From: Andrey Shvetsov <andrey.shvetsov@xxxxxx> This patch keeps the usage file up to date. Signed-off-by: Christian Gromm <christian.gromm@xxxxxxxxxxxxx> --- .../staging/most/Documentation/driver_usage.txt | 192 +++++++++++---------- 1 file changed, 105 insertions(+), 87 deletions(-) diff --git a/drivers/staging/most/Documentation/driver_usage.txt b/drivers/staging/most/Documentation/driver_usage.txt index a4dc0c3..bb9b4e8 100644 --- a/drivers/staging/most/Documentation/driver_usage.txt +++ b/drivers/staging/most/Documentation/driver_usage.txt @@ -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. + Section 1.2 Core Layer +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 1.2 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. + Section 1.3 Application Layer -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 @@ -97,84 +113,86 @@ 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 - Section 3 USB Padding +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: -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. + "device_name:channel_name:component_name:link_name[.param]" -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'. +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. -Internally the synchronous threshold is calculated as follows: +Cdev component example: + $ echo "mdev0:ep_81:cdev:my_rx_channel" >$(DRV_DIR)/add_link - frame_size = set_subbuffer_size * packets_per_xact -In case 'packets_per_xact' is set to 0xFF the maximum number of packets, -allocated within one MOST frame, is calculated that fit into _one_ 512 byte -USB full packet. +Sound component example: - frame_size = floor(MTU_USB / bandwidth_sync) * bandwidth_sync +The sound component needs an additional parameter to determine the audio +resolution that is going to be used. The following formats are available: -This frame_size is the number of synchronous data within an USB transaction, -which renders MTU_USB - frame_size bytes for padding. + - "1x8" (Mono) + - "2x16" (16-bit stereo) + - "2x24" (24-bit stereo) + - "2x32" (32-bit stereo) + - "6x16" (16-bit surround 5.1) -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 + $ echo "mdev0:ep_81:sound:most51_playback.6x16" >$(DRV_DIR)/add_link - 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. -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 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 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'. - Section 4 Routing Channels +The driver, then, calculates the synchronous threshold as follows: -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: + frame_size = set_subbuffer_size * packets_per_xact - "most_device:channel_name:link_name[.param]" +In case 'packets_per_xact' is set to 0xFF the maximum number of packets, +allocated within one MOST frame, is calculated that fit into _one_ 512 byte +USB full packet. -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. + frame_size = floor(MTU_USB / bandwidth_sync) * bandwidth_sync -Cdev AIM example: - $ echo "mdev0:ep_81:my_rx_channel" >add_link - $ echo "mdev0:ep_81" >add_link +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 -Sound/ALSA AIM example: + MTU_USB - (2 * set_subbuffer_size) -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: +bytes for padding. - - "1x8" (Mono) - - "2x16" (16-bit stereo) - - "2x24" (24-bit stereo) - - "2x32" (32-bit stereo) +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. - $ 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. -- 2.7.4 _______________________________________________ devel mailing list devel@xxxxxxxxxxxxxxxxxxxxxx http://driverdev.linuxdriverproject.org/mailman/listinfo/driverdev-devel