[J-u-boot.git] / include / linux / usb / composite.h

/*
 * composite.h -- framework for usb gadgets which are composite devices
 *
 * Copyright (C) 2006-2008 David Brownell
 *
 * SPDX-License-Identifier:	GPL-2.0+
 */

#ifndef	__LINUX_USB_COMPOSITE_H
#define	__LINUX_USB_COMPOSITE_H

/*
 * This framework is an optional layer on top of the USB Gadget interface,
 * making it easier to build (a) Composite devices, supporting multiple
 * functions within any single configuration, and (b) Multi-configuration
 * devices, also supporting multiple functions but without necessarily
 * having more than one function per configuration.
 *
 * Example:  a device with a single configuration supporting both network
 * link and mass storage functions is a composite device.  Those functions
 * might alternatively be packaged in individual configurations, but in
 * the composite model the host can use both functions at the same time.
 */

#include <common.h>
#include <linux/usb/ch9.h>
#include <linux/usb/gadget.h>
#include <usb/lin_gadget_compat.h>

/*
 * USB function drivers should return USB_GADGET_DELAYED_STATUS if they
 * wish to delay the data/status stages of the control transfer till they
 * are ready. The control transfer will then be kept from completing till
 * all the function drivers that requested for USB_GADGET_DELAYED_STAUS
 * invoke usb_composite_setup_continue().
 */
#define	USB_GADGET_DELAYED_STATUS	0x7fff /* Impossibly large value */

struct usb_configuration;

/**
 * struct usb_function - describes one function of a configuration
 * @name: For diagnostics, identifies the function.
 * @strings: tables of strings, keyed by identifiers assigned during bind()
 *	and by language IDs provided in control requests
 * @descriptors: Table of full (or low) speed descriptors, using interface and
 *	string identifiers assigned during @bind().  If this pointer is null,
 *	the function will not be available at full speed (or at low speed).
 * @hs_descriptors: Table of high speed descriptors, using interface and
 *	string identifiers assigned during @bind().  If this pointer is null,
 *	the function will not be available at high speed.
 * @config: assigned when @usb_add_function() is called; this is the
 *	configuration with which this function is associated.
 * @bind: Before the gadget can register, all of its functions bind() to the
 *	available resources including string and interface identifiers used
 *	in interface or class descriptors; endpoints; I/O buffers; and so on.
 * @unbind: Reverses @bind; called as a side effect of unregistering the
 *	driver which added this function.
 * @set_alt: (REQUIRED) Reconfigures altsettings; function drivers may
 *	initialize usb_ep.driver data at this time (when it is used).
 *	Note that setting an interface to its current altsetting resets
 *	interface state, and that all interfaces have a disabled state.
 * @get_alt: Returns the active altsetting.  If this is not provided,
 *	then only altsetting zero is supported.
 * @disable: (REQUIRED) Indicates the function should be disabled.  Reasons
 *	include host resetting or reconfiguring the gadget, and disconnection.
 * @setup: Used for interface-specific control requests.
 * @suspend: Notifies functions when the host stops sending USB traffic.
 * @resume: Notifies functions when the host restarts USB traffic.
 *
 * A single USB function uses one or more interfaces, and should in most
 * cases support operation at both full and high speeds.  Each function is
 * associated by @usb_add_function() with a one configuration; that function
 * causes @bind() to be called so resources can be allocated as part of
 * setting up a gadget driver.  Those resources include endpoints, which
 * should be allocated using @usb_ep_autoconfig().
 *
 * To support dual speed operation, a function driver provides descriptors
 * for both high and full speed operation.  Except in rare cases that don't
 * involve bulk endpoints, each speed needs different endpoint descriptors.
 *
 * Function drivers choose their own strategies for managing instance data.
 * The simplest strategy just declares it "static', which means the function
 * can only be activated once.  If the function needs to be exposed in more
 * than one configuration at a given speed, it needs to support multiple
 * usb_function structures (one for each configuration).
 *
 * A more complex strategy might encapsulate a @usb_function structure inside
 * a driver-specific instance structure to allows multiple activations.  An
 * example of multiple activations might be a CDC ACM function that supports
 * two or more distinct instances within the same configuration, providing
 * several independent logical data links to a USB host.
 */
struct usb_function {
	const char			*name;
	struct usb_gadget_strings	**strings;
	struct usb_descriptor_header	**descriptors;
	struct usb_descriptor_header	**hs_descriptors;

	struct usb_configuration	*config;

