list")._refresh()).
  4. The div.list component has a _refresh function which takes this._items array and creates a $components array from it. Notice how the same inheritance principle applies here. this._items is not directly defined on the div.list element, so it searches upward the DOM tree until it finds one, and uses that value, which happens to be the same this._items we set earlier. (We could have just passed around the array as the function's argument, but this was for the sake of explanation).

C. Pass Element as callback argument

Sometimes you may want to:

  1. Call Element #callee's function _doSomething() from Element #caller.
  2. When function _doSomething() finishes it somehow returns the control back to the element #caller

Of course we could do it like this:

ಠᴥಠ = {
  $components: [{
    id: "caller",
    onclick: function(e){
      document.querySelector("#callee")._doSomething();
    },
    _done: function(response){
      console.log(response);
    }
  }, {
    id: "callee",
    _doSomething: function(){
      // ... do something here...
      document.querySelector("#caller")._done(response);
    }
  }]
}

What's going on:

  1. When you click on the #caller element, it selects the #callee element and calls _doSomething() function on it
  2. When _doSomething() finishes it selects the originating element and calls its _done() function to return the value.

This is perfectily feasible but another way to do this is by passing the caller element itself as an argument, so that we have the handle when we're ready to call its _done() function and we don't have to run the querySelector command one more time. Here's the same example, using this approach:

ಠᴥಠ = {
  $components: [{
    id: "caller",
    onclick: function(e){
      document.querySelector("#callee")._doSomething(this);
    },
    _done: function(response){
      console.log(response);
    }
  }, {
    id: "callee",
    _doSomething: function($caller){
      // ... do something here...
      $caller._done(response);
    }
  }]
}

Notice that we're passing this as an argument to _doSomething(), so that #callee now has the handle back to the #caller element.


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