hcd.c source code [Linux/drivers/usb/core/hcd.c]

1	// SPDX-License-Identifier: GPL-2.0+
2	/*
3	* (C) Copyright Linus Torvalds 1999
4	* (C) Copyright Johannes Erdfelt 1999-2001
5	* (C) Copyright Andreas Gal 1999
6	* (C) Copyright Gregory P. Smith 1999
7	* (C) Copyright Deti Fliegl 1999
8	* (C) Copyright Randy Dunlap 2000
9	* (C) Copyright David Brownell 2000-2002
10	*/
11
12	#include <linux/bcd.h>
13	#include <linux/module.h>
14	#include <linux/version.h>
15	#include <linux/kernel.h>
16	#include <linux/sched/task_stack.h>
17	#include <linux/slab.h>
18	#include <linux/completion.h>
19	#include <linux/utsname.h>
20	#include <linux/mm.h>
21	#include <asm/io.h>
22	#include <linux/device.h>
23	#include <linux/dma-mapping.h>
24	#include <linux/mutex.h>
25	#include <asm/irq.h>
26	#include <asm/byteorder.h>
27	#include <linux/unaligned.h>
28	#include <linux/platform_device.h>
29	#include <linux/workqueue.h>
30	#include <linux/pm_runtime.h>
31	#include <linux/types.h>
32	#include <linux/genalloc.h>
33	#include <linux/io.h>
34	#include <linux/kcov.h>
35
36	#include <linux/phy/phy.h>
37	#include <linux/usb.h>
38	#include <linux/usb/hcd.h>
39	#include <linux/usb/otg.h>
40
41	#include "usb.h"
42	#include "phy.h"
43
44
45	/-------------------------------------------------------------------------/
46
47	/*
48	* USB Host Controller Driver framework
49	*
50	* Plugs into usbcore (usb_bus) and lets HCDs share code, minimizing
51	* HCD-specific behaviors/bugs.
52	*
53	* This does error checks, tracks devices and urbs, and delegates to a
54	* "hc_driver" only for code (and data) that really needs to know about
55	* hardware differences. That includes root hub registers, i/o queues,
56	* and so on ... but as little else as possible.
57	*
58	* Shared code includes most of the "root hub" code (these are emulated,
59	* though each HC's hardware works differently) and PCI glue, plus request
60	* tracking overhead. The HCD code should only block on spinlocks or on
61	* hardware handshaking; blocking on software events (such as other kernel
62	* threads releasing resources, or completing actions) is all generic.
63	*
64	* Happens the USB 2.0 spec says this would be invisible inside the "USBD",
65	* and includes mostly a "HCDI" (HCD Interface) along with some APIs used
66	* only by the hub driver ... and that neither should be seen or used by
67	* usb client device drivers.
68	*
69	* Contributors of ideas or unattributed patches include: David Brownell,
70	* Roman Weissgaerber, Rory Bolt, Greg Kroah-Hartman, ...
71	*
72	* HISTORY:
73	* 2002-02-21 Pull in most of the usb_bus support from usb.c; some
74	* associated cleanup. "usb_hcd" still != "usb_bus".
75	* 2001-12-12 Initial patch version for Linux 2.5.1 kernel.
76	*/
77
78	/-------------------------------------------------------------------------/
79
80	/ Keep track of which host controller drivers are loaded /
81	unsigned long usb_hcds_loaded;
82	EXPORT_SYMBOL_GPL(usb_hcds_loaded);
83
84	/ host controllers we manage /
85	DEFINE_IDR (usb_bus_idr);
86	EXPORT_SYMBOL_GPL (usb_bus_idr);
87
88	/ used when allocating bus numbers /
89	#define USB_MAXBUS 64
90
91	/ used when updating list of hcds /
92	DEFINE_MUTEX(usb_bus_idr_lock); / exported only for usbfs /
93	EXPORT_SYMBOL_GPL (usb_bus_idr_lock);
94
95	/ used for controlling access to virtual root hubs /
96	static DEFINE_SPINLOCK(hcd_root_hub_lock);
97
98	/ used when updating an endpoint's URB list /
99	static DEFINE_SPINLOCK(hcd_urb_list_lock);
100
101	/ used to protect against unlinking URBs after the device is gone /
102	static DEFINE_SPINLOCK(hcd_urb_unlink_lock);
103
104	/ wait queue for synchronous unlinks /
105	DECLARE_WAIT_QUEUE_HEAD(usb_kill_urb_queue);
106
107	/-------------------------------------------------------------------------/
108
109	/*
110	* Sharable chunks of root hub code.
111	*/
112
113	/-------------------------------------------------------------------------/
114	#define KERNEL_REL bin2bcd(LINUX_VERSION_MAJOR)
115	#define KERNEL_VER bin2bcd(LINUX_VERSION_PATCHLEVEL)
116
117	/ usb 3.1 root hub device descriptor /
118	static const u8 usb31_rh_dev_descriptor[`18`] = {
119	`0x12`, / __u8 bLength; /
120	USB_DT_DEVICE, / __u8 bDescriptorType; Device /
121	`0x10`, `0x03`, / __le16 bcdUSB; v3.1 /
122
123	`0x09`, / __u8 bDeviceClass; HUB_CLASSCODE /
124	`0x00`, / __u8 bDeviceSubClass; /
125	`0x03`, / __u8 bDeviceProtocol; USB 3 hub /
126	`0x09`, / __u8 bMaxPacketSize0; 2^9 = 512 Bytes /
127
128	`0x6b`, `0x1d`, / __le16 idVendor; Linux Foundation 0x1d6b /
129	`0x03`, `0x00`, / __le16 idProduct; device 0x0003 /
130	KERNEL_VER, KERNEL_REL, / __le16 bcdDevice /
131
132	`0x03`, / __u8 iManufacturer; /
133	`0x02`, / __u8 iProduct; /
134	`0x01`, / __u8 iSerialNumber; /
135	`0x01` / __u8 bNumConfigurations; /
136	};
137
138	/ usb 3.0 root hub device descriptor /
139	static const u8 usb3_rh_dev_descriptor[`18`] = {
140	`0x12`, / __u8 bLength; /
141	USB_DT_DEVICE, / __u8 bDescriptorType; Device /
142	`0x00`, `0x03`, / __le16 bcdUSB; v3.0 /
143
144	`0x09`, / __u8 bDeviceClass; HUB_CLASSCODE /
145	`0x00`, / __u8 bDeviceSubClass; /
146	`0x03`, / __u8 bDeviceProtocol; USB 3.0 hub /
147	`0x09`, / __u8 bMaxPacketSize0; 2^9 = 512 Bytes /
148
149	`0x6b`, `0x1d`, / __le16 idVendor; Linux Foundation 0x1d6b /
150	`0x03`, `0x00`, / __le16 idProduct; device 0x0003 /
151	KERNEL_VER, KERNEL_REL, / __le16 bcdDevice /
152
153	`0x03`, / __u8 iManufacturer; /
154	`0x02`, / __u8 iProduct; /
155	`0x01`, / __u8 iSerialNumber; /
156	`0x01` / __u8 bNumConfigurations; /
157	};
158
159	/ usb 2.0 root hub device descriptor /
160	static const u8 usb2_rh_dev_descriptor[`18`] = {
161	`0x12`, / __u8 bLength; /
162	USB_DT_DEVICE, / __u8 bDescriptorType; Device /
163	`0x00`, `0x02`, / __le16 bcdUSB; v2.0 /
164
165	`0x09`, / __u8 bDeviceClass; HUB_CLASSCODE /
166	`0x00`, / __u8 bDeviceSubClass; /
167	`0x00`, / __u8 bDeviceProtocol; [ usb 2.0 no TT ] /
168	`0x40`, / __u8 bMaxPacketSize0; 64 Bytes /
169
170	`0x6b`, `0x1d`, / __le16 idVendor; Linux Foundation 0x1d6b /
171	`0x02`, `0x00`, / __le16 idProduct; device 0x0002 /
172	KERNEL_VER, KERNEL_REL, / __le16 bcdDevice /
173
174	`0x03`, / __u8 iManufacturer; /
175	`0x02`, / __u8 iProduct; /
176	`0x01`, / __u8 iSerialNumber; /
177	`0x01` / __u8 bNumConfigurations; /
178	};
179
180	/ no usb 2.0 root hub "device qualifier" descriptor: one speed only /
181
182	/ usb 1.1 root hub device descriptor /
183	static const u8 usb11_rh_dev_descriptor[`18`] = {
184	`0x12`, / __u8 bLength; /
185	USB_DT_DEVICE, / __u8 bDescriptorType; Device /
186	`0x10`, `0x01`, / __le16 bcdUSB; v1.1 /
187
188	`0x09`, / __u8 bDeviceClass; HUB_CLASSCODE /
189	`0x00`, / __u8 bDeviceSubClass; /
190	`0x00`, / __u8 bDeviceProtocol; [ low/full speeds only ] /
191	`0x40`, / __u8 bMaxPacketSize0; 64 Bytes /
192
193	`0x6b`, `0x1d`, / __le16 idVendor; Linux Foundation 0x1d6b /
194	`0x01`, `0x00`, / __le16 idProduct; device 0x0001 /
195	KERNEL_VER, KERNEL_REL, / __le16 bcdDevice /
196
197	`0x03`, / __u8 iManufacturer; /
198	`0x02`, / __u8 iProduct; /
199	`0x01`, / __u8 iSerialNumber; /
200	`0x01` / __u8 bNumConfigurations; /
201	};
202
203
204	/-------------------------------------------------------------------------/
205
206	/ Configuration descriptors for our root hubs /
207
208	static const u8 fs_rh_config_descriptor[] = {
209
210	/ one configuration /
211	`0x09`, / __u8 bLength; /
212	USB_DT_CONFIG, / __u8 bDescriptorType; Configuration /
213	`0x19`, `0x00`, / __le16 wTotalLength; /
214	`0x01`, / __u8 bNumInterfaces; (1) /
215	`0x01`, / __u8 bConfigurationValue; /
216	`0x00`, / __u8 iConfiguration; /
217	`0xc0`, / __u8 bmAttributes;*
218	Bit 7: must be set,
219	6: Self-powered,
220	5: Remote wakeup,
221	4..0: resvd /*
222	`0x00`, / __u8 MaxPower; /
223
224	/ USB 1.1:*
225	* USB 2.0, single TT organization (mandatory):
226	* one interface, protocol 0
227	*
228	* USB 2.0, multiple TT organization (optional):
229	* two interfaces, protocols 1 (like single TT)
230	* and 2 (multiple TT mode) ... config is
231	* sometimes settable
232	* NOT IMPLEMENTED
233	*/
234
235	/ one interface /
236	`0x09`, / __u8 if_bLength; /
237	USB_DT_INTERFACE, / __u8 if_bDescriptorType; Interface /
238	`0x00`, / __u8 if_bInterfaceNumber; /
239	`0x00`, / __u8 if_bAlternateSetting; /
240	`0x01`, / __u8 if_bNumEndpoints; /
241	`0x09`, / __u8 if_bInterfaceClass; HUB_CLASSCODE /
242	`0x00`, / __u8 if_bInterfaceSubClass; /
243	`0x00`, / __u8 if_bInterfaceProtocol; [usb1.1 or single tt] /
244	`0x00`, / __u8 if_iInterface; /
245
246	/ one endpoint (status change endpoint) /
247	`0x07`, / __u8 ep_bLength; /
248	USB_DT_ENDPOINT, / __u8 ep_bDescriptorType; Endpoint /
249	`0x81`, / __u8 ep_bEndpointAddress; IN Endpoint 1 /
250	`0x03`, / __u8 ep_bmAttributes; Interrupt /
251	`0x02`, `0x00`, / __le16 ep_wMaxPacketSize; 1 + (MAX_ROOT_PORTS / 8) /
252	`0xff` / __u8 ep_bInterval; (255ms -- usb 2.0 spec) /
253	};
254
255	static const u8 hs_rh_config_descriptor[] = {
256
257	/ one configuration /
258	`0x09`, / __u8 bLength; /
259	USB_DT_CONFIG, / __u8 bDescriptorType; Configuration /
260	`0x19`, `0x00`, / __le16 wTotalLength; /
261	`0x01`, / __u8 bNumInterfaces; (1) /
262	`0x01`, / __u8 bConfigurationValue; /
263	`0x00`, / __u8 iConfiguration; /
264	`0xc0`, / __u8 bmAttributes;*
265	Bit 7: must be set,
266	6: Self-powered,
267	5: Remote wakeup,
268	4..0: resvd /*
269	`0x00`, / __u8 MaxPower; /
270
271	/ USB 1.1:*
272	* USB 2.0, single TT organization (mandatory):
273	* one interface, protocol 0
274	*
275	* USB 2.0, multiple TT organization (optional):
276	* two interfaces, protocols 1 (like single TT)
277	* and 2 (multiple TT mode) ... config is
278	* sometimes settable
279	* NOT IMPLEMENTED
280	*/
281
282	/ one interface /
283	`0x09`, / __u8 if_bLength; /
284	USB_DT_INTERFACE, / __u8 if_bDescriptorType; Interface /
285	`0x00`, / __u8 if_bInterfaceNumber; /
286	`0x00`, / __u8 if_bAlternateSetting; /
287	`0x01`, / __u8 if_bNumEndpoints; /
288	`0x09`, / __u8 if_bInterfaceClass; HUB_CLASSCODE /
289	`0x00`, / __u8 if_bInterfaceSubClass; /
290	`0x00`, / __u8 if_bInterfaceProtocol; [usb1.1 or single tt] /
291	`0x00`, / __u8 if_iInterface; /
292
293	/ one endpoint (status change endpoint) /
294	`0x07`, / __u8 ep_bLength; /
295	USB_DT_ENDPOINT, / __u8 ep_bDescriptorType; Endpoint /
296	`0x81`, / __u8 ep_bEndpointAddress; IN Endpoint 1 /
297	`0x03`, / __u8 ep_bmAttributes; Interrupt /
298	/ __le16 ep_wMaxPacketSize; 1 + (MAX_ROOT_PORTS / 8)*
299	* see hub.c:hub_configure() for details. */
300	(USB_MAXCHILDREN + `1` + `7`) / `8`, `0x00`,
301	`0x0c` / __u8 ep_bInterval; (256ms -- usb 2.0 spec) /
302	};
303
304	static const u8 ss_rh_config_descriptor[] = {
305	/ one configuration /
306	`0x09`, / __u8 bLength; /
307	USB_DT_CONFIG, / __u8 bDescriptorType; Configuration /
308	`0x1f`, `0x00`, / __le16 wTotalLength; /
309	`0x01`, / __u8 bNumInterfaces; (1) /
310	`0x01`, / __u8 bConfigurationValue; /
311	`0x00`, / __u8 iConfiguration; /
312	`0xc0`, / __u8 bmAttributes;*
313	Bit 7: must be set,
314	6: Self-powered,
315	5: Remote wakeup,
316	4..0: resvd /*
317	`0x00`, / __u8 MaxPower; /
318
319	/ one interface /
320	`0x09`, / __u8 if_bLength; /
321	USB_DT_INTERFACE, / __u8 if_bDescriptorType; Interface /
322	`0x00`, / __u8 if_bInterfaceNumber; /
323	`0x00`, / __u8 if_bAlternateSetting; /
324	`0x01`, / __u8 if_bNumEndpoints; /
325	`0x09`, / __u8 if_bInterfaceClass; HUB_CLASSCODE /
326	`0x00`, / __u8 if_bInterfaceSubClass; /
327	`0x00`, / __u8 if_bInterfaceProtocol; /
328	`0x00`, / __u8 if_iInterface; /
329
330	/ one endpoint (status change endpoint) /
331	`0x07`, / __u8 ep_bLength; /
332	USB_DT_ENDPOINT, / __u8 ep_bDescriptorType; Endpoint /
333	`0x81`, / __u8 ep_bEndpointAddress; IN Endpoint 1 /
334	`0x03`, / __u8 ep_bmAttributes; Interrupt /
335	/ __le16 ep_wMaxPacketSize; 1 + (MAX_ROOT_PORTS / 8)*
336	* see hub.c:hub_configure() for details. */
337	(USB_MAXCHILDREN + `1` + `7`) / `8`, `0x00`,
338	`0x0c`, / __u8 ep_bInterval; (256ms -- usb 2.0 spec) /
339
340	/ one SuperSpeed endpoint companion descriptor /
341	`0x06`, / __u8 ss_bLength /
342	USB_DT_SS_ENDPOINT_COMP, / __u8 ss_bDescriptorType; SuperSpeed EP /
343	/ Companion /
344	`0x00`, / __u8 ss_bMaxBurst; allows 1 TX between ACKs /
345	`0x00`, / __u8 ss_bmAttributes; 1 packet per service interval /
346	`0x02`, `0x00` / __le16 ss_wBytesPerInterval; 15 bits for max 15 ports /
347	};
348
349	/ authorized_default behaviour:*
350	* -1 is authorized for all devices (leftover from wireless USB)
351	* 0 is unauthorized for all devices
352	* 1 is authorized for all devices
353	* 2 is authorized for internal devices
354	*/
355	#define USB_AUTHORIZE_WIRED -1
356	#define USB_AUTHORIZE_NONE 0
357	#define USB_AUTHORIZE_ALL 1
358	#define USB_AUTHORIZE_INTERNAL 2
359
360	static int authorized_default = CONFIG_USB_DEFAULT_AUTHORIZATION_MODE;
361	module_param(authorized_default, int, S_IRUGO\|S_IWUSR);
362	MODULE_PARM_DESC(authorized_default,
363	"Default USB device authorization: 0 is not authorized, 1 is authorized (default), 2 is authorized for internal devices, -1 is authorized (same as 1)");
364	/-------------------------------------------------------------------------/
365
366	/**
367	* ascii2desc() - Helper routine for producing UTF-16LE string descriptors
368	* @s: Null-terminated ASCII (actually ISO-8859-1) string
369	* @buf: Buffer for USB string descriptor (header + UTF-16LE)
370	* @len: Length (in bytes; may be odd) of descriptor buffer.