	/* REVISIT:  bind() functions can be marked __init, which
	 * makes trouble for section mismatch analysis.  See if
	 * we can't restructure things to avoid mismatching.
	 * Related:  unbind() may kfree() but bind() won't...
	 */

	/* configuration management:  bind/unbind */
	int			(*bind)(struct usb_configuration *,
					struct usb_function *);
	void			(*unbind)(struct usb_configuration *,
					struct usb_function *);

	/* runtime state management */
	int			(*set_alt)(struct usb_function *,
					unsigned interface, unsigned alt);
	int			(*get_alt)(struct usb_function *,
					unsigned interface);
	void			(*disable)(struct usb_function *);
	int			(*setup)(struct usb_function *,
					const struct usb_ctrlrequest *);
	void			(*suspend)(struct usb_function *);
	void			(*resume)(struct usb_function *);

	/* private: */
	/* internals */
	struct list_head		list;
	DECLARE_BITMAP(endpoints, 32);
};

int usb_add_function(struct usb_configuration *, struct usb_function *);

int usb_function_deactivate(struct usb_function *);
int usb_function_activate(struct usb_function *);

int usb_interface_id(struct usb_configuration *, struct usb_function *);

/**
 * ep_choose - select descriptor endpoint at current device speed
 * @g: gadget, connected and running at some speed
 * @hs: descriptor to use for high speed operation
 * @fs: descriptor to use for full or low speed operation
 */
static inline struct usb_endpoint_descriptor *
ep_choose(struct usb_gadget *g, struct usb_endpoint_descriptor *hs,
		struct usb_endpoint_descriptor *fs)
{
	if (gadget_is_dualspeed(g) && g->speed == USB_SPEED_HIGH)
		return hs;
	return fs;
}

#define	MAX_CONFIG_INTERFACES		16	/* arbitrary; max 255 */

/**
 * struct usb_configuration - represents one gadget configuration
 * @label: For diagnostics, describes the configuration.
 * @strings: Tables of strings, keyed by identifiers assigned during @bind()
 *	and by language IDs provided in control requests.
 * @descriptors: Table of descriptors preceding all function descriptors.
 *	Examples include OTG and vendor-specific descriptors.
 * @bind: Called from @usb_add_config() to allocate resources unique to this
 *	configuration and to call @usb_add_function() for each function used.
 * @unbind: Reverses @bind; called as a side effect of unregistering the
 *	driver which added this configuration.
 * @setup: Used to delegate control requests that aren't handled by standard
 *	device infrastructure or directed at a specific interface.
 * @bConfigurationValue: Copied into configuration descriptor.
 * @iConfiguration: Copied into configuration descriptor.
 * @bmAttributes: Copied into configuration descriptor.
 * @bMaxPower: Copied into configuration descriptor.
 * @cdev: assigned by @usb_add_config() before calling @bind(); this is
 *	the device associated with this configuration.
 *
 * Configurations are building blocks for gadget drivers structured around
 * function drivers.  Simple USB gadgets require only one function and one
 * configuration, and handle dual-speed hardware by always providing the same
 * functionality.  Slightly more complex gadgets may have more than one
 * single-function configuration at a given speed; or have configurations
 * that only work at one speed.
 *
 * Composite devices are, by definition, ones with configurations which
 * include more than one function.
 *
 * The lifecycle of a usb_configuration includes allocation, initialization
 * of the fields described above, and calling @usb_add_config() to set up
 * internal data and bind it to a specific device.  The configuration's
 * @bind() method is then used to initialize all the functions and then
 * call @usb_add_function() for them.
 *
 * Those functions would normally be independant of each other, but that's
 * not mandatory.  CDC WMC devices are an example where functions often
 * depend on other functions, with some functions subsidiary to others.
 * Such interdependency may be managed in any way, so long as all of the
 * descriptors complete by the time the composite driver returns from
 * its bind() routine.
 */
struct usb_configuration {
	const char			*label;
	struct usb_gadget_strings	**strings;
	const struct usb_descriptor_header **descriptors;

