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staging: most: update driver usage file 

This patch keeps the usage file up to date.

Signed-off-by: Christian Gromm <christian.gromm@microchip.com>
Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
This commit is contained in:
Andrey Shvetsov 2017-11-21 15:05:18 +01:00 committed by Greg Kroah-Hartman
parent 3ba5515bf4
commit 2525ef557c
1 changed files with 107 additions and 89 deletions
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196
drivers/staging/most/Documentation/driver_usage.txt
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@ -23,20 +23,29 @@ audio/video streaming. Therefore, the driver perfectly fits to the mission
of Automotive Grade Linux to create open source software solutions for
automotive applications.
The driver consists basically of three layers. The hardware layer, the
core layer and the application layer. The core layer consists of the core
module only. This module handles the communication flow through all three
layers, the configuration of the driver, the configuration interface
representation in sysfs, and the buffer management.
For each of the other two layers a selection of modules is provided. These
modules can arbitrarily be combined to meet the needs of the desired
system architecture. A module of the hardware layer is referred to as an
HDM (hardware dependent module). Each module of this layer handles exactly
one of the peripheral interfaces of a network interface controller (e.g.
USB, MediaLB, I2C). A module of the application layer is referred to as an
AIM (application interfacing module). The modules of this layer give access
to MOST via one the following ways: character devices, ALSA, Networking or
V4L2.
The MOST driver uses module stacking to divide the associated modules into
three layers. From bottom up these layers are: the adapter layer, the core
layer and the application layer. The core layer implements the MOST
subsystem and consists basically of the module core.c and its API. It
registers the MOST bus with the kernel's device model, handles the data
routing through all three layers, the configuration of the driver, the
representation of the configuration interface in sysfs and the buffer
management.
For each of the other two layers a set of modules is provided. Those can be
arbitrarily combined with the core to meet the connectivity of the desired
system architecture.
A module of the adapter layer is basically a device driver for a different
subsystem. It is registered with the core to connect the MOST subsystem to
the attached network interface controller hardware. Hence, a given module
of this layer is designed to handle exactly one of the peripheral
interfaces (e.g. USB, MediaLB, I2C) the hardware provides.
A module of the application layer is referred to as a core comoponent,
which kind of extends the core by providing connectivity to the user space.
Applications, then, can access a MOST network via character devices, an
ALSA soundcard, a Network adapter or a V4L2 capture device.
To physically access MOST, an Intelligent Network Interface Controller
(INIC) is needed. For more information on available controllers visit:
@ -44,15 +53,14 @@ www.microchip.com
Section 1.1 Hardware Layer
Section 1.1 Adapter Layer
The hardware layer contains so called hardware dependent modules (HDM). For each
peripheral interface the hardware supports the driver has a suitable module
that handles the interface.
The HDMs encapsulate the peripheral interface specific knowledge of the driver
and provides an easy way of extending the number of supported interfaces.
Currently the following HDMs are available:
The adapter layer contains a pool of device drivers. For each peripheral
interface the hardware supports there is one suitable module that handles
the interface. Adapter drivers encapsulate the peripheral interface
specific knowledge of the MOST driver stack and provide an easy way of
extending the number of supported interfaces. Currently the following
interfaces are available:
1) MediaLB (DIM2)
Host wants to communicate with hardware via MediaLB.
@ -63,26 +71,34 @@ Currently the following HDMs are available:
3) USB
Host wants to communicate with the hardware via USB.
Once an adapter driver recognizes a MOST device being attached, it
registers it with the core, which, in turn, assigns the necessary members
of the embedded struct device (e.g. the bus this device belongs to and
attribute groups) and registers it with the kernel's device model.
Section 1.2 Core Layer
The core layer contains the mostcore module only, which processes the driver
configuration via sysfs, buffer management and data forwarding.
This layer implements the MOST subsystem. It contains the core module and
the header file most.h that exposes the API of the core. When inserted in
the kernel, it registers the MOST bus_type with the kernel's device model
and registers itself as a device driver for this bus. Besides these meta
tasks the core populates the configuration directory for a registered MOST
device (represented by struct most_interface) in sysfs and processes the
configuration of the device's interface. The core layer also handles the
buffer management and the data/message routing.
Section 1.3 Application Layer
Section 1.2 Application Layer
The application layer contains so called application interfacing modules (AIM).
Depending on how the driver should interface to the application, one or more
suitable modules can be selected.
The AIMs encapsulate the application interface specific knowledge of the driver
and provides access to user space or other kernel subsystems.
Currently the following AIMs are available
This layer contains a pool of device drivers that are components of the
core designed to make up the userspace experience of the MOST driver stack.
Depending on how an application is meant to interface the driver, one or
more modules of this pool can be registered with the core. Currently the
following components are available
1) Character Device
Applications can access the driver by means of character devices.
Userspace can access the driver by means of character devices.
