haiku/headers/os/drivers/device_manager.h

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/*
* Copyright 2004-2005, Haiku Inc. All Rights Reserved.
* Distributed under the terms of the MIT license.
*/
/*
Copyright (c) 2003-04, Thomas Kurschel
PnP manager; Takes care of registration and loading of PnP drivers
Read pnp_driver.h first to understand the basic idea behind PnP drivers.
To register a driver node, use register_driver. If the device got lost,
use unregister_driver (note: if the parent node is removed, your node
get removed automatically as your driver has obviously nothing to work
with anymore). To get access to a (parent) device, use load_driver/
unload_driver.
To let the manager find a consumer (see pnp_driver.h), you can either
specify its name directly during registration, using a
PNP_DRIVER_FIXED_CONSUMER attribute, or let the manager search the
appropriate consumer(s) via a PNP_DRIVER_DYNAMIC_CONSUMER attribute.
Searching of dynamic consumers is done as follows:
- First, the manager searches for a Specific driver in the base
directory (see below)
- If no Specific driver is found, all Generic drivers stored under
"generic" sub-directory are informed in turn until one returns success
- Finally, _all_ Universal drivers, stored in the "universal" sub-
directory, are informed
Specification of the base directory and of the names of Specific
drivers is done via a file name pattern given by a
PNP_DRIVER_DYNAMIC_CONSUMER attribute.
First, all substrings of the form "%attribute_name%" are replaced by the
content of the attribute "attribute_name" as follows:
- if the attribute contains an integer value, its content is converted to hex
(lowercase) with a fixed length according to the attribute's value range
- the content of string attributes is quoted by " and invalid characters
(i.e. /%" and all characters outside 32..126) are replaced by their
unsigned decimal value, delimited by %
- other attribute types cannot be used
Second, the resulting name is split into chunks according to the presence
of | characters (you can escape % and | with a ^ character). These
characters are only delimiters and get removed before further processing.
The directory before the first | character is the base directory (see
above). It contains the "generic" and the "universal" subdirectories.
The names of the specific drivers are created by first taking the entire
file name, then by removing the last chunk, then by removing the last
two chunks and so on until only the first chunk is left.
As drivers can contain multiple modules, the module name is constructed
by appending the content of the PNP_DRIVER_TYPE attribute to the driver's file
name, seperated by a slash character (note: this only applies to dynamic
consumers; for fixed consumers, you specify the module name directly via
PNP_DRIVER_FIXED_CONSUMER).
E.g. given a dynamic consumer pattern of
"pci/vendor=%vendor_id%|, device=%device_id%" for a device with the
attributes vendor_id=0x123 and device_id=0xabcd (both being uint16), the
PnP manager tries the specific drivers "pci/vendor=0123, device=abcd" and
(if the first one fails/doesn't exist) "pci/vendor=0123". If they both
refuse to handle the device, all drivers under "pci/generic" are tried
until one accepts the device. Finally, all drivers under "pci/universal"
are loaded, whatever happened before.
In practise, you should try to use specific drivers as much as possible.
If detection based on device IDs is impossible (e.g. because the bus
doesn't support them at all), you can put the driver under "generic".
Generic drivers can also be used to specify wrappers that try to load old-
style drivers if no new driver can be found. Also, they can be used to
report an error or invoke an user program that tries downloading a
proper Specific driver. Universal drivers are mainly used for
informational purposes, e.g. to publish data about each found device,
or to provide raw access to all devices.
If the device uses physical address space or I/O space or ISA DMA
channels (called I/O resources), the driver has to acquire these
resources. During hardware detection (usually via probe()),
acquire_io_resources() must be called to get exclusive access.
If no hardware could be found, they must be released via
release_io_resources(). If detection was successful, the list of
the (acquired) resources must be passed to register_device().
Resources can either belong to one hardware detection or to a device.
