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First, my question: How do you manage your iOS Run-Loop?

Next my reason: I've been researching this with a variety of prototypes (v. early stage development) and have found a number of perplexing issues.

  • First, input issues and the run loop lead me to try the following:
    • when using the most recommended system (CADisplayLink) I noted that certain touch inputs are dropped once the CPU load causes the buffer flip (presentRenderBuffer) to have to wait a frame. This occurs only on the device and not in the simulator (annoyingly - this seems to be related to wait for vsync blocking on the main thread & the way the app run-loop process touch input & eats messages)
    • when using the next most recommended system (NSTimer) I noted that certain touch inputs are dropped once the CPU load reaches a certain point in the simulator but not in the device (also annoyingly). NSTimer also results in much lower precision on when my updates fire
    • when using the least recommended system (running the run loop in it's own thread managed internally with a high-precision timer built from mach_absolute_time, all my touch input problems go away, however my ASSERT code now traps in the wrong thread and only if I usleep following the software interrupt. (My assert code is similar to http://iphone.m20.nl/wp/?p=1) I really like having my assert code trap immediately at the line that caused the problem, so this solution is not really workable for me: harder to debug.
  • Second, lost time:
    • while investigating the system, I found that regardless of framerate (bizarrely, but I suppose statistically it still makes sense w/vsync) I'm waiting approximately 22% of the time on the vsync. I've confirmed this by moving around glFlush/glFinish and by playing with how often I do the presentRenderBuffer calls. This is key time that I'd love to be processing AI, etc rather than simply stalling on a blocking gl call. The only way I can think of around this would involve moving rendering into it's own thread, but I'm not sure if it's warranted to start re-architecting for multi-threading on a single-processor device.

So has anyone found a magic bullet around these issues? Does anyone have a killer run-loop architecture that's kick-ass on this platform? At the moment it looks like I have to pick the lesser of the evils.

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I should note: when I say "Inputs are dropped" they're not actually dropped, they just lag by anywhere from a fraction of a second to up to 10 seconds. This is not the standard lag seen on iOS and other touch-screen devices, but more like the "Message consumption running slower than message generation" lag that's cumulative (gets longer as time goes on) –  Mark Jan 27 '11 at 15:28
Are you doing everything on the main thread? Have you contemplated moving any of this processing to a background thread using GCD or the like? –  Brad Larson Jan 27 '11 at 16:07
You might also be interested in the discussion (both in answers and comments) in this question: stackoverflow.com/questions/4739748/… , where several ways of manipulating the run loop for UI updates are experimented with. –  Brad Larson Jan 27 '11 at 16:13
@Brad: Item 1 & 2 under "First" were in main thread via CADisplayLink and NSTimer via the obj-c run-in-main-thread-call. I also tried 2 w/out the run-in-main-thread call. Item 3 under "First" was run in a background NSThread managed via mach_time and microsleep. I haven't played around too much with GCD -- I'm far more comfortable in c++ than obj-c. Thanks for the link, I didn't notice anything new at first boo, but I'll study it closer. –  Mark Jan 27 '11 at 16:56
What do you mean by "How do you manage the run loop"? :-) –  Ivan Vučica Feb 2 '11 at 19:43
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2 Answers

For my own iOS projects, I use the classic approach (create a window .nib, create a class inheriting EAGLView, add EAGLView to a view in a view controller which is placed in its own .nib).

At work, I took a slightly different approach inspired by SDL, which you can inspect in our opensourced library, APRIL. Main goal of APRIL is support for as many platforms as possible, while retaining simplicity (window and input management only) and being clear about licensing issues and free to use. Our developers want to write apps on one platform (Windows, Mac or Linux, according to tastes and desires) and then the code is handed over to me to adapt for other platforms.

In the approach we use in APRIL, you don't create any .nibs, and upon calling UIApplicationMain, you specify the delegate class as its fourth argument. Main code of game remains absolutely the same for each platform, and only platform-specific stuff is #ifdef'd into the code, or abstracted in a helper library.

In the app delegate you create the view controller and the window:

- (void)applicationDidFinishLaunching:(UIApplication *)application {
    // create a window.
    // early creation so Default.png can be displayed while we're waiting for 
    // game initialization
    window = [[UIWindow alloc] initWithFrame:[[UIScreen mainScreen] bounds]];

    // viewcontroller will automatically add imageview
    viewController = [[AprilViewController alloc] initWithWindow:window];
    [viewController loadView];

    // set window color
    [window setBackgroundColor:[UIColor blackColor]];

    // display the window
    [window makeKeyAndVisible];

    // thanks to Kyle Poole for this trick
    // also used in latest SDL
    // quote:
    // KP: using a selector gets around the "failed to launch application in time" if the startup code takes too long
    // This is easy to see if running with Valgrind

    [self performSelector:@selector(runMain:) withObject:nil afterDelay:0.2f];

Notice how we delay launching by 0.2? That's why I mention image view above. During those 0.2 seconds, we'd have blank screen displayed immediately after Default.png, and extra delay is introduced before control is transferred to runMain:, which releases control to the main app:

