kernel-aes67/include/linux/usb.h

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#ifndef __LINUX_USB_H
#define __LINUX_USB_H
#include <linux/mod_devicetable.h>
#include <linux/usb_ch9.h>
#define USB_MAJOR 180
[PATCH] USB: real nodes instead of usbfs This patch introduces a /sys/class/usb_device/ class where every connected usb-device will show up: tree /sys/class/usb_device/ /sys/class/usb_device/ |-- usb1.1 | |-- dev | `-- device -> ../../../devices/pci0000:00/0000:00:1d.0/usb1 |-- usb2.1 | |-- dev | `-- device -> ../../../devices/pci0000:00/0000:00:1d.1/usb2 ... The presence of the "dev" file lets udev create real device nodes. kay@pim:~/src/linux-2.6> tree /dev/bus/usb/ /dev/bus/usb/ |-- 1 | `-- 1 |-- 2 | `-- 1 ... udev rule: SUBSYSTEM="usb_device", PROGRAM="/sbin/usb_device %k", NAME="%c" (echo $1 | /bin/sed 's/usb\([0-9]*\)\.\([0-9]*\)/bus\/usb\/\1\/\2/') This makes libusb pick up the real nodes instead of the mounted usbfs: export USB_DEVFS_PATH=/dev/bus/usb Background: All this makes it possible to manage usb devices with udev instead of the devfs solution. We are currently working on a pam_console/resmgr replacement driven by udev and a pam-helper. It applies ACL's to device nodes, which is required for modern desktop functionalty like "Fast User Switching" or multiple local login support. New patch with its own major. I've succesfully disabled usbfs and use real nodes only on my box. With: "export USB_DEVFS_PATH=/dev/bus/usb" libusb picks up the udev managed nodes instead of reading usbfs files. This makes udev to provide symlinks for libusb to pick up: SUBSYSTEM="usb_device", PROGRAM="/sbin/usbdevice %k", SYMLINK="%c" /sbin/usbdevice: #!/bin/sh echo $1 | /bin/sed 's/usbdev\([0-9]*\)\.\([0-9]*\)/bus\/usb\/\1\/\2/' Signed-off-by: Kay Sievers <kay.sievers@suse.de> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2005-07-30 19:05:53 -04:00
#define USB_DEVICE_MAJOR 189
#ifdef __KERNEL__
#include <linux/config.h>
#include <linux/errno.h> /* for -ENODEV */
#include <linux/delay.h> /* for mdelay() */
#include <linux/interrupt.h> /* for in_interrupt() */
#include <linux/list.h> /* for struct list_head */
#include <linux/kref.h> /* for struct kref */
#include <linux/device.h> /* for struct device */
#include <linux/fs.h> /* for struct file_operations */
#include <linux/completion.h> /* for struct completion */
#include <linux/sched.h> /* for current && schedule_timeout */
struct usb_device;
struct usb_driver;
/*-------------------------------------------------------------------------*/
/*
* Host-side wrappers for standard USB descriptors ... these are parsed
* from the data provided by devices. Parsing turns them from a flat
* sequence of descriptors into a hierarchy:
*
* - devices have one (usually) or more configs;
* - configs have one (often) or more interfaces;
* - interfaces have one (usually) or more settings;
* - each interface setting has zero or (usually) more endpoints.
*
* And there might be other descriptors mixed in with those.
*
* Devices may also have class-specific or vendor-specific descriptors.
*/
/**
* struct usb_host_endpoint - host-side endpoint descriptor and queue
* @desc: descriptor for this endpoint, wMaxPacketSize in native byteorder
* @urb_list: urbs queued to this endpoint; maintained by usbcore
* @hcpriv: for use by HCD; typically holds hardware dma queue head (QH)
* with one or more transfer descriptors (TDs) per urb
* @extra: descriptors following this endpoint in the configuration
* @extralen: how many bytes of "extra" are valid
*
* USB requests are always queued to a given endpoint, identified by a
* descriptor within an active interface in a given USB configuration.
*/
struct usb_host_endpoint {
struct usb_endpoint_descriptor desc;
struct list_head urb_list;
void *hcpriv;
unsigned char *extra; /* Extra descriptors */
int extralen;
};
/* host-side wrapper for one interface setting's parsed descriptors */
struct usb_host_interface {
struct usb_interface_descriptor desc;
/* array of desc.bNumEndpoint endpoints associated with this
* interface setting. these will be in no particular order.
*/
struct usb_host_endpoint *endpoint;
char *string; /* iInterface string, if present */
unsigned char *extra; /* Extra descriptors */
int extralen;
};
enum usb_interface_condition {
USB_INTERFACE_UNBOUND = 0,
USB_INTERFACE_BINDING,
USB_INTERFACE_BOUND,
USB_INTERFACE_UNBINDING,
};
/**
* struct usb_interface - what usb device drivers talk to
* @altsetting: array of interface structures, one for each alternate
* setting that may be selected. Each one includes a set of
* endpoint configurations. They will be in no particular order.
* @num_altsetting: number of altsettings defined.
* @cur_altsetting: the current altsetting.
* @driver: the USB driver that is bound to this interface.
* @minor: the minor number assigned to this interface, if this
* interface is bound to a driver that uses the USB major number.
* If this interface does not use the USB major, this field should
* be unused. The driver should set this value in the probe()
* function of the driver, after it has been assigned a minor
* number from the USB core by calling usb_register_dev().
* @condition: binding state of the interface: not bound, binding
* (in probe()), bound to a driver, or unbinding (in disconnect())
* @dev: driver model's view of this device
* @class_dev: driver model's class view of this device.
*
* USB device drivers attach to interfaces on a physical device. Each
* interface encapsulates a single high level function, such as feeding
* an audio stream to a speaker or reporting a change in a volume control.
* Many USB devices only have one interface. The protocol used to talk to
* an interface's endpoints can be defined in a usb "class" specification,
* or by a product's vendor. The (default) control endpoint is part of
* every interface, but is never listed among the interface's descriptors.
*
* The driver that is bound to the interface can use standard driver model
* calls such as dev_get_drvdata() on the dev member of this structure.
*
* Each interface may have alternate settings. The initial configuration
* of a device sets altsetting 0, but the device driver can change
* that setting using usb_set_interface(). Alternate settings are often
* used to control the the use of periodic endpoints, such as by having
* different endpoints use different amounts of reserved USB bandwidth.