If a hardware detection collides with another, it has to wait;
if it collides with a device whose driver is not loaded, the
driver loading is blocked. When detection fails, i.e. if
release_io_resources() is called, all blocked drivers can be loaded
again. If the detection fails, i.e. the resources are transferred
via register_device(), all blocked devices are unregistered and
pending load requests aborted. If a hardware detection collides
with a device whose driver is loaded, acquire_io_resources() fails
with B_BUSY. As this makes a hardware rescan impossible if the
driver is loaded, you should define PNP_DRIVER_NO_LIVE_RESCAN
for nodes that use I/O resources (see below).
To search for new drivers for a given device node, use rescan(). This
marks all consumer devices as being verified and calls probe()
of all consumers drivers (see above) to let them rescan the parent
for devices. The <depth> parameter determines the nesting level, e.g.
2 means that first the consumers are scanned and then the consumers
of the consumers.
Normally, all devices can be rescanned. If a driver cannot handle
a rescan safely when it is loaded (i.e. used by a consumer), it
must set PNP_DRIVER_NO_LIVE_RESCAN, in which case the device is
ignored during rescan if the driver is loaded and attempts
to load the driver during a rescan are blocked until the rescan
is finished. If rescanning a device is not possible at all, it must
have set PNP_DRIVER_NEVER_RESCAN to always ignore it.
To distinguish between new devices, lost devices and redetected
devices, consumer devices should provide a connection code and a
device identifier. They are specified by PNP_DRIVER_CONNECTION and
PNP_DRIVER_CONNECTION respectively, and are expanded in the same way
as PNP_DRIVER_DYNAMIC_CONSUMER. It is assumed that there can be only
one device per connection and that a device can be uniquely identify
by a device identifier. If a consumer device is registered on the
same connection as an existing device but with a different device
identifier, the old device gets unregistered automatically. If both
connection and device identifier are the same, registration is
handled as a redetection and ignored (unless a different type or
driver module is specified - in this case, the device is replaced).
Devices that were not redetected during a rescan get unregistered
unless they were ignored (see above).
*/
#ifndef _DEVICE_MANAGER_H
#define _DEVICE_MANAGER_H
#include <TypeConstants.h>
#include <Drivers.h>
#include <module.h>
// type of I/O resource
enum {
IO_MEM = 1,
IO_PORT = 2,
ISA_DMA_CHANNEL = 3
};
// I/O resource description
typedef struct {
uint32 type;
// type of I/O resource
uint32 base;
// I/O memory: first physical address (32 bit)
// I/O port: first port address (16 bit)
// ISA DMA channel: channel number (0-7)
uint32 len;
// I/O memory: size of address range (32 bit)
// I/O port: size of port range (16 bit)
// ISA DMA channel: must be 1
} io_resource;
// attribute of a device node
typedef struct {
const char *name;
type_code type; // for supported types, see value
union {
uint8 ui8; // B_UINT8_TYPE
uint16 ui16; // B_UINT16_TYPE
uint32 ui32; // B_UINT32_TYPE
uint64 ui64; // B_UINT64_TYPE
const char *string; // B_STRING_TYPE
struct { // B_RAW_TYPE
void *data;
size_t len;
} raw;
} value;
} device_attr;
// handle of device node
typedef struct device_node_info *device_node_handle;
// handle of acquired I/O resource
typedef struct io_resource_info *io_resource_handle;
// handle of node attribute
typedef struct device_attr_info *device_attr_handle;
typedef struct driver_module_info driver_module_info;
// interface of PnP manager
typedef struct device_manager_info {
module_info info;
// load driver
// node - node whos driver is to be loaded
// user_cookie - cookie to be passed to init_device of driver
// interface - interface of loaded driver
// cookie - device cookie issued by loaded driver
status_t (*load_driver)(device_node_handle node, void *userCookie,
driver_module_info **interface, void **cookie);
// unload driver
status_t (*unload_driver)(device_node_handle node);
// rescan node for new dynamic drivers
// node - node whose dynamic drivers are to be scanned
// depth - recursive depth (>= 1)
status_t (*rescan)(device_node_handle node, uint32 depth);
// register device
// parent - parent node
// attributes - NULL-terminated array of node attributes
// io_resources - NULL-terminated array of I/O resources (can be NULL)
// node - new node handle
// on return, io_resources are invalid: on success I/O resources belong
// to node, on fail they are released;
// if device is already registered, B_OK is returned but *node is NULL
status_t (*register_device)(device_node_handle parent,
const device_attr *attrs,
const io_resource_handle *io_resources,
device_node_handle *node);
// unregister device
// all nodes having this node as their parent are unregistered too.