371	*
372	* Return: The number of bytes filled in: 2 + 2*strlen(s) or @len,
373	* whichever is less.
374	*
375	* Note:
376	* USB String descriptors can contain at most 126 characters; input
377	* strings longer than that are truncated.
378	*/
379	static unsigned
380	ascii2desc(char const s, u8 buf, unsigned len)
381	{
382	unsigned n, t = `2` + `2`*strlen(s);
383
384	if (t > `254`)
385	t = `254`; / Longest possible UTF string descriptor /
386	if (len > t)
387	len = t;
388
389	t += USB_DT_STRING << `8`; / Now t is first 16 bits to store /
390
391	n = len;
392	while (n--) {
393	*buf++ = t;
394	if (!n--)
395	break;
396	*buf++ = t >> `8`;
397	t = (unsigned char)*s++;
398	}
399	return len;
400	}
401
402	/**
403	* rh_string() - provides string descriptors for root hub
404	* @id: the string ID number (0: langids, 1: serial #, 2: product, 3: vendor)
405	* @hcd: the host controller for this root hub
406	* @data: buffer for output packet
407	* @len: length of the provided buffer
408	*
409	* Produces either a manufacturer, product or serial number string for the
410	* virtual root hub device.
411	*
412	* Return: The number of bytes filled in: the length of the descriptor or
413	* of the provided buffer, whichever is less.
414	*/
415	static unsigned
416	rh_string(int id, struct usb_hcd const hcd, u8 data, unsigned len)
417	{
418	char buf[`160`];
419	char const *s;
420	static char const langids[`4`] = {`4`, USB_DT_STRING, `0x09`, `0x04`};
421
422	/ language ids /
423	switch (id) {
424	case `0`:
425	/ Array of LANGID codes (0x0409 is MSFT-speak for "en-us") /
426	/ See http://www.usb.org/developers/docs/USB_LANGIDs.pdf /
427	if (len > `4`)
428	len = `4`;
429	memcpy(to: data, from: langids, len);
430	return len;
431	case `1`:
432	/ Serial number /
433	s = hcd->self.bus_name;
434	break;
435	case `2`:
436	/ Product name /
437	s = hcd->product_desc;
438	break;
439	case `3`:
440	/ Manufacturer /
441	snprintf (buf, size: sizeof buf, fmt: "%s %s %s", init_utsname()->sysname,
442	init_utsname()->release, hcd->driver->description);
443	s = buf;
444	break;
445	default:
446	/ Can't happen; caller guarantees it /
447	return `0`;
448	}
449
450	return ascii2desc(s, buf: data, len);
451	}
452
453
454	/ Root hub control transfers execute synchronously /
455	static int rh_call_control (struct usb_hcd hcd, struct* urb *urb)
456	{
457	struct usb_ctrlrequest *cmd;
458	u16 typeReq, wValue, wIndex, wLength;
459	u8 *ubuf = urb->transfer_buffer;
460	unsigned len = `0`;
461	int status;
462	u8 patch_wakeup = `0`;
463	u8 patch_protocol = `0`;
464	u16 tbuf_size;
465	u8 *tbuf = NULL;
466	const u8 *bufp;
467
468	might_sleep();
469
470	spin_lock_irq(lock: &hcd_root_hub_lock);
471	status = usb_hcd_link_urb_to_ep(hcd, urb);
472	spin_unlock_irq(lock: &hcd_root_hub_lock);
473	if (status)
474	return status;
475	urb->hcpriv = hcd; / Indicate it's queued /
476
477	cmd = (struct usb_ctrlrequest *) urb->setup_packet;
478	typeReq = (cmd->bRequestType << `8`) \| cmd->bRequest;
479	wValue = le16_to_cpu (cmd->wValue);
480	wIndex = le16_to_cpu (cmd->wIndex);
481	wLength = le16_to_cpu (cmd->wLength);
482
483	if (wLength > urb->transfer_buffer_length)
484	goto error;
485
486	/*
487	* tbuf should be at least as big as the
488	* USB hub descriptor.
489	*/
490	tbuf_size = max_t(u16, sizeof(struct usb_hub_descriptor), wLength);
491	tbuf = kzalloc(tbuf_size, GFP_KERNEL);
492	if (!tbuf) {
493	status = -ENOMEM;
494	goto err_alloc;
495	}
496
497	bufp = tbuf;
498
499
500	urb->actual_length = `0`;
501	switch (typeReq) {
502
503	/ DEVICE REQUESTS /
504
505	/ The root hub's remote wakeup enable bit is implemented using*
506	* driver model wakeup flags. If this system supports wakeup
507	* through USB, userspace may change the default "allow wakeup"
508	* policy through sysfs or these calls.
509	*
510	* Most root hubs support wakeup from downstream devices, for
511	* runtime power management (disabling USB clocks and reducing
512	* VBUS power usage). However, not all of them do so; silicon,
513	* board, and BIOS bugs here are not uncommon, so these can't
514	* be treated quite like external hubs.
515	*
516	* Likewise, not all root hubs will pass wakeup events upstream,
517	* to wake up the whole system. So don't assume root hub and
518	* controller capabilities are identical.
519	*/
520
521	case DeviceRequest \| USB_REQ_GET_STATUS:
522	tbuf[`0`] = (device_may_wakeup(dev: &hcd->self.root_hub->dev)
523	<< USB_DEVICE_REMOTE_WAKEUP)
524	\| (`1` << USB_DEVICE_SELF_POWERED);
525	tbuf[`1`] = `0`;
526	len = `2`;
527	break;
528	case DeviceOutRequest \| USB_REQ_CLEAR_FEATURE:
529	if (wValue == USB_DEVICE_REMOTE_WAKEUP)
530	device_set_wakeup_enable(dev: &hcd->self.root_hub->dev, enable: `0`);
531	else
532	goto error;
533	break;
534	case DeviceOutRequest \| USB_REQ_SET_FEATURE:
535	if (device_can_wakeup(dev: &hcd->self.root_hub->dev)
536	&& wValue == USB_DEVICE_REMOTE_WAKEUP)
537	device_set_wakeup_enable(dev: &hcd->self.root_hub->dev, enable: `1`);
538	else
539	goto error;
540	break;
541	case DeviceRequest \| USB_REQ_GET_CONFIGURATION:
542	tbuf[`0`] = `1`;
543	len = `1`;
544	fallthrough;
545	case DeviceOutRequest \| USB_REQ_SET_CONFIGURATION:
546	break;
547	case DeviceRequest \| USB_REQ_GET_DESCRIPTOR:
548	switch (wValue & `0xff00`) {
549	case USB_DT_DEVICE << `8`:
550	switch (hcd->speed) {
551	case HCD_USB32:
552	case HCD_USB31:
553	bufp = usb31_rh_dev_descriptor;
554	break;
555	case HCD_USB3:
556	bufp = usb3_rh_dev_descriptor;
557	break;
558	case HCD_USB2:
559	bufp = usb2_rh_dev_descriptor;
560	break;
561	case HCD_USB11:
562	bufp = usb11_rh_dev_descriptor;
563	break;
564	default:
565	goto error;
566	}
567	len = `18`;
568	if (hcd->has_tt)
569	patch_protocol = `1`;
570	break;
571	case USB_DT_CONFIG << `8`:
572	switch (hcd->speed) {
573	case HCD_USB32:
574	case HCD_USB31:
575	case HCD_USB3:
576	bufp = ss_rh_config_descriptor;
577	len = sizeof ss_rh_config_descriptor;
578	break;
579	case HCD_USB2:
580	bufp = hs_rh_config_descriptor;
581	len = sizeof hs_rh_config_descriptor;
582	break;
583	case HCD_USB11:
584	bufp = fs_rh_config_descriptor;
585	len = sizeof fs_rh_config_descriptor;
586	break;
587	default:
588	goto error;
589	}
590	if (device_can_wakeup(dev: &hcd->self.root_hub->dev))
591	patch_wakeup = `1`;
592	break;
593	case USB_DT_STRING << `8`:
594	if ((wValue & `0xff`) < `4`)
595	urb->actual_length = rh_string(id: wValue & `0xff`,
596	hcd, data: ubuf, len: wLength);
597	else / unsupported IDs --> "protocol stall" /
598	goto error;
599	break;
600	case USB_DT_BOS << `8`:
601	goto nongeneric;
602	default:
603	goto error;
604	}
605	break;
606	case DeviceRequest \| USB_REQ_GET_INTERFACE:
607	tbuf[`0`] = `0`;
608	len = `1`;
609	fallthrough;
610	case DeviceOutRequest \| USB_REQ_SET_INTERFACE:
611	break;
612	case DeviceOutRequest \| USB_REQ_SET_ADDRESS:
613	/ wValue == urb->dev->devaddr /
614	dev_dbg (hcd->self.controller, "root hub device address %d\n",
615	wValue);
616	break;
617
618	/ INTERFACE REQUESTS (no defined feature/status flags) /
619
620	/ ENDPOINT REQUESTS /
621
622	case EndpointRequest \| USB_REQ_GET_STATUS:
623	/ ENDPOINT_HALT flag /
624	tbuf[`0`] = `0`;
625	tbuf[`1`] = `0`;
626	len = `2`;
627	fallthrough;
628	case EndpointOutRequest \| USB_REQ_CLEAR_FEATURE:
629	case EndpointOutRequest \| USB_REQ_SET_FEATURE:
630	dev_dbg (hcd->self.controller, "no endpoint features yet\n");
631	break;
632
633	/ CLASS REQUESTS (and errors) /
634
635	default:
636	nongeneric:
637	/ non-generic request /
638	switch (typeReq) {
639	case GetHubStatus:
640	len = `4`;
641	break;
642	case GetPortStatus:
643	if (wValue == HUB_PORT_STATUS)
644	len = `4`;
645	else
646	/ other port status types return 8 bytes /
647	len = `8`;
648	break;
649	case GetHubDescriptor:
650	len = sizeof (struct usb_hub_descriptor);
651	break;
652	case DeviceRequest \| USB_REQ_GET_DESCRIPTOR:
653	/ len is returned by hub_control /
654	break;
655	}
656	status = hcd->driver->hub_control (hcd,
657	typeReq, wValue, wIndex,
658	tbuf, wLength);
659
660	if (typeReq == GetHubDescriptor)
661	usb_hub_adjust_deviceremovable(hdev: hcd->self.root_hub,
662	desc: (struct usb_hub_descriptor *)tbuf);
663	break;
664	error:
665	/ "protocol stall" on error /
666	status = -EPIPE;
667	}
668
669	if (status < `0`) {
670	len = `0`;
671	if (status != -EPIPE) {
672	dev_dbg (hcd->self.controller,
673	"CTRL: TypeReq=0x%x val=0x%x "
674	"idx=0x%x len=%d ==> %d\n",
675	typeReq, wValue, wIndex,
676	wLength, status);
677	}
678	} else if (status > `0`) {
679	/ hub_control may return the length of data copied. /
680	len = status;
681	status = `0`;
682	}
683	if (len) {
684	if (urb->transfer_buffer_length < len)
685	len = urb->transfer_buffer_length;
686	urb->actual_length = len;
687	/ always USB_DIR_IN, toward host /
688	memcpy (to: ubuf, from: bufp, len);
689
690	/ report whether RH hardware supports remote wakeup /
691	if (patch_wakeup &&
692	len > offsetof (struct usb_config_descriptor,
693	bmAttributes))
694	((struct usb_config_descriptor *)ubuf)->bmAttributes
695	\|= USB_CONFIG_ATT_WAKEUP;
696
697	/ report whether RH hardware has an integrated TT /
698	if (patch_protocol &&
699	len > offsetof(struct usb_device_descriptor,
700	bDeviceProtocol))
701	((struct usb_device_descriptor *) ubuf)->
702	bDeviceProtocol = USB_HUB_PR_HS_SINGLE_TT;
703	}
704
705	kfree(objp: tbuf);
706	err_alloc:
707
708	/ any errors get returned through the urb completion /
709	spin_lock_irq(lock: &hcd_root_hub_lock);
710	usb_hcd_unlink_urb_from_ep(hcd, urb);
711	usb_hcd_giveback_urb(hcd, urb, status);
712	spin_unlock_irq(lock: &hcd_root_hub_lock);
713	return `0`;
714	}
715
716	/-------------------------------------------------------------------------/
717
718	/*
719	* Root Hub interrupt transfers are polled using a timer if the
720	* driver requests it; otherwise the driver is responsible for
721	* calling usb_hcd_poll_rh_status() when an event occurs.
722	*
723	* Completion handler may not sleep. See usb_hcd_giveback_urb() for details.
