Documentation/usb/functionfs.rst - linux/kernel/git/bpf/bpf-next - Git at Google

 ====================
 How FunctionFS works
 ====================

 Overview
 ========

 From kernel point of view it is just a composite function with some
 unique behaviour.  It may be added to an USB configuration only after
 the user space driver has registered by writing descriptors and
 strings (the user space program has to provide the same information
 that kernel level composite functions provide when they are added to
 the configuration).

 This in particular means that the composite initialisation functions
 may not be in init section (ie. may not use the __init tag).

 From user space point of view it is a file system which when
 mounted provides an "ep0" file.  User space driver need to
 write descriptors and strings to that file.  It does not need
 to worry about endpoints, interfaces or strings numbers but
 simply provide descriptors such as if the function was the
 only one (endpoints and strings numbers starting from one and
 interface numbers starting from zero).  The FunctionFS changes
 them as needed also handling situation when numbers differ in
 different configurations.

 When descriptors and strings are written "ep#" files appear
 (one for each declared endpoint) which handle communication on
 a single endpoint.  Again, FunctionFS takes care of the real
 numbers and changing of the configuration (which means that
 "ep1" file may be really mapped to (say) endpoint 3 (and when
 configuration changes to (say) endpoint 2)).  "ep0" is used
 for receiving events and handling setup requests.

 When all files are closed the function disables itself.

 What I also want to mention is that the FunctionFS is designed in such
 a way that it is possible to mount it several times so in the end
 a gadget could use several FunctionFS functions. The idea is that
 each FunctionFS instance is identified by the device name used
 when mounting.

 One can imagine a gadget that has an Ethernet, MTP and HID interfaces
 where the last two are implemented via FunctionFS.  On user space
 level it would look like this::

   $ insmod g_ffs.ko idVendor=<ID> iSerialNumber=<string> functions=mtp,hid
   $ mkdir /dev/ffs-mtp && mount -t functionfs mtp /dev/ffs-mtp
   $ ( cd /dev/ffs-mtp && mtp-daemon ) &
   $ mkdir /dev/ffs-hid && mount -t functionfs hid /dev/ffs-hid
   $ ( cd /dev/ffs-hid && hid-daemon ) &

 On kernel level the gadget checks ffs_data->dev_name to identify
 whether its FunctionFS is designed for MTP ("mtp") or HID ("hid").

 If no "functions" module parameters is supplied, the driver accepts
 just one function with any name.

 When "functions" module parameter is supplied, only functions
 with listed names are accepted. In particular, if the "functions"
 parameter's value is just a one-element list, then the behaviour
 is similar to when there is no "functions" at all; however,
 only a function with the specified name is accepted.

 The gadget is registered only after all the declared function
 filesystems have been mounted and USB descriptors of all functions
 have been written to their ep0's.

 Conversely, the gadget is unregistered after the first USB function
 closes its endpoints.

 DMABUF interface
 ================

 FunctionFS additionally supports a DMABUF based interface, where the
 userspace can attach DMABUF objects (externally created) to an endpoint,
 and subsequently use them for data transfers.

 A userspace application can then use this interface to share DMABUF
 objects between several interfaces, allowing it to transfer data in a
 zero-copy fashion, for instance between IIO and the USB stack.

 As part of this interface, three new IOCTLs have been added. These three
 IOCTLs have to be performed on a data endpoint (ie. not ep0). They are:

   ``FUNCTIONFS_DMABUF_ATTACH(int)``
     Attach the DMABUF object, identified by its file descriptor, to the
     data endpoint. Returns zero on success, and a negative errno value
     on error.

   ``FUNCTIONFS_DMABUF_DETACH(int)``
     Detach the given DMABUF object, identified by its file descriptor,
     from the data endpoint. Returns zero on success, and a negative
     errno value on error. Note that closing the endpoint's file
     descriptor will automatically detach all attached DMABUFs.

