Documentation/eisa.txt - arm/linux-arm64-legacy - Git at Google

 EISA bus support (Marc Zyngier <maz@wild-wind.fr.eu.org>)

 This document groups random notes about porting EISA drivers to the
 new EISA/sysfs API.

 Starting from version 2.5.59, the EISA bus is almost given the same
 status as other much more mainstream busses such as PCI or USB. This
 has been possible through sysfs, which defines a nice enough set of
 abstractions to manage busses, devices and drivers.

 Although the new API is quite simple to use, converting existing
 drivers to the new infrastructure is not an easy task (mostly because
 detection code is generally also used to probe ISA cards). Moreover,
 most EISA drivers are among the oldest Linux drivers so, as you can
 imagine, some dust has settled here over the years.

 The EISA infrastructure is made up of three parts :

     - The bus code implements most of the generic code. It is shared
     among all the architectures that the EISA code runs on. It
     implements bus probing (detecting EISA cards available on the bus),
     allocates I/O resources, allows fancy naming through sysfs, and
     offers interfaces for driver to register.

     - The bus root driver implements the glue between the bus hardware
     and the generic bus code. It is responsible for discovering the
     device implementing the bus, and setting it up to be latter probed
     by the bus code. This can go from something as simple as reserving
     an I/O region on x86, to the rather more complex, like the hppa
     EISA code. This is the part to implement in order to have EISA
     running on an "new" platform.

     - The driver offers the bus a list of devices that it manages, and
     implements the necessary callbacks to probe and release devices
     whenever told to.

 Every function/structure below lives in <linux/eisa.h>, which depends
 heavily on <linux/device.h>.

 ** Bus root driver :

 int eisa_root_register (struct eisa_root_device *root);

 The eisa_root_register function is used to declare a device as the
 root of an EISA bus. The eisa_root_device structure holds a reference
 to this device, as well as some parameters for probing purposes.

 struct eisa_root_device {
 	struct device   *dev;	 /* Pointer to bridge device */
 	struct resource *res;
 	unsigned long    bus_base_addr;
 	int		 slots;  /* Max slot number */
 	int		 force_probe; /* Probe even when no slot 0 */
 	u64		 dma_mask; /* from bridge device */
 	int              bus_nr; /* Set by eisa_root_register */
 	struct resource  eisa_root_res;	/* ditto */
 };

 node          : used for eisa_root_register internal purpose
 dev           : pointer to the root device
 res           : root device I/O resource
 bus_base_addr : slot 0 address on this bus
 slots	      : max slot number to probe
 force_probe   : Probe even when slot 0 is empty (no EISA mainboard)
 dma_mask      : Default DMA mask. Usually the bridge device dma_mask.
 bus_nr	      : unique bus id, set by eisa_root_register

 ** Driver :

 int eisa_driver_register (struct eisa_driver *edrv);
 void eisa_driver_unregister (struct eisa_driver *edrv);

 Clear enough ?

 struct eisa_device_id {
         char sig[EISA_SIG_LEN];
 	unsigned long driver_data;
 };

 struct eisa_driver {
         const struct eisa_device_id *id_table;
         struct device_driver         driver;
 };

 id_table	: an array of NULL terminated EISA id strings,
 		  followed by an empty string. Each string can
 		  optionally be paired with a driver-dependant value
 		  (driver_data).

 driver		: a generic driver, such as described in
 		  Documentation/driver-model/driver.txt. Only .name,
 		  .probe and .remove members are mandatory.

 An example is the 3c59x driver :

 static struct eisa_device_id vortex_eisa_ids[] = {
 	{ "TCM5920", EISA_3C592_OFFSET },
 	{ "TCM5970", EISA_3C597_OFFSET },
 	{ "" }
 };

 static struct eisa_driver vortex_eisa_driver = {
 	.id_table = vortex_eisa_ids,
 	.driver   = {
 		.name    = "3c59x",
 		.probe   = vortex_eisa_probe,
 		.remove  = vortex_eisa_remove
 	}
 };

 ** Device :

 The sysfs framework calls .probe and .remove functions upon device
 discovery and removal (note that the .remove function is only called
 when driver is built as a module).

 Both functions are passed a pointer to a 'struct device', which is
 encapsulated in a 'struct eisa_device' described as follows :

 struct eisa_device {
         struct eisa_device_id id;
         int                   slot;
 	int                   state;
 	unsigned long         base_addr;
 	struct resource       res[EISA_MAX_RESOURCES];
 	u64                   dma_mask;
         struct device         dev; /* generic device */
 };

 id	: EISA id, as read from device. id.driver_data is set from the
 	  matching driver EISA id.
 slot	: slot number which the device was detected on
 state   : set of flags indicating the state of the device. Current
 	  flags are EISA_CONFIG_ENABLED and EISA_CONFIG_FORCED.
 res	: set of four 256 bytes I/O regions allocated to this device
 dma_mask: DMA mask set from the parent device.
 dev	: generic device (see Documentation/driver-model/device.txt)

 You can get the 'struct eisa_device' from 'struct device' using the
 'to_eisa_device' macro.