724	*/
725	void usb_hcd_poll_rh_status(struct usb_hcd *hcd)
726	{
727	struct urb *urb;
728	int length;
729	int status;
730	unsigned long flags;
731	char buffer[`6`]; / Any root hubs with > 31 ports? /
732
733	if (unlikely(!hcd->rh_pollable))
734	return;
735	if (!hcd->uses_new_polling && !hcd->status_urb)
736	return;
737
738	length = hcd->driver->hub_status_data(hcd, buffer);
739	if (length > `0`) {
740
741	/ try to complete the status urb /
742	spin_lock_irqsave(&hcd_root_hub_lock, flags);
743	urb = hcd->status_urb;
744	if (urb) {
745	clear_bit(HCD_FLAG_POLL_PENDING, addr: &hcd->flags);
746	hcd->status_urb = NULL;
747	if (urb->transfer_buffer_length >= length) {
748	status = `0`;
749	} else {
750	status = -EOVERFLOW;
751	length = urb->transfer_buffer_length;
752	}
753	urb->actual_length = length;
754	memcpy(to: urb->transfer_buffer, from: buffer, len: length);
755
756	usb_hcd_unlink_urb_from_ep(hcd, urb);
757	usb_hcd_giveback_urb(hcd, urb, status);
758	} else {
759	length = `0`;
760	set_bit(HCD_FLAG_POLL_PENDING, addr: &hcd->flags);
761	}
762	spin_unlock_irqrestore(lock: &hcd_root_hub_lock, flags);
763	}
764
765	/ The USB 2.0 spec says 256 ms. This is close enough and won't*
766	* exceed that limit if HZ is 100. The math is more clunky than
767	* maybe expected, this is to make sure that all timers for USB devices
768	* fire at the same time to give the CPU a break in between */
769	if (hcd->uses_new_polling ? HCD_POLL_RH(hcd) :
770	(length == `0` && hcd->status_urb != NULL))
771	mod_timer (timer: &hcd->rh_timer, expires: (jiffies/(HZ/`4`) + `1`) * (HZ/`4`));
772	}
773	EXPORT_SYMBOL_GPL(usb_hcd_poll_rh_status);
774
775	/ timer callback /
776	static void rh_timer_func (struct timer_list *t)
777	{
778	struct usb_hcd *_hcd = timer_container_of(_hcd, t, rh_timer);
779
780	usb_hcd_poll_rh_status(_hcd);
781	}
782
783	/-------------------------------------------------------------------------/
784
785	static int rh_queue_status (struct usb_hcd hcd, struct* urb *urb)
786	{
787	int retval;
788	unsigned long flags;
789	unsigned len = `1` + (urb->dev->maxchild / `8`);
790
791	spin_lock_irqsave (&hcd_root_hub_lock, flags);
792	if (hcd->status_urb \|\| urb->transfer_buffer_length < len) {
793	dev_dbg (hcd->self.controller, "not queuing rh status urb\n");
794	retval = -EINVAL;
795	goto done;
796	}
797
798	retval = usb_hcd_link_urb_to_ep(hcd, urb);
799	if (retval)
800	goto done;
801
802	hcd->status_urb = urb;
803	urb->hcpriv = hcd; / indicate it's queued /
804	if (!hcd->uses_new_polling)
805	mod_timer(timer: &hcd->rh_timer, expires: (jiffies/(HZ/`4`) + `1`) * (HZ/`4`));
806
807	/ If a status change has already occurred, report it ASAP /
808	else if (HCD_POLL_PENDING(hcd))
809	mod_timer(timer: &hcd->rh_timer, expires: jiffies);
810	retval = `0`;
811	done:
812	spin_unlock_irqrestore (lock: &hcd_root_hub_lock, flags);
813	return retval;
814	}
815
816	static int rh_urb_enqueue (struct usb_hcd hcd, struct* urb *urb)
817	{
818	if (usb_endpoint_xfer_int(epd: &urb->ep->desc))
819	return rh_queue_status (hcd, urb);
820	if (usb_endpoint_xfer_control(epd: &urb->ep->desc))
821	return rh_call_control (hcd, urb);
822	return -EINVAL;
823	}
824
825	/-------------------------------------------------------------------------/
826
827	/ Unlinks of root-hub control URBs are legal, but they don't do anything*
828	* since these URBs always execute synchronously.
829	*/
830	static int usb_rh_urb_dequeue(struct usb_hcd hcd, struct* urb urb, int* status)
831	{
832	unsigned long flags;
833	int rc;
834
835	spin_lock_irqsave(&hcd_root_hub_lock, flags);
836	rc = usb_hcd_check_unlink_urb(hcd, urb, status);
837	if (rc)
838	goto done;
839
840	if (usb_endpoint_num(epd: &urb->ep->desc) == `0`) { / Control URB /
841	; / Do nothing /
842
843	} else { / Status URB /
844	if (!hcd->uses_new_polling)
845	timer_delete(timer: &hcd->rh_timer);
846	if (urb == hcd->status_urb) {
847	hcd->status_urb = NULL;
848	usb_hcd_unlink_urb_from_ep(hcd, urb);
849	usb_hcd_giveback_urb(hcd, urb, status);
850	}
851	}
852	done:
853	spin_unlock_irqrestore(lock: &hcd_root_hub_lock, flags);
854	return rc;
855	}
856
857
858	/-------------------------------------------------------------------------/
859
860	/**
861	* usb_bus_init - shared initialization code
862	* @bus: the bus structure being initialized
863	*
864	* This code is used to initialize a usb_bus structure, memory for which is
865	* separately managed.
866	*/
867	static void usb_bus_init (struct usb_bus *bus)
868	{
869	memset(s: &bus->devmap, c: `0`, n: sizeof(bus->devmap));
870
871	bus->devnum_next = `1`;
872
873	bus->root_hub = NULL;
874	bus->busnum = -`1`;
875	bus->bandwidth_allocated = `0`;
876	bus->bandwidth_int_reqs = `0`;
877	bus->bandwidth_isoc_reqs = `0`;
878	mutex_init(&bus->devnum_next_mutex);
879	}
880
881	/-------------------------------------------------------------------------/
882
883	/**
884	* usb_register_bus - registers the USB host controller with the usb core
885	* @bus: pointer to the bus to register
886	*
887	* Context: task context, might sleep.
888	*
889	* Assigns a bus number, and links the controller into usbcore data
890	* structures so that it can be seen by scanning the bus list.
891	*
892	* Return: 0 if successful. A negative error code otherwise.
893	*/
894	static int usb_register_bus(struct usb_bus *bus)
895	{
896	int result = -E2BIG;
897	int busnum;
898
899	mutex_lock(lock: &usb_bus_idr_lock);
900	busnum = idr_alloc(&usb_bus_idr, ptr: bus, start: `1`, USB_MAXBUS, GFP_KERNEL);
901	if (busnum < `0`) {
902	pr_err("%s: failed to get bus number\n", usbcore_name);
903	goto error_find_busnum;
904	}
905	bus->busnum = busnum;
906	mutex_unlock(lock: &usb_bus_idr_lock);
907
908	usb_notify_add_bus(ubus: bus);
909
910	dev_info (bus->controller, "new USB bus registered, assigned bus "
911	"number %d\n", bus->busnum);
912	return `0`;
913
914	error_find_busnum:
915	mutex_unlock(lock: &usb_bus_idr_lock);
916	return result;
917	}
918
919	/**
920	* usb_deregister_bus - deregisters the USB host controller
921	* @bus: pointer to the bus to deregister
922	*
923	* Context: task context, might sleep.
924	*
925	* Recycles the bus number, and unlinks the controller from usbcore data
926	* structures so that it won't be seen by scanning the bus list.
927	*/
928	static void usb_deregister_bus (struct usb_bus *bus)
929	{
930	dev_info (bus->controller, "USB bus %d deregistered\n", bus->busnum);
931
932	/*
933	* NOTE: make sure that all the devices are removed by the
934	* controller code, as well as having it call this when cleaning
935	* itself up
936	*/
937	mutex_lock(lock: &usb_bus_idr_lock);
938	idr_remove(&usb_bus_idr, id: bus->busnum);
939	mutex_unlock(lock: &usb_bus_idr_lock);
940
941	usb_notify_remove_bus(ubus: bus);
942	}
943
944	/**
945	* register_root_hub - called by usb_add_hcd() to register a root hub
946	* @hcd: host controller for this root hub
947	*
948	* This function registers the root hub with the USB subsystem. It sets up
949	* the device properly in the device tree and then calls usb_new_device()
950	* to register the usb device. It also assigns the root hub's USB address
951	* (always 1).
952	*
953	* Return: 0 if successful. A negative error code otherwise.
954	*/
955	static int register_root_hub(struct usb_hcd *hcd)
956	{
957	struct device *parent_dev = hcd->self.controller;
958	struct usb_device *usb_dev = hcd->self.root_hub;
959	struct usb_device_descriptor *descr;
960	const int devnum = `1`;
961	int retval;
962
963	usb_dev->devnum = devnum;
964	usb_dev->bus->devnum_next = devnum + `1`;
965	set_bit(nr: devnum, addr: usb_dev->bus->devmap);
966	usb_set_device_state(udev: usb_dev, new_state: USB_STATE_ADDRESS);
967
968	mutex_lock(lock: &usb_bus_idr_lock);
969
970	usb_dev->ep0.desc.wMaxPacketSize = cpu_to_le16(`64`);
971	descr = usb_get_device_descriptor(udev: usb_dev);
972	if (IS_ERR(ptr: descr)) {
973	retval = PTR_ERR(ptr: descr);
974	mutex_unlock(lock: &usb_bus_idr_lock);
975	dev_dbg (parent_dev, "can't read %s device descriptor %d\n",
976	dev_name(&usb_dev->dev), retval);
977	return retval;
978	}
979	usb_dev->descriptor = *descr;
980	kfree(objp: descr);
981
982	if (le16_to_cpu(usb_dev->descriptor.bcdUSB) >= `0x0201`) {
983	retval = usb_get_bos_descriptor(dev: usb_dev);
984	if (!retval) {
985	usb_dev->lpm_capable = usb_device_supports_lpm(udev: usb_dev);
986	} else if (usb_dev->speed >= USB_SPEED_SUPER) {
987	mutex_unlock(lock: &usb_bus_idr_lock);
988	dev_dbg(parent_dev, "can't read %s bos descriptor %d\n",
989	dev_name(&usb_dev->dev), retval);
990	return retval;
991	}
992	}
993
994	retval = usb_new_device (dev: usb_dev);
995	if (retval) {
996	dev_err (parent_dev, "can't register root hub for %s, %d\n",
997	dev_name(&usb_dev->dev), retval);
998	} else {
999	spin_lock_irq (lock: &hcd_root_hub_lock);
1000	hcd->rh_registered = `1`;
1001	spin_unlock_irq (lock: &hcd_root_hub_lock);
1002
1003	/ Did the HC die before the root hub was registered? /
1004	if (HCD_DEAD(hcd))
1005	usb_hc_died (hcd); / This time clean up /
1006	}
1007	mutex_unlock(lock: &usb_bus_idr_lock);
1008
1009	return retval;
1010	}
1011
1012	/*
1013	* usb_hcd_start_port_resume - a root-hub port is sending a resume signal
1014	* @bus: the bus which the root hub belongs to
1015	* @portnum: the port which is being resumed
1016	*
1017	* HCDs should call this function when they know that a resume signal is
1018	* being sent to a root-hub port. The root hub will be prevented from
1019	* going into autosuspend until usb_hcd_end_port_resume() is called.
1020	*
1021	* The bus's private lock must be held by the caller.
1022	*/
1023	void usb_hcd_start_port_resume(struct usb_bus bus, int* portnum)
1024	{
1025	unsigned bit = `1` << portnum;
1026
1027	if (!(bus->resuming_ports & bit)) {
1028	bus->resuming_ports \|= bit;
1029	pm_runtime_get_noresume(dev: &bus->root_hub->dev);
1030	}
1031	}
1032	EXPORT_SYMBOL_GPL(usb_hcd_start_port_resume);
1033
1034	/*
1035	* usb_hcd_end_port_resume - a root-hub port has stopped sending a resume signal
1036	* @bus: the bus which the root hub belongs to
1037	* @portnum: the port which is being resumed
1038	*
1039	* HCDs should call this function when they know that a resume signal has
1040	* stopped being sent to a root-hub port. The root hub will be allowed to
1041	* autosuspend again.
1042	*
1043	* The bus's private lock must be held by the caller.
1044	*/
1045	void usb_hcd_end_port_resume(struct usb_bus bus, int* portnum)
1046	{
1047	unsigned bit = `1` << portnum;
1048
1049	if (bus->resuming_ports & bit) {
1050	bus->resuming_ports &= ~bit;
1051	pm_runtime_put_noidle(dev: &bus->root_hub->dev);
1052	}
1053	}
1054	EXPORT_SYMBOL_GPL(usb_hcd_end_port_resume);
1055
1056	/-------------------------------------------------------------------------/
1057
1058	/**
1059	* usb_calc_bus_time - approximate periodic transaction time in nanoseconds
1060	* @speed: from dev->speed; USB_SPEED_{LOW,FULL,HIGH}
1061	* @is_input: true iff the transaction sends data to the host
1062	* @isoc: true for isochronous transactions, false for interrupt ones
1063	* @bytecount: how many bytes in the transaction.
1064	*
1065	* Return: Approximate bus time in nanoseconds for a periodic transaction.
1066	*
1067	* Note:
1068	* See USB 2.0 spec section 5.11.3; only periodic transfers need to be
1069	* scheduled in software, this function is only used for such scheduling.
1070	*/
1071	long usb_calc_bus_time (int speed, int is_input, int isoc, int bytecount)
1072	{
1073	unsigned long tmp;
1074
1075	switch (speed) {
1076	case USB_SPEED_LOW: / INTR only /
1077	if (is_input) {
1078	tmp = (`67667L` * (`31L` + `10L` * BitTime (bytecount))) / `1000L`;
1079	return `64060L` + (`2` * BW_HUB_LS_SETUP) + BW_HOST_DELAY + tmp;
1080	} else {
1081	tmp = (`66700L` * (`31L` + `10L` * BitTime (bytecount))) / `1000L`;
1082	return `64107L` + (`2` * BW_HUB_LS_SETUP) + BW_HOST_DELAY + tmp;
1083	}
1084	case USB_SPEED_FULL: / ISOC or INTR /
1085	if (isoc) {
1086	tmp = (`8354L` * (`31L` + `10L` * BitTime (bytecount))) / `1000L`;
1087	return ((is_input) ? `7268L` : `6265L`) + BW_HOST_DELAY + tmp;
1088	} else {
1089	tmp = (`8354L` * (`31L` + `10L` * BitTime (bytecount))) / `1000L`;
1090	return `9107L` + BW_HOST_DELAY + tmp;
1091	}
1092	case USB_SPEED_HIGH: / ISOC or INTR /
1093	/ FIXME adjust for input vs output /
1094	if (isoc)
1095	tmp = HS_NSECS_ISO (bytecount);
1096	else
1097	tmp = HS_NSECS (bytecount);
1098	return tmp;
1099	default:
1100	pr_debug ("%s: bogus device speed!\n", usbcore_name);
1101	return -`1`;
1102	}
1103	}
1104	EXPORT_SYMBOL_GPL(usb_calc_bus_time);
1105
1106
1107	/-------------------------------------------------------------------------/
1108
1109	/*
1110	* Generic HC operations.