   ``FUNCTIONFS_DMABUF_TRANSFER(struct usb_ffs_dmabuf_transfer_req *)``
     Enqueue the previously attached DMABUF to the transfer queue.
     The argument is a structure that packs the DMABUF's file descriptor,
     the size in bytes to transfer (which should generally correspond to
     the size of the DMABUF), and a 'flags' field which is unused
     for now. Returns zero on success, and a negative errno value on
     error.
	====================
	How FunctionFS works
	====================

	Overview
	========

	From kernel point of view it is just a composite function with some
	unique behaviour. It may be added to an USB configuration only after
	the user space driver has registered by writing descriptors and
	strings (the user space program has to provide the same information
	that kernel level composite functions provide when they are added to
	the configuration).

	This in particular means that the composite initialisation functions
	may not be in init section (ie. may not use the __init tag).

	From user space point of view it is a file system which when
	mounted provides an "ep0" file. User space driver need to
	write descriptors and strings to that file. It does not need
	to worry about endpoints, interfaces or strings numbers but
	simply provide descriptors such as if the function was the
	only one (endpoints and strings numbers starting from one and
	interface numbers starting from zero). The FunctionFS changes
	them as needed also handling situation when numbers differ in
	different configurations.

	When descriptors and strings are written "ep#" files appear
	(one for each declared endpoint) which handle communication on
	a single endpoint. Again, FunctionFS takes care of the real
	numbers and changing of the configuration (which means that
	"ep1" file may be really mapped to (say) endpoint 3 (and when
	configuration changes to (say) endpoint 2)). "ep0" is used
	for receiving events and handling setup requests.

	When all files are closed the function disables itself.

	What I also want to mention is that the FunctionFS is designed in such
	a way that it is possible to mount it several times so in the end
	a gadget could use several FunctionFS functions. The idea is that
	each FunctionFS instance is identified by the device name used
	when mounting.

	One can imagine a gadget that has an Ethernet, MTP and HID interfaces
	where the last two are implemented via FunctionFS. On user space
	level it would look like this::

	$ insmod g_ffs.ko idVendor=<ID> iSerialNumber=<string> functions=mtp,hid
	$ mkdir /dev/ffs-mtp && mount -t functionfs mtp /dev/ffs-mtp
	$ ( cd /dev/ffs-mtp && mtp-daemon ) &
	$ mkdir /dev/ffs-hid && mount -t functionfs hid /dev/ffs-hid
	$ ( cd /dev/ffs-hid && hid-daemon ) &

	On kernel level the gadget checks ffs_data->dev_name to identify
	whether its FunctionFS is designed for MTP ("mtp") or HID ("hid").

	If no "functions" module parameters is supplied, the driver accepts
	just one function with any name.

	When "functions" module parameter is supplied, only functions
	with listed names are accepted. In particular, if the "functions"
	parameter's value is just a one-element list, then the behaviour
	is similar to when there is no "functions" at all; however,
	only a function with the specified name is accepted.

	The gadget is registered only after all the declared function
	filesystems have been mounted and USB descriptors of all functions
	have been written to their ep0's.

	Conversely, the gadget is unregistered after the first USB function
	closes its endpoints.

	DMABUF interface
	================

	FunctionFS additionally supports a DMABUF based interface, where the
	userspace can attach DMABUF objects (externally created) to an endpoint,
	and subsequently use them for data transfers.

	A userspace application can then use this interface to share DMABUF
	objects between several interfaces, allowing it to transfer data in a
	zero-copy fashion, for instance between IIO and the USB stack.

	As part of this interface, three new IOCTLs have been added. These three
	IOCTLs have to be performed on a data endpoint (ie. not ep0). They are:

	``FUNCTIONFS_DMABUF_ATTACH(int)``
	Attach the DMABUF object, identified by its file descriptor, to the
	data endpoint. Returns zero on success, and a negative errno value
	on error.

	``FUNCTIONFS_DMABUF_DETACH(int)``
	Detach the given DMABUF object, identified by its file descriptor,
	from the data endpoint. Returns zero on success, and a negative
	errno value on error. Note that closing the endpoint's file
	descriptor will automatically detach all attached DMABUFs.

	``FUNCTIONFS_DMABUF_TRANSFER(struct usb_ffs_dmabuf_transfer_req *)``
	Enqueue the previously attached DMABUF to the transfer queue.
	The argument is a structure that packs the DMABUF's file descriptor,
	the size in bytes to transfer (which should generally correspond to
	the size of the DMABUF), and a 'flags' field which is unused
	for now. Returns zero on success, and a negative errno value on
	error.