• Promise deeply lookup


    Motivation

    Consider the following synchronous JavaScript function to read a file and parse it as JSON. It is simple and easy to read, but you wouldn't want to use it in most applications as it is blocking. This means that while you are reading the file from disk (a slow operation) nothing else can happen.

    function readJSONSync(filename) {
      return JSON.parse(fs.readFileSync(filename, 'utf8'));
    }

    To make our application performant and responsive, we need to make all the operations that involve IO be asynchronous. The simplest way to do this would be to use a callback. However, a naive implementation will probably go wrong:

    function readJSON(filename, callback){
      fs.readFile(filename, 'utf8', function (err, res){
        if (err) return callback(err);
        callback(null, JSON.parse(res));
      });
    }
    • The extra callback parameter confuses our idea of what is input and what is the return value.
    • It doesn't work at all with control flow primitives.
    • It doesn't handle errors thrown by JSON.parse

    We need to handle errors thrown by JSON.parse but we also need to be careful not to handle errors thrown by the callback function. By the time we've done all of this our code is a mess of error handling:

    function readJSON(filename, callback){
      fs.readFile(filename, 'utf8', function (err, res){
        if (err) return callback(err);
        try {
          res = JSON.parse(res);
        } catch (ex) {
          return callback(ex);
        }
        callback(null, res);
      });
    }

    Despite all this mess of error handling code, we are still left with the problem of the extra callback parameter hanging around. Promises help you naturally handle errors, and write cleaner code by not having callback parameters, and without modifying the underlying architecture (i.e. you can implement them in pure JavaScript and use them to wrap existing asynchronous operations).

    What is a promise?

    The core idea behind promises is that a promise represents the result of an asynchronous operation. A promise is in one of three different states:

    • pending - The initial state of a promise.
    • fulfilled - The state of a promise representing a successful operation.
    • rejected - The state of a promise representing a failed operation.

    Once a promise is fulfilled or rejected, it is immutable (i.e. it can never change again).

    Constructing a promise

    Once all of the APIs return promises, it should be relatively rare that you need to construct one by hand. In the meantime, we need a way to polyfill existing APIs. For example:

    function readFile(filename, enc){
      return new Promise(function (fulfill, reject){
        fs.readFile(filename, enc, function (err, res){
          if (err) reject(err);
          else fulfill(res);
        });
      });
    }

    We use new Promise to construct the promise. We give the constructor a factory function which does the actual work. This function is called immediately with two arguments. The first argument fulfills the promise and the second argument rejects the promise. Once the operation has completed, we call the appropriate function.

    Awaiting a promise

    In order to use a promise, we must somehow be able to wait for it to be fulfilled or rejected. The way to do this is using promise.done (see warning at the end of this section if attempting to run these samples).

    With this in mind, it's easy to re-write our earlier readJSON function to use promises:

    function readJSON(filename){
      return new Promise(function (fulfill, reject){
        readFile(filename, 'utf8').done(function (res){
          try {
            fulfill(JSON.parse(res));
          } catch (ex) {
            reject(ex);
          }
        }, reject);
      });
    }

    This still has lots of error handling code (we'll see how we can improve on that in the next section) but it's a lot less error prone to write, and we no longer have a strange extra parameter.

    Non Standard

    Note that promise.done (used in the examples in this section) has not been standardised. It is supported by most major promise libraries though, and is useful both as a teaching aid and in production code. I recommend using it along with the following polyfill (minified / unminified): undefined

    Transformation / Chaining

    Following our example through, what we really want to do is transform the promise via another operation. In our case, this second operation is synchronous, but it might just as easily have been an asynchronous operation. Fortunately, promises have a (fully standardised, except jQuery) method for transforming promises and chaining operations.

    Put simply, .then is to .done as .map is to .forEach. To put that another way, use .then whenever you're going to do something with the result (even if that's just waiting for it to finish) and use .done whenever you aren't planning on doing anything with the result.

    Now we can re-write our original example as simply:

    function readJSON(filename){
      return readFile(filename, 'utf8').then(function (res){
        return JSON.parse(res)
      })
    }

    Since JSON.parse is just a function, we could re-write this as:

    function readJSON(filename){
      return readFile(filename, 'utf8').then(JSON.parse);
    }

    This is very close to the simple synchronous example we started out with.

    Implementations / Polyfills

    p Promises are useful both in node.js and the browser

    jQuery

    This feels like a good time to warn you that what jQuery calls a promise is in fact totally different to what everyone else calls a promise. jQuery's promises have a poorly thought out API that will likely just confuse you. Fortunately, instead of using jQuery's strange version of a promise, you can just convert it to a really simple standardised promise:

    var jQueryPromise = $.ajax('/data.json');
    var realPromise = Promise.resolve(jQueryPromise);
    //now just use `realPromise` however you like.

    Browser

    Promises are currently only supported by a pretty small selection of browsers (see kangax compatibility tables). The good news is that they're extremely easy to polyfill (minified / unminified):

    <script src="https://www.promisejs.org/polyfills/promise-7.0.4.min.js"></script>

    None of the browsers currently support Promise.prototype.done so if you want to use that feature, and you are not including the polyfill above, you must at least include this polyfill (minified / unminified):

    <script src="https://www.promisejs.org/polyfills/promise-done-7.0.4.min.js"></script>

    Node.js

    It's generally not seen as good practice to polyfill things in node.js. Instead, you're better off just requiring the library wherever you need it.

    To install promise run:

    npm install promise --save
    

    Then you can load it into a local variable using require

    var Promise = require('promise');

    The "promise" library also provides a couple of really useful extensions for interacting with node.js

    var readFile = Promise.denodeify(require('fs').readFile);
    // now `readFile` will return a promise rather than
    // expecting a callback
    
    function readJSON(filename, callback){
      // If a callback is provided, call it with error as the
      // first argument and result as the second argument,
      // then return `undefined`. If no callback is provided,
      // just return the promise.
      return readFile(filename, 'utf8')
        .then(JSON.parse)
        .nodeify(callback);
    }

    Further Reading

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  • 原文地址:https://www.cnblogs.com/xiaojikuaipao/p/6103421.html
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