1111	*/
1112
1113	/-------------------------------------------------------------------------/
1114
1115	/**
1116	* usb_hcd_link_urb_to_ep - add an URB to its endpoint queue
1117	* @hcd: host controller to which @urb was submitted
1118	* @urb: URB being submitted
1119	*
1120	* Host controller drivers should call this routine in their enqueue()
1121	* method. The HCD's private spinlock must be held and interrupts must
1122	* be disabled. The actions carried out here are required for URB
1123	* submission, as well as for endpoint shutdown and for usb_kill_urb.
1124	*
1125	* Return: 0 for no error, otherwise a negative error code (in which case
1126	* the enqueue() method must fail). If no error occurs but enqueue() fails
1127	* anyway, it must call usb_hcd_unlink_urb_from_ep() before releasing
1128	* the private spinlock and returning.
1129	*/
1130	int usb_hcd_link_urb_to_ep(struct usb_hcd hcd, struct* urb *urb)
1131	{
1132	int rc = `0`;
1133
1134	spin_lock(lock: &hcd_urb_list_lock);
1135
1136	/ Check that the URB isn't being killed /
1137	if (unlikely(atomic_read(&urb->reject))) {
1138	rc = -EPERM;
1139	goto done;
1140	}
1141
1142	if (unlikely(!urb->ep->enabled)) {
1143	rc = -ENOENT;
1144	goto done;
1145	}
1146
1147	if (unlikely(!urb->dev->can_submit)) {
1148	rc = -EHOSTUNREACH;
1149	goto done;
1150	}
1151
1152	/*
1153	* Check the host controller's state and add the URB to the
1154	* endpoint's queue.
1155	*/
1156	if (HCD_RH_RUNNING(hcd)) {
1157	urb->unlinked = `0`;
1158	list_add_tail(new: &urb->urb_list, head: &urb->ep->urb_list);
1159	} else {
1160	rc = -ESHUTDOWN;
1161	goto done;
1162	}
1163	done:
1164	spin_unlock(lock: &hcd_urb_list_lock);
1165	return rc;
1166	}
1167	EXPORT_SYMBOL_GPL(usb_hcd_link_urb_to_ep);
1168
1169	/**
1170	* usb_hcd_check_unlink_urb - check whether an URB may be unlinked
1171	* @hcd: host controller to which @urb was submitted
1172	* @urb: URB being checked for unlinkability
1173	* @status: error code to store in @urb if the unlink succeeds
1174	*
1175	* Host controller drivers should call this routine in their dequeue()
1176	* method. The HCD's private spinlock must be held and interrupts must
1177	* be disabled. The actions carried out here are required for making
1178	* sure than an unlink is valid.
1179	*
1180	* Return: 0 for no error, otherwise a negative error code (in which case
1181	* the dequeue() method must fail). The possible error codes are:
1182	*
1183	* -EIDRM: @urb was not submitted or has already completed.
1184	* The completion function may not have been called yet.
1185	*
1186	* -EBUSY: @urb has already been unlinked.
1187	*/
1188	int usb_hcd_check_unlink_urb(struct usb_hcd hcd, struct* urb *urb,
1189	int status)
1190	{
1191	struct list_head *tmp;
1192
1193	/ insist the urb is still queued /
1194	list_for_each(tmp, &urb->ep->urb_list) {
1195	if (tmp == &urb->urb_list)
1196	break;
1197	}
1198	if (tmp != &urb->urb_list)
1199	return -EIDRM;
1200
1201	/ Any status except -EINPROGRESS means something already started to*
1202	* unlink this URB from the hardware. So there's no more work to do.
1203	*/
1204	if (urb->unlinked)
1205	return -EBUSY;
1206	urb->unlinked = status;
1207	return `0`;
1208	}
1209	EXPORT_SYMBOL_GPL(usb_hcd_check_unlink_urb);
1210
1211	/**
1212	* usb_hcd_unlink_urb_from_ep - remove an URB from its endpoint queue
1213	* @hcd: host controller to which @urb was submitted
1214	* @urb: URB being unlinked
1215	*
1216	* Host controller drivers should call this routine before calling
1217	* usb_hcd_giveback_urb(). The HCD's private spinlock must be held and
1218	* interrupts must be disabled. The actions carried out here are required
1219	* for URB completion.
1220	*/
1221	void usb_hcd_unlink_urb_from_ep(struct usb_hcd hcd, struct* urb *urb)
1222	{
1223	/ clear all state linking urb to this dev (and hcd) /
1224	spin_lock(lock: &hcd_urb_list_lock);
1225	list_del_init(entry: &urb->urb_list);
1226	spin_unlock(lock: &hcd_urb_list_lock);
1227	}
1228	EXPORT_SYMBOL_GPL(usb_hcd_unlink_urb_from_ep);
1229
1230	/*
1231	* Some usb host controllers can only perform dma using a small SRAM area,
1232	* or have restrictions on addressable DRAM.
1233	* The usb core itself is however optimized for host controllers that can dma
1234	* using regular system memory - like pci devices doing bus mastering.
1235	*
1236	* To support host controllers with limited dma capabilities we provide dma
1237	* bounce buffers. This feature can be enabled by initializing
1238	* hcd->localmem_pool using usb_hcd_setup_local_mem().
1239	*
1240	* The initialized hcd->localmem_pool then tells the usb code to allocate all
1241	* data for dma using the genalloc API.
1242	*
1243	* So, to summarize...
1244	*
1245	* - We need "local" memory, canonical example being
1246	* a small SRAM on a discrete controller being the
1247	* only memory that the controller can read ...
1248	* (a) "normal" kernel memory is no good, and
1249	* (b) there's not enough to share
1250	*
1251	* - So we use that, even though the primary requirement
1252	* is that the memory be "local" (hence addressable
1253	* by that device), not "coherent".
1254	*
1255	*/
1256
1257	static int hcd_alloc_coherent(struct usb_bus *bus,
1258	gfp_t mem_flags, dma_addr_t *dma_handle,
1259	void **vaddr_handle, size_t size,
1260	enum dma_data_direction dir)
1261	{
1262	unsigned char *vaddr;
1263
1264	if (*vaddr_handle == NULL) {
1265	WARN_ON_ONCE(`1`);
1266	return -EFAULT;
1267	}
1268
1269	vaddr = hcd_buffer_alloc(bus, size: size + sizeof(unsigned long),
1270	mem_flags, dma: dma_handle);
1271	if (!vaddr)
1272	return -ENOMEM;
1273
1274	/*
1275	* Store the virtual address of the buffer at the end
1276	* of the allocated dma buffer. The size of the buffer
1277	* may be uneven so use unaligned functions instead
1278	* of just rounding up. It makes sense to optimize for
1279	* memory footprint over access speed since the amount
1280	* of memory available for dma may be limited.
1281	*/
1282	put_unaligned((unsigned long)*vaddr_handle,
1283	(unsigned long *)(vaddr + size));
1284
1285	if (dir == DMA_TO_DEVICE)
1286	memcpy(to: vaddr, from: *vaddr_handle, len: size);
1287
1288	*vaddr_handle = vaddr;
1289	return `0`;
1290	}
1291
1292	static void hcd_free_coherent(struct usb_bus bus, dma_addr_t dma_handle,
1293	void **vaddr_handle, size_t size,
1294	enum dma_data_direction dir)
1295	{
1296	unsigned char vaddr = vaddr_handle;
1297
1298	vaddr = (void )get_unaligned((unsigned* long *)(vaddr + size));
1299
1300	if (dir == DMA_FROM_DEVICE)
1301	memcpy(to: vaddr, from: *vaddr_handle, len: size);
1302
1303	hcd_buffer_free(bus, size: size + sizeof(vaddr), addr: vaddr_handle, dma: dma_handle);
1304
1305	*vaddr_handle = vaddr;
1306	*dma_handle = `0`;
1307	}
1308
1309	void usb_hcd_unmap_urb_setup_for_dma(struct usb_hcd hcd, struct* urb *urb)
1310	{
1311	if (IS_ENABLED(CONFIG_HAS_DMA) &&
1312	(urb->transfer_flags & URB_SETUP_MAP_SINGLE))
1313	dma_unmap_single(hcd->self.sysdev,
1314	urb->setup_dma,
1315	sizeof(struct usb_ctrlrequest),
1316	DMA_TO_DEVICE);
1317	else if (urb->transfer_flags & URB_SETUP_MAP_LOCAL)
1318	hcd_free_coherent(bus: urb->dev->bus,
1319	dma_handle: &urb->setup_dma,
1320	vaddr_handle: (void **) &urb->setup_packet,
1321	size: sizeof(struct usb_ctrlrequest),
1322	dir: DMA_TO_DEVICE);
1323
1324	/ Make it safe to call this routine more than once /
1325	urb->transfer_flags &= ~(URB_SETUP_MAP_SINGLE \| URB_SETUP_MAP_LOCAL);
1326	}
1327	EXPORT_SYMBOL_GPL(usb_hcd_unmap_urb_setup_for_dma);
1328
1329	static void unmap_urb_for_dma(struct usb_hcd hcd, struct* urb *urb)
1330	{
1331	if (hcd->driver->unmap_urb_for_dma)
1332	hcd->driver->unmap_urb_for_dma(hcd, urb);
1333	else
1334	usb_hcd_unmap_urb_for_dma(hcd, urb);
1335	}
1336
1337	void usb_hcd_unmap_urb_for_dma(struct usb_hcd hcd, struct* urb *urb)
1338	{
1339	enum dma_data_direction dir;
1340
1341	usb_hcd_unmap_urb_setup_for_dma(hcd, urb);
1342
1343	dir = usb_urb_dir_in(urb) ? DMA_FROM_DEVICE : DMA_TO_DEVICE;
1344	if (IS_ENABLED(CONFIG_HAS_DMA) &&
1345	(urb->transfer_flags & URB_DMA_MAP_SG)) {
1346	dma_unmap_sg(hcd->self.sysdev,
1347	urb->sg,
1348	urb->num_sgs,
1349	dir);
1350	} else if (IS_ENABLED(CONFIG_HAS_DMA) &&
1351	(urb->transfer_flags & URB_DMA_MAP_PAGE)) {
1352	dma_unmap_page(hcd->self.sysdev,
1353	urb->transfer_dma,
1354	urb->transfer_buffer_length,
1355	dir);
1356	} else if (IS_ENABLED(CONFIG_HAS_DMA) &&
1357	(urb->transfer_flags & URB_DMA_MAP_SINGLE)) {
1358	dma_unmap_single(hcd->self.sysdev,
1359	urb->transfer_dma,
1360	urb->transfer_buffer_length,
1361	dir);
1362	} else if (urb->transfer_flags & URB_MAP_LOCAL) {
1363	hcd_free_coherent(bus: urb->dev->bus,
1364	dma_handle: &urb->transfer_dma,
1365	vaddr_handle: &urb->transfer_buffer,
1366	size: urb->transfer_buffer_length,
1367	dir);
1368	} else if ((urb->transfer_flags & URB_NO_TRANSFER_DMA_MAP) && urb->sgt) {
1369	dma_sync_sgtable_for_cpu(dev: hcd->self.sysdev, sgt: urb->sgt, dir);
1370	if (dir == DMA_FROM_DEVICE)
1371	invalidate_kernel_vmap_range(vaddr: urb->transfer_buffer,
1372	size: urb->transfer_buffer_length);
1373	}
1374
1375	/ Make it safe to call this routine more than once /
1376	urb->transfer_flags &= ~(URB_DMA_MAP_SG \| URB_DMA_MAP_PAGE \|
1377	URB_DMA_MAP_SINGLE \| URB_MAP_LOCAL);
1378	}
1379	EXPORT_SYMBOL_GPL(usb_hcd_unmap_urb_for_dma);
1380
1381	static int map_urb_for_dma(struct usb_hcd hcd, struct* urb *urb,
1382	gfp_t mem_flags)
1383	{
1384	if (hcd->driver->map_urb_for_dma)
1385	return hcd->driver->map_urb_for_dma(hcd, urb, mem_flags);
1386	else
1387	return usb_hcd_map_urb_for_dma(hcd, urb, mem_flags);
1388	}
1389
1390	int usb_hcd_map_urb_for_dma(struct usb_hcd hcd, struct* urb *urb,
1391	gfp_t mem_flags)
1392	{
1393	enum dma_data_direction dir;
1394	int ret = `0`;
1395
1396	/ Map the URB's buffers for DMA access.*
1397	* Lower level HCD code should use *_dma exclusively,
1398	* unless it uses pio or talks to another transport,
1399	* or uses the provided scatter gather list for bulk.
1400	*/
1401
1402	if (usb_endpoint_xfer_control(epd: &urb->ep->desc)) {
1403	if (hcd->self.uses_pio_for_control)
1404	return ret;
1405	if (hcd->localmem_pool) {
1406	ret = hcd_alloc_coherent(
1407	bus: urb->dev->bus, mem_flags,
1408	dma_handle: &urb->setup_dma,
1409	vaddr_handle: (void **)&urb->setup_packet,
1410	size: sizeof(struct usb_ctrlrequest),
1411	dir: DMA_TO_DEVICE);
1412	if (ret)
1413	return ret;
1414	urb->transfer_flags \|= URB_SETUP_MAP_LOCAL;
1415	} else if (hcd_uses_dma(hcd)) {
1416	if (object_is_on_stack(obj: urb->setup_packet)) {
1417	WARN_ONCE(`1`, "setup packet is on stack\n");
1418	return -EAGAIN;
1419	}
1420
1421	urb->setup_dma = dma_map_single(
1422	hcd->self.sysdev,
1423	urb->setup_packet,
1424	sizeof(struct usb_ctrlrequest),
1425	DMA_TO_DEVICE);
1426	if (dma_mapping_error(dev: hcd->self.sysdev,
1427	dma_addr: urb->setup_dma))
1428	return -EAGAIN;
1429	urb->transfer_flags \|= URB_SETUP_MAP_SINGLE;
1430	}
1431	}
1432
1433	dir = usb_urb_dir_in(urb) ? DMA_FROM_DEVICE : DMA_TO_DEVICE;
1434	if (urb->transfer_flags & URB_NO_TRANSFER_DMA_MAP) {
1435	if (!urb->sgt)
1436	return `0`;
1437
1438	if (dir == DMA_TO_DEVICE)
1439	flush_kernel_vmap_range(vaddr: urb->transfer_buffer,
1440	size: urb->transfer_buffer_length);
1441	dma_sync_sgtable_for_device(dev: hcd->self.sysdev, sgt: urb->sgt, dir);
1442	} else if (urb->transfer_buffer_length != `0`) {
1443	if (hcd->localmem_pool) {
1444	ret = hcd_alloc_coherent(
1445	bus: urb->dev->bus, mem_flags,
1446	dma_handle: &urb->transfer_dma,
1447	vaddr_handle: &urb->transfer_buffer,
1448	size: urb->transfer_buffer_length,
1449	dir);
1450	if (ret == `0`)
1451	urb->transfer_flags \|= URB_MAP_LOCAL;
1452	} else if (hcd_uses_dma(hcd)) {
1453	if (urb->num_sgs) {
1454	int n;
1455
1456	/ We don't support sg for isoc transfers ! /
1457	if (usb_endpoint_xfer_isoc(epd: &urb->ep->desc)) {
1458	WARN_ON(`1`);
1459	return -EINVAL;
1460	}
1461
1462	n = dma_map_sg(
1463	hcd->self.sysdev,
1464	urb->sg,
1465	urb->num_sgs,
1466	dir);
1467	if (!n)
1468	ret = -EAGAIN;
1469	else
1470	urb->transfer_flags \|= URB_DMA_MAP_SG;
1471	urb->num_mapped_sgs = n;
1472	if (n != urb->num_sgs)
1473	urb->transfer_flags \|=
1474	URB_DMA_SG_COMBINED;
1475	} else if (urb->sg) {
1476	struct scatterlist *sg = urb->sg;
1477	urb->transfer_dma = dma_map_page(
1478	hcd->self.sysdev,
1479	sg_page(sg),
1480	sg->offset,
1481	urb->transfer_buffer_length,
1482	dir);
1483	if (dma_mapping_error(dev: hcd->self.sysdev,
1484	dma_addr: urb->transfer_dma))
1485	ret = -EAGAIN;
1486	else
1487	urb->transfer_flags \|= URB_DMA_MAP_PAGE;
1488	} else if (object_is_on_stack(obj: urb->transfer_buffer)) {
1489	WARN_ONCE(`1`, "transfer buffer is on stack\n");
1490	ret = -EAGAIN;
1491	} else {
1492	urb->transfer_dma = dma_map_single(
1493	hcd->self.sysdev,
1494	urb->transfer_buffer,
1495	urb->transfer_buffer_length,
1496	dir);
1497	if (dma_mapping_error(dev: hcd->self.sysdev,
1498	dma_addr: urb->transfer_dma))
1499	ret = -EAGAIN;
1500	else
1501	urb->transfer_flags \|= URB_DMA_MAP_SINGLE;
1502	}
1503	}
1504	if (ret && (urb->transfer_flags & (URB_SETUP_MAP_SINGLE \|
1505	URB_SETUP_MAP_LOCAL)))
1506	usb_hcd_unmap_urb_for_dma(hcd, urb);
1507	}
1508	return ret;
1509	}
1510	EXPORT_SYMBOL_GPL(usb_hcd_map_urb_for_dma);
1511
1512	/-------------------------------------------------------------------------/
1513
1514	/ may be called in any context with a valid urb->dev usecount*
1515	* caller surrenders "ownership" of urb
1516	* expects usb_submit_urb() to have sanity checked and conditioned all
1517	* inputs in the urb
1518	*/
1519	int usb_hcd_submit_urb (struct urb *urb, gfp_t mem_flags)
1520	{
1521	int status;
1522	struct usb_hcd *hcd = bus_to_hcd(bus: urb->dev->bus);
1523
1524	/ increment urb's reference count as part of giving it to the HCD*
1525	* (which will control it). HCD guarantees that it either returns
1526	* an error or calls giveback(), but not both.
