linux/Documentation/driver-api/media/drivers/vidtv.rst

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.. SPDX-License-Identifier: GPL-2.0
================================
vidtv: Virtual Digital TV driver
================================
Author: Daniel W. S. Almeida <dwlsalmeida@gmail.com>, June 2020.
Background
----------
Vidtv is a virtual DVB driver that aims to serve as a reference for driver
writers by serving as a template. It also validates the existing media DVB
APIs, thus helping userspace application writers.
Currently, it consists of:
- A fake tuner driver, which will report a bad signal quality if the chosen
frequency is too far away from a table of valid frequencies for a
particular delivery system.
- A fake demod driver, which will constantly poll the fake signal quality
returned by the tuner, simulating a device that can lose/reacquire a lock
on the signal depending on the CNR levels.
- A fake bridge driver, which is the module responsible for modprobing the
fake tuner and demod modules and implementing the demux logic. This module
takes parameters at initialization that will dictate how the simulation
behaves.
- Code reponsible for encoding a valid MPEG Transport Stream, which is then
passed to the bridge driver. This fake stream contains some hardcoded content.
For now, we have a single, audio-only channel containing a single MPEG
Elementary Stream, which in turn contains a SMPTE 302m encoded sine-wave.
Note that this particular encoder was chosen because it is the easiest
way to encode PCM audio data in a MPEG Transport Stream.
Building vidtv
--------------
vidtv is a test driver and thus is **not** enabled by default when
compiling the kernel.
In order to enable compilation of vidtv:
- Enable **DVB_TEST_DRIVERS**, then
- Enable **DVB_VIDTV**
When compiled as a module, expect the following .ko files:
- dvb_vidtv_tuner.ko
- dvb_vidtv_demod.ko
- dvb_vidtv_bridge.ko
Running vidtv
-------------
When compiled as a module, run::
modprobe vidtv
That's it! The bridge driver will initialize the tuner and demod drivers as
part of its own initialization.
You can optionally define some command-line arguments to vidtv.
Command-line arguments to vidtv
-------------------------------
Below is a list of all arguments that can be supplied to vidtv:
drop_tslock_prob_on_low_snr
Probability of losing the TS lock if the signal quality is bad.
This probability be used by the fake demodulator driver to
eventually return a status of 0 when the signal quality is not
good.
recover_tslock_prob_on_good_snr:
Probability recovering the TS lock when the signal improves. This
probability be used by the fake demodulator driver to eventually
return a status of 0x1f when/if the signal quality improves.
mock_power_up_delay_msec
Simulate a power up delay. Default: 0.
mock_tune_delay_msec
Simulate a tune delay. Default 0.
vidtv_valid_dvb_t_freqs
Valid DVB-T frequencies to simulate.
vidtv_valid_dvb_c_freqs
Valid DVB-C frequencies to simulate.
vidtv_valid_dvb_s_freqs
Valid DVB-C frequencies to simulate.
max_frequency_shift_hz,
Maximum shift in HZ allowed when tuning in a channel.
si_period_msec
How often to send SI packets. Default: 40ms.
pcr_period_msec
How often to send PCR packets. Default: 40ms.
mux_rate_kbytes_sec
Attempt to maintain this bit rate by inserting TS null packets, if
necessary. Default: 4096.
pcr_pid,
PCR PID for all channels. Default: 0x200.
mux_buf_sz_pkts,
Size for the mux buffer in multiples of 188 bytes.
vidtv internal structure
------------------------
The kernel modules are split in the following way:
vidtv_tuner.[ch]
Implements a fake tuner DVB driver.
vidtv_demod.[ch]
Implements a fake demodulator DVB driver.
vidtv_bridge.[ch]
Implements a bridge driver.
The MPEG related code is split in the following way:
vidtv_ts.[ch]
Code to work with MPEG TS packets, such as TS headers, adaptation
fields, PCR packets and NULL packets.
vidtv_psi.[ch]
This is the PSI generator. PSI packets contain general information
about a MPEG Transport Stream. A PSI generator is needed so
userspace apps can retrieve information about the Transport Stream
and eventually tune into a (dummy) channel.
Because the generator is implemented in a separate file, it can be
reused elsewhere in the media subsystem.
Currently vidtv supports working with 3 PSI tables: PAT, PMT and
SDT.
The specification for PAT and PMT can be found in *ISO 13818-1:
Systems*, while the specification for the SDT can be found in *ETSI
EN 300 468: Specification for Service Information (SI) in DVB
systems*.
