Commit 100c3da7 authored by Patrick Mochel's avatar Patrick Mochel

Merge osdl.org:/home/mochel/src/kernel/devel/linux-2.5-virgin

into osdl.org:/home/mochel/src/kernel/devel/linux-2.5-cls
parents 1ab068b3 00e1d4da
This diff is collapsed.
Driver Binding
Driver binding is the process of associating a device with a device
driver that can control it. Bus drivers have typically handled this
because there have been bus-specific structures to represent the
devices and the drivers. With generic device and device driver
structures, most of the binding can take place using common code.
Bus
~~~
The bus type structure contains a list of all devices that on that bus
type in the system. When device_register is called for a device, it is
inserted into the end of this list. The bus object also contains a
list of all drivers of that bus type. When driver_register is called
for a driver, it is inserted into the end of this list. These are the
two events which trigger driver binding.
device_register
~~~~~~~~~~~~~~~
When a new device is added, the bus's list of drivers is iterated over
to find one that supports it. In order to determine that, the device
ID of the device must match one of the device IDs that the driver
supports. The format and semantics for comparing IDs is bus-specific.
Instead of trying to derive a complex state machine and matching
algorithm, it is up to the bus driver to provide a callback to compare
a device against the IDs of a driver. The bus returns 1 if a match was
found; 0 otherwise.
int match(struct device * dev, struct device_driver * drv);
If a match is found, the device's driver field is set to the driver
and the driver's probe callback is called. This gives the driver a
chance to verify that it really does support the hardware, and that
it's in a working state.
Device Class
~~~~~~~~~~~~
Upon the successful completion of probe, the device is registered with
the class to which it belongs. Device drivers belong to one and only
class, and that is set in the driver's devclass field.
devclass_add_device is called to enumerate the device within the class
and actually register it with the class, which happens with the
class's register_dev callback.
NOTE: The device class structures and core routines to manipulate them
are not in the mainline kernel, so the discussion is still a bit
speculative.
Driver
~~~~~~
When a driver is attached to a device, the device is inserted into the
driver's list of devices.
driverfs
~~~~~~~~
A symlink is created in the bus's 'devices' directory that points to
the device's directory in the physical hierarchy.
A symlink is created in the driver's 'devices' directory that points
to the device's directory in the physical hierarchy.
A directory for the device is created in the class's directory. A
symlink is created in that directory that points to the device's
physical location in the driverfs tree.
A symlink can be created (though this isn't done yet) in the device's
physical directory to either its class directory, or the class's
top-level directory. One can also be created to point to its driver's
directory also.
driver_register
~~~~~~~~~~~~~~~
The process is almost identical for when a new driver is added.
The bus's list of devices is iterated over to find a match. Devices
that already have a driver are skipped. All the devices are iterated
over, to bind as many devices as possible to the driver.
Removal
~~~~~~~
When a device is removed, the reference count for it will eventually
go to 0. When it does, the remove callback of the driver is called. It
is removed from the driver's list of devices and the reference count
of the driver is decremented. All symlinks between the two are removed.
When a driver is removed, the list of devices that it supports is
iterated over, and the driver's remove callback is called for each
one. The device is removed from that list and the symlinks removed.
Bus Types
Definition
~~~~~~~~~~
struct bus_type {
char * name;
rwlock_t lock;
atomic_t refcount;
struct list_head node;
struct list_head devices;
struct list_head drivers;
struct driver_dir_entry dir;
struct driver_dir_entry device_dir;
struct driver_dir_entry driver_dir;
int (*match) (struct device * dev, struct device_driver * drv);
struct device (*add) (struct device * parent, char * bus_id);
};
int bus_register(struct bus_type * bus);
Declaration
~~~~~~~~~~~
Each bus type in the kernel (PCI, USB, etc) should declare one static
object of this type. They must initialize the name field, and may
optionally initialize the match callback.
struct bus_type pci_bus_type = {
name: "pci",
match: pci_bus_match,
};
The structure should be exported to drivers in a header file:
extern struct bus_type pci_bus_type;
Registration
~~~~~~~~~~~~
When a bus driver is initialized, it calls bus_register. This
initializes the rest of the fields in the bus object and inserts it
into a global list of bus types. Once the bus object is registered,
the fields in it (e.g. the rwlock_t) are usable by the bus driver.