	/* REVISIT:  bind() functions can be marked __init, which
	 * makes trouble for section mismatch analysis.  See if
	 * we can't restructure things to avoid mismatching...
	 */

	/* configuration management:  bind/unbind */
	int			(*bind)(struct usb_configuration *);
	void			(*unbind)(struct usb_configuration *);
	int			(*setup)(struct usb_configuration *,
					const struct usb_ctrlrequest *);

	/* fields in the config descriptor */
	u8			bConfigurationValue;
	u8			iConfiguration;
	u8			bmAttributes;
	u8			bMaxPower;

	struct usb_composite_dev	*cdev;

	/* private: */
	/* internals */
	struct list_head	list;
	struct list_head	functions;
	u8			next_interface_id;
	unsigned		highspeed:1;
	unsigned		fullspeed:1;
	struct usb_function	*interface[MAX_CONFIG_INTERFACES];
};

int usb_add_config(struct usb_composite_dev *,
		struct usb_configuration *);

/**
 * struct usb_composite_driver - groups configurations into a gadget
 * @name: For diagnostics, identifies the driver.
 * @dev: Template descriptor for the device, including default device
 *	identifiers.
 * @strings: tables of strings, keyed by identifiers assigned during bind()
 *	and language IDs provided in control requests
 * @bind: (REQUIRED) Used to allocate resources that are shared across the
 *	whole device, such as string IDs, and add its configurations using
 *	@usb_add_config().  This may fail by returning a negative errno
 *	value; it should return zero on successful initialization.
 * @unbind: Reverses @bind(); called as a side effect of unregistering
 *	this driver.
 * @disconnect: optional driver disconnect method
 * @suspend: Notifies when the host stops sending USB traffic,
 *	after function notifications
 * @resume: Notifies configuration when the host restarts USB traffic,
 *	before function notifications
 *
 * Devices default to reporting self powered operation.  Devices which rely
 * on bus powered operation should report this in their @bind() method.
 *
 * Before returning from @bind, various fields in the template descriptor
 * may be overridden.  These include the idVendor/idProduct/bcdDevice values
 * normally to bind the appropriate host side driver, and the three strings
 * (iManufacturer, iProduct, iSerialNumber) normally used to provide user
 * meaningful device identifiers.  (The strings will not be defined unless
 * they are defined in @dev and @strings.)  The correct ep0 maxpacket size
 * is also reported, as defined by the underlying controller driver.
 */
struct usb_composite_driver {
	const char				*name;
	const struct usb_device_descriptor	*dev;
	struct usb_gadget_strings		**strings;

	/* REVISIT:  bind() functions can be marked __init, which
	 * makes trouble for section mismatch analysis.  See if
	 * we can't restructure things to avoid mismatching...
	 */

	int			(*bind)(struct usb_composite_dev *);
	int			(*unbind)(struct usb_composite_dev *);

	void			(*disconnect)(struct usb_composite_dev *);

	/* global suspend hooks */
	void			(*suspend)(struct usb_composite_dev *);
	void			(*resume)(struct usb_composite_dev *);
};

extern int usb_composite_register(struct usb_composite_driver *);
extern void usb_composite_unregister(struct usb_composite_driver *);


/**
 * struct usb_composite_device - represents one composite usb gadget
 * @gadget: read-only, abstracts the gadget's usb peripheral controller
 * @req: used for control responses; buffer is pre-allocated
 * @bufsiz: size of buffer pre-allocated in @req
 * @config: the currently active configuration
 *
 * One of these devices is allocated and initialized before the
 * associated device driver's bind() is called.
 *
 * OPEN ISSUE:  it appears that some WUSB devices will need to be
 * built by combining a normal (wired) gadget with a wireless one.
 * This revision of the gadget framework should probably try to make
 * sure doing that won't hurt too much.
 *
 * One notion for how to handle Wireless USB devices involves:
 * (a) a second gadget here, discovery mechanism TBD, but likely
 *     needing separate "register/unregister WUSB gadget" calls;
 * (b) updates to usb_gadget to include flags "is it wireless",
 *     "is it wired", plus (presumably in a wrapper structure)
 *     bandgroup and PHY info;
 * (c) presumably a wireless_ep wrapping a usb_ep, and reporting
 *     wireless-specific parameters like maxburst and maxsequence;
 * (d) configurations that are specific to wireless links;
 * (e) function drivers that understand wireless configs and will
 *     support wireless for (additional) function instances;
 * (f) a function to support association setup (like CBAF), not
 *     necessarily requiring a wireless adapter;
 * (g) composite device setup that can create one or more wireless
 *     configs, including appropriate association setup support;
 * (h) more, TBD.
 */
struct usb_composite_dev {
	struct usb_gadget		*gadget;
	struct usb_request		*req;
	unsigned			bufsiz;

