Documentation/driver-api/driver-model/driver.rst - linux - Git at Google

 ==============
 Device Drivers
 ==============

 See the kerneldoc for the struct device_driver.

 Allocation
 ~~~~~~~~~~

 Device drivers are statically allocated structures. Though there may
 be multiple devices in a system that a driver supports, struct
 device_driver represents the driver as a whole (not a particular
 device instance).

 Initialization
 ~~~~~~~~~~~~~~

 The driver must initialize at least the name and bus fields. It should
 also initialize the devclass field (when it arrives), so it may obtain
 the proper linkage internally. It should also initialize as many of
 the callbacks as possible, though each is optional.

 Declaration
 ~~~~~~~~~~~

 As stated above, struct device_driver objects are statically
 allocated. Below is an example declaration of the eepro100
 driver. This declaration is hypothetical only; it relies on the driver
 being converted completely to the new model::

   static struct device_driver eepro100_driver = {
          .name		= "eepro100",
          .bus		= &pci_bus_type,

          .probe		= eepro100_probe,
          .remove		= eepro100_remove,
          .suspend		= eepro100_suspend,
          .resume		= eepro100_resume,
   };

 Most drivers will not be able to be converted completely to the new
 model because the bus they belong to has a bus-specific structure with
 bus-specific fields that cannot be generalized.

 The most common example of this are device ID structures. A driver
 typically defines an array of device IDs that it supports. The format
 of these structures and the semantics for comparing device IDs are
 completely bus-specific. Defining them as bus-specific entities would
 sacrifice type-safety, so we keep bus-specific structures around.

 Bus-specific drivers should include a generic struct device_driver in
 the definition of the bus-specific driver. Like this::

   struct pci_driver {
          const struct pci_device_id *id_table;
          struct device_driver	  driver;
   };

 A definition that included bus-specific fields would look like
 (using the eepro100 driver again)::

   static struct pci_driver eepro100_driver = {
          .id_table       = eepro100_pci_tbl,
          .driver	       = {
 		.name		= "eepro100",
 		.bus		= &pci_bus_type,
 		.probe		= eepro100_probe,
 		.remove		= eepro100_remove,
 		.suspend	= eepro100_suspend,
 		.resume		= eepro100_resume,
          },
   };

 Some may find the syntax of embedded struct initialization awkward or
 even a bit ugly. So far, it's the best way we've found to do what we want...

 Registration
 ~~~~~~~~~~~~

 ::

   int driver_register(struct device_driver *drv);

 The driver registers the structure on startup. For drivers that have
 no bus-specific fields (i.e. don't have a bus-specific driver
 structure), they would use driver_register and pass a pointer to their
 struct device_driver object.

 Most drivers, however, will have a bus-specific structure and will
 need to register with the bus using something like pci_driver_register.

 It is important that drivers register their driver structure as early as
 possible. Registration with the core initializes several fields in the
 struct device_driver object, including the reference count and the
 lock. These fields are assumed to be valid at all times and may be
 used by the device model core or the bus driver.


 Transition Bus Drivers
 ~~~~~~~~~~~~~~~~~~~~~~

 By defining wrapper functions, the transition to the new model can be
 made easier. Drivers can ignore the generic structure altogether and
 let the bus wrapper fill in the fields. For the callbacks, the bus can
 define generic callbacks that forward the call to the bus-specific
 callbacks of the drivers.

 This solution is intended to be only temporary. In order to get class
 information in the driver, the drivers must be modified anyway. Since
 converting drivers to the new model should reduce some infrastructural
 complexity and code size, it is recommended that they are converted as
 class information is added.

 Access
 ~~~~~~

 Once the object has been registered, it may access the common fields of
 the object, like the lock and the list of devices::

   int driver_for_each_dev(struct device_driver *drv, void *data,
 			  int (*callback)(struct device *dev, void *data));

 The devices field is a list of all the devices that have been bound to
 the driver. The LDM core provides a helper function to operate on all
 the devices a driver controls. This helper locks the driver on each
 node access, and does proper reference counting on each device as it
 accesses it.


 sysfs
 ~~~~~

 When a driver is registered, a sysfs directory is created in its
 bus's directory. In this directory, the driver can export an interface
 to userspace to control operation of the driver on a global basis;
 e.g. toggling debugging output in the driver.

 A future feature of this directory will be a 'devices' directory. This
 directory will contain symlinks to the directories of devices it
 supports.


 Callbacks
 ~~~~~~~~~

 ::

 	int	(*probe)	(struct device *dev);

 The probe() entry is called in task context, with the bus's rwsem locked
 and the driver partially bound to the device.  Drivers commonly use
 container_of() to convert "dev" to a bus-specific type, both in probe()
 and other routines.  That type often provides device resource data, such
 as pci_dev.resource[] or platform_device.resources, which is used in
 addition to dev->platform_data to initialize the driver.