Callbacks
~~~~~~~~~
match(): Attaching Drivers to Devices
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The format of device ID structures and the semantics for comparing
them are inherently bus-specific. Drivers typically declare an array
of device IDs of device they support that reside in a bus-specific
driver structure.
The purpose of the match callback is provide the bus an opportunity to
determine if a particular driver supports a particular device by
comparing the device IDs the driver supports with the device ID of a
particular device, without sacrificing bus-specific functionality or
type-safety.
When a driver is registered with the bus, the bus's list of devices is
iterated over, and the match callback is called for each device that
does not have a driver associated with it.
add(): Adding a child device
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The add callback is available to notify the bus about a child device
at a particular location.
The parent parameter is the parent device of the child to be added. If
parent == NULL, the bus should add the device as a child of a default
parent device or as a child of the root. This policy decision is up to
the bus driver.
The format of the bus_id field should be consistent with the format of
the bus_id field of the rest of the devices on the bus. This requires
the caller to know the format.
On return, the bus driver should return a pointer to the device that
was created. If the device was not created, the bus driver should
return an appropriate error code. Refer to include/linux/err.h for
helper functions to encode errors. Some sample code:
struct device * pci_bus_add(struct device * parent, char * bus_id)
{
...
/* the device already exists */
return ERR_PTR(-EEXIST);
...
}
The caller can check the return value using IS_ERR():
struct device * newdev = pci_bus_type.add(parent,bus_id);
if (IS_ERR(newdev)) {
...
}
Device and Driver Lists
~~~~~~~~~~~~~~~~~~~~~~~
The lists of devices and drivers are intended to replace the local
lists that many buses keep. They are lists of struct devices and
struct device_drivers, respectively. Bus drivers are free to use the
lists as they please, but conversion to the bus-specific type may be
necessary.
The LDM core provides helper functions for iterating over each list.
int bus_for_each_dev(struct bus_type * bus, void * data,
int (*callback)(struct device * dev, void * data));
int bus_for_each_drv(struct bus_type * bus, void * data,
int (*callback)(struct device_driver * drv, void * data));
These helpers iterate over the respective list, and call the callback
for each device or driver in the list. All list accesses are
synchronized by taking the bus's lock (read currently). The reference
count on each object in the list is incremented before the callback is
called; it is decremented after the next object has been obtained. The
lock is not held when calling the callback.
driverfs
~~~~~~~~
There is a top-level directory named 'bus'.
Each bus gets a directory in the bus directory, along with two default
directories:
/sys/bus/pci/
|-- devices
`-- drivers
Drivers registered with the bus get a directory in the bus's drivers
directory:
/sys/bus/pci/
|-- devices
`-- drivers
|-- Intel ICH
|-- Intel ICH Joystick
|-- agpgart
`-- e100
Each device that is discovered a bus of that type gets a symlink in
the bus's devices directory to the device's directory in the physical
hierarchy:
/sys/bus/pci/
|-- devices
| |-- 00:00.0 -> ../../../root/pci0/00:00.0
| |-- 00:01.0 -> ../../../root/pci0/00:01.0
| `-- 00:02.0 -> ../../../root/pci0/00:02.0
`-- drivers
Exporting Attributes
~~~~~~~~~~~~~~~~~~~~
struct bus_attribute {
struct attribute attr;
ssize_t (*show)(struct bus_type *, char * buf, size_t count, loff_t off);
ssize_t (*store)(struct bus_type *, const char * buf, size_t count, loff_t off);
};
Bus drivers can export attributes using the BUS_ATTR macro that works
similarly to the DEVICE_ATTR macro for devices. For example, a definition
like this:
static BUS_ATTR(debug,0644,show_debug,store_debug);
is equivalent to declaring:
static bus_attribute bus_attr_debug;
This can then be used to add and remove the attribute from the bus's
driverfs directory using:
int bus_create_file(struct bus_type *, struct bus_attribute *);
void bus_remove_file(struct bus_type *, struct bus_attribute *);
Device Classes
Introduction
~~~~~~~~~~~~
A device class describes a type of device, like an audio or network
device. The following device classes have been identified:
<Insert List of Device Classes Here>
Each device class defines a set of semantics and a programming interface
that devices of that class adhere to. Device drivers are the
implemention of that programming interface for a particular device on
a particular bus.