	struct usb_configuration	*config;

	/* private: */
	/* internals */
	unsigned int			suspended:1;
	struct usb_device_descriptor __aligned(CONFIG_SYS_CACHELINE_SIZE) desc;
	struct list_head		configs;
	struct usb_composite_driver	*driver;
	u8				next_string_id;

	/* the gadget driver won't enable the data pullup
	 * while the deactivation count is nonzero.
	 */
	unsigned			deactivations;
};

extern int usb_string_id(struct usb_composite_dev *c);
extern int usb_string_ids_tab(struct usb_composite_dev *c,
			      struct usb_string *str);
extern int usb_string_ids_n(struct usb_composite_dev *c, unsigned n);

#endif	/* __LINUX_USB_COMPOSITE_H */
Commit	Line	Data
7010f5b9 ŁM	1	/*
	2	* composite.h -- framework for usb gadgets which are composite devices
	3	*
	4	* Copyright (C) 2006-2008 David Brownell
	5	*
1a459660	6	* SPDX-License-Identifier: GPL-2.0+
7010f5b9 ŁM	7	*/
	8
	9	#ifndef __LINUX_USB_COMPOSITE_H
	10	#define __LINUX_USB_COMPOSITE_H
	11
	12	/*
	13	* This framework is an optional layer on top of the USB Gadget interface,
	14	* making it easier to build (a) Composite devices, supporting multiple
	15	* functions within any single configuration, and (b) Multi-configuration
	16	* devices, also supporting multiple functions but without necessarily
	17	* having more than one function per configuration.
	18	*
	19	* Example: a device with a single configuration supporting both network
	20	* link and mass storage functions is a composite device. Those functions
	21	* might alternatively be packaged in individual configurations, but in
	22	* the composite model the host can use both functions at the same time.
	23	*/
	24
	25	#include <common.h>
	26	#include <linux/usb/ch9.h>
	27	#include <linux/usb/gadget.h>
	28	#include <usb/lin_gadget_compat.h>
	29
6f803906 KVA	30	/*
	31	* USB function drivers should return USB_GADGET_DELAYED_STATUS if they
	32	* wish to delay the data/status stages of the control transfer till they
	33	* are ready. The control transfer will then be kept from completing till
	34	* all the function drivers that requested for USB_GADGET_DELAYED_STAUS
	35	* invoke usb_composite_setup_continue().
	36	*/
	37	#define USB_GADGET_DELAYED_STATUS 0x7fff /* Impossibly large value */
	38
7010f5b9 ŁM	39	struct usb_configuration;
	40
	41	/**
	42	* struct usb_function - describes one function of a configuration
	43	* @name: For diagnostics, identifies the function.
	44	* @strings: tables of strings, keyed by identifiers assigned during bind()
	45	* and by language IDs provided in control requests
	46	* @descriptors: Table of full (or low) speed descriptors, using interface and
	47	* string identifiers assigned during @bind(). If this pointer is null,
	48	* the function will not be available at full speed (or at low speed).
	49	* @hs_descriptors: Table of high speed descriptors, using interface and
	50	* string identifiers assigned during @bind(). If this pointer is null,
	51	* the function will not be available at high speed.
	52	* @config: assigned when @usb_add_function() is called; this is the
	53	* configuration with which this function is associated.
	54	* @bind: Before the gadget can register, all of its functions bind() to the
	55	* available resources including string and interface identifiers used
	56	* in interface or class descriptors; endpoints; I/O buffers; and so on.
	57	* @unbind: Reverses @bind; called as a side effect of unregistering the
	58	* driver which added this function.
	59	* @set_alt: (REQUIRED) Reconfigures altsettings; function drivers may
	60	* initialize usb_ep.driver data at this time (when it is used).
	61	* Note that setting an interface to its current altsetting resets
	62	* interface state, and that all interfaces have a disabled state.
	63	* @get_alt: Returns the active altsetting. If this is not provided,
	64	* then only altsetting zero is supported.
	65	* @disable: (REQUIRED) Indicates the function should be disabled. Reasons
	66	* include host resetting or reconfiguring the gadget, and disconnection.
	67	* @setup: Used for interface-specific control requests.
