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authorTakashi Iwai <tiwai@suse.de>2016-11-10 13:06:55 +0300
committerTakashi Iwai <tiwai@suse.de>2016-11-10 20:09:30 +0300
commit20a1d0f44d9447a68c387a2f561db4720302fb7c (patch)
treebc60ed6a51537a95c0df0d5d85ca1f97aa338c3d /Documentation/sound/designs
parente9df12c3bac69e2cdfd76d7717bed92dee7cd617 (diff)
downloadlinux-20a1d0f44d9447a68c387a2f561db4720302fb7c.tar.xz
ALSA: doc: ReSTize timestamping document
A simple conversion from a plain text file. Put to designs subdirectory. Signed-off-by: Takashi Iwai <tiwai@suse.de>
Diffstat (limited to 'Documentation/sound/designs')
-rw-r--r--Documentation/sound/designs/index.rst1
-rw-r--r--Documentation/sound/designs/timestamping.rst215
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diff --git a/Documentation/sound/designs/index.rst b/Documentation/sound/designs/index.rst
index f7ca11307033..798b1a44bbbd 100644
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+++ b/Documentation/sound/designs/index.rst
@@ -7,6 +7,7 @@ Designs and Implementations
control-names
channel-mapping-api
compress-offload
+ timestamping
procfile
powersave
oss-emulation
diff --git a/Documentation/sound/designs/timestamping.rst b/Documentation/sound/designs/timestamping.rst
new file mode 100644
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@@ -0,0 +1,215 @@
+=====================
+ALSA PCM Timestamping
+=====================
+
+The ALSA API can provide two different system timestamps:
+
+- Trigger_tstamp is the system time snapshot taken when the .trigger
+ callback is invoked. This snapshot is taken by the ALSA core in the
+ general case, but specific hardware may have synchronization
+ capabilities or conversely may only be able to provide a correct
+ estimate with a delay. In the latter two cases, the low-level driver
+ is responsible for updating the trigger_tstamp at the most appropriate
+ and precise moment. Applications should not rely solely on the first
+ trigger_tstamp but update their internal calculations if the driver
+ provides a refined estimate with a delay.
+
+- tstamp is the current system timestamp updated during the last
+ event or application query.
+ The difference (tstamp - trigger_tstamp) defines the elapsed time.
+
+The ALSA API provides two basic pieces of information, avail
+and delay, which combined with the trigger and current system
+timestamps allow for applications to keep track of the 'fullness' of
+the ring buffer and the amount of queued samples.
+
+The use of these different pointers and time information depends on
+the application needs:
+
+- ``avail`` reports how much can be written in the ring buffer
+- ``delay`` reports the time it will take to hear a new sample after all
+ queued samples have been played out.
+
+When timestamps are enabled, the avail/delay information is reported
+along with a snapshot of system time. Applications can select from
+``CLOCK_REALTIME`` (NTP corrections including going backwards),
+``CLOCK_MONOTONIC`` (NTP corrections but never going backwards),
+``CLOCK_MONOTIC_RAW`` (without NTP corrections) and change the mode
+dynamically with sw_params
+
+
+The ALSA API also provide an audio_tstamp which reflects the passage
+of time as measured by different components of audio hardware. In
+ascii-art, this could be represented as follows (for the playback
+case):
+::
+
+ --------------------------------------------------------------> time
+ ^ ^ ^ ^ ^
+ | | | | |
+ analog link dma app FullBuffer
+ time time time time time
+ | | | | |
+ |< codec delay >|<--hw delay-->|<queued samples>|<---avail->|
+ |<----------------- delay---------------------->| |
+ |<----ring buffer length---->|
+
+
+The analog time is taken at the last stage of the playback, as close
+as possible to the actual transducer
+
+The link time is taken at the output of the SoC/chipset as the samples
+are pushed on a link. The link time can be directly measured if
+supported in hardware by sample counters or wallclocks (e.g. with
+HDAudio 24MHz or PTP clock for networked solutions) or indirectly
+estimated (e.g. with the frame counter in USB).