Device classes are agnostic with respect to what bus a device resides
on.
Programming Interface
~~~~~~~~~~~~~~~~~~~~~
The device class structure looks like:
typedef int (*devclass_add)(struct device *);
typedef void (*devclass_remove)(struct device *);
struct device_class {
char * name;
rwlock_t lock;
u32 devnum;
struct list_head node;
struct list_head drivers;
struct list_head intf_list;
struct driver_dir_entry dir;
struct driver_dir_entry device_dir;
struct driver_dir_entry driver_dir;
devclass_add add_device;
devclass_remove remove_device;
};
A typical device class definition would look like:
struct device_class input_devclass = {
.name = "input",
.add_device = input_add_device,
.remove_device = input_remove_device,
};
Each device class structure should be exported in a header file so it
can be used by drivers, extensions and interfaces.
Device classes are registered and unregistered with the core using:
int devclass_register(struct device_class * cls);
void devclass_unregister(struct device_class * cls);
Devices
~~~~~~~
As devices are bound to drivers, they are added to the device class
that the driver belongs to. Before the driver model core, this would
typically happen during the driver's probe() callback, once the device
has been initialized. It now happens after the probe() callback
finishes from the core.
The device is enumerated in the class. Each time a device is added to
the class, the class's devnum field is incremented and assigned to the
device. The field is never decremented, so if the device is removed
from the class and re-added, it will receive a different enumerated
value.
The class is allowed to create a class-specific structure for the
device and store it in the device's class_data pointer.
There is no list of devices in the device class. Each driver has a
list of devices that it supports. The device class has a list of
drivers of that particular class. To access all of the devices in the
class, iterate over the device lists of each driver in the class.
Device Drivers
~~~~~~~~~~~~~~
Device drivers are added to device classes when they are registered
with the core. A driver specifies the class it belongs to by setting
the struct device_driver::devclass field.
driverfs directory structure
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
There is a top-level driverfs directory named 'class'.
Each class gets a directory in the class directory, along with two
default subdirectories:
class/
`-- input
|-- devices
`-- drivers
Drivers registered with the class get a symlink in the drivers/ directory
that points the driver's directory (under its bus directory):
class/
`-- input
|-- devices
`-- drivers
`-- usb:usb_mouse -> ../../../bus/drivers/usb_mouse/
Each device gets a symlink in the devices/ directory that points to the
device's directory in the physical hierarchy:
class/
`-- input
|-- devices
| `-- 1 -> ../../../root/pci0/00:1f.0/usb_bus/00:1f.2-1:0/
`-- drivers
Exporting Attributes
~~~~~~~~~~~~~~~~~~~~
struct devclass_attribute {
struct attribute attr;
ssize_t (*show)(struct device_class *, char * buf, size_t count, loff_t off);
ssize_t (*store)(struct device_class *, const char * buf, size_t count, loff_t off);
};
Class drivers can export attributes using the DEVCLASS_ATTR macro that works
similarly to the DEVICE_ATTR macro for devices. For example, a definition
like this:
static DEVCLASS_ATTR(debug,0644,show_debug,store_debug);
is equivalent to declaring:
static devclass_attribute devclass_attr_debug;
The bus driver can add and remove the attribute from the class's
driverfs directory using:
int devclass_create_file(struct device_class *, struct devclass_attribute *);
void devclass_remove_file(struct device_class *, struct devclass_attribute *);
In the example above, the file will be named 'debug' in placed in the
class's directory in driverfs.
Interfaces
~~~~~~~~~~
There may exist multiple mechanisms for accessing the same device of a
particular class type. Device interfaces describe these mechanisms.
When a device is added to a device class, the core attempts to add it
to every interface that is registered with the device class.
The Basic Device Structure
~~~~~~~~~~~~~~~~~~~~~~~~~~
struct device {
struct list_head g_list;
struct list_head node;
struct list_head bus_list;
struct list_head driver_list;
struct list_head intf_list;
struct list_head children;
struct device * parent;
char name[DEVICE_NAME_SIZE];
char bus_id[BUS_ID_SIZE];
spinlock_t lock;
atomic_t refcount;
struct bus_type * bus;
struct driver_dir_entry dir;
u32 class_num;
struct device_driver *driver;
void *driver_data;
void *platform_data;
u32 current_state;
unsigned char *saved_state;
void (*release)(struct device * dev);
};
Fields
~~~~~~
g_list: Node in the global device list.
node: Node in device's parent's children list.
bus_list: Node in device's bus's devices list.
driver_list: Node in device's driver's devices list.
intf_list: List of intf_data. There is one structure allocated for
each interface that the device supports.
children: List of child devices.
name: ASCII description of device.