1527	*/
1528	usb_get_urb(urb);
1529	atomic_inc(v: &urb->use_count);
1530	atomic_inc(v: &urb->dev->urbnum);
1531	usbmon_urb_submit(bus: &hcd->self, urb);
1532
1533	/ NOTE requirements on root-hub callers (usbfs and the hub*
1534	* driver, for now): URBs' urb->transfer_buffer must be
1535	* valid and usb_buffer_{sync,unmap}() not be needed, since
1536	* they could clobber root hub response data. Also, control
1537	* URBs must be submitted in process context with interrupts
1538	* enabled.
1539	*/
1540
1541	if (is_root_hub(udev: urb->dev)) {
1542	status = rh_urb_enqueue(hcd, urb);
1543	} else {
1544	status = map_urb_for_dma(hcd, urb, mem_flags);
1545	if (likely(status == `0`)) {
1546	status = hcd->driver->urb_enqueue(hcd, urb, mem_flags);
1547	if (unlikely(status))
1548	unmap_urb_for_dma(hcd, urb);
1549	}
1550	}
1551
1552	if (unlikely(status)) {
1553	usbmon_urb_submit_error(bus: &hcd->self, urb, error: status);
1554	urb->hcpriv = NULL;
1555	INIT_LIST_HEAD(list: &urb->urb_list);
1556	atomic_dec(v: &urb->use_count);
1557	/*
1558	* Order the write of urb->use_count above before the read
1559	* of urb->reject below. Pairs with the memory barriers in
1560	* usb_kill_urb() and usb_poison_urb().
1561	*/
1562	smp_mb__after_atomic();
1563
1564	atomic_dec(v: &urb->dev->urbnum);
1565	if (atomic_read(v: &urb->reject))
1566	wake_up(&usb_kill_urb_queue);
1567	usb_put_urb(urb);
1568	}
1569	return status;
1570	}
1571
1572	/-------------------------------------------------------------------------/
1573
1574	/ this makes the hcd giveback() the urb more quickly, by kicking it*
1575	* off hardware queues (which may take a while) and returning it as
1576	* soon as practical. we've already set up the urb's return status,
1577	* but we can't know if the callback completed already.
1578	*/
1579	static int unlink1(struct usb_hcd hcd, struct* urb urb, int* status)
1580	{
1581	int value;
1582
1583	if (is_root_hub(udev: urb->dev))
1584	value = usb_rh_urb_dequeue(hcd, urb, status);
1585	else {
1586
1587	/ The only reason an HCD might fail this call is if*
1588	* it has not yet fully queued the urb to begin with.
1589	* Such failures should be harmless. */
1590	value = hcd->driver->urb_dequeue(hcd, urb, status);
1591	}
1592	return value;
1593	}
1594
1595	/*
1596	* called in any context
1597	*
1598	* caller guarantees urb won't be recycled till both unlink()
1599	* and the urb's completion function return
1600	*/
1601	int usb_hcd_unlink_urb (struct urb urb, int* status)
1602	{
1603	struct usb_hcd *hcd;
1604	struct usb_device *udev = urb->dev;
1605	int retval = -EIDRM;
1606	unsigned long flags;
1607
1608	/ Prevent the device and bus from going away while*
1609	* the unlink is carried out. If they are already gone
1610	* then urb->use_count must be 0, since disconnected
1611	* devices can't have any active URBs.
1612	*/
1613	spin_lock_irqsave(&hcd_urb_unlink_lock, flags);
1614	if (atomic_read(v: &urb->use_count) > `0`) {
1615	retval = `0`;
1616	usb_get_dev(dev: udev);
1617	}
1618	spin_unlock_irqrestore(lock: &hcd_urb_unlink_lock, flags);
1619	if (retval == `0`) {
1620	hcd = bus_to_hcd(bus: urb->dev->bus);
1621	retval = unlink1(hcd, urb, status);
1622	if (retval == `0`)
1623	retval = -EINPROGRESS;
1624	else if (retval != -EIDRM && retval != -EBUSY)
1625	dev_dbg(&udev->dev, "hcd_unlink_urb %p fail %d\n",
1626	urb, retval);
1627	usb_put_dev(dev: udev);
1628	}
1629	return retval;
1630	}
1631
1632	/-------------------------------------------------------------------------/
1633
1634	static void __usb_hcd_giveback_urb(struct urb *urb)
1635	{
1636	struct usb_hcd *hcd = bus_to_hcd(bus: urb->dev->bus);
1637	struct usb_anchor *anchor = urb->anchor;
1638	int status = urb->unlinked;
1639
1640	urb->hcpriv = NULL;
1641	if (unlikely((urb->transfer_flags & URB_SHORT_NOT_OK) &&
1642	urb->actual_length < urb->transfer_buffer_length &&
1643	!status))
1644	status = -EREMOTEIO;
1645
1646	unmap_urb_for_dma(hcd, urb);
1647	usbmon_urb_complete(bus: &hcd->self, urb, status);
1648	usb_anchor_suspend_wakeups(anchor);
1649	usb_unanchor_urb(urb);
1650	if (likely(status == `0`))
1651	usb_led_activity(ev: USB_LED_EVENT_HOST);
1652
1653	/ pass ownership to the completion handler /
1654	urb->status = status;
1655	/*
1656	* This function can be called in task context inside another remote
1657	* coverage collection section, but kcov doesn't support that kind of
1658	* recursion yet. Only collect coverage in softirq context for now.
1659	*/
1660	kcov_remote_start_usb_softirq(id: (u64)urb->dev->bus->busnum);
1661	urb->complete(urb);
1662	kcov_remote_stop_softirq();
1663
1664	usb_anchor_resume_wakeups(anchor);
1665	atomic_dec(v: &urb->use_count);
1666	/*
1667	* Order the write of urb->use_count above before the read
1668	* of urb->reject below. Pairs with the memory barriers in
1669	* usb_kill_urb() and usb_poison_urb().
1670	*/
1671	smp_mb__after_atomic();
1672
1673	if (unlikely(atomic_read(&urb->reject)))
1674	wake_up(&usb_kill_urb_queue);
1675	usb_put_urb(urb);
1676	}
1677
1678	static void usb_giveback_urb_bh(struct work_struct *work)
1679	{
1680	struct giveback_urb_bh *bh =
1681	container_of(work, struct giveback_urb_bh, bh);
1682	struct list_head local_list;
1683
1684	spin_lock_irq(lock: &bh->lock);
1685	bh->running = true;
1686	list_replace_init(old: &bh->head, new: &local_list);
1687	spin_unlock_irq(lock: &bh->lock);
1688
1689	while (!list_empty(head: &local_list)) {
1690	struct urb *urb;
1691
1692	urb = list_entry(local_list.next, struct urb, urb_list);
1693	list_del_init(entry: &urb->urb_list);
1694	bh->completing_ep = urb->ep;
1695	__usb_hcd_giveback_urb(urb);
1696	bh->completing_ep = NULL;
1697	}
1698
1699	/*
1700	* giveback new URBs next time to prevent this function
1701	* from not exiting for a long time.
1702	*/
1703	spin_lock_irq(lock: &bh->lock);
1704	if (!list_empty(head: &bh->head)) {
1705	if (bh->high_prio)
1706	queue_work(wq: system_bh_highpri_wq, work: &bh->bh);
1707	else
1708	queue_work(wq: system_bh_wq, work: &bh->bh);
1709	}
1710	bh->running = false;
1711	spin_unlock_irq(lock: &bh->lock);
1712	}
1713
1714	/**
1715	* usb_hcd_giveback_urb - return URB from HCD to device driver
1716	* @hcd: host controller returning the URB
1717	* @urb: urb being returned to the USB device driver.
1718	* @status: completion status code for the URB.
1719	*
1720	* Context: atomic. The completion callback is invoked either in a work queue
1721	* (BH) context or in the caller's context, depending on whether the HCD_BH
1722	* flag is set in the @hcd structure, except that URBs submitted to the
1723	* root hub always complete in BH context.
1724	*
1725	* This hands the URB from HCD to its USB device driver, using its
1726	* completion function. The HCD has freed all per-urb resources
1727	* (and is done using urb->hcpriv). It also released all HCD locks;
1728	* the device driver won't cause problems if it frees, modifies,
1729	* or resubmits this URB.
1730	*
1731	* If @urb was unlinked, the value of @status will be overridden by
1732	* @urb->unlinked. Erroneous short transfers are detected in case
1733	* the HCD hasn't checked for them.
1734	*/
1735	void usb_hcd_giveback_urb(struct usb_hcd hcd, struct* urb urb, int* status)
1736	{
1737	struct giveback_urb_bh *bh;
1738	bool running;
1739
1740	/ pass status to BH via unlinked /
1741	if (likely(!urb->unlinked))
1742	urb->unlinked = status;
1743
1744	if (!hcd_giveback_urb_in_bh(hcd) && !is_root_hub(udev: urb->dev)) {
1745	__usb_hcd_giveback_urb(urb);
1746	return;
1747	}
1748
1749	if (usb_pipeisoc(urb->pipe) \|\| usb_pipeint(urb->pipe))
1750	bh = &hcd->high_prio_bh;
1751	else
1752	bh = &hcd->low_prio_bh;
1753
1754	spin_lock(lock: &bh->lock);
1755	list_add_tail(new: &urb->urb_list, head: &bh->head);
1756	running = bh->running;
1757	spin_unlock(lock: &bh->lock);
1758
1759	if (running)
1760	;
1761	else if (bh->high_prio)
1762	queue_work(wq: system_bh_highpri_wq, work: &bh->bh);
1763	else
1764	queue_work(wq: system_bh_wq, work: &bh->bh);
1765	}
1766	EXPORT_SYMBOL_GPL(usb_hcd_giveback_urb);
1767
1768	/-------------------------------------------------------------------------/
1769
1770	/ Cancel all URBs pending on this endpoint and wait for the endpoint's*
1771	* queue to drain completely. The caller must first insure that no more
1772	* URBs can be submitted for this endpoint.
1773	*/
1774	void usb_hcd_flush_endpoint(struct usb_device *udev,
1775	struct usb_host_endpoint *ep)
1776	{
1777	struct usb_hcd *hcd;
1778	struct urb *urb;
1779
1780	if (!ep)
1781	return;
1782	might_sleep();
1783	hcd = bus_to_hcd(bus: udev->bus);
1784
1785	/ No more submits can occur /
1786	spin_lock_irq(lock: &hcd_urb_list_lock);
1787	rescan:
1788	list_for_each_entry_reverse(urb, &ep->urb_list, urb_list) {
1789	int is_in;
1790
1791	if (urb->unlinked)
1792	continue;
1793	usb_get_urb (urb);
1794	is_in = usb_urb_dir_in(urb);
1795	spin_unlock(lock: &hcd_urb_list_lock);
1796
1797	/ kick hcd /
1798	unlink1(hcd, urb, status: -ESHUTDOWN);
1799	dev_dbg (hcd->self.controller,
1800	"shutdown urb %p ep%d%s-%s\n",
1801	urb, usb_endpoint_num(&ep->desc),
1802	is_in ? "in" : "out",
1803	usb_ep_type_string(usb_endpoint_type(&ep->desc)));
1804	usb_put_urb (urb);
1805
1806	/ list contents may have changed /
1807	spin_lock(lock: &hcd_urb_list_lock);
1808	goto rescan;
1809	}
1810	spin_unlock_irq(lock: &hcd_urb_list_lock);
1811
1812	/ Wait until the endpoint queue is completely empty /
1813	while (!list_empty (head: &ep->urb_list)) {
1814	spin_lock_irq(lock: &hcd_urb_list_lock);
1815
1816	/ The list may have changed while we acquired the spinlock /
1817	urb = NULL;
1818	if (!list_empty (head: &ep->urb_list)) {
1819	urb = list_entry (ep->urb_list.prev, struct urb,
1820	urb_list);
1821	usb_get_urb (urb);
1822	}
1823	spin_unlock_irq(lock: &hcd_urb_list_lock);
1824
1825	if (urb) {
1826	usb_kill_urb (urb);
1827	usb_put_urb (urb);
1828	}
1829	}
1830	}
1831
1832	/**
1833	* usb_hcd_alloc_bandwidth - check whether a new bandwidth setting exceeds
1834	* the bus bandwidth
1835	* @udev: target &usb_device
1836	* @new_config: new configuration to install
1837	* @cur_alt: the current alternate interface setting
1838	* @new_alt: alternate interface setting that is being installed
1839	*
1840	* To change configurations, pass in the new configuration in new_config,
1841	* and pass NULL for cur_alt and new_alt.
1842	*
1843	* To reset a device's configuration (put the device in the ADDRESSED state),
1844	* pass in NULL for new_config, cur_alt, and new_alt.
1845	*
1846	* To change alternate interface settings, pass in NULL for new_config,
1847	* pass in the current alternate interface setting in cur_alt,
1848	* and pass in the new alternate interface setting in new_alt.
1849	*
1850	* Return: An error if the requested bandwidth change exceeds the
1851	* bus bandwidth or host controller internal resources.
