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I am looking at the 'Metronome' sample code from the iOS SDK (http://developer.apple.com/library/ios/#samplecode/Metronome/Introduction/Intro.html). I am running the metronome at 60 BPM, which means a tick every second. When I look at an external watch (the PC's watch), I see the metronome is running too slow - it misses about one beat each minute, which is app. 15msec of consistent error. The relevant code piece is:

- (void)startDriverTimer:(id)info {    
    NSAutoreleasePool *pool = [[NSAutoreleasePool alloc] init];       

    // Give the sound thread high priority to keep the timing steady.    
    [NSThread setThreadPriority:1.0];    
    BOOL continuePlaying = YES;   

    while (continuePlaying) {  // Loop until cancelled.   
        // An autorelease pool to prevent the build-up of temporary objects.    
        NSAutoreleasePool *loopPool = [[NSAutoreleasePool alloc] init];     
        [self playSound];

        [self performSelectorOnMainThread:@selector(animateArmToOppositeExtreme) withObject:nil waitUntilDone:NO];    
        NSDate *curtainTime = [[NSDate alloc] initWithTimeIntervalSinceNow:self.duration];    
        NSDate *currentTime = [[NSDate alloc] init];  
        // Wake up periodically to see if we've been cancelled. 
        while (continuePlaying && ([currentTime compare:curtainTime] != NSOrderedDescending)) {     
            if ([soundPlayerThread isCancelled] == YES) {    
                continuePlaying = NO;    
            [NSThread sleepForTimeInterval:0.01];    
            [currentTime release];    
            currentTime = [[NSDate alloc] init];    

        [curtainTime release];   
        [currentTime release];     
        [loopPool drain];    
    [pool drain];    



is 1.0 second in the case of 60 BPM. I wonder where this error comes from, and how can I make a more accurate timer/interval counter.

EDIT: The problem exists as well when I change the sleep time to smaller values, e.g .001.

EDIT2 (update): The problem exists as well when I use the CFAbsoluteTimeGetCurrent() method for timing. When I use the same method to measure timing between a button tap events, the timing seems accurate - I tap once a second (while watching a watch), and the measured rate is 60 BPM (on average). So I guess it must be some issue with the NSThread (?). Another thing is that on the device (iPod) the problem seems more severe then on the simulator.

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7 Answers

up vote 18 down vote accepted

Ok, I have some answers after doing some more tests, so I am sharing it with anyone who is interested.

I've placed a variable to measure time intervals between ticks, inside the play method (the method that actually sends the play message to the AVAudioPlayer object), and as my simple compare-to-external-watch experiment showed, the 60 BPM was too slow - I got these time intervals (in seconds):


My conclusion was that some overhead time elapses after each 1-second-interval is counted, and that extra time (about 10msec) is accumulated to a noticeable amount after a few tens of seconds --- quite bad for a metronome. So instead of measuring the interval between calls, I decided to measure the total interval from the first call, so that the error won't be accumulated. In other words I've replaced this condition:

while (continuePlaying && ((currentTime0 + [duration doubleValue]) >= currentTime1)

with this condition:

while (continuePlaying && ((_currentTime0 + _cnt * [duration doubleValue]) >= currentTime1 ))

where now _currentTime0 and _cnt are class members (sorry if it's a c++ jargon, I am quite new to Obj-C), the former holds the time stamp of the first call to the method, and the latter is an int counting number of ticks (==function calls). This resulted in the following measured time intervals:


and it is evident even without calculating the average, that these values fluctuate around 1.0 second (and the average is close to 1.0 with at least a millisecond of accuracy).

I will be happy to hear more insights regarding what causes the extra time to elapse - 10msec sounds as eternity for a modern CPU - though I am not familiar with the specs of the iPod CPU (it's iPod 4G, and Wikipedia says the CUP is PowerVR SGX GPU 535 @ 200 MHz)

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+1 Thanks for sharing! Those numbers give me an idea of the jitter to expect when using sleepForTimeInterval. –  Emile Cormier Dec 3 '11 at 2:42
1.0002901538 is what I got averaging. –  quantumpotato Dec 11 '11 at 18:58
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I'm very interested in this too, also noticed the fallacy of using NSTimer and the Metronome example.