	68	* @suspend: Notifies functions when the host stops sending USB traffic.
	69	* @resume: Notifies functions when the host restarts USB traffic.
	70	*
	71	* A single USB function uses one or more interfaces, and should in most
	72	* cases support operation at both full and high speeds. Each function is
	73	* associated by @usb_add_function() with a one configuration; that function
	74	* causes @bind() to be called so resources can be allocated as part of
	75	* setting up a gadget driver. Those resources include endpoints, which
	76	* should be allocated using @usb_ep_autoconfig().
	77	*
	78	* To support dual speed operation, a function driver provides descriptors
	79	* for both high and full speed operation. Except in rare cases that don't
	80	* involve bulk endpoints, each speed needs different endpoint descriptors.
	81	*
	82	* Function drivers choose their own strategies for managing instance data.
	83	* The simplest strategy just declares it "static', which means the function
	84	* can only be activated once. If the function needs to be exposed in more
	85	* than one configuration at a given speed, it needs to support multiple
	86	* usb_function structures (one for each configuration).
	87	*
	88	* A more complex strategy might encapsulate a @usb_function structure inside
	89	* a driver-specific instance structure to allows multiple activations. An
	90	* example of multiple activations might be a CDC ACM function that supports
	91	* two or more distinct instances within the same configuration, providing
	92	* several independent logical data links to a USB host.
	93	*/
	94	struct usb_function {
	95	const char *name;
	96	struct usb_gadget_strings **strings;
	97	struct usb_descriptor_header **descriptors;
	98	struct usb_descriptor_header **hs_descriptors;
	99
	100	struct usb_configuration *config;
	101
	102	/* REVISIT: bind() functions can be marked __init, which
103	* makes trouble for section mismatch analysis. See if
104	* we can't restructure things to avoid mismatching.
105	* Related: unbind() may kfree() but bind() won't...
106	*/
107
108	/* configuration management: bind/unbind */
109	int (bind)(struct usb_configuration ,
110	struct usb_function *);
111	void (unbind)(struct usb_configuration ,
112	struct usb_function *);
113
114	/* runtime state management */
115	int (set_alt)(struct usb_function ,
116	unsigned interface, unsigned alt);
117	int (get_alt)(struct usb_function ,
118	unsigned interface);
119	void (disable)(struct usb_function );
120	int (setup)(struct usb_function ,
121	const struct usb_ctrlrequest *);
122	void (suspend)(struct usb_function );
123	void (resume)(struct usb_function );
124
125	/* private: */
126	/* internals */
127	struct list_head list;
128	DECLARE_BITMAP(endpoints, 32);
129	};
130
131	int usb_add_function(struct usb_configuration , struct usb_function );
132
133	int usb_function_deactivate(struct usb_function *);
134	int usb_function_activate(struct usb_function *);
135
136	int usb_interface_id(struct usb_configuration , struct usb_function );
137
138	/**
139	* ep_choose - select descriptor endpoint at current device speed
140	* @g: gadget, connected and running at some speed
141	* @hs: descriptor to use for high speed operation
142	* @fs: descriptor to use for full or low speed operation
143	*/
144	static inline struct usb_endpoint_descriptor *
145	ep_choose(struct usb_gadget g, struct usb_endpoint_descriptor hs,
146	struct usb_endpoint_descriptor *fs)
147	{
148	if (gadget_is_dualspeed(g) && g->speed == USB_SPEED_HIGH)
149	return hs;
150	return fs;
151	}
152
153	#define MAX_CONFIG_INTERFACES 16 /* arbitrary; max 255 */
154
155	/**
156	* struct usb_configuration - represents one gadget configuration
157	* @label: For diagnostics, describes the configuration.
158	* @strings: Tables of strings, keyed by identifiers assigned during @bind()
159	* and by language IDs provided in control requests.
160	* @descriptors: Table of descriptors preceding all function descriptors.
161	* Examples include OTG and vendor-specific descriptors.
