I'm trying to understand servlets and advantages it offers over CGI. It was mentioned that a new process is started everytime in CGI and it is slow compared to servlet. Can someone explain what exactly is a process here and how servlet it beneficial over CGI ?
A CGI can be thought of a normal executable - it's a program that is run, does something, then ends. Like a dos or shell command. The issue is that there is a small amount of overhead in starting up such an executable, with the operating system allocating memory, loading the program into memory, running it, then deallocating everything. If you're running a website with many 100's of requests per second, this overhead can become significant, with potential many copies of this CGI ending up in memory should many concurrent HTTP requests hit the server.
Servlets on the other hand, have its resources allocated just once, for one single instance held in memory. This single instance can process many HTTP requests concurrently, the single instance sharing it's allocated resources between all requests. This can be an issue - instance and static variables may be corrupted if two requests attempt to access. However, the advantages of efficiency and speed far outweighs this.
I have been building a real-time notification system. It’s part of a web application, but events have to be seen as soon as they occur. Long polling was not an option because it would be expensive for the web server to hold on to connections when no events are available, so I had to go for short-lived polls.
Each client hits the web server every, say, 2 seconds (this is a fairly high rate). When events are available, they are sent as JSON to the JavaScript client. Now, this requires a server set-up to handle a high number of short-lived connections. I have implemented one such system using the Yaws web server. However, because Yaws starts quite a number of many other services, it feels heavy and connections begin to get either refused or aborted when they go beyond 30,000 (maybe because I am running some ETS Tables in the same Erlang VM as Yaws is running on [separating these may require rpc:call/4, which—I fear—will increase latency]). I know that there are operating-system-specific tweaks to do, and those have been done.
This would not be a problem if it was easy to cluster up several Yaws instances. In Yaws, i am using a few appmods, and I am doing things RESTfully. I was thinking that the Cowboy web server might enhance things a bit here. I have not used Cowboy before, but I have used Misultin. Looking at Cowboy, it is a full fledged OTP Application and it seems to be easy to cluster, and being lightweight, may perhaps increase on the number of clients the overall system can handle. Storage is on Mnesia, which I can distribute easily to add more nodes (maybe by replication), so that there is a Cowboy instance in front of every Mnesia instance.
My questions are:
Is my speculation correct, that if I switched from Yaws to Cowboy, I might increase the performance significantly?
Yaws has a clean API via Appmods and the #arg{} record. Does Cowboy have an equivalent of these two things (illustrate please)?
Can Cowboy handle file uploads? If so, which server (Yaws or Cowboy), in your opinion would be better to use in the case of frequent file uploads? Illustrate how file uploads are done with Cowboy.
It is possible to run several Yaws instances on the same machine. Do you think that creating many Yaws instances per server (physical box) and having the client-load distributed across these would help? What do I need to know about doing this?
When I set the yaws.conf parameter max_connections = nolimit, how would I specify the same in Cowboy?
Now, I followed the interview with Cowboy author and he discusses the reasons why Cowboy is more lightweight than Yaws. He says that
The biggest difference is the use of binaries instead of lists. The generic acceptor pool is another. I could list a lot of other small differences but I figure these aren’t the most interesting.
That because Cowboy uses the listener-pool library Ranch, it somehow ends up with a higher capability of handling more connections, plus the use of binaries and not lists.
Another quote from the same interview:
Since we use one process per connection instead of two, and we use binaries instead of lists, we end up using a lot less memory than other projects without user intervention. Cowboy is also lazy, it doesn’t do anything unless required. So we don’t have much in memory until the user starts calling functions.
I wonder how yaws handles this case. Somehow, my problem domain needs lightweight HTTP handling. It’s actually true that Yaws will lead to more memory consumption as compared to say, Mochiweb, Misultin or Cowboy. My greatest concern is that Yaws has the best/cleanest API whereby it gives us access to the #arg{} containing everything we need as an Erlang record, so that we can get them out ourselves, than the others which have numerous functions for extracting stuff outside. Even the documentation: Yaws docs are pretty good and straightforward. Perhaps I need to look at more Cowboy code for things like file uploading and simple GET and POST request handling.
