Documentation/tty/tty_driver.rst - linux - Git at Google

 .. SPDX-License-Identifier: GPL-2.0

 =============================
 TTY Driver and TTY Operations
 =============================

 .. contents:: :local:

 Allocation
 ==========

 The first thing a driver needs to do is to allocate a struct tty_driver. This
 is done by tty_alloc_driver() (or __tty_alloc_driver()). Next, the newly
 allocated structure is filled with information. See `TTY Driver Reference`_ at
 the end of this document on what actually shall be filled in.

 The allocation routines expect a number of devices the driver can handle at
 most and flags. Flags are those starting ``TTY_DRIVER_`` listed and described
 in `TTY Driver Flags`_ below.

 When the driver is about to be freed, tty_driver_kref_put() is called on that.
 It will decrements the reference count and if it reaches zero, the driver is
 freed.

 For reference, both allocation and deallocation functions are explained here in
 detail:

 .. kernel-doc:: drivers/tty/tty_io.c
    :identifiers: __tty_alloc_driver tty_driver_kref_put

 TTY Driver Flags
 ----------------

 Here comes the documentation of flags accepted by tty_alloc_driver() (or
 __tty_alloc_driver()):

 .. kernel-doc:: include/linux/tty_driver.h
    :doc: TTY Driver Flags

 ----

 Registration
 ============

 When a struct tty_driver is allocated and filled in, it can be registered using
 tty_register_driver(). It is recommended to pass ``TTY_DRIVER_DYNAMIC_DEV`` in
 flags of tty_alloc_driver(). If it is not passed, *all* devices are also
 registered during tty_register_driver() and the following paragraph of
 registering devices can be skipped for such drivers. However, the struct
 tty_port part in `Registering Devices`_ is still relevant there.

 .. kernel-doc:: drivers/tty/tty_io.c
    :identifiers: tty_register_driver tty_unregister_driver

 Registering Devices
 -------------------

 Every TTY device shall be backed by a struct tty_port. Usually, TTY drivers
 embed tty_port into device's private structures. Further details about handling
 tty_port can be found in :doc:`tty_port`. The driver is also recommended to use
 tty_port's reference counting by tty_port_get() and tty_port_put(). The final
 put is supposed to free the tty_port including the device's private struct.

 Unless ``TTY_DRIVER_DYNAMIC_DEV`` was passed as flags to tty_alloc_driver(),
 TTY driver is supposed to register every device discovered in the system
 (the latter is preferred). This is performed by tty_register_device(). Or by
 tty_register_device_attr() if the driver wants to expose some information
 through struct attribute_group. Both of them register ``index``'th device and
 upon return, the device can be opened. There are also preferred tty_port
 variants described in `Linking Devices to Ports`_ later. It is up to driver to
 manage free indices and choosing the right one. The TTY layer only refuses to
 register more devices than passed to tty_alloc_driver().

 When the device is opened, the TTY layer allocates struct tty_struct and starts
 calling operations from :c:member:`tty_driver.ops`, see `TTY Operations
 Reference`_.

 The registration routines are documented as follows:

 .. kernel-doc:: drivers/tty/tty_io.c
    :identifiers: tty_register_device tty_register_device_attr
         tty_unregister_device

 ----

 Linking Devices to Ports
 ------------------------
 As stated earlier, every TTY device shall have a struct tty_port assigned to
 it. It must be known to the TTY layer at :c:member:`tty_driver.ops.install()`
 at latest.  There are few helpers to *link* the two. Ideally, the driver uses
 tty_port_register_device() or tty_port_register_device_attr() instead of
 tty_register_device() and tty_register_device_attr() at the registration time.
 This way, the driver needs not care about linking later on.

 If that is not possible, the driver still can link the tty_port to a specific
 index *before* the actual registration by tty_port_link_device(). If it still
 does not fit, tty_port_install() can be used from the
 :c:member:`tty_driver.ops.install` hook as a last resort. The last one is
 dedicated mostly for in-memory devices like PTY where tty_ports are allocated
 on demand.

 The linking routines are documented here:

 .. kernel-doc::  drivers/tty/tty_port.c
    :identifiers: tty_port_link_device tty_port_register_device
         tty_port_register_device_attr

 ----

 TTY Driver Reference
 ====================

 All members of struct tty_driver are documented here. The required members are
 noted at the end. struct tty_operations are documented next.