* All standards-conformant USB devices that use isochronous endpoints
* will use them in non-default settings.
*
* The USB specification says that alternate setting numbers must run from
* 0 to one less than the total number of alternate settings. But some
* devices manage to mess this up, and the structures aren't necessarily
* stored in numerical order anyhow. Use usb_altnum_to_altsetting() to
* look up an alternate setting in the altsetting array based on its number.
*/
struct usb_interface {
/* array of alternate settings for this interface,
* stored in no particular order */
struct usb_host_interface *altsetting;
struct usb_host_interface *cur_altsetting; /* the currently
* active alternate setting */
unsigned num_altsetting; /* number of alternate settings */
int minor; /* minor number this interface is bound to */
enum usb_interface_condition condition; /* state of binding */
struct device dev; /* interface specific device info */
struct class_device *class_dev;
};
#define to_usb_interface(d) container_of(d, struct usb_interface, dev)
#define interface_to_usbdev(intf) \
container_of(intf->dev.parent, struct usb_device, dev)
static inline void *usb_get_intfdata (struct usb_interface *intf)
{
return dev_get_drvdata (&intf->dev);
}
static inline void usb_set_intfdata (struct usb_interface *intf, void *data)
{
dev_set_drvdata(&intf->dev, data);
}
struct usb_interface *usb_get_intf(struct usb_interface *intf);
void usb_put_intf(struct usb_interface *intf);
/* this maximum is arbitrary */
#define USB_MAXINTERFACES 32
/**
* struct usb_interface_cache - long-term representation of a device interface
* @num_altsetting: number of altsettings defined.
* @ref: reference counter.
* @altsetting: variable-length array of interface structures, one for
* each alternate setting that may be selected. Each one includes a
* set of endpoint configurations. They will be in no particular order.
*
* These structures persist for the lifetime of a usb_device, unlike
* struct usb_interface (which persists only as long as its configuration
* is installed). The altsetting arrays can be accessed through these
* structures at any time, permitting comparison of configurations and
* providing support for the /proc/bus/usb/devices pseudo-file.
*/
struct usb_interface_cache {
unsigned num_altsetting; /* number of alternate settings */
struct kref ref; /* reference counter */
/* variable-length array of alternate settings for this interface,
* stored in no particular order */
struct usb_host_interface altsetting[0];
};
#define ref_to_usb_interface_cache(r) \
container_of(r, struct usb_interface_cache, ref)
#define altsetting_to_usb_interface_cache(a) \
container_of(a, struct usb_interface_cache, altsetting[0])
/**
* struct usb_host_config - representation of a device's configuration
* @desc: the device's configuration descriptor.
* @string: pointer to the cached version of the iConfiguration string, if
* present for this configuration.
* @interface: array of pointers to usb_interface structures, one for each
* interface in the configuration. The number of interfaces is stored
* in desc.bNumInterfaces. These pointers are valid only while the
* the configuration is active.
* @intf_cache: array of pointers to usb_interface_cache structures, one
* for each interface in the configuration. These structures exist
* for the entire life of the device.
* @extra: pointer to buffer containing all extra descriptors associated
* with this configuration (those preceding the first interface
* descriptor).
* @extralen: length of the extra descriptors buffer.
*
* USB devices may have multiple configurations, but only one can be active
* at any time. Each encapsulates a different operational environment;
* for example, a dual-speed device would have separate configurations for
* full-speed and high-speed operation. The number of configurations
* available is stored in the device descriptor as bNumConfigurations.
*
* A configuration can contain multiple interfaces. Each corresponds to
* a different function of the USB device, and all are available whenever
* the configuration is active. The USB standard says that interfaces
* are supposed to be numbered from 0 to desc.bNumInterfaces-1, but a lot
* of devices get this wrong. In addition, the interface array is not
* guaranteed to be sorted in numerical order. Use usb_ifnum_to_if() to
* look up an interface entry based on its number.
*
* Device drivers should not attempt to activate configurations. The choice
* of which configuration to install is a policy decision based on such
* considerations as available power, functionality provided, and the user's
* desires (expressed through hotplug scripts). However, drivers can call
* usb_reset_configuration() to reinitialize the current configuration and
* all its interfaces.
*/
struct usb_host_config {
struct usb_config_descriptor desc;
char *string;
/* the interfaces associated with this configuration,
* stored in no particular order */
struct usb_interface *interface[USB_MAXINTERFACES];
/* Interface information available even when this is not the
* active configuration */
struct usb_interface_cache *intf_cache[USB_MAXINTERFACES];
unsigned char *extra; /* Extra descriptors */
int extralen;
};
int __usb_get_extra_descriptor(char *buffer, unsigned size,
unsigned char type, void **ptr);
#define usb_get_extra_descriptor(ifpoint,type,ptr)\
__usb_get_extra_descriptor((ifpoint)->extra,(ifpoint)->extralen,\
type,(void**)ptr)
/* -------------------------------------------------------------------------- */
struct usb_operations;
/* USB device number allocation bitmap */
struct usb_devmap {
unsigned long devicemap[128 / (8*sizeof(unsigned long))];
};
/*
* Allocated per bus (tree of devices) we have:
*/
struct usb_bus {
struct device *controller; /* host/master side hardware */
int busnum; /* Bus number (in order of reg) */
char *bus_name; /* stable id (PCI slot_name etc) */
u8 otg_port; /* 0, or number of OTG/HNP port */
unsigned is_b_host:1; /* true during some HNP roleswitches */
unsigned b_hnp_enable:1; /* OTG: did A-Host enable HNP? */
int devnum_next; /* Next open device number in round-robin allocation */
struct usb_devmap devmap; /* device address allocation map */
struct usb_operations *op; /* Operations (specific to the HC) */
struct usb_device *root_hub; /* Root hub */
struct list_head bus_list; /* list of busses */
void *hcpriv; /* Host Controller private data */
int bandwidth_allocated; /* on this bus: how much of the time
* reserved for periodic (intr/iso)
* requests is used, on average?
* Units: microseconds/frame.
* Limits: Full/low speed reserve 90%,
* while high speed reserves 80%.