 This callback holds the driver-specific logic to bind the driver to a
 given device.  That includes verifying that the device is present, that
 it's a version the driver can handle, that driver data structures can
 be allocated and initialized, and that any hardware can be initialized.
 Drivers often store a pointer to their state with dev_set_drvdata().
 When the driver has successfully bound itself to that device, then probe()
 returns zero and the driver model code will finish its part of binding
 the driver to that device.

 A driver's probe() may return a negative errno value to indicate that
 the driver did not bind to this device, in which case it should have
 released all resources it allocated.

 Optionally, probe() may return -EPROBE_DEFER if the driver depends on
 resources that are not yet available (e.g., supplied by a driver that
 hasn't initialized yet).  The driver core will put the device onto the
 deferred probe list and will try to call it again later. If a driver
 must defer, it should return -EPROBE_DEFER as early as possible to
 reduce the amount of time spent on setup work that will need to be
 unwound and reexecuted at a later time.

 .. warning::
       -EPROBE_DEFER must not be returned if probe() has already created
       child devices, even if those child devices are removed again
       in a cleanup path. If -EPROBE_DEFER is returned after a child
       device has been registered, it may result in an infinite loop of
       .probe() calls to the same driver.

 ::

 	void	(*sync_state)	(struct device *dev);

 sync_state is called only once for a device. It's called when all the consumer
 devices of the device have successfully probed. The list of consumers of the
 device is obtained by looking at the device links connecting that device to its
 consumer devices.

 The first attempt to call sync_state() is made during late_initcall_sync() to
 give firmware and drivers time to link devices to each other. During the first
 attempt at calling sync_state(), if all the consumers of the device at that
 point in time have already probed successfully, sync_state() is called right
 away. If there are no consumers of the device during the first attempt, that
 too is considered as "all consumers of the device have probed" and sync_state()
 is called right away.

 If during the first attempt at calling sync_state() for a device, there are
 still consumers that haven't probed successfully, the sync_state() call is
 postponed and reattempted in the future only when one or more consumers of the
 device probe successfully. If during the reattempt, the driver core finds that
 there are one or more consumers of the device that haven't probed yet, then
 sync_state() call is postponed again.

 A typical use case for sync_state() is to have the kernel cleanly take over
 management of devices from the bootloader. For example, if a device is left on
 and at a particular hardware configuration by the bootloader, the device's
 driver might need to keep the device in the boot configuration until all the
 consumers of the device have probed. Once all the consumers of the device have
 probed, the device's driver can synchronize the hardware state of the device to
 match the aggregated software state requested by all the consumers. Hence the
 name sync_state().

 While obvious examples of resources that can benefit from sync_state() include
 resources such as regulator, sync_state() can also be useful for complex
 resources like IOMMUs. For example, IOMMUs with multiple consumers (devices
 whose addresses are remapped by the IOMMU) might need to keep their mappings
 fixed at (or additive to) the boot configuration until all its consumers have
 probed.

 While the typical use case for sync_state() is to have the kernel cleanly take
 over management of devices from the bootloader, the usage of sync_state() is
 not restricted to that. Use it whenever it makes sense to take an action after
 all the consumers of a device have probed::

 	int 	(*remove)	(struct device *dev);

 remove is called to unbind a driver from a device. This may be
 called if a device is physically removed from the system, if the
 driver module is being unloaded, during a reboot sequence, or
 in other cases.

 It is up to the driver to determine if the device is present or
 not. It should free any resources allocated specifically for the
 device; i.e. anything in the device's driver_data field.

 If the device is still present, it should quiesce the device and place
 it into a supported low-power state.

 ::

 	int	(*suspend)	(struct device *dev, pm_message_t state);

 suspend is called to put the device in a low power state.

 ::

 	int	(*resume)	(struct device *dev);

 Resume is used to bring a device back from a low power state.


 Attributes
 ~~~~~~~~~~

 ::

   struct driver_attribute {
           struct attribute        attr;
           ssize_t (*show)(struct device_driver *driver, char *buf);
           ssize_t (*store)(struct device_driver *, const char *buf, size_t count);
   };

 Device drivers can export attributes via their sysfs directories.
 Drivers can declare attributes using a DRIVER_ATTR_RW and DRIVER_ATTR_RO
 macro that works identically to the DEVICE_ATTR_RW and DEVICE_ATTR_RO
 macros.

 Example::

 	DRIVER_ATTR_RW(debug);

 This is equivalent to declaring::

 	struct driver_attribute driver_attr_debug;

 This can then be used to add and remove the attribute from the
 driver's directory using::

   int driver_create_file(struct device_driver *, const struct driver_attribute *);
   void driver_remove_file(struct device_driver *, const struct driver_attribute *);
	==============
	Device Drivers
	==============

	See the kerneldoc for the struct device_driver.

	Allocation
	~~~~~~~~~~

	Device drivers are statically allocated structures. Though there may
	be multiple devices in a system that a driver supports, struct
	device_driver represents the driver as a whole (not a particular
	device instance).