 .. kernel-doc:: include/linux/tty_driver.h
    :identifiers: tty_driver

 ----

 TTY Operations Reference
 ========================

 When a TTY is registered, these driver hooks can be invoked by the TTY layer:

 .. kernel-doc:: include/linux/tty_driver.h
    :identifiers: tty_operations
	.. SPDX-License-Identifier: GPL-2.0

	=============================
	TTY Driver and TTY Operations
	=============================

	.. contents:: :local:

	Allocation
	==========

	The first thing a driver needs to do is to allocate a struct tty_driver. This
	is done by tty_alloc_driver() (or __tty_alloc_driver()). Next, the newly
	allocated structure is filled with information. See `TTY Driver Reference`_ at
	the end of this document on what actually shall be filled in.

	The allocation routines expect a number of devices the driver can handle at
	most and flags. Flags are those starting ``TTY_DRIVER_`` listed and described
	in `TTY Driver Flags`_ below.

	When the driver is about to be freed, tty_driver_kref_put() is called on that.
	It will decrements the reference count and if it reaches zero, the driver is
	freed.

	For reference, both allocation and deallocation functions are explained here in
	detail:

	.. kernel-doc:: drivers/tty/tty_io.c
	:identifiers: __tty_alloc_driver tty_driver_kref_put

	TTY Driver Flags
	----------------

	Here comes the documentation of flags accepted by tty_alloc_driver() (or
	__tty_alloc_driver()):

	.. kernel-doc:: include/linux/tty_driver.h
	:doc: TTY Driver Flags

	----

	Registration
	============

	When a struct tty_driver is allocated and filled in, it can be registered using
	tty_register_driver(). It is recommended to pass ``TTY_DRIVER_DYNAMIC_DEV`` in
	flags of tty_alloc_driver(). If it is not passed, all devices are also
	registered during tty_register_driver() and the following paragraph of
	registering devices can be skipped for such drivers. However, the struct
	tty_port part in `Registering Devices`_ is still relevant there.

	.. kernel-doc:: drivers/tty/tty_io.c
	:identifiers: tty_register_driver tty_unregister_driver

	Registering Devices
	-------------------

	Every TTY device shall be backed by a struct tty_port. Usually, TTY drivers
	embed tty_port into device's private structures. Further details about handling
	tty_port can be found in :doc:`tty_port`. The driver is also recommended to use
	tty_port's reference counting by tty_port_get() and tty_port_put(). The final
	put is supposed to free the tty_port including the device's private struct.

	Unless ``TTY_DRIVER_DYNAMIC_DEV`` was passed as flags to tty_alloc_driver(),
	TTY driver is supposed to register every device discovered in the system
	(the latter is preferred). This is performed by tty_register_device(). Or by
	tty_register_device_attr() if the driver wants to expose some information
	through struct attribute_group. Both of them register ``index``'th device and
	upon return, the device can be opened. There are also preferred tty_port
	variants described in `Linking Devices to Ports`_ later. It is up to driver to
	manage free indices and choosing the right one. The TTY layer only refuses to
	register more devices than passed to tty_alloc_driver().

	When the device is opened, the TTY layer allocates struct tty_struct and starts
	calling operations from :c:member:`tty_driver.ops`, see `TTY Operations
	Reference`_.

	The registration routines are documented as follows:

	.. kernel-doc:: drivers/tty/tty_io.c
	:identifiers: tty_register_device tty_register_device_attr
	tty_unregister_device

	----

	Linking Devices to Ports
	------------------------
	As stated earlier, every TTY device shall have a struct tty_port assigned to
	it. It must be known to the TTY layer at :c:member:`tty_driver.ops.install()`
	at latest. There are few helpers to link the two. Ideally, the driver uses
	tty_port_register_device() or tty_port_register_device_attr() instead of
	tty_register_device() and tty_register_device_attr() at the registration time.
	This way, the driver needs not care about linking later on.

	If that is not possible, the driver still can link the tty_port to a specific
	index before the actual registration by tty_port_link_device(). If it still
	does not fit, tty_port_install() can be used from the
	:c:member:`tty_driver.ops.install` hook as a last resort. The last one is
	dedicated mostly for in-memory devices like PTY where tty_ports are allocated
	on demand.

	The linking routines are documented here:

	.. kernel-doc:: drivers/tty/tty_port.c
	:identifiers: tty_port_link_device tty_port_register_device
	tty_port_register_device_attr

	----

	TTY Driver Reference
	====================

	All members of struct tty_driver are documented here. The required members are
	noted at the end. struct tty_operations are documented next.

	.. kernel-doc:: include/linux/tty_driver.h
	:identifiers: tty_driver

	----

	TTY Operations Reference
	========================

	When a TTY is registered, these driver hooks can be invoked by the TTY layer:

	.. kernel-doc:: include/linux/tty_driver.h
	:identifiers: tty_operations