// if the node contains PNP_MANAGER_ID_GENERATOR/PNP_MANAGER_AUTO_ID
// pairs, the id specified this way is freed too
status_t (*unregister_device)(device_node_handle node);
// acquire I/O resources
// resources - NULL-terminated array of resources to acquire
// handles - NULL-terminated array of handles (one per resource);
// array must be provided by caller
// return B_BUSY if a resource is used by a loaded driver
status_t (*acquire_io_resources)(io_resource *resources,
io_resource_handle *handles);
// release I/O resources
// handles - NULL-terminated array of handles
status_t (*release_io_resources)(const io_resource_handle *handles);
// find device by node content
// the given attributes must _uniquely_ identify a device node;
// parent - parent node (-1 for don't-care)
// attrs - list of attributes (can be NULL)
// return: NULL if no device or multiple(!) devices found
device_node_handle (*find_device)(device_node_handle parent,
const device_attr *attrs);
// create unique id
// generator - name of id set
// if result >= 0 - unique id
// result < 0 - error code
int32 (*create_id)(const char *generator);
// free unique id
status_t (*free_id)(const char *generator, uint32 id);
// get parent device node
device_node_handle (*get_parent)(device_node_handle node);
// helpers to extract attribute by name.
// if <recursive> is true, parent nodes are scanned if
// attribute isn't found in current node; unless you declared
// the attribute yourself, use recursive search to handle
// intermittent nodes, e.g. defined by filter drivers, transparently.
// for raw and string attributes, you get a copy that must
// be freed by caller
status_t (*get_attr_uint8)(device_node_handle node,
const char *name, uint8 *value, bool recursive);
status_t (*get_attr_uint16)(device_node_handle node,
const char *name, uint16 *value, bool recursive);
status_t (*get_attr_uint32)(device_node_handle node,
const char *name, uint32 *value, bool recursive);
status_t (*get_attr_uint64)(device_node_handle node,
const char *name, uint64 *value, bool recursive);
status_t (*get_attr_string)(device_node_handle node,
const char *name, char **value, bool recursive);
status_t (*get_attr_raw)(device_node_handle node,
const char *name, void **data, size_t *_size,
bool recursive);
// get next attribute of node;
// on call, *<attr_handle> must contain handle of an attribute;
// on return, *<attr_handle> is replaced by the next attribute or
// NULL if it was the last;
// to get the first attribute, <attr_handle> must point to NULL;
// the returned handle must be released by either passing it to
// another get_next_attr() call or by using release_attr()
// directly
status_t (*get_next_attr)(device_node_handle node,
device_attr_handle *attrHandle);
// release attribute handle <attr_handle> of <node>;
// see get_next_attr
status_t (*release_attr)(device_node_handle node,
device_attr_handle attr_handle);
// retrieve attribute data with handle given;
// <attr> is only valid as long as you don't release <attr_handle>
// implicitely or explicitely
status_t (*retrieve_attr)(device_attr_handle attr_handle,
const device_attr **attr);
// change/add attribute <attr> of/to node
status_t (*write_attr)(device_node_handle node,
const device_attr *attr);
// remove attribute of node by name
// <name> is name of attribute
status_t (*remove_attr)(device_node_handle node, const char *name);
} device_manager_info;
// standard attributes:
// if you are using an id generator (see create_id), you can let the
// manager automatically free the id when the node is deleted by setting
// the following attributes:
// name of generator (string)
#define PNP_MANAGER_ID_GENERATOR "id_generator"
// generated id (uint32)
#define PNP_MANAGER_AUTO_ID "auto_id"
// modulename of PnP manager
#define DEVICE_MANAGER_MODULE_NAME "sys/device_manager/v1"
// former pnp_driver.h
/*
Copyright (c) 2003-04, Thomas Kurschel
Required interface of PnP drivers
In contrast to standard BeOS drivers, PnP drivers are normal modules
having the interface described below.