It isn't strictly necessary, but using a real TS file helps when
debugging PSI tables. Vidtv currently tries to replicate the PSI
structure found in this file: `TS1Globo.ts
<https://tsduck.io/streams/brazil-isdb-tb/TS1globo.ts>`_.
A good way to visualize the structure of streams is by using
`DVBInspector <https://sourceforge.net/projects/dvbinspector/>`_.
vidtv_pes.[ch]
Implements the PES logic to convert encoder data into MPEG TS
packets. These can then be fed into a TS multiplexer and eventually
into userspace.
vidtv_encoder.h
An interface for vidtv encoders. New encoders can be added to this
driver by implementing the calls in this file.
vidtv_s302m.[ch]
Implements a S302M encoder to make it possible to insert PCM audio
data in the generated MPEG Transport Stream. The relevant
specification is available online as *SMPTE 302M-2007: Television -
Mapping of AES3 Data into MPEG-2 Transport Stream*.
The resulting MPEG Elementary Stream is conveyed in a private
stream with a S302M registration descriptor attached.
This shall enable passing an audio signal into userspace so it can
be decoded and played by media software. The corresponding decoder
in ffmpeg is located in 'libavcodec/s302m.c' and is experimental.
vidtv_channel.[ch]
Implements a 'channel' abstraction.
When vidtv boots, it will create some hardcoded channels:
#. Their services will be concatenated to populate the SDT.
#. Their programs will be concatenated to populate the PAT
#. For each program in the PAT, a PMT section will be created
#. The PMT section for a channel will be assigned its streams.
#. Every stream will have its corresponding encoder polled in a
loop to produce TS packets.
These packets may be interleaved by the muxer and then delivered
to the bridge.
vidtv_mux.[ch]
Implements a MPEG TS mux, loosely based on the ffmpeg
implementation in "libavcodec/mpegtsenc.c"
The muxer runs a loop which is responsible for:
#. Keeping track of the amount of time elapsed since the last
iteration.
#. Polling encoders in order to fetch 'elapsed_time' worth of data.
#. Inserting PSI and/or PCR packets, if needed.
#. Padding the resulting stream with NULL packets if
necessary in order to maintain the chosen bit rate.
#. Delivering the resulting TS packets to the bridge
driver so it can pass them to the demux.
Testing vidtv with v4l-utils
----------------------------
Using the tools in v4l-utils is a great way to test and inspect the output of
vidtv. It is hosted here: `v4l-utils Documentation
<https://linuxtv.org/wiki/index.php/V4l-utils>`_.
From its webpage::
The v4l-utils are a series of packages for handling media devices.
It is hosted at http://git.linuxtv.org/v4l-utils.git, and packaged
on most distributions.
It provides a series of libraries and utilities to be used to
control several aspect of the media boards.
Start by installing v4l-utils and then modprobing vidtv::
modprobe dvb_vidtv_bridge
If the driver is OK, it should load and its probing code will run. This will
pull in the tuner and demod drivers.
Using dvb-fe-tool
~~~~~~~~~~~~~~~~~
The first step to check whether the demod loaded successfully is to run::
$ dvb-fe-tool
This should return what is currently set up at the demod struct, i.e.::
static const struct dvb_frontend_ops vidtv_demod_ops = {
.delsys = {
SYS_DVBT,
SYS_DVBT2,
SYS_DVBC_ANNEX_A,
SYS_DVBS,
SYS_DVBS2,
},
.info = {
.name = "Dummy demod for DVB-T/T2/C/S/S2",
.frequency_min_hz = 51 * MHz,
.frequency_max_hz = 2150 * MHz,
.frequency_stepsize_hz = 62500,
.frequency_tolerance_hz = 29500 * kHz,
.symbol_rate_min = 1000000,
.symbol_rate_max = 45000000,
.caps = FE_CAN_FEC_1_2 |
FE_CAN_FEC_2_3 |
FE_CAN_FEC_3_4 |
FE_CAN_FEC_4_5 |
FE_CAN_FEC_5_6 |
FE_CAN_FEC_6_7 |
FE_CAN_FEC_7_8 |
FE_CAN_FEC_8_9 |
FE_CAN_QAM_16 |
FE_CAN_QAM_64 |
FE_CAN_QAM_32 |
FE_CAN_QAM_128 |
FE_CAN_QAM_256 |
FE_CAN_QAM_AUTO |
FE_CAN_QPSK |
FE_CAN_FEC_AUTO |
FE_CAN_INVERSION_AUTO |
FE_CAN_TRANSMISSION_MODE_AUTO |
FE_CAN_GUARD_INTERVAL_AUTO |
FE_CAN_HIERARCHY_AUTO,
}
....