+
+The DMA time is measured using counters - typically the least reliable
+of all measurements due to the bursty nature of DMA transfers.
+
+The app time corresponds to the time tracked by an application after
+writing in the ring buffer.
+
+The application can query the hardware capabilities, define which
+audio time it wants reported by selecting the relevant settings in
+audio_tstamp_config fields, thus get an estimate of the timestamp
+accuracy. It can also request the delay-to-analog be included in the
+measurement. Direct access to the link time is very interesting on
+platforms that provide an embedded DSP; measuring directly the link
+time with dedicated hardware, possibly synchronized with system time,
+removes the need to keep track of internal DSP processing times and
+latency.
+
+In case the application requests an audio tstamp that is not supported
+in hardware/low-level driver, the type is overridden as DEFAULT and the
+timestamp will report the DMA time based on the hw_pointer value.
+
+For backwards compatibility with previous implementations that did not
+provide timestamp selection, with a zero-valued COMPAT timestamp type
+the results will default to the HDAudio wall clock for playback
+streams and to the DMA time (hw_ptr) in all other cases.
+
+The audio timestamp accuracy can be returned to user-space, so that
+appropriate decisions are made:
+
+- for dma time (default), the granularity of the transfers can be
+ inferred from the steps between updates and in turn provide
+ information on how much the application pointer can be rewound
+ safely.
+
+- the link time can be used to track long-term drifts between audio
+ and system time using the (tstamp-trigger_tstamp)/audio_tstamp
+ ratio, the precision helps define how much smoothing/low-pass
+ filtering is required. The link time can be either reset on startup
+ or reported as is (the latter being useful to compare progress of
+ different streams - but may require the wallclock to be always
+ running and not wrap-around during idle periods). If supported in
+ hardware, the absolute link time could also be used to define a
+ precise start time (patches WIP)
+
+- including the delay in the audio timestamp may
+ counter-intuitively not increase the precision of timestamps, e.g. if a
+ codec includes variable-latency DSP processing or a chain of
+ hardware components the delay is typically not known with precision.
+
+The accuracy is reported in nanosecond units (using an unsigned 32-bit
+word), which gives a max precision of 4.29s, more than enough for
+audio applications...
+
+Due to the varied nature of timestamping needs, even for a single
+application, the audio_tstamp_config can be changed dynamically. In
+the ``STATUS`` ioctl, the parameters are read-only and do not allow for
+any application selection. To work around this limitation without
+impacting legacy applications, a new ``STATUS_EXT`` ioctl is introduced
+with read/write parameters. ALSA-lib will be modified to make use of
+``STATUS_EXT`` and effectively deprecate ``STATUS``.
+
+The ALSA API only allows for a single audio timestamp to be reported
+at a time. This is a conscious design decision, reading the audio
+timestamps from hardware registers or from IPC takes time, the more
+timestamps are read the more imprecise the combined measurements
+are. To avoid any interpretation issues, a single (system, audio)
+timestamp is reported. Applications that need different timestamps
+will be required to issue multiple queries and perform an
+interpolation of the results
+
+In some hardware-specific configuration, the system timestamp is
+latched by a low-level audio subsystem, and the information provided
+back to the driver. Due to potential delays in the communication with
+the hardware, there is a risk of misalignment with the avail and delay
+information. To make sure applications are not confused, a
+driver_timestamp field is added in the snd_pcm_status structure; this
+timestamp shows when the information is put together by the driver
+before returning from the ``STATUS`` and ``STATUS_EXT`` ioctl. in most cases
+this driver_timestamp will be identical to the regular system tstamp.