 ** Misc stuff :

 void eisa_set_drvdata (struct eisa_device *edev, void *data);

 Stores data into the device's driver_data area.

 void *eisa_get_drvdata (struct eisa_device *edev):

 Gets the pointer previously stored into the device's driver_data area.

 int eisa_get_region_index (void *addr);

 Returns the region number (0 <= x < EISA_MAX_RESOURCES) of a given
 address.

 ** Kernel parameters :

 eisa_bus.enable_dev :

 A comma-separated list of slots to be enabled, even if the firmware
 set the card as disabled. The driver must be able to properly
 initialize the device in such conditions.

 eisa_bus.disable_dev :

 A comma-separated list of slots to be enabled, even if the firmware
 set the card as enabled. The driver won't be called to handle this
 device.

 virtual_root.force_probe :

 Force the probing code to probe EISA slots even when it cannot find an
 EISA compliant mainboard (nothing appears on slot 0). Defaultd to 0
 (don't force), and set to 1 (force probing) when either
 CONFIG_ALPHA_JENSEN or CONFIG_EISA_VLB_PRIMING are set.

 ** Random notes :

 Converting an EISA driver to the new API mostly involves *deleting*
 code (since probing is now in the core EISA code). Unfortunately, most
 drivers share their probing routine between ISA, MCA and EISA. Special
 care must be taken when ripping out the EISA code, so other busses
 won't suffer from these surgical strikes...

 You *must not* expect any EISA device to be detected when returning
 from eisa_driver_register, since the chances are that the bus has not
 yet been probed. In fact, that's what happens most of the time (the
 bus root driver usually kicks in rather late in the boot process).
 Unfortunately, most drivers are doing the probing by themselves, and
 expect to have explored the whole machine when they exit their probe
 routine.

 For example, switching your favorite EISA SCSI card to the "hotplug"
 model is "the right thing"(tm).

 ** Thanks :

 I'd like to thank the following people for their help :
 - Xavier Benigni for lending me a wonderful Alpha Jensen,
 - James Bottomley, Jeff Garzik for getting this stuff into the kernel,
 - Andries Brouwer for contributing numerous EISA ids,
 - Catrin Jones for coping with far too many machines at home.
	EISA bus support (Marc Zyngier <maz@wild-wind.fr.eu.org>)

	This document groups random notes about porting EISA drivers to the
	new EISA/sysfs API.

	Starting from version 2.5.59, the EISA bus is almost given the same
	status as other much more mainstream busses such as PCI or USB. This
	has been possible through sysfs, which defines a nice enough set of
	abstractions to manage busses, devices and drivers.

	Although the new API is quite simple to use, converting existing
	drivers to the new infrastructure is not an easy task (mostly because
	detection code is generally also used to probe ISA cards). Moreover,
	most EISA drivers are among the oldest Linux drivers so, as you can
	imagine, some dust has settled here over the years.

	The EISA infrastructure is made up of three parts :

	- The bus code implements most of the generic code. It is shared
	among all the architectures that the EISA code runs on. It
	implements bus probing (detecting EISA cards available on the bus),
	allocates I/O resources, allows fancy naming through sysfs, and
	offers interfaces for driver to register.

	- The bus root driver implements the glue between the bus hardware
	and the generic bus code. It is responsible for discovering the
	device implementing the bus, and setting it up to be latter probed
	by the bus code. This can go from something as simple as reserving
	an I/O region on x86, to the rather more complex, like the hppa
	EISA code. This is the part to implement in order to have EISA
	running on an "new" platform.

	- The driver offers the bus a list of devices that it manages, and
	implements the necessary callbacks to probe and release devices
	whenever told to.

	Every function/structure below lives in <linux/eisa.h>, which depends
	heavily on <linux/device.h>.