1852	*/
1853	int usb_hcd_alloc_bandwidth(struct usb_device *udev,
1854	struct usb_host_config *new_config,
1855	struct usb_host_interface *cur_alt,
1856	struct usb_host_interface *new_alt)
1857	{
1858	int num_intfs, i, j;
1859	struct usb_host_interface *alt = NULL;
1860	int ret = `0`;
1861	struct usb_hcd *hcd;
1862	struct usb_host_endpoint *ep;
1863
1864	hcd = bus_to_hcd(bus: udev->bus);
1865	if (!hcd->driver->check_bandwidth)
1866	return `0`;
1867
1868	/ Configuration is being removed - set configuration 0 /
1869	if (!new_config && !cur_alt) {
1870	for (i = `1`; i < `16`; ++i) {
1871	ep = udev->ep_out[i];
1872	if (ep)
1873	hcd->driver->drop_endpoint(hcd, udev, ep);
1874	ep = udev->ep_in[i];
1875	if (ep)
1876	hcd->driver->drop_endpoint(hcd, udev, ep);
1877	}
1878	hcd->driver->check_bandwidth(hcd, udev);
1879	return `0`;
1880	}
1881	/ Check if the HCD says there's enough bandwidth. Enable all endpoints*
1882	* each interface's alt setting 0 and ask the HCD to check the bandwidth
1883	* of the bus. There will always be bandwidth for endpoint 0, so it's
1884	* ok to exclude it.
1885	*/
1886	if (new_config) {
1887	num_intfs = new_config->desc.bNumInterfaces;
1888	/ Remove endpoints (except endpoint 0, which is always on the*
1889	* schedule) from the old config from the schedule
1890	*/
1891	for (i = `1`; i < `16`; ++i) {
1892	ep = udev->ep_out[i];
1893	if (ep) {
1894	ret = hcd->driver->drop_endpoint(hcd, udev, ep);
1895	if (ret < `0`)
1896	goto reset;
1897	}
1898	ep = udev->ep_in[i];
1899	if (ep) {
1900	ret = hcd->driver->drop_endpoint(hcd, udev, ep);
1901	if (ret < `0`)
1902	goto reset;
1903	}
1904	}
1905	for (i = `0`; i < num_intfs; ++i) {
1906	struct usb_host_interface *first_alt;
1907	int iface_num;
1908
1909	first_alt = &new_config->intf_cache[i]->altsetting[`0`];
1910	iface_num = first_alt->desc.bInterfaceNumber;
1911	/ Set up endpoints for alternate interface setting 0 /
1912	alt = usb_find_alt_setting(config: new_config, iface_num, alt_num: `0`);
1913	if (!alt)
1914	/ No alt setting 0? Pick the first setting. /
1915	alt = first_alt;
1916
1917	for (j = `0`; j < alt->desc.bNumEndpoints; j++) {
1918	ret = hcd->driver->add_endpoint(hcd, udev, &alt->endpoint[j]);
1919	if (ret < `0`)
1920	goto reset;
1921	}
1922	}
1923	}
1924	if (cur_alt && new_alt) {
1925	struct usb_interface *iface = usb_ifnum_to_if(dev: udev,
1926	ifnum: cur_alt->desc.bInterfaceNumber);
1927
1928	if (!iface)
1929	return -EINVAL;
1930	if (iface->resetting_device) {
1931	/*
1932	* The USB core just reset the device, so the xHCI host
1933	* and the device will think alt setting 0 is installed.
1934	* However, the USB core will pass in the alternate
1935	* setting installed before the reset as cur_alt. Dig
1936	* out the alternate setting 0 structure, or the first
1937	* alternate setting if a broken device doesn't have alt
1938	* setting 0.
1939	*/
1940	cur_alt = usb_altnum_to_altsetting(intf: iface, altnum: `0`);
1941	if (!cur_alt)
1942	cur_alt = &iface->altsetting[`0`];
1943	}
1944
1945	/ Drop all the endpoints in the current alt setting /
1946	for (i = `0`; i < cur_alt->desc.bNumEndpoints; i++) {
1947	ret = hcd->driver->drop_endpoint(hcd, udev,
1948	&cur_alt->endpoint[i]);
1949	if (ret < `0`)
1950	goto reset;
1951	}
1952	/ Add all the endpoints in the new alt setting /
1953	for (i = `0`; i < new_alt->desc.bNumEndpoints; i++) {
1954	ret = hcd->driver->add_endpoint(hcd, udev,
1955	&new_alt->endpoint[i]);
1956	if (ret < `0`)
1957	goto reset;
1958	}
1959	}
1960	ret = hcd->driver->check_bandwidth(hcd, udev);
1961	reset:
1962	if (ret < `0`)
1963	hcd->driver->reset_bandwidth(hcd, udev);
1964	return ret;
1965	}
1966
1967	/ Disables the endpoint: synchronizes with the hcd to make sure all*
1968	* endpoint state is gone from hardware. usb_hcd_flush_endpoint() must
1969	* have been called previously. Use for set_configuration, set_interface,
1970	* driver removal, physical disconnect.
1971	*
1972	* example: a qh stored in ep->hcpriv, holding state related to endpoint
1973	* type, maxpacket size, toggle, halt status, and scheduling.
1974	*/
1975	void usb_hcd_disable_endpoint(struct usb_device *udev,
1976	struct usb_host_endpoint *ep)
1977	{
1978	struct usb_hcd *hcd;
1979
1980	might_sleep();
1981	hcd = bus_to_hcd(bus: udev->bus);
1982	if (hcd->driver->endpoint_disable)
1983	hcd->driver->endpoint_disable(hcd, ep);
1984	}
1985
1986	/**
1987	* usb_hcd_reset_endpoint - reset host endpoint state
1988	* @udev: USB device.
1989	* @ep: the endpoint to reset.
1990	*
1991	* Resets any host endpoint state such as the toggle bit, sequence
1992	* number and current window.
1993	*/
1994	void usb_hcd_reset_endpoint(struct usb_device *udev,
1995	struct usb_host_endpoint *ep)
1996	{
1997	struct usb_hcd *hcd = bus_to_hcd(bus: udev->bus);
1998
1999	if (hcd->driver->endpoint_reset)
2000	hcd->driver->endpoint_reset(hcd, ep);
2001	else {
2002	int epnum = usb_endpoint_num(epd: &ep->desc);
2003	int is_out = usb_endpoint_dir_out(epd: &ep->desc);
2004	int is_control = usb_endpoint_xfer_control(epd: &ep->desc);
2005
2006	usb_settoggle(udev, epnum, is_out, `0`);
2007	if (is_control)
2008	usb_settoggle(udev, epnum, !is_out, `0`);
2009	}
2010	}
2011
2012	/**
2013	* usb_alloc_streams - allocate bulk endpoint stream IDs.
2014	* @interface: alternate setting that includes all endpoints.
2015	* @eps: array of endpoints that need streams.
2016	* @num_eps: number of endpoints in the array.
2017	* @num_streams: number of streams to allocate.
2018	* @mem_flags: flags hcd should use to allocate memory.
2019	*
2020	* Sets up a group of bulk endpoints to have @num_streams stream IDs available.
2021	* Drivers may queue multiple transfers to different stream IDs, which may
2022	* complete in a different order than they were queued.
2023	*
2024	* Return: On success, the number of allocated streams. On failure, a negative
2025	* error code.
2026	*/
2027	int usb_alloc_streams(struct usb_interface *interface,
2028	struct usb_host_endpoint *eps, unsigned* int num_eps,
2029	unsigned int num_streams, gfp_t mem_flags)
2030	{
2031	struct usb_hcd *hcd;
2032	struct usb_device *dev;
2033	int i, ret;
2034
2035	dev = interface_to_usbdev(interface);
2036	hcd = bus_to_hcd(bus: dev->bus);
2037	if (!hcd->driver->alloc_streams \|\| !hcd->driver->free_streams)
2038	return -EINVAL;
2039	if (dev->speed < USB_SPEED_SUPER)
2040	return -EINVAL;
2041	if (dev->state < USB_STATE_CONFIGURED)
2042	return -ENODEV;
2043
2044	for (i = `0`; i < num_eps; i++) {
2045	/ Streams only apply to bulk endpoints. /
2046	if (!usb_endpoint_xfer_bulk(epd: &eps[i]->desc))
2047	return -EINVAL;
2048	/ Re-alloc is not allowed /
2049	if (eps[i]->streams)
2050	return -EINVAL;
2051	}
2052
2053	ret = hcd->driver->alloc_streams(hcd, dev, eps, num_eps,
2054	num_streams, mem_flags);
2055	if (ret < `0`)
2056	return ret;
2057
2058	for (i = `0`; i < num_eps; i++)
2059	eps[i]->streams = ret;
2060
2061	return ret;
2062	}
2063	EXPORT_SYMBOL_GPL(usb_alloc_streams);
2064
2065	/**
2066	* usb_free_streams - free bulk endpoint stream IDs.
2067	* @interface: alternate setting that includes all endpoints.
2068	* @eps: array of endpoints to remove streams from.
2069	* @num_eps: number of endpoints in the array.
2070	* @mem_flags: flags hcd should use to allocate memory.
2071	*
2072	* Reverts a group of bulk endpoints back to not using stream IDs.
2073	* Can fail if we are given bad arguments, or HCD is broken.
2074	*
2075	* Return: 0 on success. On failure, a negative error code.
2076	*/
2077	int usb_free_streams(struct usb_interface *interface,
2078	struct usb_host_endpoint *eps, unsigned* int num_eps,
2079	gfp_t mem_flags)
2080	{
2081	struct usb_hcd *hcd;
2082	struct usb_device *dev;
2083	int i, ret;
2084
2085	dev = interface_to_usbdev(interface);
2086	hcd = bus_to_hcd(bus: dev->bus);
2087	if (dev->speed < USB_SPEED_SUPER)
2088	return -EINVAL;
2089
2090	/ Double-free is not allowed /
2091	for (i = `0`; i < num_eps; i++)
2092	if (!eps[i] \|\| !eps[i]->streams)
2093	return -EINVAL;
2094
2095	ret = hcd->driver->free_streams(hcd, dev, eps, num_eps, mem_flags);
2096	if (ret < `0`)
2097	return ret;
2098
2099	for (i = `0`; i < num_eps; i++)
2100	eps[i]->streams = `0`;
2101
2102	return ret;
2103	}
2104	EXPORT_SYMBOL_GPL(usb_free_streams);
2105
2106	/ Protect against drivers that try to unlink URBs after the device*
2107	* is gone, by waiting until all unlinks for @udev are finished.
2108	* Since we don't currently track URBs by device, simply wait until
2109	* nothing is running in the locked region of usb_hcd_unlink_urb().
2110	*/
2111	void usb_hcd_synchronize_unlinks(struct usb_device *udev)
2112	{
2113	spin_lock_irq(lock: &hcd_urb_unlink_lock);
2114	spin_unlock_irq(lock: &hcd_urb_unlink_lock);
2115	}
2116
2117	/-------------------------------------------------------------------------/
2118
2119	/ called in any context /
2120	int usb_hcd_get_frame_number (struct usb_device *udev)
2121	{
2122	struct usb_hcd *hcd = bus_to_hcd(bus: udev->bus);
2123
2124	if (!HCD_RH_RUNNING(hcd))
2125	return -ESHUTDOWN;
2126	return hcd->driver->get_frame_number (hcd);
2127	}
2128
2129	/-------------------------------------------------------------------------/
2130	#ifdef CONFIG_USB_HCD_TEST_MODE
2131
2132	static void usb_ehset_completion(struct urb *urb)
2133	{
2134	struct completion *done = urb->context;
2135
2136	complete(done);
2137	}
2138	/*
2139	* Allocate and initialize a control URB. This request will be used by the
2140	* EHSET SINGLE_STEP_SET_FEATURE test in which the DATA and STATUS stages
2141	* of the GetDescriptor request are sent 15 seconds after the SETUP stage.
2142	* Return NULL if failed.