I'm currently looking into CAMediaTiming Protocol...yet i have no idea how to use it, but it could prove to be a more precise solution as it's used for animations. I could also be completely wrong since games slow down when too much goes on. I'm basing my theory on my favorite game where precise timing is required when "fighting opponents on the streets". The game's fps has been reduced to 30 i think compared to its console counterparts which clocks at 60. Yet the game's combo system's timing is very crucial, e.g. a combo consists of hitting a button then another one exactly 3 frames later, so either:

  • the game on the iOS is more forgiving on timing
  • the developers implemented their own timing system
  • else they're using the Metronome's timer loop or the CAMediaTiming protocol.

Info on timing in animations is found here: http://developer.apple.com/library/ios/#documentation/Cocoa/Conceptual/Animation_Types_Timing/Articles/Timing.html#//apple_ref/doc/uid/TP40006670-SW1

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If you need <100msec precision, look into CADisplayLink. It calls a selector at regular intervals, as fast as 60 times a second, i.e. every .0166667 sec.

If you want to do your metronome test, you'd set frameInterval to 60 so it gets called back once a second.

self.syncTimer = [CADisplayLink displayLinkWithTarget:self selector:@selector(syncFired:)];
self.syncTimer.frameInterval = 60;
[self.syncTimer addToRunLoop:[NSRunLoop mainRunLoop] forMode:NSDefaultRunLoopMode];

-(void)syncFired:(CADisplayLink *)displayLink
    static NSTimeInterval lastSync = 0;
    NSTimeInterval now = CACurrentMediaTime();
    if (lastSync > 0) {
        NSLog(@"interval: %f", now - lastSync);
    lastSync = now;

In my tests, that timer is called consistently every second within 0.0001 sec.

On the off chance you're running on a device with a different refresh rate than 60Hz, you'd have to divide displayLink.duration into 1.0 and round to the nearest integer (not the floor).

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What about rates >60? In addition, I don't like the idea of coupling a timer to display hardware, it feels like a hack that invites troubles, isn't it..? –  Itamar Katz Apr 28 '13 at 11:18
If it's a hack, it's one with a long and honored history and is very likely to remain supported. Once you get called, you can use CACurrentMediaTime() to get more precision, but I don't know any technique for getting faster callbacks on iOS. –  AlexChaffee Apr 28 '13 at 16:22
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Using a while loop and sleep to time a metronome is not a robust way to solve this problem as it is likely to produce timing that is jittery and that drifts, as you have seen. I believe the standard way to solve this problem is to use Core Audio (in one way or another) to feed a continuous audio stream containing your metronome ticks separated by the correct amount of silence between them, depending on the tempo. Because you know the exact sample rate, you can time your ticks very accurately. Unfortunately, generating the audio yourself is quite a bit more difficult than what you're attempting to do, but this Stackoverflow question might get you started.

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thanks ! took me a little while to figure out to use CFAbsoluteTimeGetCurrent() for currentTime0 and currentTime1 , and had to cast duration (CGFloat) seperately ( double myDuration = (double)duration) as was having a mare trying to use doubleValue .

your suggestion works perfectly for my needs - have you managed to increase accuracy ?

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I am not I understand - accuracy of what? If you refer to the original problem, then yes, measuring using the method described in my answer does improve the accuracy. –  Itamar Katz Jan 1 '11 at 11:52
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Did you consider using a NSTimer instead of this "strange" while-loop-solution? It seems for me, that you are - not only a bit - overcomplicating very very simple things here ...

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If you need accurate timing (of course 'accurate' is a matter of application), NSTimer is not good enough. See the NSTimer class reference: A timer is not a real-time mechanism; it fires only when one of the run loop modes to which the timer has been added is running and able to check if the timer’s firing time has passed. Because of the various input sources a typical run loop manages, the effective resolution of the time interval for a timer is limited to on the order of 50-100 milliseconds. The "strange" while-loop is Apple's imp for the metronome, and even this is not accurate enough –  Itamar Katz May 26 '11 at 11:44
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The problem is more fundamental. IOS is not a real time OS so the time it takes to do various operations is not "determinate". It varies. For accuracy you would need a real time OS like RIM's New QNX operating system.

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You are right, but viewing it on a practical point of view, the available accuracy might be "good enough" for a given application, and the available accuracy depends on the implementation, the API you use, etc. –  Itamar Katz Apr 21 '12 at 19:30
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