Can someone give a clear definition together with a simple example that explains what is a "callback hell" for someone who does not know JavaScript and node.js ?

When (in what kind of settings) does the "callback hell problem" occur?

Why does it occur?

Is "callback hell" always related to asynchronous computations?

Or can "callback hell" occur also in a single threaded application?

I took the Reactive Course at Coursera and Erik Meijer said in one of his lectures that RX solves the problem of "callback hell". I asked what is a "callback hell" on the Coursera forum but I got no clear answer.

After explaining "callback hell" on a simple example, could you also show how RX solves the "callback hell problem" on that simple example?

up vote 102 down vote accepted

1) What is a "callback hell" for someone who does not know javascript and node.js ?

This other question has some examples of Javascript callback hell: How to avoid long nesting of asynchronous functions in Node.js

The problem in Javascript is that the only way to "freeze" a computation and have the "rest of it" execute latter (asynchronously) is to put "the rest of it" inside a callback.

For example, say I want to run code that looks like this:

x = getData();
y = getMoreData(x);
z = getMoreData(y);
...

What happens if now I want to make the getData functions asynchronous, meaning that I get a chance to run some other code while I am waiting for them to return their values? In Javascript, the only way would be to rewrite everything that touches an async computation using continuation passing style:

getData(function(x){
    getMoreData(x, function(y){
        getMoreData(y, function(z){ 
            ...
        });
    });
});

I don't think I need to convince anyone that this version is uglier than the previous one. :-)

2) When (in what kind of settings) does the "callback hell problem" occur?

When you have lots of callback functions in your code! It gets harder to work with them the more of them you have in your code and it gets particularly bad when you need to do loops, try-catch blocks and things like that.

For example, as far as I know, in JavaScript the only way to execute a series of asynchronous functions where one is run after the previous returns is using a recursive function. You cant use a for loop.

//we would like to write
for(var i=0; i<10; i++){
    doSomething(i);
}
blah();

Instead, we might need to end up writing:

function loop(i, onDone){
    if(i >= 10){
        onDone()
    }else{
        doSomething(i, function(){
            loop(i+1, onDone);
        });
     }
}
loop(0, function(){
    blah();
});

//ugh!

The number of questions we get here on StackOverflow asking how to do this kind of thing is a testament to how confusing it is :)

3) Why does it occur ?

It occurs because in JavaScript the only way to delay a computation so that it runs after the asynchronous call returns is to put the delayed code inside a callback function. You cannot delay code that was written in traditional synchronous style so you end up with nested callbacks everywhere.

4) Or can "callback hell" occur also in a single threaded application?

Asynchronous programming has to do with concurrency while a single-thread has to do with parallelism. The two concepts are actually not the same thing.

You can still have concurrent code in a single threaded context. In fact, JavaScript, the queen of callback hell, is single threaded.

What is the difference between concurrency and parallelism?

5) could you please also show how RX solves the "callback hell problem" on that simple example.

I don't know anything about RX in particular, but usually this problem gets solved by adding native support for asynchronous computation in the programming language. This can very a lot and can come in different names (async, generators, coroutines, callcc, ...). For example, in Python we can implement that previous loop example with something along the lines of:

def myLoop():
    for i in range(10):
        doSomething(i)
        yield

myGen = myLoop()

This is not the full code but the idea is that the "yield" pauses our for loop until someone calls myGen.next(). The important thing is that we could still write the code using a for loop, without needing to turn out logic "inside out" like we had to do in that recursive loop function.

  • Thank you for the clear and detailed explanation! – jhegedus Aug 2 '14 at 18:55
  • So callback hell can only occur in an async setting? If my code is fully sychronous (ie. no concurrency) then "callback hell" can not occur if I understand your answer correctly, is that right? – jhegedus Aug 2 '14 at 19:04
  • Callback hell has more to do with how annoying it is to code using continuation passing style. Theroretically you could still rewrite all your functions using CPS style even for a regular program (the wikipedia article has some examples) but, for good reason, most people dont do that. Usually we only use continuation passing style if we are forced to, which is the case for Javascript async programming. – hugomg Aug 2 '14 at 19:09
  • btw, I googled for the reactive extensions and I am getting the impression that they are more similar to a Promise library and not a language extension introducing async syntax. Promises help deal with the callback nesting and with the exception handling but they arent as neat as the syntax extensions. The for loop is still annoying to code and you still need to translate code from the synchronous style to the promise style. – hugomg Aug 2 '14 at 19:17
  • thanks again, very interesting points ! – jhegedus Aug 2 '14 at 19:22

Just answer the question: could you please also show how RX solves the "callback hell problem" on that simple example?