2143	*/
2144	static struct urb *request_single_step_set_feature_urb(
2145	struct usb_device *udev,
2146	void *dr,
2147	void *buf,
2148	struct completion *done)
2149	{
2150	struct urb *urb;
2151	struct usb_hcd *hcd = bus_to_hcd(udev->bus);
2152
2153	urb = usb_alloc_urb(`0`, GFP_KERNEL);
2154	if (!urb)
2155	return NULL;
2156
2157	urb->pipe = usb_rcvctrlpipe(udev, `0`);
2158
2159	urb->ep = &udev->ep0;
2160	urb->dev = udev;
2161	urb->setup_packet = (void *)dr;
2162	urb->transfer_buffer = buf;
2163	urb->transfer_buffer_length = USB_DT_DEVICE_SIZE;
2164	urb->complete = usb_ehset_completion;
2165	urb->status = -EINPROGRESS;
2166	urb->actual_length = `0`;
2167	urb->transfer_flags = URB_DIR_IN \| URB_NO_TRANSFER_DMA_MAP;
2168	usb_get_urb(urb);
2169	atomic_inc(&urb->use_count);
2170	atomic_inc(&urb->dev->urbnum);
2171	if (map_urb_for_dma(hcd, urb, GFP_KERNEL)) {
2172	usb_put_urb(urb);
2173	usb_free_urb(urb);
2174	return NULL;
2175	}
2176
2177	urb->context = done;
2178	return urb;
2179	}
2180
2181	int ehset_single_step_set_feature(struct usb_hcd hcd, int* port)
2182	{
2183	int retval = -ENOMEM;
2184	struct usb_ctrlrequest *dr;
2185	struct urb *urb;
2186	struct usb_device *udev;
2187	struct usb_device_descriptor *buf;
2188	DECLARE_COMPLETION_ONSTACK(done);
2189
2190	/ Obtain udev of the rhub's child port /
2191	udev = usb_hub_find_child(hcd->self.root_hub, port);
2192	if (!udev) {
2193	dev_err(hcd->self.controller, "No device attached to the RootHub\n");
2194	return -ENODEV;
2195	}
2196	buf = kmalloc(USB_DT_DEVICE_SIZE, GFP_KERNEL);
2197	if (!buf)
2198	return -ENOMEM;
2199
2200	dr = kmalloc(sizeof(struct usb_ctrlrequest), GFP_KERNEL);
2201	if (!dr) {
2202	kfree(buf);
2203	return -ENOMEM;
2204	}
2205
2206	/ Fill Setup packet for GetDescriptor /
2207	dr->bRequestType = USB_DIR_IN;
2208	dr->bRequest = USB_REQ_GET_DESCRIPTOR;
2209	dr->wValue = cpu_to_le16(USB_DT_DEVICE << `8`);
2210	dr->wIndex = `0`;
2211	dr->wLength = cpu_to_le16(USB_DT_DEVICE_SIZE);
2212	urb = request_single_step_set_feature_urb(udev, dr, buf, &done);
2213	if (!urb)
2214	goto cleanup;
2215
2216	/ Submit just the SETUP stage /
2217	retval = hcd->driver->submit_single_step_set_feature(hcd, urb, `1`);
2218	if (retval)
2219	goto out1;
2220	if (!wait_for_completion_timeout(&done, msecs_to_jiffies(`2000`))) {
2221	usb_kill_urb(urb);
2222	retval = -ETIMEDOUT;
2223	dev_err(hcd->self.controller,
2224	"%s SETUP stage timed out on ep0\n", __func__);
2225	goto out1;
2226	}
2227	msleep(`15` * `1000`);
2228
2229	/ Complete remaining DATA and STATUS stages using the same URB /
2230	urb->status = -EINPROGRESS;
2231	urb->transfer_flags &= ~URB_NO_TRANSFER_DMA_MAP;
2232	usb_get_urb(urb);
2233	atomic_inc(&urb->use_count);
2234	atomic_inc(&urb->dev->urbnum);
2235	if (map_urb_for_dma(hcd, urb, GFP_KERNEL)) {
2236	usb_put_urb(urb);
2237	goto out1;
2238	}
2239
2240	retval = hcd->driver->submit_single_step_set_feature(hcd, urb, `0`);
2241	if (!retval && !wait_for_completion_timeout(&done,
2242	msecs_to_jiffies(`2000`))) {
2243	usb_kill_urb(urb);
2244	retval = -ETIMEDOUT;
2245	dev_err(hcd->self.controller,
2246	"%s IN stage timed out on ep0\n", __func__);
2247	}
2248	out1:
2249	usb_free_urb(urb);
2250	cleanup:
2251	kfree(dr);
2252	kfree(buf);
2253	return retval;
2254	}
2255	EXPORT_SYMBOL_GPL(ehset_single_step_set_feature);
2256	#endif /* CONFIG_USB_HCD_TEST_MODE */
2257
2258	/-------------------------------------------------------------------------/
2259
2260	#ifdef CONFIG_PM
2261
2262	int hcd_bus_suspend(struct usb_device *rhdev, pm_message_t msg)
2263	{
2264	struct usb_hcd *hcd = bus_to_hcd(bus: rhdev->bus);
2265	int status;
2266	int old_state = hcd->state;
2267
2268	dev_dbg(&rhdev->dev, "bus %ssuspend, wakeup %d\n",
2269	(PMSG_IS_AUTO(msg) ? "auto-" : ""),
2270	rhdev->do_remote_wakeup);
2271	if (HCD_DEAD(hcd)) {
2272	dev_dbg(&rhdev->dev, "skipped %s of dead bus\n", "suspend");
2273	return `0`;
2274	}
2275
2276	if (!hcd->driver->bus_suspend) {
2277	status = -ENOENT;
2278	} else {
2279	clear_bit(HCD_FLAG_RH_RUNNING, addr: &hcd->flags);
2280	hcd->state = HC_STATE_QUIESCING;
2281	status = hcd->driver->bus_suspend(hcd);
2282	}
2283	if (status == `0`) {
2284	usb_set_device_state(udev: rhdev, new_state: USB_STATE_SUSPENDED);
2285	hcd->state = HC_STATE_SUSPENDED;
2286
2287	if (!PMSG_IS_AUTO(msg))
2288	usb_phy_roothub_suspend(controller_dev: hcd->self.sysdev,
2289	phy_roothub: hcd->phy_roothub);
2290
2291	/ Did we race with a root-hub wakeup event? /
2292	if (rhdev->do_remote_wakeup) {
2293	char buffer[`6`];
2294
2295	status = hcd->driver->hub_status_data(hcd, buffer);
2296	if (status != `0`) {
2297	dev_dbg(&rhdev->dev, "suspend raced with wakeup event\n");
2298	hcd_bus_resume(rhdev, PMSG_AUTO_RESUME);
2299	status = -EBUSY;
2300	}
2301	}
2302	} else {
2303	spin_lock_irq(lock: &hcd_root_hub_lock);
2304	if (!HCD_DEAD(hcd)) {
2305	set_bit(HCD_FLAG_RH_RUNNING, addr: &hcd->flags);
2306	hcd->state = old_state;
2307	}
2308	spin_unlock_irq(lock: &hcd_root_hub_lock);
2309	dev_dbg(&rhdev->dev, "bus %s fail, err %d\n",
2310	"suspend", status);
2311	}
2312	return status;
2313	}
2314
2315	int hcd_bus_resume(struct usb_device *rhdev, pm_message_t msg)
2316	{
2317	struct usb_hcd *hcd = bus_to_hcd(bus: rhdev->bus);
2318	int status;
2319	int old_state = hcd->state;
2320
2321	dev_dbg(&rhdev->dev, "usb %sresume\n",
2322	(PMSG_IS_AUTO(msg) ? "auto-" : ""));
2323	if (HCD_DEAD(hcd)) {
2324	dev_dbg(&rhdev->dev, "skipped %s of dead bus\n", "resume");
2325	return `0`;
2326	}
2327
2328	if (!PMSG_IS_AUTO(msg)) {
2329	status = usb_phy_roothub_resume(controller_dev: hcd->self.sysdev,
2330	phy_roothub: hcd->phy_roothub);
2331	if (status)
2332	return status;
2333	}
2334
2335	if (!hcd->driver->bus_resume)
2336	return -ENOENT;
2337	if (HCD_RH_RUNNING(hcd))
2338	return `0`;
2339
2340	hcd->state = HC_STATE_RESUMING;
2341	status = hcd->driver->bus_resume(hcd);
2342	clear_bit(HCD_FLAG_WAKEUP_PENDING, addr: &hcd->flags);
2343	if (status == `0`)
2344	status = usb_phy_roothub_calibrate(phy_roothub: hcd->phy_roothub);
2345
2346	if (status == `0`) {
2347	struct usb_device *udev;
2348	int port1;
2349
2350	spin_lock_irq(lock: &hcd_root_hub_lock);
2351	if (!HCD_DEAD(hcd)) {
2352	usb_set_device_state(udev: rhdev, new_state: rhdev->actconfig
2353	? USB_STATE_CONFIGURED
2354	: USB_STATE_ADDRESS);
2355	set_bit(HCD_FLAG_RH_RUNNING, addr: &hcd->flags);
2356	hcd->state = HC_STATE_RUNNING;
2357	}
2358	spin_unlock_irq(lock: &hcd_root_hub_lock);
2359
2360	/*
2361	* Check whether any of the enabled ports on the root hub are
2362	* unsuspended. If they are then a TRSMRCY delay is needed
2363	* (this is what the USB-2 spec calls a "global resume").
2364	* Otherwise we can skip the delay.
2365	*/
2366	usb_hub_for_each_child(rhdev, port1, udev) {
2367	if (udev->state != USB_STATE_NOTATTACHED &&
2368	!udev->port_is_suspended) {
2369	usleep_range(min: `10000`, max: `11000`); / TRSMRCY /
2370	break;
2371	}
2372	}
2373	} else {
2374	hcd->state = old_state;
2375	usb_phy_roothub_suspend(controller_dev: hcd->self.sysdev, phy_roothub: hcd->phy_roothub);
2376	dev_dbg(&rhdev->dev, "bus %s fail, err %d\n",
2377	"resume", status);
2378	if (status != -ESHUTDOWN)
2379	usb_hc_died(hcd);
2380	}
2381	return status;
2382	}
2383
2384	/ Workqueue routine for root-hub remote wakeup /
2385	static void hcd_resume_work(struct work_struct *work)
2386	{
2387	struct usb_hcd hcd = container_of(work, struct* usb_hcd, wakeup_work);
2388	struct usb_device *udev = hcd->self.root_hub;
2389
2390	usb_remote_wakeup(dev: udev);
2391	}
2392
2393	/**
2394	* usb_hcd_resume_root_hub - called by HCD to resume its root hub
2395	* @hcd: host controller for this root hub
2396	*
2397	* The USB host controller calls this function when its root hub is
2398	* suspended (with the remote wakeup feature enabled) and a remote
2399	* wakeup request is received. The routine submits a workqueue request
2400	* to resume the root hub (that is, manage its downstream ports again).
2401	*/
2402	void usb_hcd_resume_root_hub (struct usb_hcd *hcd)
2403	{
2404	unsigned long flags;
2405
2406	spin_lock_irqsave (&hcd_root_hub_lock, flags);
2407	if (hcd->rh_registered) {
2408	pm_wakeup_event(dev: &hcd->self.root_hub->dev, msec: `0`);
2409	set_bit(HCD_FLAG_WAKEUP_PENDING, addr: &hcd->flags);
2410	queue_work(wq: pm_wq, work: &hcd->wakeup_work);
2411	}
2412	spin_unlock_irqrestore (lock: &hcd_root_hub_lock, flags);
2413	}
2414	EXPORT_SYMBOL_GPL(usb_hcd_resume_root_hub);
2415
2416	#endif /* CONFIG_PM */
2417
2418	/-------------------------------------------------------------------------/
2419
2420	#ifdef CONFIG_USB_OTG
2421
2422	/**
2423	* usb_bus_start_enum - start immediate enumeration (for OTG)
2424	* @bus: the bus (must use hcd framework)
2425	* @port_num: 1-based number of port; usually bus->otg_port
2426	* Context: atomic
2427	*
2428	* Starts enumeration, with an immediate reset followed later by
2429	* hub_wq identifying and possibly configuring the device.
2430	* This is needed by OTG controller drivers, where it helps meet
2431	* HNP protocol timing requirements for starting a port reset.
2432	*
2433	* Return: 0 if successful.
2434	*/
2435	int usb_bus_start_enum(struct usb_bus bus, unsigned* port_num)
2436	{
2437	struct usb_hcd *hcd;
2438	int status = -EOPNOTSUPP;
2439
2440	/ NOTE: since HNP can't start by grabbing the bus's address0_sem,*
2441	* boards with root hubs hooked up to internal devices (instead of
2442	* just the OTG port) may need more attention to resetting...
2443	*/
2444	hcd = bus_to_hcd(bus);
2445	if (port_num && hcd->driver->start_port_reset)
2446	status = hcd->driver->start_port_reset(hcd, port_num);
2447
2448	/ allocate hub_wq shortly after (first) root port reset finishes;*
2449	* it may issue others, until at least 50 msecs have passed.
2450	*/
2451	if (status == `0`)
2452	mod_timer(&hcd->rh_timer, jiffies + msecs_to_jiffies(`10`));
2453	return status;
2454	}
2455	EXPORT_SYMBOL_GPL(usb_bus_start_enum);
2456
2457	#endif
2458
2459	/-------------------------------------------------------------------------/
2460
2461	/**
2462	* usb_hcd_irq - hook IRQs to HCD framework (bus glue)
2463	* @irq: the IRQ being raised
2464	* @__hcd: pointer to the HCD whose IRQ is being signaled
2465	*
2466	* If the controller isn't HALTed, calls the driver's irq handler.
2467	* Checks whether the controller is now dead.
2468	*
2469	* Return: %IRQ_HANDLED if the IRQ was handled. %IRQ_NONE otherwise.
2470	*/
2471	irqreturn_t usb_hcd_irq (int irq, void *__hcd)
2472	{
2473	struct usb_hcd *hcd = __hcd;
2474	irqreturn_t rc;
2475
2476	if (unlikely(HCD_DEAD(hcd) \|\| !HCD_HW_ACCESSIBLE(hcd)))
2477	rc = IRQ_NONE;
2478	else if (hcd->driver->irq(hcd) == IRQ_NONE)
2479	rc = IRQ_NONE;
2480	else
2481	rc = IRQ_HANDLED;
2482
2483	return rc;
2484	}
2485	EXPORT_SYMBOL_GPL(usb_hcd_irq);
2486
2487	/-------------------------------------------------------------------------/
2488
2489	/ Workqueue routine for when the root-hub has died. /
2490	static void hcd_died_work(struct work_struct *work)
2491	{
2492	struct usb_hcd hcd = container_of(work, struct* usb_hcd, died_work);
2493	static char *env[] = {
2494	"ERROR=DEAD",
2495	NULL
2496	};
2497
2498	/ Notify user space that the host controller has died /
2499	kobject_uevent_env(kobj: &hcd->self.root_hub->dev.kobj, action: KOBJ_OFFLINE, envp: env);
2500	}
2501
2502	/**
2503	* usb_hc_died - report abnormal shutdown of a host controller (bus glue)
2504	* @hcd: pointer to the HCD representing the controller
2505	*
2506	* This is called by bus glue to report a USB host controller that died
2507	* while operations may still have been pending. It's called automatically
2508	* by the PCI glue, so only glue for non-PCI busses should need to call it.
2509	*
2510	* Only call this function with the primary HCD.
2511	*/
2512	void usb_hc_died (struct usb_hcd *hcd)
2513	{
2514	unsigned long flags;
2515
2516	dev_err (hcd->self.controller, "HC died; cleaning up\n");
2517
2518	spin_lock_irqsave (&hcd_root_hub_lock, flags);
2519	clear_bit(HCD_FLAG_RH_RUNNING, addr: &hcd->flags);
2520	set_bit(HCD_FLAG_DEAD, addr: &hcd->flags);
2521	if (hcd->rh_registered) {
2522	clear_bit(HCD_FLAG_POLL_RH, addr: &hcd->flags);
2523
2524	/ make hub_wq clean up old urbs and devices /
2525	usb_set_device_state (udev: hcd->self.root_hub,
2526	new_state: USB_STATE_NOTATTACHED);
2527	usb_kick_hub_wq(dev: hcd->self.root_hub);
2528	}
2529	if (usb_hcd_is_primary_hcd(hcd) && hcd->shared_hcd) {
2530	hcd = hcd->shared_hcd;
2531	clear_bit(HCD_FLAG_RH_RUNNING, addr: &hcd->flags);
2532	set_bit(HCD_FLAG_DEAD, addr: &hcd->flags);
2533	if (hcd->rh_registered) {
2534	clear_bit(HCD_FLAG_POLL_RH, addr: &hcd->flags);
2535
2536	/ make hub_wq clean up old urbs and devices /
2537	usb_set_device_state(udev: hcd->self.root_hub,
2538	new_state: USB_STATE_NOTATTACHED);
2539	usb_kick_hub_wq(dev: hcd->self.root_hub);
2540	}
2541	}
2542
2543	/ Handle the case where this function gets called with a shared HCD /
2544	if (usb_hcd_is_primary_hcd(hcd))
2545	schedule_work(work: &hcd->died_work);
2546	else
2547	schedule_work(work: &hcd->primary_hcd->died_work);
2548
2549	spin_unlock_irqrestore (lock: &hcd_root_hub_lock, flags);
2550	/ Make sure that the other roothub is also deallocated. /
2551	}
2552	EXPORT_SYMBOL_GPL (usb_hc_died);
2553
2554	/-------------------------------------------------------------------------/
2555
2556	static void init_giveback_urb_bh(struct giveback_urb_bh *bh)
2557	{
2558
2559	spin_lock_init(&bh->lock);
2560	INIT_LIST_HEAD(list: &bh->head);
2561	INIT_WORK(&bh->bh, usb_giveback_urb_bh);
2562	}
2563
2564	struct usb_hcd __usb_create_hcd(const* struct hc_driver *driver,
2565	struct device sysdev, struct* device dev, const* char *bus_name,
2566	struct usb_hcd *primary_hcd)
2567	{
2568	struct usb_hcd *hcd;
2569
2570	hcd = kzalloc(sizeof(*hcd) + driver->hcd_priv_size, GFP_KERNEL);
2571	if (!hcd)
2572	return NULL;
2573	if (primary_hcd == NULL) {
2574	hcd->address0_mutex = kmalloc(sizeof(*hcd->address0_mutex),
2575	GFP_KERNEL);
2576	if (!hcd->address0_mutex) {
2577	kfree(objp: hcd);
2578	dev_dbg(dev, "hcd address0 mutex alloc failed\n");
2579	return NULL;
2580	}
2581	mutex_init(hcd->address0_mutex);
2582	hcd->bandwidth_mutex = kmalloc(sizeof(*hcd->bandwidth_mutex),
2583	GFP_KERNEL);
2584	if (!hcd->bandwidth_mutex) {
2585	kfree(objp: hcd->address0_mutex);
2586	kfree(objp: hcd);
2587	dev_dbg(dev, "hcd bandwidth mutex alloc failed\n");
2588	return NULL;
2589	}
2590	mutex_init(hcd->bandwidth_mutex);
2591	dev_set_drvdata(dev, data: hcd);
2592	} else {
2593	mutex_lock(lock: &usb_port_peer_mutex);
2594	hcd->address0_mutex = primary_hcd->address0_mutex;
2595	hcd->bandwidth_mutex = primary_hcd->bandwidth_mutex;
2596	hcd->primary_hcd = primary_hcd;
2597	primary_hcd->primary_hcd = primary_hcd;
2598	hcd->shared_hcd = primary_hcd;
2599	primary_hcd->shared_hcd = hcd;
2600	mutex_unlock(lock: &usb_port_peer_mutex);
2601	}
2602
2603	kref_init(kref: &hcd->kref);
2604
2605	usb_bus_init(bus: &hcd->self);
2606	hcd->self.controller = dev;
2607	hcd->self.sysdev = sysdev;
2608	hcd->self.bus_name = bus_name;
2609
2610	timer_setup(&hcd->rh_timer, rh_timer_func, `0`);
2611	#ifdef CONFIG_PM
2612	INIT_WORK(&hcd->wakeup_work, hcd_resume_work);
2613	#endif
2614
2615	INIT_WORK(&hcd->died_work, hcd_died_work);
2616
2617	hcd->driver = driver;
2618	hcd->speed = driver->flags & HCD_MASK;
2619	hcd->product_desc = (driver->product_desc) ? driver->product_desc :
2620	"USB Host Controller";
2621	return hcd;
2622	}
2623	EXPORT_SYMBOL_GPL(__usb_create_hcd);
2624
2625	/**
2626	* usb_create_shared_hcd - create and initialize an HCD structure
2627	* @driver: HC driver that will use this hcd
2628	* @dev: device for this HC, stored in hcd->self.controller
2629	* @bus_name: value to store in hcd->self.bus_name
2630	* @primary_hcd: a pointer to the usb_hcd structure that is sharing the
2631	* PCI device. Only allocate certain resources for the primary HCD
2632	*
2633	* Context: task context, might sleep.
