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2017-06-12ALSA: pcm: use %s instead of %c for format of PCM buffer tracepointsTakashi Sakamoto1-6/+6
As long as I know, in userspace, '%c' format on printing format for tracepoint is replaced with '>c<' by existent tracing program; i.g. 'perf-trace' and 'trace-cmd'. This is inconvenient. This commit replaces the format with '%s'. The length of letters in the format string is not changed, thus this commit doesn't increase object size. In theory, I should work for improvements of these tracing programs, but here I'd like to save my time to work for the other projects. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-06-12ALSA: pcm: add 'applptr' event of tracepointTakashi Sakamoto1-0/+38
In design of ALSA PCM core, status and control data for runtime of ALSA PCM substream are shared between kernel/user spaces by page frame mapping with read-only attribute. Both of hardware-side and application-side position on PCM buffer are maintained as a part of the status data. In a view of ALSA PCM application, these two positions can be updated by executing ioctl(2) with some commands. There's an event of tracepoint for hardware-side position; 'hwptr'. On the other hand, no events for application-side position. This commit adds a new event for this purpose; 'applptr'. When the application-side position is changed in kernel space, this event is probed with useful information for developers. I note that the event is not probed for all of ALSA PCM applications, When applications are written by read/write programming scenario, the event is surely probed. The applications execute ioctl(2) with SNDRV_PCM_IOCTL_[READ|WRITE][N/I]_FRAMES to read/write any PCM frame, then ALSA PCM core updates the application-side position in kernel land. However, when applications are written by mmap programming scenario, if maintaining the application side position in kernel space accurately, applications should voluntarily execute ioctl(2) with SNDRV_PCM_IOCTL_SYNC_PTR to commit the number of handled PCM frames. If not voluntarily, the application-side position is not changed, thus the added event is not probed. There's a loophole, using architectures to which ALSA PCM core judges non cache coherent. In this case, the status and control data is not mapped into processe's VMA for any applications. Userland library, alsa-lib, is programmed for this case. It executes ioctl(2) with SNDRV_PCM_IOCTL_SYNC_PTR command every time to requiring the status and control data. ARM is such an architecture. Below is an example with serial sound interface (ssi) on i.mx6 quad core SoC. I use v4.1 kernel released by fsl-community with patches from VIA Tech. Inc. for VAB820, and my backport patches for relevant features for this patchset. I use Ubuntu 17.04 from ports.ubuntu.com as user land for armhf architecture. $ aplay -v -M -D hw:imx6vab820sgtl5,0 /dev/urandom -f S16_LE -r 48000 --period-size=128 --buffer-size=256 Playing raw data '/dev/urandom' : Signed 16 bit Little Endian, Rate 48000 Hz, Mono Hardware PCM card 0 'imx6-vab820-sgtl5000' device 0 subdevice 0 Its setup is: stream : PLAYBACK access : MMAP_INTERLEAVED format : S16_LE subformat : STD channels : 1 rate : 48000 exact rate : 48000 (48000/1) msbits : 16 buffer_size : 256 period_size : 128 period_time : 2666 tstamp_mode : NONE tstamp_type : MONOTONIC period_step : 1 avail_min : 128 period_event : 0 start_threshold : 256 stop_threshold : 256 silence_threshold: 0 silence_size : 0 boundary : 1073741824 appl_ptr : 0 hw_ptr : 0 mmap_area[0] = 0x76f98000,0,16 (16) $ trace-cmd record -e snd_pcm:hwptr -e snd_pcm:applptr $ trace-cmd report ... 60.208495: applptr: pcmC0D0p/sub0: prev=1792, curr=1792, avail=0, period=128, buf=256 60.208633: applptr: pcmC0D0p/sub0: prev=1792, curr=1792, avail=0, period=128, buf=256 60.210022: hwptr: pcmC0D0p/sub0: IRQ: pos=128, old=1536, base=1536, period=128, buf=256 60.210202: applptr: pcmC0D0p/sub0: prev=1792, curr=1792, avail=128, period=128, buf=256 60.210344: hwptr: pcmC0D0p/sub0: POS: pos=128, old=1664, base=1536, period=128, buf=256 60.210348: applptr: pcmC0D0p/sub0: prev=1792, curr=1792, avail=128, period=128, buf=256 60.210486: applptr: pcmC0D0p/sub0: prev=1792, curr=1792, avail=128, period=128, buf=256 60.210626: applptr: pcmC0D0p/sub0: prev=1792, curr=1920, avail=0, period=128, buf=256 60.211002: applptr: pcmC0D0p/sub0: prev=1920, curr=1920, avail=0, period=128, buf=256 60.211142: hwptr: pcmC0D0p/sub0: POS: pos=128, old=1664, base=1536, period=128, buf=256 60.211146: applptr: pcmC0D0p/sub0: prev=1920, curr=1920, avail=0, period=128, buf=256 60.211287: applptr: pcmC0D0p/sub0: prev=1920, curr=1920, avail=0, period=128, buf=256 60.212690: hwptr: pcmC0D0p/sub0: IRQ: pos=0, old=1664, base=1536, period=128, buf=256 60.212866: applptr: pcmC0D0p/sub0: prev=1920, curr=1920, avail=128, period=128, buf=256 60.212999: hwptr: pcmC0D0p/sub0: POS: pos=0, old=1792, base=1792, period=128, buf=256 60.213003: applptr: pcmC0D0p/sub0: prev=1920, curr=1920, avail=128, period=128, buf=256 60.213135: applptr: pcmC0D0p/sub0: prev=1920, curr=1920, avail=128, period=128, buf=256 60.213276: applptr: pcmC0D0p/sub0: prev=1920, curr=2048, avail=0, period=128, buf=256 60.213654: applptr: pcmC0D0p/sub0: prev=2048, curr=2048, avail=0, period=128, buf=256 