*/
int bandwidth_int_reqs; /* number of Interrupt requests */
int bandwidth_isoc_reqs; /* number of Isoc. requests */
struct dentry *usbfs_dentry; /* usbfs dentry entry for the bus */
struct class_device *class_dev; /* class device for this bus */
struct kref kref; /* handles reference counting this bus */
void (*release)(struct usb_bus *bus); /* function to destroy this bus's memory */
#if defined(CONFIG_USB_MON)
struct mon_bus *mon_bus; /* non-null when associated */
int monitored; /* non-zero when monitored */
#endif
};
/* -------------------------------------------------------------------------- */
/* This is arbitrary.
* From USB 2.0 spec Table 11-13, offset 7, a hub can
* have up to 255 ports. The most yet reported is 10.
*/
#define USB_MAXCHILDREN (16)
struct usb_tt;
/*
* struct usb_device - kernel's representation of a USB device
*
* FIXME: Write the kerneldoc!
*
* Usbcore drivers should not set usbdev->state directly. Instead use
* usb_set_device_state().
*/
struct usb_device {
int devnum; /* Address on USB bus */
char devpath [16]; /* Use in messages: /port/port/... */
enum usb_device_state state; /* configured, not attached, etc */
enum usb_device_speed speed; /* high/full/low (or error) */
struct usb_tt *tt; /* low/full speed dev, highspeed hub */
int ttport; /* device port on that tt hub */
struct semaphore serialize;
unsigned int toggle[2]; /* one bit for each endpoint ([0] = IN, [1] = OUT) */
struct usb_device *parent; /* our hub, unless we're the root */
struct usb_bus *bus; /* Bus we're part of */
struct usb_host_endpoint ep0;
struct device dev; /* Generic device interface */
struct usb_device_descriptor descriptor;/* Descriptor */
struct usb_host_config *config; /* All of the configs */
struct usb_host_config *actconfig;/* the active configuration */
struct usb_host_endpoint *ep_in[16];
struct usb_host_endpoint *ep_out[16];
char **rawdescriptors; /* Raw descriptors for each config */
int have_langid; /* whether string_langid is valid yet */
int string_langid; /* language ID for strings */
char *product;
char *manufacturer;
char *serial; /* static strings from the device */
struct list_head filelist;
[PATCH] USB: real nodes instead of usbfs This patch introduces a /sys/class/usb_device/ class where every connected usb-device will show up: tree /sys/class/usb_device/ /sys/class/usb_device/ |-- usb1.1 | |-- dev | `-- device -> ../../../devices/pci0000:00/0000:00:1d.0/usb1 |-- usb2.1 | |-- dev | `-- device -> ../../../devices/pci0000:00/0000:00:1d.1/usb2 ... The presence of the "dev" file lets udev create real device nodes. kay@pim:~/src/linux-2.6> tree /dev/bus/usb/ /dev/bus/usb/ |-- 1 | `-- 1 |-- 2 | `-- 1 ... udev rule: SUBSYSTEM="usb_device", PROGRAM="/sbin/usb_device %k", NAME="%c" (echo $1 | /bin/sed 's/usb\([0-9]*\)\.\([0-9]*\)/bus\/usb\/\1\/\2/') This makes libusb pick up the real nodes instead of the mounted usbfs: export USB_DEVFS_PATH=/dev/bus/usb Background: All this makes it possible to manage usb devices with udev instead of the devfs solution. We are currently working on a pam_console/resmgr replacement driven by udev and a pam-helper. It applies ACL's to device nodes, which is required for modern desktop functionalty like "Fast User Switching" or multiple local login support. New patch with its own major. I've succesfully disabled usbfs and use real nodes only on my box. With: "export USB_DEVFS_PATH=/dev/bus/usb" libusb picks up the udev managed nodes instead of reading usbfs files. This makes udev to provide symlinks for libusb to pick up: SUBSYSTEM="usb_device", PROGRAM="/sbin/usbdevice %k", SYMLINK="%c" /sbin/usbdevice: #!/bin/sh echo $1 | /bin/sed 's/usbdev\([0-9]*\)\.\([0-9]*\)/bus\/usb\/\1\/\2/' Signed-off-by: Kay Sievers <kay.sievers@suse.de> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2005-07-30 19:05:53 -04:00
struct class_device *class_dev;
struct dentry *usbfs_dentry; /* usbfs dentry entry for the device */
/*
* Child devices - these can be either new devices
* (if this is a hub device), or different instances
* of this same device.
*
* Each instance needs its own set of data structures.
*/
int maxchild; /* Number of ports if hub */
struct usb_device *children[USB_MAXCHILDREN];
};
#define to_usb_device(d) container_of(d, struct usb_device, dev)
extern struct usb_device *usb_get_dev(struct usb_device *dev);
extern void usb_put_dev(struct usb_device *dev);
extern void usb_lock_device(struct usb_device *udev);
extern int usb_trylock_device(struct usb_device *udev);
extern int usb_lock_device_for_reset(struct usb_device *udev,
struct usb_interface *iface);
extern void usb_unlock_device(struct usb_device *udev);
/* USB port reset for device reinitialization */
extern int usb_reset_device(struct usb_device *dev);
extern struct usb_device *usb_find_device(u16 vendor_id, u16 product_id);
/*-------------------------------------------------------------------------*/
/* for drivers using iso endpoints */
extern int usb_get_current_frame_number (struct usb_device *usb_dev);
/* used these for multi-interface device registration */
extern int usb_driver_claim_interface(struct usb_driver *driver,
struct usb_interface *iface, void* priv);
/**
* usb_interface_claimed - returns true iff an interface is claimed
* @iface: the interface being checked
*
* Returns true (nonzero) iff the interface is claimed, else false (zero).
* Callers must own the driver model's usb bus readlock. So driver
* probe() entries don't need extra locking, but other call contexts
* may need to explicitly claim that lock.
*
*/
static inline int usb_interface_claimed(struct usb_interface *iface) {
return (iface->dev.driver != NULL);
}
extern void usb_driver_release_interface(struct usb_driver *driver,
struct usb_interface *iface);
const struct usb_device_id *usb_match_id(struct usb_interface *interface,
const struct usb_device_id *id);
extern struct usb_interface *usb_find_interface(struct usb_driver *drv,
int minor);
extern struct usb_interface *usb_ifnum_to_if(struct usb_device *dev,
unsigned ifnum);
extern struct usb_host_interface *usb_altnum_to_altsetting(
struct usb_interface *intf, unsigned int altnum);
/**
* usb_make_path - returns stable device path in the usb tree
* @dev: the device whose path is being constructed
* @buf: where to put the string
* @size: how big is "buf"?