Otherwise, the questions I asked earlier, remain as pressing concerns. Yaws is pretty good, but seems to be overkill for this fast light-weight short-lived high rate poll situation, what do you think?
Your 30000 refusal limit sounds an awful lot like a 32k limit somewhere. Either the default process count, which is 32k, or some system limit on file descriptors and so on. You should not rule out the possibility that the limitation is on the kernel side of things. I've seen systems come to their limits quite easily due to kernel configurations which can be really hard to handle.
Since you're using an event loop as opposed to threads, how does the actual server look?
I know it uses an event loop, but how do you separate out the requests? And how do you prevent your server from running extremely slowly (since it, I assume, can only push one thing at a time since it's threadless?)
Some sort of pseudo-code would be great.
Forgive my ignorance; of course, if there's somewhere that explains it in a non-basic "this is good enough until you get 1000 visitors way", I'd be glad to know of it.
The implementation details of a long poll server would vary so much from platform to platform that your assumptions might not be correct.
I implemented a COMET server for our website using .NET. I leveraged HttpListener to do all the boring http stuff and Microsoft CCR to deal with all the async IO. It uses a pool of threads to service requests as and when they come in. It's not a thread per client, but it's not single threaded either generally requiring a few tens of threads to stay fluid as user numbers rise. This approach means that we scale easily across multiple CPU cores. CCRs async enumerator pattern really helped keep the asynchronous logic nice and tidy, and I can read the code fairly easily a year later.
This approach has proved extremely scalable. I've tested up to 20000 clients, whereupon we became bound by network IO. It handles all our clients (who are "permanently" connected, reconnecting every 30s) ticking along at 1-2% server load. It's definitely worth reconsidering your assumption that you must either choose an event loop architecture as opposed to multiple threads. The middle ground works very nicely for me, and the .NET asynchronous programming model for dealing with IO bound tasks really takes you away from needing to micro-manage threads. Effectively, when there's IO data to process, a thread is borrowed from the pool to do that processing, and subsequently returned to the pool ready to service another request. All the complicated IOCP stuff is abstracted away.
From all the articles I've read so far about Mochiweb, I've heard this over and over again that Mochiweb provides very good scalability. My question is, how exactly does Mochiweb get its scalability property? Is it from Erlang's inherent scalability properties or does Mochiweb have any additional code that explicitly enables it to scale well? Put another way, if I were to write a simple HTTP server in Erlang myself, with a simple 'loop' (recursive function) to handle requests, would it have the same level of scalability as a simple web server built using the Mochiweb framework?
UPDATE: I'm not planning to implement a full blown web-server supporting every feature possible. My requirements are very specific - to handle POST data from a HTML form with fixed controls.
Probably. :-)
If you were to write a web server that handles each request in a separate process (light weight thread in Erlang) you could reach the same kind of "scalability" easily. Of course the feature set would be different, unless you implement everything Mochiweb has.
Erlang also has great built in support for distribution among many machines, this might be possible to use to gain even more scalability.
MochiWeb isn't scalable itself, as far as I understand it. It's a fast, tiny server library that can handle thousands of requests per second. The way in which it does that has nothing to do with "scalability" (aside from adjusting the number of mochiweb_acceptors that are listening at any given time).
What you get with MochiWeb is a solid web server library, and Erlang's scalability features. If you want to run a single MochiWeb server, when a request comes in, you can still offload the work of processing that request to any machine you want, thanks to Erlang's distributed node infrastructure and cheap message passing. If you want to run multiple MochiWeb servers, you can put them behind a load balancer and use mnesia's distributed features to sync session data between machines.
The point is, MochiWeb is small and fast (enough). Erlang is the scalability power tool.