The magic is flatMap. We can write the following code in Rx for @hugomg's example:

def getData() = Observable[X]
getData().flatMap(x -> Observable[Y])
         .flatMap(y -> Observable[Z])
         .map(z -> ...)...

It's like you are writing some synchronous FP codes, but actually you can make them asynchronous by Scheduler.

  • Thank you very much! – jhegedus Aug 5 '14 at 13:47
  • nice explanation – user2045474 Jul 8 '15 at 4:04

Callback hell is any code where the use of function callbacks in async code becomes obscure or difficult to follow. Generally, when there is more than one level of indirection, code using callbacks can become harder to follow, harder to refactor, and harder to test. A code smell is multiple levels of indentation due to passing multiple layers of function literals.

This often happens when behaviour has dependencies, i.e. when A must happen before B must happen before C. Then you get code like this:

a({
    parameter : someParameter,
    callback : function() {
        b({
             parameter : someOtherParameter,
             callback : function({
                 c(yetAnotherParameter)
        })
    }
});

If you have lots of behavioural dependencies in your code like this, it can get troublesome fast. Especially if it branches...

a({
    parameter : someParameter,
    callback : function(status) {
        if (status == states.SUCCESS) {
          b(function(status) {
              if (status == states.SUCCESS) {
                 c(function(status){
                     if (status == states.SUCCESS) {
                         // Not an exaggeration. I have seen
                         // code that looks like this regularly.
                     }
                 });
              }
          });
        } elseif (status == states.PENDING {
          ...
        }
    }
});

This won't do. How can we make asynchronous code execute in a determined order without having to pass all these callbacks around?

RX is short for 'reactive extensions'. I haven't used it, but Googling suggests it's an event-based framework, which makes sense. Events are a common pattern to make code execute in order without creating brittle coupling. You can make C listen to the event 'bFinished' which only happens after B is called listening to 'aFinished'. You can then easily add extra steps or extend this kind of behaviour, and can easily test that your code executes in order by merely broadcasting events in your test case.

To address the question of how Rx solves callback hell:

First let's describe callback hell again.

Imagine a case were we must do http to get three resources - person, planet and galaxy. Our objective is to find the galaxy the person lives in. First we must get the person, then the planet, then the galaxy. That's three callbacks for three asynchronous operations.

getPerson(person => {
   getPlanet(person, (planet) => {
       getGalaxy(planet, (galaxy) => {
           console.log(galaxy);
       });
   });
});

Each callback is nested. Each inner callback is dependent on its parent. This leads to the "pyramid of doom" style of callback hell. The code looks like a > sign.

To solve this in RxJs you could do something like so:

getPerson()
  .map(person => getPlanet(person))
  .map(planet => getGalaxy(planet))
  .mergeAll()
  .subscribe(galaxy => console.log(galaxy));

With the mergeMap AKA flatMap operator you could make it more succinct:

getPerson()
  .mergeMap(person => getPlanet(person))
  .mergeMap(planet => getGalaxy(planet))
  .subscribe(galaxy => console.log(galaxy));

As you can see, the code is flattened and contains a single chain of method calls. We have no "pyramid of doom".

Hence, callback hell is avoided.

In case you were wondering, promises are another way to avoid callback hell, but promises are eager, not lazy like observables and (generally speaking) you cannot cancel them as easily.

Use jazz.js https://github.com/Javanile/Jazz.js

it simplify like this:


    // run sequential task chained
    jj.script([
        // first task
        function(next) {
            // at end of this process 'next' point to second task and run it 
            callAsyncProcess1(next);
        },
      // second task
      function(next) {
        // at end of this process 'next' point to thirt task and run it 
        callAsyncProcess2(next);
      },
      // thirt task
      function(next) {
        // at end of this process 'next' point to (if have) 
        callAsyncProcess3(next);
      },
    ]);

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