*
* Returns length of the string (> 0) or negative if size was too small.
*
* This identifier is intended to be "stable", reflecting physical paths in
* hardware such as physical bus addresses for host controllers or ports on
* USB hubs. That makes it stay the same until systems are physically
* reconfigured, by re-cabling a tree of USB devices or by moving USB host
* controllers. Adding and removing devices, including virtual root hubs
* in host controller driver modules, does not change these path identifers;
* neither does rebooting or re-enumerating. These are more useful identifiers
* than changeable ("unstable") ones like bus numbers or device addresses.
*
* With a partial exception for devices connected to USB 2.0 root hubs, these
* identifiers are also predictable. So long as the device tree isn't changed,
* plugging any USB device into a given hub port always gives it the same path.
* Because of the use of "companion" controllers, devices connected to ports on
* USB 2.0 root hubs (EHCI host controllers) will get one path ID if they are
* high speed, and a different one if they are full or low speed.
*/
static inline int usb_make_path (struct usb_device *dev, char *buf, size_t size)
{
int actual;
actual = snprintf (buf, size, "usb-%s-%s", dev->bus->bus_name, dev->devpath);
return (actual >= (int)size) ? -1 : actual;
}
/*-------------------------------------------------------------------------*/
#define USB_DEVICE_ID_MATCH_DEVICE (USB_DEVICE_ID_MATCH_VENDOR | USB_DEVICE_ID_MATCH_PRODUCT)
#define USB_DEVICE_ID_MATCH_DEV_RANGE (USB_DEVICE_ID_MATCH_DEV_LO | USB_DEVICE_ID_MATCH_DEV_HI)
#define USB_DEVICE_ID_MATCH_DEVICE_AND_VERSION (USB_DEVICE_ID_MATCH_DEVICE | USB_DEVICE_ID_MATCH_DEV_RANGE)
#define USB_DEVICE_ID_MATCH_DEV_INFO \
(USB_DEVICE_ID_MATCH_DEV_CLASS | USB_DEVICE_ID_MATCH_DEV_SUBCLASS | USB_DEVICE_ID_MATCH_DEV_PROTOCOL)
#define USB_DEVICE_ID_MATCH_INT_INFO \
(USB_DEVICE_ID_MATCH_INT_CLASS | USB_DEVICE_ID_MATCH_INT_SUBCLASS | USB_DEVICE_ID_MATCH_INT_PROTOCOL)
/**
* USB_DEVICE - macro used to describe a specific usb device
* @vend: the 16 bit USB Vendor ID
* @prod: the 16 bit USB Product ID
*
* This macro is used to create a struct usb_device_id that matches a
* specific device.
*/
#define USB_DEVICE(vend,prod) \
.match_flags = USB_DEVICE_ID_MATCH_DEVICE, .idVendor = (vend), .idProduct = (prod)
/**
* USB_DEVICE_VER - macro used to describe a specific usb device with a version range
* @vend: the 16 bit USB Vendor ID
* @prod: the 16 bit USB Product ID
* @lo: the bcdDevice_lo value
* @hi: the bcdDevice_hi value
*
* This macro is used to create a struct usb_device_id that matches a
* specific device, with a version range.
*/
#define USB_DEVICE_VER(vend,prod,lo,hi) \
.match_flags = USB_DEVICE_ID_MATCH_DEVICE_AND_VERSION, .idVendor = (vend), .idProduct = (prod), .bcdDevice_lo = (lo), .bcdDevice_hi = (hi)
/**
* USB_DEVICE_INFO - macro used to describe a class of usb devices
* @cl: bDeviceClass value
* @sc: bDeviceSubClass value
* @pr: bDeviceProtocol value
*
* This macro is used to create a struct usb_device_id that matches a
* specific class of devices.
*/
#define USB_DEVICE_INFO(cl,sc,pr) \
.match_flags = USB_DEVICE_ID_MATCH_DEV_INFO, .bDeviceClass = (cl), .bDeviceSubClass = (sc), .bDeviceProtocol = (pr)
/**
* USB_INTERFACE_INFO - macro used to describe a class of usb interfaces
* @cl: bInterfaceClass value
* @sc: bInterfaceSubClass value
* @pr: bInterfaceProtocol value
*
* This macro is used to create a struct usb_device_id that matches a
* specific class of interfaces.
*/
#define USB_INTERFACE_INFO(cl,sc,pr) \
.match_flags = USB_DEVICE_ID_MATCH_INT_INFO, .bInterfaceClass = (cl), .bInterfaceSubClass = (sc), .bInterfaceProtocol = (pr)
/* -------------------------------------------------------------------------- */
/**
* struct usb_driver - identifies USB driver to usbcore
* @owner: Pointer to the module owner of this driver; initialize
* it using THIS_MODULE.
* @name: The driver name should be unique among USB drivers,
* and should normally be the same as the module name.
* @probe: Called to see if the driver is willing to manage a particular
* interface on a device. If it is, probe returns zero and uses
* dev_set_drvdata() to associate driver-specific data with the
* interface. It may also use usb_set_interface() to specify the
* appropriate altsetting. If unwilling to manage the interface,
* return a negative errno value.
* @disconnect: Called when the interface is no longer accessible, usually
* because its device has been (or is being) disconnected or the
* driver module is being unloaded.
* @ioctl: Used for drivers that want to talk to userspace through
* the "usbfs" filesystem. This lets devices provide ways to
* expose information to user space regardless of where they
* do (or don't) show up otherwise in the filesystem.
* @suspend: Called when the device is going to be suspended by the system.
* @resume: Called when the device is being resumed by the system.
* @id_table: USB drivers use ID table to support hotplugging.
* Export this with MODULE_DEVICE_TABLE(usb,...). This must be set
* or your driver's probe function will never get called.
* @driver: the driver model core driver structure.
*
* USB drivers must provide a name, probe() and disconnect() methods,
* and an id_table. Other driver fields are optional.
*
* The id_table is used in hotplugging. It holds a set of descriptors,
* and specialized data may be associated with each entry. That table
* is used by both user and kernel mode hotplugging support.
*
* The probe() and disconnect() methods are called in a context where
* they can sleep, but they should avoid abusing the privilege. Most
* work to connect to a device should be done when the device is opened,
* and undone at the last close. The disconnect code needs to address
* concurrency issues with respect to open() and close() methods, as
* well as forcing all pending I/O requests to complete (by unlinking
* them as necessary, and blocking until the unlinks complete).