Example: " 3Com Corporation 3c905 100BaseTX [Boomerang]"
bus_id: ASCII representation of device's bus position. This
field should a name unique across all devices on the
bus type the device belongs to.
Example: PCI bus_ids are in the form of
<bus number>:<slot number>.<function number>
This name is unique across all PCI devices in the system.
lock: Spinlock for the device.
refcount: Reference count on the device.
bus: Pointer to struct bus_type that device belongs to.
dir: Device's driverfs directory.
driver: Pointer to struct device_driver that controls the device.
driver_data: Driver-specific data.
class_num: Class-enumerated value of the device.
platform_data: Platform data specific to the device.
current_state: Current power state of the device.
saved_state: Pointer to saved state of the device. This is usable by
the device driver controlling the device.
release: Callback to free the device after all references have
gone away. This should be set by the allocator of the
device (i.e. the bus driver that discovered the device).
Programming Interface
~~~~~~~~~~~~~~~~~~~~~
The bus driver that discovers the device uses this to register the
device with the core:
int device_register(struct device * dev);
The bus should initialize the following fields:
- parent
- name
- bus_id
- bus
A device is removed from the core when its reference count goes to
0. The reference count can be adjusted using:
struct device * get_device(struct device * dev);
void put_device(struct device * dev);
get_device() will return a pointer to the struct device passed to it
if the reference is not already 0 (if it's in the process of being
removed already).
A driver can take use the lock in the device structure using:
void lock_device(struct device * dev);
void unlock_device(struct device * dev);
Attributes
~~~~~~~~~~
struct device_attribute {
struct attribute attr;
ssize_t (*show)(struct device * dev, char * buf, size_t count, loff_t off);
ssize_t (*store)(struct device * dev, const char * buf, size_t count, loff_t off);
};
Attributes of devices can be exported via drivers using a simple
procfs-like interface.
Please see Documentation/filesystems/driverfs.txt for more information
on how driverfs works.
Attributes are declared using a macro called DEVICE_ATTR:
#define DEVICE_ATTR(name,mode,show,store)
Example:
DEVICE_ATTR(power,0644,show_power,store_power);
This declares a structure of type struct device_attribute named
'dev_attr_power'. This can then be added and removed to the device's
directory using:
int device_create_file(struct device *device, struct device_attribute * entry);
void device_remove_file(struct device * dev, struct device_attribute * attr);
Example:
device_create_file(dev,&dev_attr_power);
device_remove_file(dev,&dev_attr_power);
The file name will be 'power' with a mode of 0644 (-rw-r--r--).
This diff is collapsed.
Device Interfaces
Introduction
~~~~~~~~~~~~
Device interfaces are the logical interfaces of device classes that correlate
directly to userspace interfaces, like device nodes.
Each device class may have multiple interfaces through which you can
access the same device. An input device may support the mouse interface,
the 'evdev' interface, and the touchscreen interface. A SCSI disk would
support the disk interface, the SCSI generic interface, and possibly a raw
device interface.
Device interfaces are registered with the class they belong to. As devices
are added to the class, they are added to each interface registered with
the class. The interface is responsible for determining whether the device
supports the interface or not.
Programming Interface
~~~~~~~~~~~~~~~~~~~~~
struct device_interface {
char * name;
rwlock_t lock;
u32 devnum;
struct device_class * devclass;
struct list_head node;
struct driver_dir_entry dir;
int (*add_device)(struct device *);
int (*add_device)(struct intf_data *);
};
int interface_register(struct device_interface *);
void interface_unregister(struct device_interface *);
An interface must specify the device class it belongs to. It is added
to that class's list of interfaces on registration.
Interfaces can be added to a device class at any time. Whenever it is
added, each device in the class is passed to the interface's
add_device callback. When an interface is removed, each device is
removed from the interface.