Every device is described by its driver via a PnP node with properties
described in PnP Node Attributes. Devices are organized in a hierarchy,
e.g. a devfs device is a hard disk device that is connected to a
controller, which is a PCI device, that is connected to a PCI bus.
Every device is connected to its lower-level device via a parent link
stored in its Node. The higher-level is called the consumer of the
lower-level device. If the lower-level device gets removed, all its
consumers are removed too.
In our example, the hierarchy is
devfs device -> hard disk -> controller -> PCI device -> PCI bus
If the PCI bus is removed, everything up to including the devfs device
is removed too.
The driver hierarchy is constructed bottom-up, i.e. the lower-level
driver searches for a corresponding consumer, which in turns searches
for its consumer and so on. The lowest driver is usually something like
a PCI bus, the highest driver is normally a devfs entry (see pnp_devfs.h).
Registration of devices and the search for appropriate consumers is
done via the pnp_manager (see pnp_manager.h).
When a potential consumer is found, it gets informed about the new
lower-level device and can either refuse its handling or accept it.
On accept, it has to create a new node with the lower-level device
node as its parent.
Loading of drivers is done on demand, i.e. if the consumer wants to
access its lower-level device, it explicitely loads the corresponding
driver, and once it doesn't need it anymore, the lower-level driver
must be unloaded. Usually, this process happens recursively, i.e. in
our example, the hard disk driver loads the controller driver, which
loads the PCI device driver which loads the PCI bus driver. The same
process applies to unloading.
Because of this dynamic loading, drivers must store persistent data
in the node of their devices. Please be aware that you cannot modify
a node once published.
If a device gets removed, you must unregister its node. As said, the
PnP manager will automatically unregister all consumers too. The
corresponding drivers are notified to stop talking to their lower-level
devices and to terminate running requests. Normally, you want to use a
dedicated variable that is verified at each call to make sure that the
parent is still there. The notification is done independantly of the
driver being loaded by its consumer(s) or not. If it isn't loaded,
the notification callback gets NULL as the device cookie; normally, the
driver returns immediately in this case. As soon as both the device
is removed and the driver is unloaded, device_cleanup gets called to
free resources that couldn't be safely removed in device_removed when
the driver was still loaded.
If a device has exactly one consumer, they often interact in some way.
To simplify that, the consumer can pass a user-cookie to its parent
during load. In this case, it's up to the parent driver to get a
pointer to the interface of the consumer. Effectively, such consumers
have one interface for their consumers (base on pnp_driver_info), and
a another for their parents (with a completely driver-specific
structure).
In terms of synchronization, loading/unloading/remove-notifications
are executed synchroniously, i.e. if e.g. a device is to be unloaded
but the drive currently handles a remove-notification, the unloading
is delayed until the nofication callback returns. If multiple consumers
load a driver, the driver gets initialized only once; subsequent load
requests increase an internal load count only and return immediately.
In turn, unloading only happens once the load count reaches zero.
*/
// interface of device driver
struct driver_module_info {
module_info info;
status_t (*init_device)(device_node_handle node, void *user_cookie, void **cookie);
// driver is loaded.
// node - node of device
// user_cookie - cookie passed by loading driver
// cookie - cookie issued by this driver
status_t (*uninit_device)(void *cookie);
// driver gets unloaded.
status_t (*register_device)(device_node_handle parent);
// parent was added or is rescanned.
// check whether this parent is supported and register
// any consumer device. Dynamic consumers must return
// B_OK if they support this parent. All other return
// values are ignored.
void (*device_removed)(device_node_handle node, void *cookie);
// a device node, registered by this driver, got removed.