*/
struct usb_driver {
struct module *owner;
const char *name;
int (*probe) (struct usb_interface *intf,
const struct usb_device_id *id);
void (*disconnect) (struct usb_interface *intf);
int (*ioctl) (struct usb_interface *intf, unsigned int code, void *buf);
int (*suspend) (struct usb_interface *intf, pm_message_t message);
int (*resume) (struct usb_interface *intf);
const struct usb_device_id *id_table;
struct device_driver driver;
};
#define to_usb_driver(d) container_of(d, struct usb_driver, driver)
extern struct bus_type usb_bus_type;
/**
* struct usb_class_driver - identifies a USB driver that wants to use the USB major number
* @name: devfs name for this driver. Will also be used by the driver
* class code to create a usb class device.
* @fops: pointer to the struct file_operations of this driver.
* @mode: the mode for the devfs file to be created for this driver.
* @minor_base: the start of the minor range for this driver.
*
* This structure is used for the usb_register_dev() and
* usb_unregister_dev() functions, to consolidate a number of the
* parameters used for them.
*/
struct usb_class_driver {
char *name;
struct file_operations *fops;
mode_t mode;
int minor_base;
};
/*
* use these in module_init()/module_exit()
* and don't forget MODULE_DEVICE_TABLE(usb, ...)
*/
extern int usb_register(struct usb_driver *);
extern void usb_deregister(struct usb_driver *);
extern int usb_register_dev(struct usb_interface *intf,
struct usb_class_driver *class_driver);
extern void usb_deregister_dev(struct usb_interface *intf,
struct usb_class_driver *class_driver);
extern int usb_disabled(void);
/* -------------------------------------------------------------------------- */
/*
* URB support, for asynchronous request completions
*/
/*
* urb->transfer_flags:
*/
#define URB_SHORT_NOT_OK 0x0001 /* report short reads as errors */
#define URB_ISO_ASAP 0x0002 /* iso-only, urb->start_frame ignored */
#define URB_NO_TRANSFER_DMA_MAP 0x0004 /* urb->transfer_dma valid on submit */
#define URB_NO_SETUP_DMA_MAP 0x0008 /* urb->setup_dma valid on submit */
#define URB_NO_FSBR 0x0020 /* UHCI-specific */
#define URB_ZERO_PACKET 0x0040 /* Finish bulk OUTs with short packet */
#define URB_NO_INTERRUPT 0x0080 /* HINT: no non-error interrupt needed */
struct usb_iso_packet_descriptor {
unsigned int offset;
unsigned int length; /* expected length */
unsigned int actual_length;
unsigned int status;
};
struct urb;
struct pt_regs;
typedef void (*usb_complete_t)(struct urb *, struct pt_regs *);
/**
* struct urb - USB Request Block
* @urb_list: For use by current owner of the URB.
* @pipe: Holds endpoint number, direction, type, and more.
* Create these values with the eight macros available;
* usb_{snd,rcv}TYPEpipe(dev,endpoint), where the TYPE is "ctrl"
* (control), "bulk", "int" (interrupt), or "iso" (isochronous).
* For example usb_sndbulkpipe() or usb_rcvintpipe(). Endpoint
* numbers range from zero to fifteen. Note that "in" endpoint two
* is a different endpoint (and pipe) from "out" endpoint two.
* The current configuration controls the existence, type, and
* maximum packet size of any given endpoint.
* @dev: Identifies the USB device to perform the request.
* @status: This is read in non-iso completion functions to get the
* status of the particular request. ISO requests only use it
* to tell whether the URB was unlinked; detailed status for
* each frame is in the fields of the iso_frame-desc.
* @transfer_flags: A variety of flags may be used to affect how URB
* submission, unlinking, or operation are handled. Different
* kinds of URB can use different flags.
* @transfer_buffer: This identifies the buffer to (or from) which
* the I/O request will be performed (unless URB_NO_TRANSFER_DMA_MAP
* is set). This buffer must be suitable for DMA; allocate it with
* kmalloc() or equivalent. For transfers to "in" endpoints, contents
* of this buffer will be modified. This buffer is used for the data
* stage of control transfers.
* @transfer_dma: When transfer_flags includes URB_NO_TRANSFER_DMA_MAP,
* the device driver is saying that it provided this DMA address,
* which the host controller driver should use in preference to the
* transfer_buffer.
* @transfer_buffer_length: How big is transfer_buffer. The transfer may
* be broken up into chunks according to the current maximum packet
* size for the endpoint, which is a function of the configuration
* and is encoded in the pipe. When the length is zero, neither
* transfer_buffer nor transfer_dma is used.
* @actual_length: This is read in non-iso completion functions, and
* it tells how many bytes (out of transfer_buffer_length) were
* transferred. It will normally be the same as requested, unless
* either an error was reported or a short read was performed.
* The URB_SHORT_NOT_OK transfer flag may be used to make such
* short reads be reported as errors.
* @setup_packet: Only used for control transfers, this points to eight bytes
* of setup data. Control transfers always start by sending this data
* to the device. Then transfer_buffer is read or written, if needed.
* @setup_dma: For control transfers with URB_NO_SETUP_DMA_MAP set, the
* device driver has provided this DMA address for the setup packet.
* The host controller driver should use this in preference to
* setup_packet.
* @start_frame: Returns the initial frame for isochronous transfers.
* @number_of_packets: Lists the number of ISO transfer buffers.
* @interval: Specifies the polling interval for interrupt or isochronous
* transfers. The units are frames (milliseconds) for for full and low
* speed devices, and microframes (1/8 millisecond) for highspeed ones.
* @error_count: Returns the number of ISO transfers that reported errors.
* @context: For use in completion functions. This normally points to
* request-specific driver context.
* @complete: Completion handler. This URB is passed as the parameter to the
* completion function. The completion function may then do what
* it likes with the URB, including resubmitting or freeing it.
* @iso_frame_desc: Used to provide arrays of ISO transfer buffers and to
* collect the transfer status for each buffer.
*
* This structure identifies USB transfer requests. URBs must be allocated by
* calling usb_alloc_urb() and freed with a call to usb_free_urb().
