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Let's say I play a stereo WAV file with 317,520,000 samples, which is theoretically 1 hour long. Assuming no interruptions of the playback, will the file finish playing in exactly one hour, or is there some occasional tiny variation in the playback speed such that it would be slightly more or slightly less (by some number of milliseconds) than one hour?

I am trying to synchronize animation with audio, and I am using a System.Diagnostics.Stopwatch to keep the frames matching the audio. But if the playback speed of WAV audio in Windows can vary slightly over time, then the audio will drift out of sync with the Stopwatch-driven animation.

Which leads to a second question: it appears that a Stopwatch - while highly granular and accurate for short durations - runs slightly fast. On my laptop, a Stopwatch run for exactly 24 hours (as measured by the computer's system time and a real stopwatch) shows an elapsed time of 24 hours plus about 5 seconds (not milliseconds).

Is this a known problem with Stopwatch? (A related question would be "am I crazy?", but you can try it for yourself.) Given its usage as a diagnostics tool, I can see where a discrepancy like this would only show up when measuring long durations, for which most people would use something other than a Stopwatch.

If I'm really lucky, then both Stopwatch and audio playback are driven by the same underlying mechanism, and thus will stay in sync with each other for days on end. Any chance this is true?

Update: I just did the math, and if Stopwatch drifts by 5 seconds over 24 hours, this means it will drift by 10 milliseconds after just 172 seconds. So in 3 minutes the animation will start being perceptably out of sync.

I'm experimenting with periodically (every 10 seconds or so) re-starting the timer from the waveOutWrite callback, but this isn't working because then the whole next set of timer events is offset by whatever the inaccuracy of the callback happened to be. Sucks to be me.

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How do you know your "real stopwatch" isn't running slightly slow? – Benoit Mar 15 '10 at 0:13
@Ben S: also timed with a desk clock (with seconds) and another PC. Everything had the same time give or take half a second, except the Stopwatch. I only tried this because of another StackOverflow question where somebody mentioned that Stopwatch was running about 10 seconds per 24 hours fast on their PC. I'd love to see this confirmed/refuted by others. – MusiGenesis Mar 15 '10 at 0:19
Here was that question: stackoverflow.com/questions/1416139/… – MusiGenesis Mar 15 '10 at 0:23
Would it not be possible to set up some tests for this? I believe you could sample the time from the atomic clock in Washington, then use Stopwatch and other mechanisms over the course of eight hours or so, and build a graph of relative accuracies... – Dave Swersky Mar 15 '10 at 0:25
Interesting, I'm gonna star this to see where it goes. Have you searched for a bug report on this? I would have thought someone would have caught this by now, unless the Stopwatch documentation specifically says it should only be used for short durations. – Benoit Mar 15 '10 at 0:26

No clock will measure time "exactly", as all physical devices are bound to have some variations and measurement errors. This means that ALL clocks will be slightly too fast or too slow (though the amount of error may differ wildly, depending on the clock).

In your case, the audio output is driven by the clock on the soundcard which drives the DAC. I don't know the .NET platform, but i assume that Stopwatch is some kind of system timer, which means it is driven by a DIFFERENT clock (the one on your motherboard, presumably).

Now in general, two different physical clocks will NEVER run at exactly the same speed - for the reasons outlined above. That is where the discrepancy you got came from. The same thing will happen to your animation - you can absolutely never assume the system clock and the soundcard DAC clock are the same - they will differ!

This means that if you want to keep two streams (video and audio) synchronized, they must be driven by the same clock. As you cannot change the clock that drives your soundcard, it's a good bet to sync everything to the soundcard.

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I think you're absolutely right that audio speed would be driven by the chip on the soundcard, and there's no way Stopwatch is driven by the same chip. The problem I ran into with syncing to the soundcard is that the API I'm using (waveOutOpen and waveOutWrite) communicates back to the calling app via messages, so while these events generally keep in sync with the audio, they're so erratically timed that the animation is noticeably jerky (I had to switch to using Stopwatch to make the animation smooth). – MusiGenesis Mar 15 '10 at 1:20
Basically, Stopwatch is precise enough for smooth animation, but eventually gets out of sync with the music. The waveOut callbacks stay in sync forever, but aren't smooth enough for animation. I need to come up with some way of combining the two, like using the callbacks to periodically adjust the Stopwatch. – MusiGenesis Mar 15 '10 at 1:23
FWIW, in Windows the video clock is driven by the audio clock. If you're rendering audio, you get the audio clock by calling waveOutGetPosition (since audio is isochronous, the position is directly corrolated with time). All the other audio rendering APIs have a similar "GetPosition" API that can be used to determine the audio rendering position. – Larry Osterman Mar 15 '10 at 1:55
@MusiGenesis: Win32 messages in general are not meant for timing-sensitive communication. Try requesting callbacks instead of messages. Also, note that with such high sync requirements, you would be probably better off with an API like DirectSound. – slacker Mar 15 '10 at 2:13
@Larry: thank you for this info. I feel like a dunce for not knowing about a method designed for exactly this problem. I only recently started doing animation complex enough for me to notice the slightly erratic timing of the waveOutWrite callbacks. – MusiGenesis Mar 15 '10 at 2:15
up vote 0 down vote accepted

Larry Osterman provided the answer in a comment:

FWIW, in Windows the video clock is driven by the audio clock. If you're rendering audio, you get the audio clock by calling waveOutGetPosition (since audio is isochronous, the position is directly corrolated with time). All the other audio rendering APIs have a similar "GetPosition" API that can be used to determine the audio rendering position.

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