Devices
~~~~~~~
Once a device is added to a device class, it is added to each
interface that is registered with the device class. The class
is expected to place a class-specific data structure in
struct device::class_data. The interface can use that (along with
other fields of struct device) to determine whether or not the driver
and/or device support that particular interface.
Data
~~~~
struct intf_data {
struct list_head node;
struct device_interface * intf;
struct device * dev;
u32 intf_num;
};
int interface_add_data(struct interface_data *);
The interface is responsible for allocating and initializing a struct
intf_data and calling interface_add_data() to add it to the device's list
of interfaces it belongs to. This list will be iterated over when the device
is removed from the class (instead of all possible interfaces for a class).
This structure should probably be embedded in whatever per-device data
structure the interface is allocating anyway.
Devices are enumerated within the interface. This happens in interface_add_data()
and the enumerated value is stored in the struct intf_data for that device.
driverfs
~~~~~~~~
Each interface is given a directory in the directory of the device
class it belongs to:
Interfaces get a directory in the class's directory as well:
class/
`-- input
|-- devices
|-- drivers
|-- mouse
`-- evdev
When a device is added to the interface, a symlink is created that points
to the device's directory in the physical hierarchy:
class/
`-- input
|-- devices
| `-- 1 -> ../../../root/pci0/00:1f.0/usb_bus/00:1f.2-1:0/
|-- drivers
| `-- usb:usb_mouse -> ../../../bus/drivers/usb_mouse/
|-- mouse
| `-- 1 -> ../../../root/pci0/00:1f.0/usb_bus/00:1f.2-1:0/
`-- evdev
`-- 1 -> ../../../root/pci0/00:1f.0/usb_bus/00:1f.2-1:0/
Future Plans
~~~~~~~~~~~~
A device interface is correlated directly with a userspace interface
for a device, specifically a device node. For instance, a SCSI disk
exposes at least two interfaces to userspace: the standard SCSI disk
interface and the SCSI generic interface. It might also export a raw
device interface.
Many interfaces have a major number associated with them and each
device gets a minor number. Or, multiple interfaces might share one
major number, and each get receive a range of minor numbers (like in
the case of input devices).
These major and minor numbers could be stored in the interface
structure. Major and minor allocation could happen when the interface
is registered with the class, or via a helper function.
The Linux Kernel Device Model
Patrick Mochel <mochel@osdl.org>
26 August 2002
Overview
~~~~~~~~
This driver model is a unification of all the current, disparate driver models
that are currently in the kernel. It is intended is to augment the
bus-specific drivers for bridges and devices by consolidating a set of data
and operations into globally accessible data structures.
Current driver models implement some sort of tree-like structure (sometimes
just a list) for the devices they control. But, there is no linkage between
the different bus types.
A common data structure can provide this linkage with little overhead: when a
bus driver discovers a particular device, it can insert it into the global
tree as well as its local tree. In fact, the local tree becomes just a subset
of the global tree.
Common data fields can also be moved out of the local bus models into the
global model. Some of the manipulation of these fields can also be
consolidated. Most likely, manipulation functions will become a set
of helper functions, which the bus drivers wrap around to include any
bus-specific items.
The common device and bridge interface currently reflects the goals of the
modern PC: namely the ability to do seamless Plug and Play, power management,
and hot plug. (The model dictated by Intel and Microsoft (read: ACPI) ensures
us that any device in the system may fit any of these criteria.)
In reality, not every bus will be able to support such operations. But, most
buses will support a majority of those operations, and all future buses will.
In other words, a bus that doesn't support an operation is the exception,
instead of the other way around.
Downstream Access
~~~~~~~~~~~~~~~~~
Common data fields have been moved out of individual bus layers into a common
data structure. But, these fields must still be accessed by the bus layers,
and sometimes by the device-specific drivers.
Other bus layers are encouraged to do what has been done for the PCI layer.
struct pci_dev now looks like this:
struct pci_dev {
...
struct device device;
};
Note first that it is statically allocated. This means only one allocation on
device discovery. Note also that it is at the _end_ of struct pci_dev. This is
to make people think about what they're doing when switching between the bus
driver and the global driver; and to prevent against mindless casts between
the two.
The PCI bus layer freely accesses the fields of struct device. It knows about
the structure of struct pci_dev, and it should know the structure of struct
device. PCI devices that have been converted generally do not touch the fields
of struct device. More precisely, device-specific drivers should not touch
fields of struct device unless there is a strong compelling reason to do so.