60.213796: hwptr: pcmC0D0p/sub0: POS: pos=0, old=1792, base=1792, period=128, buf=256 60.213800: applptr: pcmC0D0p/sub0: prev=2048, curr=2048, avail=0, period=128, buf=256 60.213937: applptr: pcmC0D0p/sub0: prev=2048, curr=2048, avail=0, period=128, buf=256 60.215356: hwptr: pcmC0D0p/sub0: IRQ: pos=128, old=1792, base=1792, period=128, buf=256 60.215542: applptr: pcmC0D0p/sub0: prev=2048, curr=2048, avail=128, period=128, buf=256 60.215679: hwptr: pcmC0D0p/sub0: POS: pos=128, old=1920, base=1792, period=128, buf=256 60.215683: applptr: pcmC0D0p/sub0: prev=2048, curr=2048, avail=128, period=128, buf=256 60.215813: applptr: pcmC0D0p/sub0: prev=2048, curr=2048, avail=128, period=128, buf=256 60.215947: applptr: pcmC0D0p/sub0: prev=2048, curr=2176, avail=0, period=128, buf=256 ... We can surely see 'applptr' event is probed even if the application run for mmap programming scenario ('-M' option and 'hw' plugin). Below is a result of strace: 02:44:15.886382 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.887203 poll([{fd=4, events=POLLOUT|POLLERR|POLLNVAL}], 1, -1) = 1 ([{fd=4, revents=POLLOUT}]) 02:44:15.887471 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.887637 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.887805 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.887969 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.888132 read(3, "..."..., 256) = 256 02:44:15.889040 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.889221 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.889431 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.889606 poll([{fd=4, events=POLLOUT|POLLERR|POLLNVAL}], 1, -1) = 1 ([{fd=4, revents=POLLOUT}]) 02:44:15.889833 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.889998 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.890164 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.891048 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.891228 read(3, "..."..., 256) = 256 02:44:15.891497 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.891661 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.891829 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 02:44:15.891991 poll([{fd=4, events=POLLOUT|POLLERR|POLLNVAL}], 1, -1) = 1 ([{fd=4, revents=POLLOUT}]) 02:44:15.893007 ioctl(4, SNDRV_PCM_IOCTL_SYNC_PTR, 0x56a32b30) = 0 We can see 7 calls of ioctl(2) with SNDRV_PCM_IOCTL_SYNC_PTR per loop with call of poll(2). 128 PCM frames are transferred per loop of one poll(2), because the PCM substream is configured with S16_LE format and 1 channel (2 byte * 1 * 128 = 256 bytes). This equals to the size of period of PCM buffer. Comparing to the probed data, one of the 7 calls of ioctl(2) is actually used to commit the number of copied PCM frames to kernel space. The other calls are just used to check runtime status of PCM substream; e.g. XRUN. The tracepoint event is useful to investigate this case. I note that below modules are related to the above sample. * snd-soc-dummy.ko * snd-soc-imx-sgtl5000.ko * snd-soc-fsl-ssi.ko * snd-soc-imx-pcm-dma.ko * snd-soc-sgtl5000.ko My additional note is lock acquisition. The event is probed under acquiring PCM stream lock. This means that calculation in the event is free from any hardware events. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2014-11-04ALSA: pcm: Replace PCM hwptr tracking with tracepointsTakashi Iwai1-0/+110
ALSA PCM core has a mechanism tracking the PCM hwptr updates for analyzing XRUNs. But its log is limited (up to 10) and its log output is a kernel message, which is hard to handle. In this patch, the hwptr logging is moved to the tracing infrastructure instead of its own. Not only the hwptr updates but also XRUN and hwptr errors are recorded on the trace log, so that user can see such events at the exact timing. The new "snd_pcm" entry will appear in the tracing events: # ls -F /sys/kernel/debug/tracing/events/snd_pcm enable filter hw_ptr_error/ hwptr/ xrun/ The hwptr is for the regular hwptr update events. An event trace looks like: aplay-26187 [004] d..3 4012.834761: hwptr: pcmC0D0p/sub0: POS: pos=488, old=0, base=0, period=1024, buf=16384 "POS" shows the hwptr update by the explicit position update call and "IRQ" means the hwptr update by the interrupt, i.e. snd_pcm_period_elapsed() call. The "pos" is the passed ring-buffer offset by the caller, "old" is the previous hwptr, "base" is the hwptr base position, "period" and "buf" are period- and buffer-size of the target PCM substream. (Note that the hwptr position displayed here isn't the ring-buffer offset. It increments up to the PCM position boundary.) The XRUN event appears similarly, but without "pos" field. The hwptr error events appear with the PCM identifier and its reason string, such as "Lost interrupt?". The XRUN and hwptr error reports on kernel message are still left, can be turned on/off via xrun_debug proc like before. But the bit 3, 4, 5 and 6 bits of xrun_debug proc are dropped by this patch. Also, along with the change, the message strings have been reformatted to be a bit more consistent. Last but not least, the hwptr reporting is enabled only when CONFIG_SND_PCM_XRUN_DEBUG is set. Signed-off-by: Takashi Iwai <tiwai@suse.de>
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