For more information on dvb-fe-tools check its online documentation here:
`dvb-fe-tool Documentation
<https://www.linuxtv.org/wiki/index.php/Dvb-fe-tool>`_.
Using dvb-scan
~~~~~~~~~~~~~~
In order to tune into a channel and read the PSI tables, we can use dvb-scan.
For this, one should provide a configuration file known as a 'scan file',
here's an example::
[Channel]
FREQUENCY = 330000000
MODULATION = QAM/AUTO
SYMBOL_RATE = 6940000
INNER_FEC = AUTO
DELIVERY_SYSTEM = DVBC/ANNEX_A
.. note::
The parameters depend on the video standard you're testing.
.. note::
Vidtv is a fake driver and does not validate much of the information
in the scan file. Just specifying 'FREQUENCY' and 'DELIVERY_SYSTEM'
should be enough for DVB-T/DVB-T2. For DVB-S/DVB-C however, you
should also provide 'SYMBOL_RATE'.
You can browse scan tables online here: `dvb-scan-tables
<https://git.linuxtv.org/dtv-scan-tables.git>`_.
Assuming this channel is named 'channel.conf', you can then run::
$ dvbv5-scan channel.conf
For more information on dvb-scan, check its documentation online here:
`dvb-scan Documentation <https://www.linuxtv.org/wiki/index.php/Dvbscan>`_.
Using dvb-zap
~~~~~~~~~~~~~
dvbv5-zap is a command line tool that can be used to record MPEG-TS to disk. The
typical use is to tune into a channel and put it into record mode. The example
below - which is taken from the documentation - illustrates that::
$ dvbv5-zap -c dvb_channel.conf "trilhas sonoras" -r
using demux '/dev/dvb/adapter0/demux0'
reading channels from file 'dvb_channel.conf'
service has pid type 05: 204
tuning to 573000000 Hz
audio pid 104
dvb_set_pesfilter 104
Lock (0x1f) Quality= Good Signal= 100.00% C/N= -13.80dB UCB= 70 postBER= 3.14x10^-3 PER= 0
DVR interface '/dev/dvb/adapter0/dvr0' can now be opened
The channel can be watched by playing the contents of the DVR interface, with
some player that recognizes the MPEG-TS format, such as *mplayer* or *vlc*.
By playing the contents of the stream one can visually inspect the workings of
vidtv, e.g.::
$ mplayer /dev/dvb/adapter0/dvr0
For more information on dvb-zap check its online documentation here:
`dvb-zap Documentation
<https://www.linuxtv.org/wiki/index.php/Dvbv5-zap>`_.
See also: `zap <https://www.linuxtv.org/wiki/index.php/Zap>`_.
What can still be improved in vidtv
-----------------------------------
Add *debugfs* integration
~~~~~~~~~~~~~~~~~~~~~~~~~
Although frontend drivers provide DVBv5 statistics via the .read_status
call, a nice addition would be to make additional statistics available to
userspace via debugfs, which is a simple-to-use, RAM-based filesystem
specifically designed for debug purposes.
The logic for this would be implemented on a separate file so as not to
pollute the frontend driver. These statistics are driver-specific and can
be useful during tests.
The Siano driver is one example of a driver using
debugfs to convey driver-specific statistics to userspace and it can be
used as a reference.
This should be further enabled and disabled via a Kconfig
option for convenience.
Add a way to test video
~~~~~~~~~~~~~~~~~~~~~~~
Currently, vidtv can only encode PCM audio. It would be great to implement
a barebones version of MPEG-2 video encoding so we can also test video. The
first place to look into is *ISO 13818-2: Information technology — Generic
coding of moving pictures and associated audio information — Part 2: Video*,
which covers the encoding of compressed video in MPEG Transport Streams.
This might optionally use the Video4Linux2 Test Pattern Generator, v4l2-tpg,
which resides at::
drivers/media/common/v4l2-tpg/
Add white noise simulation
~~~~~~~~~~~~~~~~~~~~~~~~~~
The vidtv tuner already has code to identify whether the chosen frequency
is too far away from a table of valid frequencies. For now, this means that
the demodulator can eventually lose the lock on the signal, since the tuner will
report a bad signal quality.
A nice addition is to simulate some noise when the signal quality is bad by:
- Randomly dropping some TS packets. This will trigger a continuity error if the
continuity counter is updated but the packet is not passed on to the demux.
- Updating the error statistics accordingly (e.g. BER, etc).
- Simulating some noise in the encoded data.