This abstraction is prevention of unnecessary pain during transitional phases.
If the name of the field changes or is removed, then every downstream driver
will break. On the other hand, if only the bus layer (and not the device
layer) accesses struct device, it is only those that need to change.
User Interface
~~~~~~~~~~~~~~
By virtue of having a complete hierarchical view of all the devices in the
system, exporting a complete hierarchical view to userspace becomes relatively
easy. This has been accomplished by implementing a special purpose virtual
file system named driverfs. It is hence possible for the user to mount the
whole driverfs filesystem anywhere in userspace.
This can be done permanently by providing the following entry into the
/etc/fstab (under the provision that the mount point does exist, of course):
none /devices driverfs defaults 0 0
Or by hand on the command line:
~: mount -t driverfs none /devices
Whenever a device is inserted into the tree, a directory is created for it.
This directory may be populated at each layer of discovery - the global layer,
the bus layer, or the device layer.
The global layer currently creates two files - name and 'power'. The
former only reports the name of the device. The latter reports the
current power state of the device. It also be used to set the current
power state.
The bus layer may also create files for the devices it finds while probing the
bus. For example, the PCI layer currently creates 'irq' and 'resource' files
for each PCI device.
A device-specific driver may also export files in its directory to expose
device-specific data or tunable interfaces.
More information about the driverfs directory layout can be found in
the other documents in this directory and in the file
Documentation/filesystems/driverfs.txt.
Platform Devices and Drivers
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Platform devices
~~~~~~~~~~~~~~~~
Platform devices are devices that typically appear as autonomous
entities in the system. This includes legacy port-based devices and
host bridges to peripheral buses.
Platform drivers
~~~~~~~~~~~~~~~~
Drivers for platform devices have typically very simple and
unstructured. Either the device was present at a particular I/O port
and the driver was loaded, or there was not. There was no possibility
of hotplugging or alternative discovery besides probing at a specific
I/O address and expecting a specific response.
Other Architectures, Modern Firmware, and new Platforms
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
These devices are not always at the legacy I/O ports. This is true on
other architectures and on some modern architectures. In most cases,
the drivers are modified to discover the devices at other well-known
ports for the given platform. However, the firmware in these systems
does usually know where exactly these devices reside, and in some
cases, it's the only way of discovering them.
The Platform Bus
~~~~~~~~~~~~~~~~
A platform bus has been created to deal with these issues. First and
foremost, it groups all the legacy devices under a common bus, and
gives them a common parent if they don't already have one.
But, besides the organizational benefits, the platform bus can also
accomodate firmware-based enumeration.
Device Discovery
~~~~~~~~~~~~~~~~
The platform bus has no concept of probing for devices. Devices
discovery is left up to either the legacy drivers or the
firmware. These entities are expected to notify the platform of
devices that it discovers via the bus's add() callback:
platform_bus.add(parent,bus_id).
Bus IDs
~~~~~~~
Bus IDs are the canonical name for the device. There is no globally
standard addressing mechanism for legacy devices. In the IA-32 world,
we have Pnp IDs to use, as well as the legacy I/O ports. However,
neither tell what the device really is or have any meaning on other
platforms.
Since both PnP IDs and the legacy I/O ports (and other standard I/O
ports for specific devices) have a 1:1 mapping, we map the
platform-specific name or identifier to a generic name (at least
within the scope of the kernel).
For example, a serial driver might find a device at I/O 0x3f8. The
ACPI firmware might also discover a device with PnP ID (_HID)
PNP0501. Both correspond to the same device should be mapped to the
canonical name 'serial'.
The bus_id field should be a concatenation of the canonical name and
the instance of that type of device. For example, the device at I/O
port 0x3f8 should have a bus_id of "serial0". This places the
responsibility of enumerating devices of a particular type up to the
discovery mechanism. But, they are the entity that should know best
(as opposed to the platform bus driver).
Drivers
~~~~~~~
Drivers for platform devices should have a name that is the same as
the canonical name of the devices they support. This allows the
platform bus driver to do simple matching with the basic data
structures to determine if a driver supports a certain device.
For example, a legacy serial driver should have a name of 'serial' and
register itself with the platform bus.