If you roll your own server solution, you could probably meet or beat MochiWeb's efficiency and "scalability" out of the box. But then you'd have to rethink everything they've already thought of, and you'd have to battle test it yourself.
I've always been under the impression that using the ThreadPool for (let's say non-critical) short-lived background tasks was considered best practice, even in ASP.NET, but then I came across this article that seems to suggest otherwise - the argument being that you should leave the ThreadPool to deal with ASP.NET related requests.
So here's how I've been doing small asynchronous tasks so far:
ThreadPool.QueueUserWorkItem(s => PostLog(logEvent))
And the article is suggesting instead to create a thread explicitly, similar to:
new Thread(() => PostLog(logEvent)){ IsBackground = true }.Start()
The first method has the advantage of being managed and bounded, but there's the potential (if the article is correct) that the background tasks are then vying for threads with ASP.NET request-handlers. The second method frees up the ThreadPool, but at the cost of being unbounded and thus potentially using up too many resources.
So my question is, is the advice in the article correct?
If your site was getting so much traffic that your ThreadPool was getting full, then is it better to go out-of-band, or would a full ThreadPool imply that you're getting to the limit of your resources anyway, in which case you shouldn't be trying to start your own threads?
Clarification: I'm just asking in the scope of small non-critical asynchronous tasks (eg, remote logging), not expensive work items that would require a separate process (in these cases I agree you'll need a more robust solution).
Other answers here seem to be leaving out the most important point:
Unless you are trying to parallelize a CPU-intensive operation in order to get it done faster on a low-load site, there is no point in using a worker thread at all.
That goes for both free threads, created by new Thread(...), and worker threads in the ThreadPool that respond to QueueUserWorkItem requests.
Yes, it's true, you can starve the ThreadPool in an ASP.NET process by queuing too many work items. It will prevent ASP.NET from processing further requests. The information in the article is accurate in that respect; the same thread pool used for QueueUserWorkItem is also used to serve requests.
But if you are actually queuing enough work items to cause this starvation, then you should be starving the thread pool! If you are running literally hundreds of CPU-intensive operations at the same time, what good would it do to have another worker thread to serve an ASP.NET request, when the machine is already overloaded? If you're running into this situation, you need to redesign completely!
Most of the time I see or hear about multi-threaded code being inappropriately used in ASP.NET, it's not for queuing CPU-intensive work. It's for queuing I/O-bound work. And if you want to do I/O work, then you should be using an I/O thread (I/O Completion Port).
Specifically, you should be using the async callbacks supported by whatever library class you're using. These methods are always very clearly labeled; they start with the words Begin and End. As in Stream.BeginRead, Socket.BeginConnect, WebRequest.BeginGetResponse, and so on.
These methods do use the ThreadPool, but they use IOCPs, which do not interfere with ASP.NET requests. They are a special kind of lightweight thread that can be "woken up" by an interrupt signal from the I/O system. And in an ASP.NET application, you normally have one I/O thread for each worker thread, so every single request can have one async operation queued up. That's literally hundreds of async operations without any significant performance degradation (assuming the I/O subsystem can keep up). It's way more than you'll ever need.
Just keep in mind that async delegates do not work this way - they'll end up using a worker thread, just like ThreadPool.QueueUserWorkItem. It's only the built-in async methods of the .NET Framework library classes that are capable of doing this. You can do it yourself, but it's complicated and a little bit dangerous and probably beyond the scope of this discussion.
The best answer to this question, in my opinion, is don't use the ThreadPool or a background Thread instance in ASP.NET. It's not at all like spinning up a thread in a Windows Forms application, where you do it to keep the UI responsive and don't care about how efficient it is. In ASP.NET, your concern is throughput, and all that context switching on all those worker threads is absolutely going to kill your throughput whether you use the ThreadPool or not.
Please, if you find yourself writing threading code in ASP.NET - consider whether or not it could be rewritten to use pre-existing asynchronous methods, and if it can't, then please consider whether or not you really, truly need the code to run in a background thread at all. In the majority of cases, you will probably be adding complexity for no net benefit.