2) Networking
Standard networking applications (e.g. iperf) can by used to access
@ -97,26 +113,62 @@ Currently the following AIMs are available
used to access the driver via the ALSA subsystem.
Section 2 Usage of the MOST Driver
Section 2 Configuration
Section 2.1 Configuration
See ABI/sysfs-class-most.txt
See ABI/sysfs-bus-most.txt
Section 2.2 Routing Channels
To connect a configured channel to a certain core component and make it
accessible for user space applications, the driver attribute 'add_link' is
used. The configuration string passed to it has the following format:
"device_name:channel_name:component_name:link_name[.param]"
It is the concatenation of up to four substrings separated by a colon. The
substrings contain the names of the MOST interface, the channel, the
component driver and a custom name with which the link is going to be
referenced with. Since some components need additional information, the
link name can be extended with a component-specific parameter (separated by
a dot). In case the character device component is loaded, the handle would
also appear as a device node in the /dev directory.
Cdev component example:
$ echo "mdev0:ep_81:cdev:my_rx_channel" >$(DRV_DIR)/add_link
Sound component example:
The sound component needs an additional parameter to determine the audio
resolution that is going to be used. The following formats are available:
- "1x8" (Mono)
- "2x16" (16-bit stereo)
- "2x24" (24-bit stereo)
- "2x32" (32-bit stereo)
- "6x16" (16-bit surround 5.1)
$ echo "mdev0:ep_81:sound:most51_playback.6x16" >$(DRV_DIR)/add_link
Section 3 USB Padding
Section 2.3 USB Padding
When transceiving synchronous or isochronous data, the number of packets per USB
transaction and the sub-buffer size need to be configured. These values
are needed for the driver to process buffer padding, as expected by hardware,
which is for performance optimization purposes of the USB transmission.
When transceiving synchronous or isochronous data, the number of packets
per USB transaction and the sub-buffer size need to be configured. These
values are needed for the driver to process buffer padding, as expected by
hardware, which is for performance optimization purposes of the USB
transmission.
When transmitting synchronous data the allocated channel width needs to be
written to 'set_subbuffer_size'. Additionally, the number of MOST frames that
should travel to the host within one USB transaction need to be written to
'packets_per_xact'.
written to 'set_subbuffer_size'. Additionally, the number of MOST frames
that should travel to the host within one USB transaction need to be
written to 'packets_per_xact'.
Internally the synchronous threshold is calculated as follows:
The driver, then, calculates the synchronous threshold as follows:
frame_size = set_subbuffer_size * packets_per_xact
@ -126,55 +178,21 @@ USB full packet.
frame_size = floor(MTU_USB / bandwidth_sync) * bandwidth_sync
This frame_size is the number of synchronous data within an USB transaction,
which renders MTU_USB - frame_size bytes for padding.
This frame_size is the number of synchronous data within an USB
transaction, which renders MTU_USB - frame_size bytes for padding.
When transmitting isochronous AVP data the desired packet size needs to be
written to 'set_subbuffer_size' and hardware will always expect two isochronous
packets within one USB transaction. This renders
written to 'set_subbuffer_size' and hardware will always expect two
isochronous packets within one USB transaction. This renders
MTU_USB - (2 * set_subbuffer_size)
bytes for padding.
Note that at least 2 times set_subbuffer_size bytes for isochronous data or
set_subbuffer_size times packts_per_xact bytes for synchronous data need to be
put in the transmission buffer and passed to the driver.
Note that at least (2 * set_subbuffer_size) bytes for isochronous data or
(set_subbuffer_size * packts_per_xact) bytes for synchronous data need to
be put in the transmission buffer and passed to the driver.
Since HDMs are allowed to change a chosen configuration to best fit its
constraints, it is recommended to always double check the configuration and read
back the previously written files.
Section 4 Routing Channels
To connect a channel that has been configured as outlined above to an AIM and
make it accessible to user space applications, the attribute file 'add_link' is
used. To actually bind a channel to the AIM a string needs to be written to the
file that complies with the following syntax:
"most_device:channel_name:link_name[.param]"
The example above links the channel "channel_name" of the device "most_device"
to the AIM. In case the AIM interfaces the VFS this would also create a device
node "link_name" in the /dev directory. The parameter "param" is an AIM dependent
string, which can be omitted in case the used AIM does not make any use of it.
Cdev AIM example:
$ echo "mdev0:ep_81:my_rx_channel" >add_link
$ echo "mdev0:ep_81" >add_link
Sound/ALSA AIM example:
The sound/ALSA AIM needs an additional parameter to determine the audio resolution
that is going to be used. The following strings can be used:
- "1x8" (Mono)
- "2x16" (16-bit stereo)
- "2x24" (24-bit stereo)
- "2x32" (32-bit stereo)
$ echo "mdev0:ep_81:audio_rx.2x16" >add_link
$ echo "mdev0:ep_81" >add_link
Since adapter drivers are allowed to change a chosen configuration to best
fit its constraints, it is recommended to always double check the
configuration and read back the previously written files.