Driver Binding
~~~~~~~~~~~~~~
Legacy drivers assume they are bound to the device once they start up
and probe an I/O port. Divorcing them from this will be a difficult
process. However, that shouldn't prevent us from impelementing
firmware-based enumeration.
The firmware should notify the platform bus about devices before the
legacy drivers have had a chance to load. Once the drivers are loaded,
they driver model core will attempt to bind the driver to any
previously-discovered devices. Once that has happened, it will be free
to discover any other devices it pleases.
# Makefile for the Linux device tree
obj-y := core.o sys.o interface.o power.o bus.o \
driver.o class.o intf.o
driver.o class.o intf.o platform.o
obj-y += fs/
......
......@@ -97,15 +97,10 @@ static int device_attach(struct device * dev)
static void device_detach(struct device * dev)
{
struct device_driver * drv;
struct device_driver * drv = dev->driver;
if (dev->driver) {
if (drv) {
devclass_remove_device(dev);
spin_lock(&device_lock);
drv = dev->driver;
spin_unlock(&device_lock);
/* detach from driver */
if (drv && drv->remove)
drv->remove(dev);
......
/*
* platform.c - platform 'psuedo' bus for legacy devices
*
* Please see Documentation/driver-model/platform.txt for more
* information.
*/
#include <linux/device.h>
#include <linux/module.h>
#include <linux/init.h>
static int platform_match(struct device * dev, struct device_driver * drv)
{
return 0;
}
struct bus_type platform_bus = {
.name = "platform",
.match = platform_match,
};
static int __init platform_bus_init(void)
{
return bus_register(&platform_bus);
}
postcore_initcall(platform_bus_init);
......@@ -92,13 +92,13 @@ void device_resume(u32 level)
*/
void device_shutdown(void)
{
struct list_head * node;
struct list_head * node, * next;
struct device * prev = NULL;
printk(KERN_EMERG "Shutting down devices\n");
spin_lock(&device_lock);
list_for_each(node,&global_device_list) {
list_for_each_safe(node,next,&global_device_list) {
struct device * dev = get_device_locked(to_dev(node));
if (dev) {
spin_unlock(&device_lock);
......@@ -111,6 +111,8 @@ void device_shutdown(void)
}
}
spin_unlock(&device_lock);
if (prev)
put_device(prev);
}
EXPORT_SYMBOL(device_suspend);
......
......@@ -444,6 +444,8 @@ struct pci_dev * __devinit pci_scan_device(struct pci_dev *temp)
return NULL;
}
pci_name_device(dev);
/* now put in global tree */
strcpy(dev->dev.name,dev->name);
strcpy(dev->dev.bus_id,dev->slot_name);
......@@ -471,7 +473,6 @@ struct pci_dev * __devinit pci_scan_slot(struct pci_dev *temp)
dev = pci_scan_device(temp);
if (!dev)
continue;
pci_name_device(dev);
if (!func) {
is_multi = hdr_type & 0x80;
first_dev = dev;
......
......@@ -150,7 +150,6 @@ static int driverfs_mknod(struct inode *dir, struct dentry *dentry, int mode, in
inode = driverfs_get_inode(dir->i_sb, mode, dev);
if (inode) {
d_instantiate(dentry, inode);
dget(dentry);
error = 0;
}
return error;
......@@ -223,48 +222,10 @@ static int driverfs_unlink(struct inode *dir, struct dentry *dentry)
struct inode *inode = dentry->d_inode;
down(&inode->i_sem);
dentry->d_inode->i_nlink--;
dput(dentry);
up(&inode->i_sem);
d_delete(dentry);
return 0;
}
static void d_unhash(struct dentry *dentry)
{
dget(dentry);
spin_lock(&dcache_lock);
switch (atomic_read(&dentry->d_count)) {
default:
spin_unlock(&dcache_lock);
shrink_dcache_parent(dentry);
spin_lock(&dcache_lock);
if (atomic_read(&dentry->d_count) != 2)
break;
case 2:
list_del_init(&dentry->d_hash);
}
spin_unlock(&dcache_lock);
}
static int driverfs_rmdir(struct inode *dir, struct dentry *dentry)
{
int error = -ENOTEMPTY;
struct inode * inode = dentry->d_inode;
down(&inode->i_sem);
d_unhash(dentry);
