Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

This is a two part question. Hope someone could reply with a complete answer.

NSOperations are powerful objects. They can be of two different types: non-concurrent or concurrent.

The first type runs synchronously. You can take advantage of a non-concurrent operations by adding them into a NSOperationQueue. The latter creates a thread(s) for you. The result consists in running that operation in a concurrent manner. The only caveat regards the lifecycle of such an operation. When its main method finishes, then it is removed form the queue. This is can be a problem when you deal with async APIs.

Now, what about concurrent operations? From Apple doc

If you want to implement a concurrent operation—that is, one that runs asynchronously with respect to the calling thread—you must write additional code to start the operation asynchronously. For example, you might spawn a separate thread, call an asynchronous system function, or do anything else to ensure that the start method starts the task and returns immediately and, in all likelihood, before the task is finished.

This is quite almost clear to me. They run asynchronously. But you must take the appropriate actions to ensure that they do.

What it is not clear to me is the following. Doc says:

Note: In OS X v10.6, operation queues ignore the value returned by isConcurrent and always call the start method of your operation from a separate thread.

What it really means? What happens if I add a concurrent operation in a NSOperationQueue?

Then, in this post Concurrent Operations, concurrent operations are used to download some HTTP content by means of NSURLConnection (in its async form). Operations are concurrent and included in a specific queue.

UrlDownloaderOperation * operation = [UrlDownloaderOperation urlDownloaderWithUrlString:url];
[_queue addOperation:operation];

Since NSURLConnection requires a loop to run, the author shunt the start method in the main thread (so I suppose adding the operation to the queue it has spawn a different one). In this manner, the main run loop can invoke the delegate included in the operation.

- (void)start
    if (![NSThread isMainThread])
        [self performSelectorOnMainThread:@selector(start) withObject:nil waitUntilDone:NO];

    [self willChangeValueForKey:@"isExecuting"];
    _isExecuting = YES;
    [self didChangeValueForKey:@"isExecuting"];

    NSURLRequest * request = [NSURLRequest requestWithURL:_url];
    _connection = [[NSURLConnection alloc] initWithRequest:request
    if (_connection == nil)
        [self finish];

- (BOOL)isConcurrent
    return YES;

// delegate method here...

My question is the following. Is this thread safe? The run loop listens for sources but invoked methods are called in a background thread. Am I wrong?


I've completed some tests on my own based on the code provided by Dave Dribin (see 1). I've noticed, as you wrote, that callbacks of NSURLConnection are called in the main thread.

Ok, but now I'm still very confusing. I'll try to explain my doubts.

Why including within a concurrent operation an async pattern where its callback are called in the main thread? Shunting the start method to the main thread it allows to execute callbacks in the main thread, and what about queues and operations? Where do I take advantage of threading mechanisms provided by GCD?

Hope this is clear.

share|improve this question
up vote 8 down vote accepted

This is kind of a long answer, but the short version is that what you're doing is totally fine and thread safe since you've forced the important part of the operation to run on the main thread.

Your first question was, "What happens if I add a concurrent operation in a NSOperationQueue?" As of iOS 4, NSOperationQueue uses GCD behind the scenes. When your operation reaches the top of the queue, it gets submitted to GCD, which manages a pool of private threads that grows and shrinks dynamically as needed. GCD assigns one of these threads to run the start method of your operation, and guarantees this thread will never be the main thread.

When the start method finishes in a concurrent operation, nothing special happens (which is the point). The queue will allow your operation to run forever until you set isFinished to YES and do the proper KVO willChange/didChange calls, regardless of the calling thread. Typically you'd make a method called finish to do that, which it looks like you have.

All this is fine and well, but there are some caveats involved if you need to observe or manipulate the thread on which your operation is running. The important thing to remember is this: don't mess with threads managed by GCD. You can't guarantee they'll live past the current frame of execution, and you definitely can't guarantee that subsequent delegate calls (i.e., from NSURLConnection) will occur on the same thread. In fact, they probably won't.

In your code sample, you've shunted start off to the main thread so you don't need to worry much about background threads (GCD or otherwise). When you create an NSURLConnection it gets scheduled on the current run loop, and all of its delegate methods will get called on that run loop's thread, meaning that starting the connection on the main thread guarantees its delegate callbacks also happen on the main thread. In this sense it's "thread safe" because almost nothing is actually happening on a background thread besides the start of the operation itself, which may actually be an advantage because GCD can immediately reclaim the thread and use it for something else.

Let's imagine what would happen if you didn't force start to run on the main thread and just used the thread given to you by GCD. A run loop can potentially hang forever if its thread disappears, such as when it gets reclaimed by GCD into its private pool. There's some techniques floating around for keeping the thread alive (such as adding an empty NSPort), but they don't apply to threads created by GCD, only to threads you create yourself and can guarantee the lifetime of.

The danger here is that under light load you actually can get away with running a run loop on a GCD thread and think everything is fine. Once you start running many parallel operations, especially if you need to cancel them midflight, you'll start to see operations that never complete and never deallocate, leaking memory. If you wanted to be completely safe, you'd need to create your own dedicated NSThread and keep the run loop going forever.

In the real world, it's much easier to do what you're doing and just run the connection on the main thread. Managing the connection consumes very little CPU and in most cases won't interfere with your UI, so there's very little to gain by running the connection completely in the background. The main thread's run loop is always running and you don't need to mess with it.

It is possible, however, to run an NSURLConnection connection entirely in the background using the dedicated thread method described above. For an example, check out JXHTTP, in particular the classes JXOperation and JXURLConnectionOperation

share|improve this answer
NSOperation is a natural way to encapsulate any long-running, parallelizable task (regardless of the threading advantages). NSURLConnection gives you a lot of control via its delegate methods (where to put response data, how to respond to redirection, etc) but they're asynchronous, so if you want to use them inside an NSOperation that means it has to be concurrent (otherwise the operation won't live past the exit of its start method and continue waiting for delegate callbacks). – roland Jan 12 '13 at 13:48
The other main advantage is that it allows you to cancel the connection at any time (for instance, if you were loading an image for a view that the user just dismissed) which is not possible via Cocoa's other connection techniques. You could even override the cancel method of NSOperation and have it cancel the NSURLConnection at the same time. – roland Jan 12 '13 at 13:49
You don't need to do anything to take advantage of GCD, NSOperationQueue manages it for you behind the scenes. In any case, there's not much performance to be gained here anyway. You spend way more time waiting for data over the wire than you do storing it when it arrives. Whatever you wind up doing with the downloaded data is going to be more CPU intensive, and that's the part you should consider doing on a background queue. – roland Jan 12 '13 at 13:55
You're right, there's no reason you can't use NSURLConnection directly in a view controller or something like that. Don't get too hung up on the threading aspect of it though, the biggest advantage of NSOperationQueue is that you can order the operations and limit how many happen at the same time. For instance, if you needed to download 100 images you'd probably only want to do a few at a time rather than kick off 100 simultaneous connections. In this case your view controller would have an NSOperationQueue with maxConcurrentOperationCount set to 2 or 4. – roland Jan 12 '13 at 14:51
You don't need to do any thread creation, like I said before don't worry about the thread the queue gives you. The only thing you need to worry about is about is setting isFinished to YES with the KVO willChange/didChange calls (both are important). – roland Jan 14 '13 at 16:16

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.