	Initialization
	~~~~~~~~~~~~~~

	The driver must initialize at least the name and bus fields. It should
	also initialize the devclass field (when it arrives), so it may obtain
	the proper linkage internally. It should also initialize as many of
	the callbacks as possible, though each is optional.

	Declaration
	~~~~~~~~~~~

	As stated above, struct device_driver objects are statically
	allocated. Below is an example declaration of the eepro100
	driver. This declaration is hypothetical only; it relies on the driver
	being converted completely to the new model::

	static struct device_driver eepro100_driver = {
	.name = "eepro100",
	.bus = &pci_bus_type,

	.probe = eepro100_probe,
	.remove = eepro100_remove,
	.suspend = eepro100_suspend,
	.resume = eepro100_resume,
	};

	Most drivers will not be able to be converted completely to the new
	model because the bus they belong to has a bus-specific structure with
	bus-specific fields that cannot be generalized.

	The most common example of this are device ID structures. A driver
	typically defines an array of device IDs that it supports. The format
	of these structures and the semantics for comparing device IDs are
	completely bus-specific. Defining them as bus-specific entities would
	sacrifice type-safety, so we keep bus-specific structures around.

	Bus-specific drivers should include a generic struct device_driver in
	the definition of the bus-specific driver. Like this::

	struct pci_driver {
	const struct pci_device_id *id_table;
	struct device_driver driver;
	};

	A definition that included bus-specific fields would look like
	(using the eepro100 driver again)::

	static struct pci_driver eepro100_driver = {
	.id_table = eepro100_pci_tbl,
	.driver = {
	.name = "eepro100",
	.bus = &pci_bus_type,
	.probe = eepro100_probe,
	.remove = eepro100_remove,
	.suspend = eepro100_suspend,
	.resume = eepro100_resume,
	},
	};

	Some may find the syntax of embedded struct initialization awkward or
	even a bit ugly. So far, it's the best way we've found to do what we want...

	Registration
	~~~~~~~~~~~~

	::

	int driver_register(struct device_driver *drv);

	The driver registers the structure on startup. For drivers that have
	no bus-specific fields (i.e. don't have a bus-specific driver
	structure), they would use driver_register and pass a pointer to their
	struct device_driver object.

	Most drivers, however, will have a bus-specific structure and will
	need to register with the bus using something like pci_driver_register.

	It is important that drivers register their driver structure as early as
	possible. Registration with the core initializes several fields in the
	struct device_driver object, including the reference count and the
	lock. These fields are assumed to be valid at all times and may be
	used by the device model core or the bus driver.


	Transition Bus Drivers
	~~~~~~~~~~~~~~~~~~~~~~

	By defining wrapper functions, the transition to the new model can be
	made easier. Drivers can ignore the generic structure altogether and
	let the bus wrapper fill in the fields. For the callbacks, the bus can
	define generic callbacks that forward the call to the bus-specific
	callbacks of the drivers.

	This solution is intended to be only temporary. In order to get class
	information in the driver, the drivers must be modified anyway. Since
	converting drivers to the new model should reduce some infrastructural
	complexity and code size, it is recommended that they are converted as
	class information is added.

	Access
	~~~~~~

	Once the object has been registered, it may access the common fields of
	the object, like the lock and the list of devices::

	int driver_for_each_dev(struct device_driver drv, void data,
	int (callback)(struct device dev, void *data));

	The devices field is a list of all the devices that have been bound to
	the driver. The LDM core provides a helper function to operate on all
	the devices a driver controls. This helper locks the driver on each
	node access, and does proper reference counting on each device as it
	accesses it.


	sysfs
	~~~~~

	When a driver is registered, a sysfs directory is created in its
	bus's directory. In this directory, the driver can export an interface
	to userspace to control operation of the driver on a global basis;
	e.g. toggling debugging output in the driver.

	A future feature of this directory will be a 'devices' directory. This
	directory will contain symlinks to the directories of devices it
	supports.