if (driverfs_empty(dentry)) {
dentry->d_inode->i_nlink -= 2;
dput(dentry);
inode->i_flags |= S_DEAD;
dir->i_nlink--;
error = 0;
}
up(&inode->i_sem);
if (!error)
d_delete(dentry);
d_invalidate(dentry);
dput(dentry);
return error;
return 0;
}
/**
......@@ -622,9 +583,6 @@ driverfs_create_file(struct attribute * entry,
if (!entry || !parent)
return -EINVAL;
/* make sure we're mounted */
get_mount();
if (!parent->dentry) {
put_mount();
return -EINVAL;
......@@ -638,8 +596,6 @@ driverfs_create_file(struct attribute * entry,
} else
error = PTR_ERR(dentry);
up(&parent->dentry->d_inode->i_sem);
if (error)
put_mount();
return error;
}
......@@ -659,8 +615,6 @@ int driverfs_create_symlink(struct driver_dir_entry * parent,
if (!parent)
return -EINVAL;
get_mount();
if (!parent->dentry) {
put_mount();
return -EINVAL;
......@@ -672,8 +626,6 @@ int driverfs_create_symlink(struct driver_dir_entry * parent,
else
error = PTR_ERR(dentry);
up(&parent->dentry->d_inode->i_sem);
if (error)
put_mount();
return error;
}
......@@ -699,8 +651,6 @@ void driverfs_remove_file(struct driver_dir_entry * dir, const char * name)
if (dentry->d_inode &&
(dentry->d_parent->d_inode == dir->dentry->d_inode)) {
driverfs_unlink(dir->dentry->d_inode,dentry);
dput(dentry);
put_mount();
}
}
up(&dir->dentry->d_inode->i_sem);
......@@ -711,33 +661,39 @@ void driverfs_remove_file(struct driver_dir_entry * dir, const char * name)
* @dir: directory to remove
*
* To make sure we don't orphan anyone, first remove
* all the children in the list, then do vfs_rmdir() to remove it
* and decrement the refcount..
* all the children in the list, then do clean up the directory.
*/
void driverfs_remove_dir(struct driver_dir_entry * dir)
{
struct list_head * node;
struct list_head * node, * next;
struct dentry * dentry = dir->dentry;
struct dentry * parent;
if (!dentry)
goto done;
down(&dentry->d_parent->d_inode->i_sem);
parent = dget(dentry->d_parent);
down(&parent->d_inode->i_sem);
down(&dentry->d_inode->i_sem);
node = dentry->d_subdirs.next;
while (node != &dentry->d_subdirs) {
list_for_each_safe(node,next,&dentry->d_subdirs) {
struct dentry * d = list_entry(node,struct dentry,d_child);
/* make sure dentry is still there */
if (d->d_inode)
driverfs_unlink(dentry->d_inode,d);
}
node = node->next;
driverfs_unlink(dentry->d_inode,d);
dput(d);
put_mount();
d_invalidate(dentry);
if (driverfs_empty(dentry)) {
dentry->d_inode->i_nlink -= 2;
dentry->d_inode->i_flags |= S_DEAD;
parent->d_inode->i_nlink--;
}
up(&dentry->d_inode->i_sem);
driverfs_rmdir(dentry->d_parent->d_inode,dentry);
up(&dentry->d_parent->d_inode->i_sem);
dput(dentry);
up(&parent->d_inode->i_sem);
dput(parent);
done:
put_mount();
}
......
......@@ -65,7 +65,8 @@ struct bus_type {
struct driver_dir_entry device_dir;
struct driver_dir_entry driver_dir;
int (*match) (struct device * dev, struct device_driver * drv);
int (*match)(struct device * dev, struct device_driver * drv);
struct device * (*add) (struct device * parent, char * bus_id);
};
......@@ -281,6 +282,8 @@ struct device {
void *driver_data; /* data private to the driver */
u32 class_num; /* class-enumerated value */
void * class_data; /* class-specific data */
void *platform_data; /* Platform specific data (e.g. ACPI,
BIOS data relevant to device) */
......@@ -378,6 +381,9 @@ extern void put_device(struct device * dev);
extern int register_sys_device(struct device * dev);
extern void unregister_sys_device(struct device * dev);
/* drivers/base/platform.c */
extern struct bus_type platform_bus;
/* drivers/base/power.c */
extern int device_suspend(u32 state, u32 level);
extern void device_resume(u32 level);
......
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