	** Bus root driver :

	int eisa_root_register (struct eisa_root_device *root);

	The eisa_root_register function is used to declare a device as the
	root of an EISA bus. The eisa_root_device structure holds a reference
	to this device, as well as some parameters for probing purposes.

	struct eisa_root_device {
	struct device dev; / Pointer to bridge device */
	struct resource *res;
	unsigned long bus_base_addr;
	int slots; /* Max slot number */
	int force_probe; /* Probe even when no slot 0 */
	u64 dma_mask; /* from bridge device */
	int bus_nr; /* Set by eisa_root_register */
	struct resource eisa_root_res; /* ditto */
	};

	node : used for eisa_root_register internal purpose
	dev : pointer to the root device
	res : root device I/O resource
	bus_base_addr : slot 0 address on this bus
	slots : max slot number to probe
	force_probe : Probe even when slot 0 is empty (no EISA mainboard)
	dma_mask : Default DMA mask. Usually the bridge device dma_mask.
	bus_nr : unique bus id, set by eisa_root_register

	** Driver :

	int eisa_driver_register (struct eisa_driver *edrv);
	void eisa_driver_unregister (struct eisa_driver *edrv);

	Clear enough ?

	struct eisa_device_id {
	char sig[EISA_SIG_LEN];
	unsigned long driver_data;
	};

	struct eisa_driver {
	const struct eisa_device_id *id_table;
	struct device_driver driver;
	};

	id_table : an array of NULL terminated EISA id strings,
	followed by an empty string. Each string can
	optionally be paired with a driver-dependant value
	(driver_data).

	driver : a generic driver, such as described in
	Documentation/driver-model/driver.txt. Only .name,
	.probe and .remove members are mandatory.

	An example is the 3c59x driver :

	static struct eisa_device_id vortex_eisa_ids[] = {
	{ "TCM5920", EISA_3C592_OFFSET },
	{ "TCM5970", EISA_3C597_OFFSET },
	{ "" }
	};

	static struct eisa_driver vortex_eisa_driver = {
	.id_table = vortex_eisa_ids,
	.driver = {
	.name = "3c59x",
	.probe = vortex_eisa_probe,
	.remove = vortex_eisa_remove
	}
	};

	** Device :

	The sysfs framework calls .probe and .remove functions upon device
	discovery and removal (note that the .remove function is only called
	when driver is built as a module).

	Both functions are passed a pointer to a 'struct device', which is
	encapsulated in a 'struct eisa_device' described as follows :

	struct eisa_device {
	struct eisa_device_id id;
	int slot;
	int state;
	unsigned long base_addr;
	struct resource res[EISA_MAX_RESOURCES];
	u64 dma_mask;
	struct device dev; /* generic device */
	};

	id : EISA id, as read from device. id.driver_data is set from the
	matching driver EISA id.
	slot : slot number which the device was detected on
	state : set of flags indicating the state of the device. Current
	flags are EISA_CONFIG_ENABLED and EISA_CONFIG_FORCED.
	res : set of four 256 bytes I/O regions allocated to this device
	dma_mask: DMA mask set from the parent device.
	dev : generic device (see Documentation/driver-model/device.txt)

	You can get the 'struct eisa_device' from 'struct device' using the
	'to_eisa_device' macro.

	** Misc stuff :

	void eisa_set_drvdata (struct eisa_device edev, void data);

	Stores data into the device's driver_data area.

	void eisa_get_drvdata (struct eisa_device edev):

	Gets the pointer previously stored into the device's driver_data area.

	int eisa_get_region_index (void *addr);

	Returns the region number (0 <= x < EISA_MAX_RESOURCES) of a given
	address.

	** Kernel parameters :

	eisa_bus.enable_dev :

	A comma-separated list of slots to be enabled, even if the firmware
	set the card as disabled. The driver must be able to properly
	initialize the device in such conditions.

	eisa_bus.disable_dev :

	A comma-separated list of slots to be enabled, even if the firmware
	set the card as enabled. The driver won't be called to handle this
	device.

	virtual_root.force_probe :

	Force the probing code to probe EISA slots even when it cannot find an
	EISA compliant mainboard (nothing appears on slot 0). Defaultd to 0
	(don't force), and set to 1 (force probing) when either
	CONFIG_ALPHA_JENSEN or CONFIG_EISA_VLB_PRIMING are set.

	** Random notes :

	Converting an EISA driver to the new API mostly involves deleting
	code (since probing is now in the core EISA code). Unfortunately, most
	drivers share their probing routine between ISA, MCA and EISA. Special
	care must be taken when ripping out the EISA code, so other busses
	won't suffer from these surgical strikes...

	You must not expect any EISA device to be detected when returning
	from eisa_driver_register, since the chances are that the bus has not
	yet been probed. In fact, that's what happens most of the time (the
	bus root driver usually kicks in rather late in the boot process).
	Unfortunately, most drivers are doing the probing by themselves, and
	expect to have explored the whole machine when they exit their probe
	routine.

	For example, switching your favorite EISA SCSI card to the "hotplug"
	model is "the right thing"(tm).

	** Thanks :

	I'd like to thank the following people for their help :
	- Xavier Benigni for lending me a wonderful Alpha Jensen,
	- James Bottomley, Jeff Garzik for getting this stuff into the kernel,
	- Andries Brouwer for contributing numerous EISA ids,
	- Catrin Jones for coping with far too many machines at home.