162	* @bind: Called from @usb_add_config() to allocate resources unique to this
163	* configuration and to call @usb_add_function() for each function used.
164	* @unbind: Reverses @bind; called as a side effect of unregistering the
165	* driver which added this configuration.
166	* @setup: Used to delegate control requests that aren't handled by standard
167	* device infrastructure or directed at a specific interface.
168	* @bConfigurationValue: Copied into configuration descriptor.
169	* @iConfiguration: Copied into configuration descriptor.
170	* @bmAttributes: Copied into configuration descriptor.
171	* @bMaxPower: Copied into configuration descriptor.
172	* @cdev: assigned by @usb_add_config() before calling @bind(); this is
173	* the device associated with this configuration.
174	*
175	* Configurations are building blocks for gadget drivers structured around
176	* function drivers. Simple USB gadgets require only one function and one
177	* configuration, and handle dual-speed hardware by always providing the same
178	* functionality. Slightly more complex gadgets may have more than one
179	* single-function configuration at a given speed; or have configurations
180	* that only work at one speed.
181	*
182	* Composite devices are, by definition, ones with configurations which
183	* include more than one function.
184	*
185	* The lifecycle of a usb_configuration includes allocation, initialization
186	* of the fields described above, and calling @usb_add_config() to set up
187	* internal data and bind it to a specific device. The configuration's
188	* @bind() method is then used to initialize all the functions and then
189	* call @usb_add_function() for them.
190	*
191	* Those functions would normally be independant of each other, but that's
192	* not mandatory. CDC WMC devices are an example where functions often
193	* depend on other functions, with some functions subsidiary to others.
194	* Such interdependency may be managed in any way, so long as all of the
195	* descriptors complete by the time the composite driver returns from
196	* its bind() routine.
197	*/
198	struct usb_configuration {
199	const char *label;
200	struct usb_gadget_strings **strings;
201	const struct usb_descriptor_header **descriptors;
202
203	/* REVISIT: bind() functions can be marked __init, which
204	* makes trouble for section mismatch analysis. See if
205	* we can't restructure things to avoid mismatching...
206	*/
207
208	/* configuration management: bind/unbind */
209	int (bind)(struct usb_configuration );
210	void (unbind)(struct usb_configuration );
211	int (setup)(struct usb_configuration ,
212	const struct usb_ctrlrequest *);
213
214	/* fields in the config descriptor */
215	u8 bConfigurationValue;
216	u8 iConfiguration;
217	u8 bmAttributes;
218	u8 bMaxPower;
219
220	struct usb_composite_dev *cdev;
221
222	/* private: */
223	/* internals */
224	struct list_head list;
225	struct list_head functions;
226	u8 next_interface_id;
227	unsigned highspeed:1;
228	unsigned fullspeed:1;
229	struct usb_function *interface[MAX_CONFIG_INTERFACES];
230	};
231
232	int usb_add_config(struct usb_composite_dev *,
233	struct usb_configuration *);
234
235	/**
236	* struct usb_composite_driver - groups configurations into a gadget
237	* @name: For diagnostics, identifies the driver.
238	* @dev: Template descriptor for the device, including default device
239	* identifiers.
240	* @strings: tables of strings, keyed by identifiers assigned during bind()
241	* and language IDs provided in control requests
242	* @bind: (REQUIRED) Used to allocate resources that are shared across the
243	* whole device, such as string IDs, and add its configurations using
244	* @usb_add_config(). This may fail by returning a negative errno
245	* value; it should return zero on successful initialization.
246	* @unbind: Reverses @bind(); called as a side effect of unregistering
247	* this driver.
248	* @disconnect: optional driver disconnect method
249	* @suspend: Notifies when the host stops sending USB traffic,
250	* after function notifications
251	* @resume: Notifies configuration when the host restarts USB traffic,