* Initialization may be done using various usb_fill_*_urb() functions. URBs
* are submitted using usb_submit_urb(), and pending requests may be canceled
* using usb_unlink_urb() or usb_kill_urb().
*
* Data Transfer Buffers:
*
* Normally drivers provide I/O buffers allocated with kmalloc() or otherwise
* taken from the general page pool. That is provided by transfer_buffer
* (control requests also use setup_packet), and host controller drivers
* perform a dma mapping (and unmapping) for each buffer transferred. Those
* mapping operations can be expensive on some platforms (perhaps using a dma
* bounce buffer or talking to an IOMMU),
* although they're cheap on commodity x86 and ppc hardware.
*
* Alternatively, drivers may pass the URB_NO_xxx_DMA_MAP transfer flags,
* which tell the host controller driver that no such mapping is needed since
* the device driver is DMA-aware. For example, a device driver might
* allocate a DMA buffer with usb_buffer_alloc() or call usb_buffer_map().
* When these transfer flags are provided, host controller drivers will
* attempt to use the dma addresses found in the transfer_dma and/or
* setup_dma fields rather than determining a dma address themselves. (Note
* that transfer_buffer and setup_packet must still be set because not all
* host controllers use DMA, nor do virtual root hubs).
*
* Initialization:
*
* All URBs submitted must initialize the dev, pipe, transfer_flags (may be
* zero), and complete fields. All URBs must also initialize
* transfer_buffer and transfer_buffer_length. They may provide the
* URB_SHORT_NOT_OK transfer flag, indicating that short reads are
* to be treated as errors; that flag is invalid for write requests.
*
* Bulk URBs may
* use the URB_ZERO_PACKET transfer flag, indicating that bulk OUT transfers
* should always terminate with a short packet, even if it means adding an
* extra zero length packet.
*
* Control URBs must provide a setup_packet. The setup_packet and
* transfer_buffer may each be mapped for DMA or not, independently of
* the other. The transfer_flags bits URB_NO_TRANSFER_DMA_MAP and
* URB_NO_SETUP_DMA_MAP indicate which buffers have already been mapped.
* URB_NO_SETUP_DMA_MAP is ignored for non-control URBs.
*
* Interrupt URBs must provide an interval, saying how often (in milliseconds
* or, for highspeed devices, 125 microsecond units)
* to poll for transfers. After the URB has been submitted, the interval
* field reflects how the transfer was actually scheduled.
* The polling interval may be more frequent than requested.
* For example, some controllers have a maximum interval of 32 milliseconds,
* while others support intervals of up to 1024 milliseconds.
* Isochronous URBs also have transfer intervals. (Note that for isochronous
* endpoints, as well as high speed interrupt endpoints, the encoding of
* the transfer interval in the endpoint descriptor is logarithmic.
* Device drivers must convert that value to linear units themselves.)
*
* Isochronous URBs normally use the URB_ISO_ASAP transfer flag, telling
* the host controller to schedule the transfer as soon as bandwidth
* utilization allows, and then set start_frame to reflect the actual frame
* selected during submission. Otherwise drivers must specify the start_frame
* and handle the case where the transfer can't begin then. However, drivers
* won't know how bandwidth is currently allocated, and while they can
* find the current frame using usb_get_current_frame_number () they can't
* know the range for that frame number. (Ranges for frame counter values
* are HC-specific, and can go from 256 to 65536 frames from "now".)
*
* Isochronous URBs have a different data transfer model, in part because
* the quality of service is only "best effort". Callers provide specially
* allocated URBs, with number_of_packets worth of iso_frame_desc structures
* at the end. Each such packet is an individual ISO transfer. Isochronous
* URBs are normally queued, submitted by drivers to arrange that
* transfers are at least double buffered, and then explicitly resubmitted
* in completion handlers, so
* that data (such as audio or video) streams at as constant a rate as the
* host controller scheduler can support.
*
* Completion Callbacks:
*
* The completion callback is made in_interrupt(), and one of the first
* things that a completion handler should do is check the status field.
* The status field is provided for all URBs. It is used to report
* unlinked URBs, and status for all non-ISO transfers. It should not
* be examined before the URB is returned to the completion handler.
*
* The context field is normally used to link URBs back to the relevant
* driver or request state.
*
* When the completion callback is invoked for non-isochronous URBs, the
* actual_length field tells how many bytes were transferred. This field
* is updated even when the URB terminated with an error or was unlinked.
*
* ISO transfer status is reported in the status and actual_length fields
* of the iso_frame_desc array, and the number of errors is reported in
* error_count. Completion callbacks for ISO transfers will normally
* (re)submit URBs to ensure a constant transfer rate.
*
* Note that even fields marked "public" should not be touched by the driver
* when the urb is owned by the hcd, that is, since the call to
* usb_submit_urb() till the entry into the completion routine.
*/
struct urb
{
/* private, usb core and host controller only fields in the urb */
struct kref kref; /* reference count of the URB */
spinlock_t lock; /* lock for the URB */
void *hcpriv; /* private data for host controller */
int bandwidth; /* bandwidth for INT/ISO request */
atomic_t use_count; /* concurrent submissions counter */
u8 reject; /* submissions will fail */
/* public, documented fields in the urb that can be used by drivers */
struct list_head urb_list; /* list head for use by the urb owner */
struct usb_device *dev; /* (in) pointer to associated device */
unsigned int pipe; /* (in) pipe information */
int status; /* (return) non-ISO status */
unsigned int transfer_flags; /* (in) URB_SHORT_NOT_OK | ...*/
void *transfer_buffer; /* (in) associated data buffer */
dma_addr_t transfer_dma; /* (in) dma addr for transfer_buffer */
int transfer_buffer_length; /* (in) data buffer length */
int actual_length; /* (return) actual transfer length */
unsigned char *setup_packet; /* (in) setup packet (control only) */
dma_addr_t setup_dma; /* (in) dma addr for setup_packet */
int start_frame; /* (modify) start frame (ISO) */
int number_of_packets; /* (in) number of ISO packets */
int interval; /* (modify) transfer interval (INT/ISO) */
int error_count; /* (return) number of ISO errors */
void *context; /* (in) context for completion */
usb_complete_t complete; /* (in) completion routine */
struct usb_iso_packet_descriptor iso_frame_desc[0]; /* (in) ISO ONLY */
};
/* -------------------------------------------------------------------------- */
/**
* usb_fill_control_urb - initializes a control urb
* @urb: pointer to the urb to initialize.
