Hi David,
On Wed, Mar 24, 2021 at 04:57:31PM +0100, David Henningsson wrote:
However, the timing jitter of IRQ handler invocation is issued in this case, as well as PCM interface, even if the data rate of MIDI physical layer is quite low nowadays (31.25 Kbit / sec ~= 3906.25 byte / sec). As long as I experienced, in actual running Linux system, the invocation of IRQ handler has no guarantee for timing jitter, mainly due to CPU level IRQ mask (like spin_lock). Therefore the interval of each invocation is not so precise to decide event timestamp, at least for time slot comes from MIDI physical layer.
Nevertheless, I think your idea is enough interesting, with conditions to deliver information from driver (or driver developer) to applications (ALSA Sequencer or userspace applications). Even if we have some limitation and restriction to precise timestamp, it's worth to work for it. It seems to be required that improvements at interface level and documentation about how to use the frame timestamp you implemented.
Right, so first, I believe the most common way to transport midi these days is through USB, where the 31.25 Kbit/sec limit does not apply: instead we have a granularity of 1/8 ms but many messages can fit in each one. So that limit is - for many if not most cases - gone.
Second; you're probably right in that there is still some jitter w r t when the IRQ fires. That is regrettable, but the earlier we get that timestamp the better, so a timestamp in IRQ context would at least be better than in a workqueue that fires after the IRQ, or in userspace that possibly has scheduling delays.
Btw, I checked the "struct urb" and there was no timestamp in there, so I don't know how to get a better timestamp than in snd_rawmidi_receive. But maybe other interfaces (PCI, Firewire etc) offers something better.
Hm. Regardless of type of hardware; e.g. OHCI/EHCI/xHCI, 1394 OHCI, or PCI-e extension card, for software to process sampled data, it's always issue that the jitter between triggering IRQ (hardware side) and invoking IRQ handler (processor side). As an actual example, let me share my experience in 1394 OHCI.
1394 OHCI controller is governed by 24.576 Mhz clock (or double depending on vendors). In IEEE 1394, ishcornous service is 8,000 times per second. 1394 OHCI specification allows software to schedule hardware IRQ per isochronous cycle.
Once ALSA firewire stack is programmed to schedule the hardwar IRQ evenry 16 isochronous cycle. The corresponding IRQ handler is expected to invoke every 2 milli second. As long as I tested in usual desktop environment[2], the jitter is between 150 micro second and 4.7 milli second. In the worst case, it's 6.0 milli seconds. The above is also the same wnen using 'threadirqs'.
When using 'isolcpus' and arranging 'smp_affinity' to reduce load from one of processor core to invoke the IRQ handler, the interval is 2 milli second with +- several nano seconds, therefore the 1394 OHCI controller can trigger hardware IRQ so precise. The jitter comes from processor side. I think many running contexts on the same processor core masks IRQ so often and the jitter is not deterministic.
Here, what I'd like to tell you is that we can not handle the system time as is as timestamp of received MIDI messages, as long as relying on IRQ context. We need some arrangements to construct better timestamp with some compensations. In this point, the 3rd version of patch is not enough[3], in my opinion.
My intension is not to discourage you, but it's better to have more care. As one of the care, I think we can use extension of 'struct snd_rawmidi_status' to deliver some useful information to ALSA rawmidi applications, or including other parameters to the frame structure. But I don't have ideas about what information should be delivered, sorry...
[1] https://github.com/systemd/systemd/pull/19124 [2] I used stock image of Ubuntu 19.10 desktop for the trial. [3] https://mailman.alsa-project.org/pipermail/alsa-devel/2021-March/182842.html
Thanks
Takashi Sakamoto