I have spent a good amount of time today trying to find the answers to my own questions, guided by some of the comments and other answers left for me here. I share my findings here in case others may consider them useful.
The use of an event loop to deal with this kind of applications is not new.
Handling user input is the most complex aspect of interactive
programming. An application may be sensitive to multiple input
devices, such as mouse and keyboard, and may multiplex these among
multiple input devices (e.g. different windows). Managing this
many-to-many mapping is usually in the province of of User Interface
Management Systems (UIMS) toolkits. Since most UIMS are implemented
in sequential languages they must resort to various techniques to
emulate the necessary concurrency. Typically this toolkits use an
event-loop that monitors the stream of input events and maps the events to call-back functions (or event handlers) provided by the
- Jonh H. Reppy - Concurrent Programming in ML
The use of event loops is present in other famous UI toolkits like Java Swing and Winforms. In Java all UI work must be done within the EventDispatchThread whearas in Winforms all UI work must be done within the thread that created the Window object. So, even when these languages support true multithreading they still require all UI code to be run in a single thread of execution.
servers that perform well under load. To do so, it uses event-driven
- “Because it’s bare and does not come with I/O APIs.” [Node.js can thus introduce its own non-blocking APIs.]
- “DOM API is event-based. Everyone is already used to running without threads and on an event loop.” [Web developers are not scared of
The latest implementation of Node.js seems to use a library called libuv, designed for the implementation of this kind of applications. This library is a core part of the design of node. We can find the definition of event loops in its documentation. Evidently this plays an important role in the current implementation of Node.js.
About Other EcmaScript Compatible Engines
print(x); // Global print function prints to the console
version(170); // Tell Rhino we want JS 1.7 language features
readFile(file); // Read a text file and return its contents as a string
readUrl(url); // Read the textual contents of a URL and return as a string
spawn(f); // Run f() or load and execute file f in a new thread
runCommand(cmd, // Run a system command with zero or more command-line args
quit() // Make Rhino exit
About Event-Driven Design, Multicores and True Concurrency
is single-threaded: a browser will never run two event handlers at the
same time, and it will never trigger a timer while an event handler is
running, for example. Concurrent updates to application state or to
the document are simply not possible, and client-side programmers do
not need to think about, or even understand, concurrent programming. A
long: otherwise they will tie up the event loop and the web browser
will become unresponsive to user input. This is the reason that Ajax
APIs are always asynchronous and the reason that client-side
The Web Workers specification very carefully relaxes the
it defines are effectively parallel threads of execution. Web workers
live in a self-contained execution environment, however, with no
access to the Window or Document object and can communicate with the
main thread only through asynchronous message passing. This means that
concurrent modifications of the DOM are still not possible, but it
also means that there is now a way to use synchronous APIs and write
long-running functions that do not stall the event loop and hang the
browser. Creating a new worker is not a heavyweight operation like
opening a new browser window, but workers are not flyweight threads
either, and it does not make sense to create new workers to perform
trivial operations. Complex web applications may find it useful to
create tens of workers, but it is unlikely that an application with
hundreds or thousands of workers would be practical.
What About Node.js True Parallelism?
Node.js is a fast-evolving technology, and perhaps that's why it is difficult to find opinions that are up-to-date. But basically, since it follows the same event-driven model as the browsers do, it is impossible to simply program a piece of code and expect it will take advantage of our multiple cores in the server. Since Node.js is implemented using non-blocking technologies, we could assume that every time we do some form of I/O (i.e. read a file, send something through a socket, write to a database, etc.), under the hood, the node engine could be spawning multiple threads and maybe taking advantage of the cores, but our code would still be run serially.
These days, it looks like node.js clustering is the solution for this problem. There are also some libraries like Node Worker that seem to implement the Web Worker concept in node. These libraries basically let us spawn new independent processes within node.js. (Although I have not experimented with this yet).
What About Portability?
It looks like there is no way that, in terms of the concurrency models, we can guarantee that all these libraries will play nice in all environments.
Although in the realm of browsers they all seem to work similarly, and since Node.js runs in an event loop, many things may still work, but there not guarantees that this should work in other engines. I guess this is probably one of the disadvantages of EcmaScript compared to other more extensive specifications like those defining the Java Virtual Machine or the CLR.
Perhaps something gets standardize later. In the future of EcmaScript, more concurrency ideas are being discussed today. See the EcmaSript Wiki: Strawman Proposals Communicating Event-Loop Concurrency and Distribution