+
+Examples of typestamping with HDaudio:
+
+1. DMA timestamp, no compensation for DMA+analog delay
+::
+
+ $ ./audio_time -p --ts_type=1
+ playback: systime: 341121338 nsec, audio time 342000000 nsec, systime delta -878662
+ playback: systime: 426236663 nsec, audio time 427187500 nsec, systime delta -950837
+ playback: systime: 597080580 nsec, audio time 598000000 nsec, systime delta -919420
+ playback: systime: 682059782 nsec, audio time 683020833 nsec, systime delta -961051
+ playback: systime: 852896415 nsec, audio time 853854166 nsec, systime delta -957751
+ playback: systime: 937903344 nsec, audio time 938854166 nsec, systime delta -950822
+
+2. DMA timestamp, compensation for DMA+analog delay
+::
+
+ $ ./audio_time -p --ts_type=1 -d
+ playback: systime: 341053347 nsec, audio time 341062500 nsec, systime delta -9153
+ playback: systime: 426072447 nsec, audio time 426062500 nsec, systime delta 9947
+ playback: systime: 596899518 nsec, audio time 596895833 nsec, systime delta 3685
+ playback: systime: 681915317 nsec, audio time 681916666 nsec, systime delta -1349
+ playback: systime: 852741306 nsec, audio time 852750000 nsec, systime delta -8694
+
+3. link timestamp, compensation for DMA+analog delay
+::
+
+ $ ./audio_time -p --ts_type=2 -d
+ playback: systime: 341060004 nsec, audio time 341062791 nsec, systime delta -2787
+ playback: systime: 426242074 nsec, audio time 426244875 nsec, systime delta -2801
+ playback: systime: 597080992 nsec, audio time 597084583 nsec, systime delta -3591
+ playback: systime: 682084512 nsec, audio time 682088291 nsec, systime delta -3779
+ playback: systime: 852936229 nsec, audio time 852940916 nsec, systime delta -4687
+ playback: systime: 938107562 nsec, audio time 938112708 nsec, systime delta -5146
+
+Example 1 shows that the timestamp at the DMA level is close to 1ms
+ahead of the actual playback time (as a side time this sort of
+measurement can help define rewind safeguards). Compensating for the
+DMA-link delay in example 2 helps remove the hardware buffering but
+the information is still very jittery, with up to one sample of
+error. In example 3 where the timestamps are measured with the link
+wallclock, the timestamps show a monotonic behavior and a lower
+dispersion.
+
+Example 3 and 4 are with USB audio class. Example 3 shows a high
+offset between audio time and system time due to buffering. Example 4
+shows how compensating for the delay exposes a 1ms accuracy (due to
+the use of the frame counter by the driver)
+
+Example 3: DMA timestamp, no compensation for delay, delta of ~5ms
+::
+
+ $ ./audio_time -p -Dhw:1 -t1
+ playback: systime: 120174019 nsec, audio time 125000000 nsec, systime delta -4825981
+ playback: systime: 245041136 nsec, audio time 250000000 nsec, systime delta -4958864
+ playback: systime: 370106088 nsec, audio time 375000000 nsec, systime delta -4893912
+ playback: systime: 495040065 nsec, audio time 500000000 nsec, systime delta -4959935
+ playback: systime: 620038179 nsec, audio time 625000000 nsec, systime delta -4961821
+ playback: systime: 745087741 nsec, audio time 750000000 nsec, systime delta -4912259
+ playback: systime: 870037336 nsec, audio time 875000000 nsec, systime delta -4962664
+
+Example 4: DMA timestamp, compensation for delay, delay of ~1ms
+::
+
+ $ ./audio_time -p -Dhw:1 -t1 -d
+ playback: systime: 120190520 nsec, audio time 120000000 nsec, systime delta 190520
+ playback: systime: 245036740 nsec, audio time 244000000 nsec, systime delta 1036740
+ playback: systime: 370034081 nsec, audio time 369000000 nsec, systime delta 1034081
+ playback: systime: 495159907 nsec, audio time 494000000 nsec, systime delta 1159907
+ playback: systime: 620098824 nsec, audio time 619000000 nsec, systime delta 1098824
+ playback: systime: 745031847 nsec, audio time 744000000 nsec, systime delta 1031847