Per Thomas Marquadt of the ASP.NET team at Microsoft, it is safe to use the ASP.NET ThreadPool (QueueUserWorkItem).
From the article:
Q) If my ASP.NET Application uses CLR ThreadPool threads, won’t I starve ASP.NET, which also uses the CLR ThreadPool to execute requests?
..
A) To summarize, don’t worry about
starving ASP.NET of threads, and if
you think there’s a problem here let
me know and we’ll take care of it.
Q) Should I create my own threads
(new Thread)? Won’t this be better
for ASP.NET, since it uses the CLR
ThreadPool.
A) Please don’t. Or to put it a
different way, no!!! If you’re really
smart—much smarter than me—then you
can create your own threads;
otherwise, don’t even think about it.
Here are some reasons why you should
not frequently create new threads:
It is very expensive, compared to
QueueUserWorkItem...By the way, if you can write a better ThreadPool than the CLR’s, I encourage you to apply for a job at Microsoft, because we’re definitely looking for people like you!.
Websites shouldn't go around spawning threads.
You typically move this functionality out into a Windows Service that you then communicate with (I use MSMQ to talk to them).
-- Edit
I described an implementation here: Queue-Based Background Processing in ASP.NET MVC Web Application
-- Edit
To expand why this is even better than just threads:
Using MSMQ, you can communicate to another server. You can write to a queue across machines, so if you determine, for some reason, that your background task is using up the resources of the main server too much, you can just shift it quite trivially.
It also allows you to batch-process whatever task you were trying to do (send emails/whatever).
I definitely think that general practice for quick, low-priority asynchronous work in ASP.NET would be to use the .NET thread pool, particularly for high-traffic scenarios as you want your resources to be bounded.
Also, the implementation of threading is hidden - if you start spawning your own threads, you have to manage them properly as well. Not saying you couldn't do it, but why reinvent that wheel?
If performance becomes an issue, and you can establish that the thread pool is the limiting factor (and not database connections, outgoing network connections, memory, page timeouts etc) then you tweak the thread pool configuration to allow more worker threads, higher queued requests, etc.
If you don't have a performance problem then choosing to spawn new threads to reduce contention with the ASP.NET request queue is classic premature optimization.
Ideally you wouldn't need to use a separate thread to do a logging operation though - just enable the original thread to complete the operation as quickly as possible, which is where MSMQ and a separate consumer thread / process come in to the picture. I agree that this is heavier and more work to implement, but you really need the durability here - the volatility of a shared, in-memory queue will quickly wear out its welcome.
You should use QueueUserWorkItem, and avoid creating new threads like you would avoid the plague. For a visual that explains why you won't starve ASP.NET, since it uses the same ThreadPool, imagine a very skilled juggler using two hands to keep a half dozen bowling pins, swords, or whatever in flight. For a visual of why creating your own threads is bad, imagine what happens in Seattle at rush hour when heavily used entrance ramps to the highway allow vehicles to enter traffic immediately instead of using a light and limiting the number of entrances to one every few seconds. Finally, for a detailed explanation, please see this link:
http://blogs.msdn.com/tmarq/archive/2010/04/14/performing-asynchronous-work-or-tasks-in-asp-net-applications.aspx
Thanks,
Thomas
That article is not correct. ASP.NET has it's own pool of threads, managed worker threads, for serving ASP.NET requests. This pool is usually a few hundred threads and is separate from the ThreadPool pool, which is some smaller multiple of processors.
Using ThreadPool in ASP.NET will not interfere with ASP.NET worker threads. Using ThreadPool is fine.
It would also be acceptable to setup a single thread which is just for logging messages and using producer/consumer pattern to pass logs messages to that thread. In that case, since the thread is long-lived, you should create a single new thread to run the logging.
Using a new thread for every message is definitely overkill.