252	* before function notifications
253	*
254	* Devices default to reporting self powered operation. Devices which rely
255	* on bus powered operation should report this in their @bind() method.
256	*
257	* Before returning from @bind, various fields in the template descriptor
258	* may be overridden. These include the idVendor/idProduct/bcdDevice values
259	* normally to bind the appropriate host side driver, and the three strings
260	* (iManufacturer, iProduct, iSerialNumber) normally used to provide user
261	* meaningful device identifiers. (The strings will not be defined unless
262	* they are defined in @dev and @strings.) The correct ep0 maxpacket size
263	* is also reported, as defined by the underlying controller driver.
264	*/
265	struct usb_composite_driver {
266	const char *name;
267	const struct usb_device_descriptor *dev;
268	struct usb_gadget_strings **strings;
269
270	/* REVISIT: bind() functions can be marked __init, which
271	* makes trouble for section mismatch analysis. See if
272	* we can't restructure things to avoid mismatching...
273	*/
274
275	int (bind)(struct usb_composite_dev );
276	int (unbind)(struct usb_composite_dev );
277
278	void (disconnect)(struct usb_composite_dev );
279
280	/* global suspend hooks */
281	void (suspend)(struct usb_composite_dev );
282	void (resume)(struct usb_composite_dev );
283	};
284
285	extern int usb_composite_register(struct usb_composite_driver *);
286	extern void usb_composite_unregister(struct usb_composite_driver *);
287
288
289	/**
290	* struct usb_composite_device - represents one composite usb gadget
291	* @gadget: read-only, abstracts the gadget's usb peripheral controller
292	* @req: used for control responses; buffer is pre-allocated
293	* @bufsiz: size of buffer pre-allocated in @req
294	* @config: the currently active configuration
295	*
296	* One of these devices is allocated and initialized before the
297	* associated device driver's bind() is called.
298	*
299	* OPEN ISSUE: it appears that some WUSB devices will need to be
300	* built by combining a normal (wired) gadget with a wireless one.
301	* This revision of the gadget framework should probably try to make
302	* sure doing that won't hurt too much.
303	*
304	* One notion for how to handle Wireless USB devices involves:
305	* (a) a second gadget here, discovery mechanism TBD, but likely
306	* needing separate "register/unregister WUSB gadget" calls;
307	* (b) updates to usb_gadget to include flags "is it wireless",
308	* "is it wired", plus (presumably in a wrapper structure)
309	* bandgroup and PHY info;
310	* (c) presumably a wireless_ep wrapping a usb_ep, and reporting
311	* wireless-specific parameters like maxburst and maxsequence;
312	* (d) configurations that are specific to wireless links;
313	* (e) function drivers that understand wireless configs and will
314	* support wireless for (additional) function instances;
315	* (f) a function to support association setup (like CBAF), not
316	* necessarily requiring a wireless adapter;
317	* (g) composite device setup that can create one or more wireless
318	* configs, including appropriate association setup support;
319	* (h) more, TBD.
320	*/
321	struct usb_composite_dev {
322	struct usb_gadget *gadget;
323	struct usb_request *req;
324	unsigned bufsiz;
325
326	struct usb_configuration *config;
327
328	/* private: */
329	/* internals */
330	unsigned int suspended:1;
b37c4a2b	331	struct usb_device_descriptor __aligned(CONFIG_SYS_CACHELINE_SIZE) desc;
7010f5b9 ŁM	332	struct list_head configs;
	333	struct usb_composite_driver *driver;
	334	u8 next_string_id;
	335
	336	/* the gadget driver won't enable the data pullup
	337	* while the deactivation count is nonzero.
	338	*/
	339	unsigned deactivations;
	340	};
	341
	342	extern int usb_string_id(struct usb_composite_dev *c);
	343	extern int usb_string_ids_tab(struct usb_composite_dev *c,
	344	struct usb_string *str);
	345	extern int usb_string_ids_n(struct usb_composite_dev *c, unsigned n);
	346
	347	#endif /* __LINUX_USB_COMPOSITE_H */