* @dev: pointer to the struct usb_device for this urb.
* @pipe: the endpoint pipe
* @setup_packet: pointer to the setup_packet buffer
* @transfer_buffer: pointer to the transfer buffer
* @buffer_length: length of the transfer buffer
* @complete: pointer to the usb_complete_t function
* @context: what to set the urb context to.
*
* Initializes a control urb with the proper information needed to submit
* it to a device.
*/
static inline void usb_fill_control_urb (struct urb *urb,
struct usb_device *dev,
unsigned int pipe,
unsigned char *setup_packet,
void *transfer_buffer,
int buffer_length,
usb_complete_t complete,
void *context)
{
spin_lock_init(&urb->lock);
urb->dev = dev;
urb->pipe = pipe;
urb->setup_packet = setup_packet;
urb->transfer_buffer = transfer_buffer;
urb->transfer_buffer_length = buffer_length;
urb->complete = complete;
urb->context = context;
}
/**
* usb_fill_bulk_urb - macro to help initialize a bulk urb
* @urb: pointer to the urb to initialize.
* @dev: pointer to the struct usb_device for this urb.
* @pipe: the endpoint pipe
* @transfer_buffer: pointer to the transfer buffer
* @buffer_length: length of the transfer buffer
* @complete: pointer to the usb_complete_t function
* @context: what to set the urb context to.
*
* Initializes a bulk urb with the proper information needed to submit it
* to a device.
*/
static inline void usb_fill_bulk_urb (struct urb *urb,
struct usb_device *dev,
unsigned int pipe,
void *transfer_buffer,
int buffer_length,
usb_complete_t complete,
void *context)
{
spin_lock_init(&urb->lock);
urb->dev = dev;
urb->pipe = pipe;
urb->transfer_buffer = transfer_buffer;
urb->transfer_buffer_length = buffer_length;
urb->complete = complete;
urb->context = context;
}
/**
* usb_fill_int_urb - macro to help initialize a interrupt urb
* @urb: pointer to the urb to initialize.
* @dev: pointer to the struct usb_device for this urb.
* @pipe: the endpoint pipe
* @transfer_buffer: pointer to the transfer buffer
* @buffer_length: length of the transfer buffer
* @complete: pointer to the usb_complete_t function
* @context: what to set the urb context to.
* @interval: what to set the urb interval to, encoded like
* the endpoint descriptor's bInterval value.
*
* Initializes a interrupt urb with the proper information needed to submit
* it to a device.
* Note that high speed interrupt endpoints use a logarithmic encoding of
* the endpoint interval, and express polling intervals in microframes
* (eight per millisecond) rather than in frames (one per millisecond).
*/
static inline void usb_fill_int_urb (struct urb *urb,
struct usb_device *dev,
unsigned int pipe,
void *transfer_buffer,
int buffer_length,
usb_complete_t complete,
void *context,
int interval)
{
spin_lock_init(&urb->lock);
urb->dev = dev;
urb->pipe = pipe;
urb->transfer_buffer = transfer_buffer;
urb->transfer_buffer_length = buffer_length;
urb->complete = complete;
urb->context = context;
if (dev->speed == USB_SPEED_HIGH)
urb->interval = 1 << (interval - 1);
else
urb->interval = interval;
urb->start_frame = -1;
}
extern void usb_init_urb(struct urb *urb);
extern struct urb *usb_alloc_urb(int iso_packets, unsigned mem_flags);
extern void usb_free_urb(struct urb *urb);
#define usb_put_urb usb_free_urb
extern struct urb *usb_get_urb(struct urb *urb);
extern int usb_submit_urb(struct urb *urb, unsigned mem_flags);
extern int usb_unlink_urb(struct urb *urb);
extern void usb_kill_urb(struct urb *urb);
#define HAVE_USB_BUFFERS
void *usb_buffer_alloc (struct usb_device *dev, size_t size,
unsigned mem_flags, dma_addr_t *dma);
void usb_buffer_free (struct usb_device *dev, size_t size,
void *addr, dma_addr_t dma);
#if 0
struct urb *usb_buffer_map (struct urb *urb);
void usb_buffer_dmasync (struct urb *urb);
void usb_buffer_unmap (struct urb *urb);
#endif
struct scatterlist;
int usb_buffer_map_sg (struct usb_device *dev, unsigned pipe,
struct scatterlist *sg, int nents);
#if 0
void usb_buffer_dmasync_sg (struct usb_device *dev, unsigned pipe,
struct scatterlist *sg, int n_hw_ents);
#endif
void usb_buffer_unmap_sg (struct usb_device *dev, unsigned pipe,
struct scatterlist *sg, int n_hw_ents);
/*-------------------------------------------------------------------*
* SYNCHRONOUS CALL SUPPORT *
*-------------------------------------------------------------------*/
extern int usb_control_msg(struct usb_device *dev, unsigned int pipe,
__u8 request, __u8 requesttype, __u16 value, __u16 index,
void *data, __u16 size, int timeout);
extern int usb_bulk_msg(struct usb_device *usb_dev, unsigned int pipe,
void *data, int len, int *actual_length,
int timeout);
/* selective suspend/resume */
extern int usb_suspend_device(struct usb_device *dev, pm_message_t message);
extern int usb_resume_device(struct usb_device *dev);
/* wrappers around usb_control_msg() for the most common standard requests */
extern int usb_get_descriptor(struct usb_device *dev, unsigned char desctype,
unsigned char descindex, void *buf, int size);
extern int usb_get_status(struct usb_device *dev,
int type, int target, void *data);
extern int usb_get_string(struct usb_device *dev,
unsigned short langid, unsigned char index, void *buf, int size);
extern int usb_string(struct usb_device *dev, int index,
char *buf, size_t size);
/* wrappers that also update important state inside usbcore */
extern int usb_clear_halt(struct usb_device *dev, int pipe);
extern int usb_reset_configuration(struct usb_device *dev);
extern int usb_set_interface(struct usb_device *dev, int ifnum, int alternate);
/*
* timeouts, in milliseconds, used for sending/receiving control messages
* they typically complete within a few frames (msec) after they're issued
* USB identifies 5 second timeouts, maybe more in a few cases, and a few
* slow devices (like some MGE Ellipse UPSes) actually push that limit.