Another alternative, if you're only talking about logging, is to use a library like log4net. It handles logging in a separate thread and takes care of all the context issues that could come up in that scenario.
I'd say the article is wrong. If you're running a large .NET shop you can safely use the pool across multiple apps and multiple websites (using seperate app pools), simply based on one statement in the ThreadPool documentation:
There is one thread pool per process.
The thread pool has a default size of
250 worker threads per available
processor, and 1000 I/O completion
threads. The number of threads in the
thread pool can be changed by using
the SetMaxThreads method. Each thread
uses the default stack size and runs
at the default priority.
I was asked a similar question at work last week and I'll give you the same answer. Why are you multi threading web applications per request? A web server is a fantastic system optimized heavily to provide many requests in a timely fashion (i.e. multi threading). Think of what happens when you request almost any page on the web.
A request is made for some page
Html is served back
The Html tells the client to make further requets (js, css, images, etc..)
Further information is served back
You give the example of remote logging, but that should be a concern of your logger. An asynchronous process should be in place to receive messages in a timely fashion. Sam even points out that your logger (log4net) should already support this.
Sam is also correct in that using the Thread Pool on the CLR will not cause issues with the thread pool in IIS. The thing to be concerned with here though, is that you are not spawning threads from a process, you are spawning new threads off of IIS threadpool threads. There is a difference and the distinction is important.
Threads vs Process
Both threads and processes are methods
of parallelizing an application.
However, processes are independent
execution units that contain their own
state information, use their own
address spaces, and only interact with
each other via interprocess
communication mechanisms (generally
managed by the operating system).
Applications are typically divided
into processes during the design
phase, and a master process explicitly
spawns sub-processes when it makes
sense to logically separate
significant application functionality.
Processes, in other words, are an
architectural construct.
By contrast, a thread is a coding
construct that doesn't affect the
architecture of an application. A
single process might contains multiple
threads; all threads within a process
share the same state and same memory
space, and can communicate with each
other directly, because they share the
same variables.
Source
You can use Parallel.For or Parallel.ForEach and define the limit of possible threads you want to allocate to run smoothly and prevent pool starvation.
However, being run in background you will need to use pure TPL style below in ASP.Net web application.
var ts = new CancellationTokenSource();
CancellationToken ct = ts.Token;
ParallelOptions po = new ParallelOptions();
po.CancellationToken = ts.Token;
po.MaxDegreeOfParallelism = 6; //limit here
Task.Factory.StartNew(()=>
{
Parallel.ForEach(collectionList, po, (collectionItem) =>
{
//Code Here PostLog(logEvent);
}
});
I do not agree with the referenced article(C#feeds.com). It is easy to create a new thread but dangerous. The optimal number of active threads to run on a single core is actually surprisingly low - less than 10. It is way too easy to cause the machine to waste time switching threads if threads are created for minor tasks. Threads are a resource that REQUIRE management. The WorkItem abstraction is there to handle this.
There is a trade off here between reducing the number of threads available for requests and creating too many threads to allow any of them to process efficiently. This is a very dynamic situation but I think one that should be actively managed (in this case by the thread pool) rather than leaving it to the processer to stay ahead of the creation of threads.
Finally the article makes some pretty sweeping statements about the dangers of using the ThreadPool but it really needs something concrete to back them up.
Whether or not IIS uses the same ThreadPool to handle incoming requests seems hard to get a definitive answer to, and also seems to have changed over versions. So it would seem like a good idea not to use ThreadPool threads excessively, so that IIS has a lot of them available. On the other hand, spawning your own thread for every little task seems like a bad idea. Presumably, you have some sort of locking in your logging, so only one thread could progress at a time, and the rest would just take turns getting scheduled and unscheduled (not to mention the overhead of spawning a new thread). Essentially, you run into the exact problems the ThreadPool was designed to avoid.
It seems that a reasonable compromise would be for your app to allocate a single logging thread that you could pass messages to. You would want to be careful that sending messages is as fast as possible so that you don't slow down your app.