// if the driver wasn't loaded when this happenes, no (un)init_device
// is called and thus <cookie> is NULL;
void (*device_cleanup)(device_node_handle node);
// a device node, registered by this driver, got removed and
// the driver got unloaded
};
// standard attributes:
// module name of driver (required, string)
#define PNP_DRIVER_DRIVER "driver"
// type of driver (required, string)
#define PNP_DRIVER_TYPE "type"
// module name of fixed consumer - see pnp_manager.h (optional, string)
// append "/0", "/1" etc. if there are multiple fixed consumers
#define PNP_DRIVER_FIXED_CONSUMER "consumer/fixed"
// dynamic consumers pattern - see pnp_manager.h (optional, string)
// append "/0", "/1" etc. if there are multiple dynamic consumers
#define PNP_DRIVER_DYNAMIC_CONSUMER "consumer/dynamic"
// connection of parent the device is attached to (optional, string)
// there can be only one device per connection
#define PNP_DRIVER_CONNECTION "connection"
// pattern device identifier (optional, string)
// it is expanded and used to detect changed devices
#define PNP_DRIVER_DEVICE_IDENTIFIER "device_identifier"
// driver must not be loaded during rescan (optional, uint8)
// if != 0, driver must not be loaded during rescan
// nor can rescan be started when driver is loaded
// if the device uses I/O resources, you _must_ set this
// flag as the rescan would always fail if the driver is loaded
// due to resource contention
#define PNP_DRIVER_NO_LIVE_RESCAN "no_live_rescan"
// never rescan this device (optional, uint8)
// if != 0, device is never checked during rescan
#define PNP_DRIVER_NEVER_RESCAN "never_rescan"
// keep driver loaded loaded (optional, uint8)
// if != 0, the driver is loaded automatically whenever the node
// is registered and unloaded whenever the node is unregistered.
// if = 1, driver is temporarily unloaded during rescan
// if = 2, driver is not unloaded during rescan
// avoid the second case (2) as this makes replacing the driver
// impossible without a reboot.
#define PNP_DRIVER_ALWAYS_LOADED "always_loaded"
// former pnp_bus.h
/*
Copyright (c) 2003-04, Thomas Kurschel
Required interface of PnP bus drivers
Busses consist of two node layers: the lower layer defines the bus,
the upper layer defines the abstract devices connected to the bus.
Both layers are handled by a bus manager. Actual device nodes are
on top of abstract device nodes.
E.g. if we have a PCI bus with an IDE controller on it, we get
IDE controller -> PCI device -> PCI bus
with:
IDE controller = actual device node
PCI device = abstract device node
PCI bus = bus node
The PCI bus manager establishes both the PCI devices and the PCI busses.
Abstract device nodes act as a gateway between actual device nodes
and the corresponding bus node. They are constructed by the bus
node driver via its rescan() hook. To identify a bus node, define
PNP_BUS_IS_BUS as an attribute of it. As a result, the PnP manager
will call the rescan() method of the bus driver whenever the
bus is to be rescanned. Afterwards, all possible dynamic consumers
are informed as done for normal nodes.
Normally, potential device drivers are notified immediately when
rescan() registers a new abstract device node. But sometimes, device
drivers need to know _all_ devices connected to the bus for correct
detection. To ensure this, the bus node must define
PNP_BUS_NOTIFY_CONSUMERS_AFTER_RESCAN. In this case, scanning for
consumers is postponed until rescan() has finished.
If hot-plugging of devices can be detected automatically (e.g. USB),
you should define PNP_DRIVER_ALWAYS_LOADED, so the bus driver is
always loaded and thus capable of handling hot-plug events generated
by the bus controller hardware.
*/
// interface of PnP bus
typedef struct bus_module_info {
driver_module_info info;
// (re)scan bus and register all devices.
// driver is always loaded during this call, but other hooks may
// be called concurrently
status_t (*rescan) (void *cookie);
} bus_module_info;
// standard attributes:
// PnP bus identification (required, uint8)
// define this to let the PnP manager know that this is a PnP bus
// the actual content is ignored
#define PNP_BUS_IS_BUS "bus/is_bus"
// defer searching for consumers (optional, uint8)
// if != 0, probe() of consumers is called after rescan() of bus
// else, probe() of consumers is called during rescan() of bus
// normally, consumers are informed about a new device as soon as
// it is registered by rescan(), i.e. not all devices may have been
// detected and registered yet;
// with this flag, detection of consumers is postponed until
// rescan() has finished, i.e. when all devices are registered
#define PNP_BUS_DEFER_PROBE "bus/defer_probe"
#endif /* _DEVICE_MANAGER_H */