*/
#define USB_CTRL_GET_TIMEOUT 5000
#define USB_CTRL_SET_TIMEOUT 5000
/**
* struct usb_sg_request - support for scatter/gather I/O
* @status: zero indicates success, else negative errno
* @bytes: counts bytes transferred.
*
* These requests are initialized using usb_sg_init(), and then are used
* as request handles passed to usb_sg_wait() or usb_sg_cancel(). Most
* members of the request object aren't for driver access.
*
* The status and bytecount values are valid only after usb_sg_wait()
* returns. If the status is zero, then the bytecount matches the total
* from the request.
*
* After an error completion, drivers may need to clear a halt condition
* on the endpoint.
*/
struct usb_sg_request {
int status;
size_t bytes;
/*
* members below are private to usbcore,
* and are not provided for driver access!
*/
spinlock_t lock;
struct usb_device *dev;
int pipe;
struct scatterlist *sg;
int nents;
int entries;
struct urb **urbs;
int count;
struct completion complete;
};
int usb_sg_init (
struct usb_sg_request *io,
struct usb_device *dev,
unsigned pipe,
unsigned period,
struct scatterlist *sg,
int nents,
size_t length,
unsigned mem_flags
);
void usb_sg_cancel (struct usb_sg_request *io);
void usb_sg_wait (struct usb_sg_request *io);
/* -------------------------------------------------------------------------- */
/*
* For various legacy reasons, Linux has a small cookie that's paired with
* a struct usb_device to identify an endpoint queue. Queue characteristics
* are defined by the endpoint's descriptor. This cookie is called a "pipe",
* an unsigned int encoded as:
*
* - direction: bit 7 (0 = Host-to-Device [Out],
* 1 = Device-to-Host [In] ...
* like endpoint bEndpointAddress)
* - device address: bits 8-14 ... bit positions known to uhci-hcd
* - endpoint: bits 15-18 ... bit positions known to uhci-hcd
* - pipe type: bits 30-31 (00 = isochronous, 01 = interrupt,
* 10 = control, 11 = bulk)
*
* Given the device address and endpoint descriptor, pipes are redundant.
*/
/* NOTE: these are not the standard USB_ENDPOINT_XFER_* values!! */
/* (yet ... they're the values used by usbfs) */
#define PIPE_ISOCHRONOUS 0
#define PIPE_INTERRUPT 1
#define PIPE_CONTROL 2
#define PIPE_BULK 3
#define usb_pipein(pipe) ((pipe) & USB_DIR_IN)
#define usb_pipeout(pipe) (!usb_pipein(pipe))
#define usb_pipedevice(pipe) (((pipe) >> 8) & 0x7f)
#define usb_pipeendpoint(pipe) (((pipe) >> 15) & 0xf)
#define usb_pipetype(pipe) (((pipe) >> 30) & 3)
#define usb_pipeisoc(pipe) (usb_pipetype((pipe)) == PIPE_ISOCHRONOUS)
#define usb_pipeint(pipe) (usb_pipetype((pipe)) == PIPE_INTERRUPT)
#define usb_pipecontrol(pipe) (usb_pipetype((pipe)) == PIPE_CONTROL)
#define usb_pipebulk(pipe) (usb_pipetype((pipe)) == PIPE_BULK)
/* The D0/D1 toggle bits ... USE WITH CAUTION (they're almost hcd-internal) */
#define usb_gettoggle(dev, ep, out) (((dev)->toggle[out] >> (ep)) & 1)
#define usb_dotoggle(dev, ep, out) ((dev)->toggle[out] ^= (1 << (ep)))
#define usb_settoggle(dev, ep, out, bit) ((dev)->toggle[out] = ((dev)->toggle[out] & ~(1 << (ep))) | ((bit) << (ep)))
static inline unsigned int __create_pipe(struct usb_device *dev, unsigned int endpoint)
{
return (dev->devnum << 8) | (endpoint << 15);
}
/* Create various pipes... */
#define usb_sndctrlpipe(dev,endpoint) ((PIPE_CONTROL << 30) | __create_pipe(dev,endpoint))
#define usb_rcvctrlpipe(dev,endpoint) ((PIPE_CONTROL << 30) | __create_pipe(dev,endpoint) | USB_DIR_IN)
#define usb_sndisocpipe(dev,endpoint) ((PIPE_ISOCHRONOUS << 30) | __create_pipe(dev,endpoint))
#define usb_rcvisocpipe(dev,endpoint) ((PIPE_ISOCHRONOUS << 30) | __create_pipe(dev,endpoint) | USB_DIR_IN)
#define usb_sndbulkpipe(dev,endpoint) ((PIPE_BULK << 30) | __create_pipe(dev,endpoint))
#define usb_rcvbulkpipe(dev,endpoint) ((PIPE_BULK << 30) | __create_pipe(dev,endpoint) | USB_DIR_IN)
#define usb_sndintpipe(dev,endpoint) ((PIPE_INTERRUPT << 30) | __create_pipe(dev,endpoint))
#define usb_rcvintpipe(dev,endpoint) ((PIPE_INTERRUPT << 30) | __create_pipe(dev,endpoint) | USB_DIR_IN)
/*-------------------------------------------------------------------------*/
static inline __u16
usb_maxpacket(struct usb_device *udev, int pipe, int is_out)
{
struct usb_host_endpoint *ep;
unsigned epnum = usb_pipeendpoint(pipe);
if (is_out) {
WARN_ON(usb_pipein(pipe));
ep = udev->ep_out[epnum];
} else {
WARN_ON(usb_pipeout(pipe));
ep = udev->ep_in[epnum];
}
if (!ep)
return 0;
/* NOTE: only 0x07ff bits are for packet size... */
return le16_to_cpu(ep->desc.wMaxPacketSize);
}
/* -------------------------------------------------------------------------- */
#ifdef DEBUG
#define dbg(format, arg...) printk(KERN_DEBUG "%s: " format "\n" , __FILE__ , ## arg)
#else
#define dbg(format, arg...) do {} while (0)
#endif
#define err(format, arg...) printk(KERN_ERR "%s: " format "\n" , __FILE__ , ## arg)
#define info(format, arg...) printk(KERN_INFO "%s: " format "\n" , __FILE__ , ## arg)
#define warn(format, arg...) printk(KERN_WARNING "%s: " format "\n" , __FILE__ , ## arg)
#endif /* __KERNEL__ */
#endif