- (void)runMain:(id)sender
    // thanks to Kyle Poole for this trick
    char *argv[] = {"april_ios"};
    int status = april_RealMain (1, argv); //gArgc, gArgv);
#pragma unused(status)

So, now the control is never transferred back to UIApplication's actual main loop. You then create your own main loop.

    void iOSWindow::enterMainLoop()
            while (mRunning) 
                    // parse UIKit events

    void iOSWindow::doEvents()
            SInt32 result;
            do {
                    result = CFRunLoopRunInMode(kCFRunLoopDefaultMode, 0, TRUE);
            } while(result == kCFRunLoopRunHandledSource);

(On a side note, view controller is used, of course, to simplify rotation of UI to match device orientation.)

Both of these approaches use CADisplayLink if supported by the OS. I have not noticed any issues with either of the methods, although my private projects are primarily accelerometer based. I suspect APRIL approach might make some of the problems go away, too.

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That is really fascinating Ivan. In fact you have described how to achieve .. control is transferred away from UIApplication's actual main loop. You then create your own main loop ... Awesome! Wonderful! –  Joe Blow Feb 7 '11 at 10:12
it looks like you're doing things similar to the way we were, that is, getting rid of the .nib, etc. I find your "doEvents" method v. interesting, though, as my intuition tells me the problems I'm getting are in event handling. I'm going to have to experiment with that one. I'm also interesting in how you're initiating things in APRIL. For my loop initialization when I ran things in my own run loop I simply spawned another thread and managed things that way, and that worked great except for the software interrupt kicking in on the wrong thread. –  Mark Feb 7 '11 at 16:59
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You obviously have expert understanding of animation and blitting issues in general, so, I don't know if this is much of an answer for you in terms of the iOS problem but:

"The only way I can think of around this would involve moving rendering into it's own thread, but I'm not sure if it's warranted to start re-architecting for multi-threading on a single-processor device"

I would just perhaps suggest that: it's commonplace and, err, idiomatic, to bugger about with background processes in iOS, in spite of there being 1x processor. I'm only able to talk in general terms versus your very technically knowledgeable specifics, but: the situation seems to be that as the Apple engineers make the whole cocoa, runloop milieu more complicated the solution in their head to the "type of problem you describe" seems to be ... "developers should background things".

For example, if you look at this other question Mysterious "progressive slowing" problem in run loop / drawRect.

and particularly review the example output, near the bottom, you can see the "pauses inserted by the OS" are following some sort of stateful pattern (there's some specific heuristic going on there, in an attempt by the Apple engineers to, as it were, helpfully share time around) although the heuristic is a mystery and indeed nobody was able to work out at exactly which stage the waiting was happening.

I only learned about threads and background activity on iOS a few, err, hours ago. Fortunately the whole thing is trivially easy on iOS, it's not like on lisa. Thus, when you say: "not sure if it's warranted to start re-architecting for multi-threading", my point is, it's more or less completely trivial and, as I try to phrase it, idiomatic and what the iOS engineers "want you to do".

Thus for example with the problem in the question, while it remains utterly mysterious (A) precisely where the waiting is happening and (B) what heuristic they are using to try to 'help', in fact we just stuffed every sort of processing possible in background threads, GCD, etc, and it works out great. (We do things like visual processing so are usually grinding away on the processor - the interface just annoys me!)

I guess the point is I found backgrounding different on iOS (simpler (trivial) - more ubiquitous, idiomatic) than Dad's environments, so - perhaps that is something of an answer to your question.

For example: in making something work on both a manycore mac and an ipad, i found myself using different approaches: on the ipad one is "throwing things in the background to avoid the type of general problem you describe" whereas on the multicore mac it's the more traditional concept of speeding up the work via parallelism.

So, you may find this useless or not.

A further meta-answer: if you are new to iOS I encourage you to spend a DTS on this. (ie email apple and ask them.) If you can get the right engineer at Apple they are fabulous. (You may well get a minimum-wage engineer at first, I think they screen newbie questions that way. Just complain that you want the boss and you may well get an incredible answer to the type of really advanced question you are asking here.)

"So has anyone found a magic bullet around these issues?" my solution as of last week is ignore the problem, go with the "iOS flow" and background everything.

Perhaps this ramble will help in some way!

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the difficulty re-architecting that I'm referring to has more to do with concurrency than anything else. I'm fairly well versed in pthreads, so NSThread is pretty straight-forward. The difficulties are in architecting a system where you can run your ai in one thread (Input handling, world object updating) and render in another (world object rendering) while both systems manage to not be locked too tightly. I've seen multi-threaded architectures that have been mutexed into what's basically a single thread simply because the system's architecture couldn't handle the concurrency problem. –  Mark Feb 4 '11 at 13:42
And now that I think about it, the mutlti-threading would still leave me with the same ASSERT problem that I experienced with the seperate run-loop thread. Doh! I'll try your suggestion of e-mailing apple. Thx. –  Mark Feb 4 '11 at 13:46
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