	Callbacks
	~~~~~~~~~

	::

	int (probe) (struct device dev);

	The probe() entry is called in task context, with the bus's rwsem locked
	and the driver partially bound to the device. Drivers commonly use
	container_of() to convert "dev" to a bus-specific type, both in probe()
	and other routines. That type often provides device resource data, such
	as pci_dev.resource[] or platform_device.resources, which is used in
	addition to dev->platform_data to initialize the driver.

	This callback holds the driver-specific logic to bind the driver to a
	given device. That includes verifying that the device is present, that
	it's a version the driver can handle, that driver data structures can
	be allocated and initialized, and that any hardware can be initialized.
	Drivers often store a pointer to their state with dev_set_drvdata().
	When the driver has successfully bound itself to that device, then probe()
	returns zero and the driver model code will finish its part of binding
	the driver to that device.

	A driver's probe() may return a negative errno value to indicate that
	the driver did not bind to this device, in which case it should have
	released all resources it allocated.

	Optionally, probe() may return -EPROBE_DEFER if the driver depends on
	resources that are not yet available (e.g., supplied by a driver that
	hasn't initialized yet). The driver core will put the device onto the
	deferred probe list and will try to call it again later. If a driver
	must defer, it should return -EPROBE_DEFER as early as possible to
	reduce the amount of time spent on setup work that will need to be
	unwound and reexecuted at a later time.

	.. warning::
	-EPROBE_DEFER must not be returned if probe() has already created
	child devices, even if those child devices are removed again
	in a cleanup path. If -EPROBE_DEFER is returned after a child
	device has been registered, it may result in an infinite loop of
	.probe() calls to the same driver.

	::

	void (sync_state) (struct device dev);

	sync_state is called only once for a device. It's called when all the consumer
	devices of the device have successfully probed. The list of consumers of the
	device is obtained by looking at the device links connecting that device to its
	consumer devices.

	The first attempt to call sync_state() is made during late_initcall_sync() to
	give firmware and drivers time to link devices to each other. During the first
	attempt at calling sync_state(), if all the consumers of the device at that
	point in time have already probed successfully, sync_state() is called right
	away. If there are no consumers of the device during the first attempt, that
	too is considered as "all consumers of the device have probed" and sync_state()
	is called right away.

	If during the first attempt at calling sync_state() for a device, there are
	still consumers that haven't probed successfully, the sync_state() call is
	postponed and reattempted in the future only when one or more consumers of the
	device probe successfully. If during the reattempt, the driver core finds that
	there are one or more consumers of the device that haven't probed yet, then
	sync_state() call is postponed again.

	A typical use case for sync_state() is to have the kernel cleanly take over
	management of devices from the bootloader. For example, if a device is left on
	and at a particular hardware configuration by the bootloader, the device's
	driver might need to keep the device in the boot configuration until all the
	consumers of the device have probed. Once all the consumers of the device have
	probed, the device's driver can synchronize the hardware state of the device to
	match the aggregated software state requested by all the consumers. Hence the
	name sync_state().

	While obvious examples of resources that can benefit from sync_state() include
	resources such as regulator, sync_state() can also be useful for complex
	resources like IOMMUs. For example, IOMMUs with multiple consumers (devices
	whose addresses are remapped by the IOMMU) might need to keep their mappings
	fixed at (or additive to) the boot configuration until all its consumers have
	probed.

	While the typical use case for sync_state() is to have the kernel cleanly take
	over management of devices from the bootloader, the usage of sync_state() is
	not restricted to that. Use it whenever it makes sense to take an action after
	all the consumers of a device have probed::

	int (remove) (struct device dev);

	remove is called to unbind a driver from a device. This may be
	called if a device is physically removed from the system, if the
	driver module is being unloaded, during a reboot sequence, or
	in other cases.

	It is up to the driver to determine if the device is present or
	not. It should free any resources allocated specifically for the
	device; i.e. anything in the device's driver_data field.

	If the device is still present, it should quiesce the device and place
	it into a supported low-power state.

	::

	int (suspend) (struct device dev, pm_message_t state);

	suspend is called to put the device in a low power state.

	::

	int (resume) (struct device dev);

	Resume is used to bring a device back from a low power state.


	Attributes
	~~~~~~~~~~

	::

	struct driver_attribute {
	struct attribute attr;
	ssize_t (show)(struct device_driver driver, char *buf);
	ssize_t (store)(struct device_driver , const char *buf, size_t count);
	};

	Device drivers can export attributes via their sysfs directories.
	Drivers can declare attributes using a DRIVER_ATTR_RW and DRIVER_ATTR_RO
	macro that works identically to the DEVICE_ATTR_RW and DEVICE_ATTR_RO
	macros.

	Example::

	DRIVER_ATTR_RW(debug);

	This is equivalent to declaring::

	struct driver_attribute driver_attr_debug;

	This can then be used to add and remove the attribute from the
	driver's directory using::

	int driver_create_file(struct device_driver , const struct driver_attribute );
	void driver_remove_file(struct device_driver , const struct driver_attribute );