2634	*
2635	* Allocate a struct usb_hcd, with extra space at the end for the
2636	* HC driver's private data. Initialize the generic members of the
2637	* hcd structure.
2638	*
2639	* Return: On success, a pointer to the created and initialized HCD structure.
2640	* On failure (e.g. if memory is unavailable), %NULL.
2641	*/
2642	struct usb_hcd usb_create_shared_hcd(const* struct hc_driver *driver,
2643	struct device dev, const* char *bus_name,
2644	struct usb_hcd *primary_hcd)
2645	{
2646	return __usb_create_hcd(driver, dev, dev, bus_name, primary_hcd);
2647	}
2648	EXPORT_SYMBOL_GPL(usb_create_shared_hcd);
2649
2650	/**
2651	* usb_create_hcd - create and initialize an HCD structure
2652	* @driver: HC driver that will use this hcd
2653	* @dev: device for this HC, stored in hcd->self.controller
2654	* @bus_name: value to store in hcd->self.bus_name
2655	*
2656	* Context: task context, might sleep.
2657	*
2658	* Allocate a struct usb_hcd, with extra space at the end for the
2659	* HC driver's private data. Initialize the generic members of the
2660	* hcd structure.
2661	*
2662	* Return: On success, a pointer to the created and initialized HCD
2663	* structure. On failure (e.g. if memory is unavailable), %NULL.
2664	*/
2665	struct usb_hcd usb_create_hcd(const* struct hc_driver *driver,
2666	struct device dev, const* char *bus_name)
2667	{
2668	return __usb_create_hcd(driver, dev, dev, bus_name, NULL);
2669	}
2670	EXPORT_SYMBOL_GPL(usb_create_hcd);
2671
2672	/*
2673	* Roothubs that share one PCI device must also share the bandwidth mutex.
2674	* Don't deallocate the bandwidth_mutex until the last shared usb_hcd is
2675	* deallocated.
2676	*
2677	* Make sure to deallocate the bandwidth_mutex only when the last HCD is
2678	* freed. When hcd_release() is called for either hcd in a peer set,
2679	* invalidate the peer's ->shared_hcd and ->primary_hcd pointers.
2680	*/
2681	static void hcd_release(struct kref *kref)
2682	{
2683	struct usb_hcd hcd = container_of (kref, struct* usb_hcd, kref);
2684
2685	mutex_lock(lock: &usb_port_peer_mutex);
2686	if (hcd->shared_hcd) {
2687	struct usb_hcd *peer = hcd->shared_hcd;
2688
2689	peer->shared_hcd = NULL;
2690	peer->primary_hcd = NULL;
2691	} else {
2692	kfree(objp: hcd->address0_mutex);
2693	kfree(objp: hcd->bandwidth_mutex);
2694	}
2695	mutex_unlock(lock: &usb_port_peer_mutex);
2696	kfree(objp: hcd);
2697	}
2698
2699	struct usb_hcd usb_get_hcd (struct* usb_hcd *hcd)
2700	{
2701	if (hcd)
2702	kref_get (kref: &hcd->kref);
2703	return hcd;
2704	}
2705	EXPORT_SYMBOL_GPL(usb_get_hcd);
2706
2707	void usb_put_hcd (struct usb_hcd *hcd)
2708	{
2709	if (hcd)
2710	kref_put (kref: &hcd->kref, release: hcd_release);
2711	}
2712	EXPORT_SYMBOL_GPL(usb_put_hcd);
2713
2714	int usb_hcd_is_primary_hcd(struct usb_hcd *hcd)
2715	{
2716	if (!hcd->primary_hcd)
2717	return `1`;
2718	return hcd == hcd->primary_hcd;
2719	}
2720	EXPORT_SYMBOL_GPL(usb_hcd_is_primary_hcd);
2721
2722	int usb_hcd_find_raw_port_number(struct usb_hcd hcd, int* port1)
2723	{
2724	if (!hcd->driver->find_raw_port_number)
2725	return port1;
2726
2727	return hcd->driver->find_raw_port_number(hcd, port1);
2728	}
2729
2730	static int usb_hcd_request_irqs(struct usb_hcd *hcd,
2731	unsigned int irqnum, unsigned long irqflags)
2732	{
2733	int retval;
2734
2735	if (hcd->driver->irq) {
2736
2737	snprintf(buf: hcd->irq_descr, size: sizeof(hcd->irq_descr), fmt: "%s:usb%d",
2738	hcd->driver->description, hcd->self.busnum);
2739	retval = request_irq(irq: irqnum, handler: &usb_hcd_irq, flags: irqflags,
2740	name: hcd->irq_descr, dev: hcd);
2741	if (retval != `0`) {
2742	dev_err(hcd->self.controller,
2743	"request interrupt %d failed\n",
2744	irqnum);
2745	return retval;
2746	}
2747	hcd->irq = irqnum;
2748	dev_info(hcd->self.controller, "irq %d, %s 0x%08llx\n", irqnum,
2749	(hcd->driver->flags & HCD_MEMORY) ?
2750	"io mem" : "io port",
2751	(unsigned long long)hcd->rsrc_start);
2752	} else {
2753	hcd->irq = `0`;
2754	if (hcd->rsrc_start)
2755	dev_info(hcd->self.controller, "%s 0x%08llx\n",
2756	(hcd->driver->flags & HCD_MEMORY) ?
2757	"io mem" : "io port",
2758	(unsigned long long)hcd->rsrc_start);
2759	}
2760	return `0`;
2761	}
2762
2763	/*
2764	* Before we free this root hub, flush in-flight peering attempts
2765	* and disable peer lookups
2766	*/
2767	static void usb_put_invalidate_rhdev(struct usb_hcd *hcd)
2768	{
2769	struct usb_device *rhdev;
2770
2771	mutex_lock(lock: &usb_port_peer_mutex);
2772	rhdev = hcd->self.root_hub;
2773	hcd->self.root_hub = NULL;
2774	mutex_unlock(lock: &usb_port_peer_mutex);
2775	usb_put_dev(dev: rhdev);
2776	}
2777
2778	/**
2779	* usb_stop_hcd - Halt the HCD
2780	* @hcd: the usb_hcd that has to be halted
2781	*
2782	* Stop the root-hub polling timer and invoke the HCD's ->stop callback.
2783	*/
2784	static void usb_stop_hcd(struct usb_hcd *hcd)
2785	{
2786	hcd->rh_pollable = `0`;
2787	clear_bit(HCD_FLAG_POLL_RH, addr: &hcd->flags);
2788	timer_delete_sync(timer: &hcd->rh_timer);
2789
2790	hcd->driver->stop(hcd);
2791	hcd->state = HC_STATE_HALT;
2792
2793	/ In case the HCD restarted the timer, stop it again. /
2794	clear_bit(HCD_FLAG_POLL_RH, addr: &hcd->flags);
2795	timer_delete_sync(timer: &hcd->rh_timer);
2796	}
2797
2798	/**
2799	* usb_add_hcd - finish generic HCD structure initialization and register
2800	* @hcd: the usb_hcd structure to initialize
2801	* @irqnum: Interrupt line to allocate
2802	* @irqflags: Interrupt type flags
2803	*
2804	* Finish the remaining parts of generic HCD initialization: allocate the
2805	* buffers of consistent memory, register the bus, request the IRQ line,
2806	* and call the driver's reset() and start() routines.
2807	*/
2808	int usb_add_hcd(struct usb_hcd *hcd,
2809	unsigned int irqnum, unsigned long irqflags)
2810	{
2811	int retval;
2812	struct usb_device *rhdev;
2813	struct usb_hcd *shared_hcd;
2814	int skip_phy_initialization;
2815
2816	if (usb_hcd_is_primary_hcd(hcd))
2817	skip_phy_initialization = hcd->skip_phy_initialization;
2818	else
2819	skip_phy_initialization = hcd->primary_hcd->skip_phy_initialization;
2820
2821	if (!skip_phy_initialization) {
2822	if (usb_hcd_is_primary_hcd(hcd)) {
2823	hcd->phy_roothub = usb_phy_roothub_alloc(dev: hcd->self.sysdev);
2824	if (IS_ERR(ptr: hcd->phy_roothub))
2825	return PTR_ERR(ptr: hcd->phy_roothub);
2826	} else {
2827	hcd->phy_roothub = usb_phy_roothub_alloc_usb3_phy(dev: hcd->self.sysdev);
2828	if (IS_ERR(ptr: hcd->phy_roothub))
2829	return PTR_ERR(ptr: hcd->phy_roothub);
2830	}
2831
2832	retval = usb_phy_roothub_init(phy_roothub: hcd->phy_roothub);
2833	if (retval)
2834	return retval;
2835
2836	retval = usb_phy_roothub_set_mode(phy_roothub: hcd->phy_roothub,
2837	mode: PHY_MODE_USB_HOST_SS);
2838	if (retval)
2839	retval = usb_phy_roothub_set_mode(phy_roothub: hcd->phy_roothub,
2840	mode: PHY_MODE_USB_HOST);
2841	if (retval)
2842	goto err_usb_phy_roothub_power_on;
2843
2844	retval = usb_phy_roothub_power_on(phy_roothub: hcd->phy_roothub);
2845	if (retval)
2846	goto err_usb_phy_roothub_power_on;
2847	}
2848
2849	dev_info(hcd->self.controller, "%s\n", hcd->product_desc);
2850
2851	switch (authorized_default) {
2852	case USB_AUTHORIZE_NONE:
2853	hcd->dev_policy = USB_DEVICE_AUTHORIZE_NONE;
2854	break;
2855
2856	case USB_AUTHORIZE_INTERNAL:
2857	hcd->dev_policy = USB_DEVICE_AUTHORIZE_INTERNAL;
2858	break;
2859
2860	case USB_AUTHORIZE_ALL:
2861	case USB_AUTHORIZE_WIRED:
2862	default:
2863	hcd->dev_policy = USB_DEVICE_AUTHORIZE_ALL;
2864	break;
2865	}
2866
2867	set_bit(HCD_FLAG_HW_ACCESSIBLE, addr: &hcd->flags);
2868
2869	/ per default all interfaces are authorized /
2870	set_bit(HCD_FLAG_INTF_AUTHORIZED, addr: &hcd->flags);
2871
2872	/ HC is in reset state, but accessible. Now do the one-time init,*
2873	* bottom up so that hcds can customize the root hubs before hub_wq
2874	* starts talking to them. (Note, bus id is assigned early too.)
2875	*/
2876	retval = hcd_buffer_create(hcd);
2877	if (retval != `0`) {
2878	dev_dbg(hcd->self.sysdev, "pool alloc failed\n");
2879	goto err_create_buf;
2880	}
2881
2882	retval = usb_register_bus(bus: &hcd->self);
2883	if (retval < `0`)
2884	goto err_register_bus;
2885
2886	rhdev = usb_alloc_dev(NULL, &hcd->self, port: `0`);
2887	if (rhdev == NULL) {
2888	dev_err(hcd->self.sysdev, "unable to allocate root hub\n");
2889	retval = -ENOMEM;
2890	goto err_allocate_root_hub;
2891	}
2892	mutex_lock(lock: &usb_port_peer_mutex);
2893	hcd->self.root_hub = rhdev;
2894	mutex_unlock(lock: &usb_port_peer_mutex);
2895
2896	rhdev->rx_lanes = `1`;
2897	rhdev->tx_lanes = `1`;
2898	rhdev->ssp_rate = USB_SSP_GEN_UNKNOWN;
2899
2900	switch (hcd->speed) {
2901	case HCD_USB11:
2902	rhdev->speed = USB_SPEED_FULL;
2903	break;
2904	case HCD_USB2:
2905	rhdev->speed = USB_SPEED_HIGH;
2906	break;
2907	case HCD_USB3:
2908	rhdev->speed = USB_SPEED_SUPER;
2909	break;
2910	case HCD_USB32:
2911	rhdev->rx_lanes = `2`;
2912	rhdev->tx_lanes = `2`;
2913	rhdev->ssp_rate = USB_SSP_GEN_2x2;
2914	rhdev->speed = USB_SPEED_SUPER_PLUS;
2915	break;
2916	case HCD_USB31:
2917	rhdev->ssp_rate = USB_SSP_GEN_2x1;
2918	rhdev->speed = USB_SPEED_SUPER_PLUS;
2919	break;
2920	default:
2921	retval = -EINVAL;
2922	goto err_set_rh_speed;
2923	}
2924
2925	/ wakeup flag init defaults to "everything works" for root hubs,*
2926	* but drivers can override it in reset() if needed, along with
2927	* recording the overall controller's system wakeup capability.
2928	*/
2929	device_set_wakeup_capable(dev: &rhdev->dev, capable: `1`);
2930
2931	/ HCD_FLAG_RH_RUNNING doesn't matter until the root hub is*
2932	* registered. But since the controller can die at any time,
2933	* let's initialize the flag before touching the hardware.
2934	*/
2935	set_bit(HCD_FLAG_RH_RUNNING, addr: &hcd->flags);
2936
2937	/ "reset" is misnamed; its role is now one-time init. the controller*
2938	* should already have been reset (and boot firmware kicked off etc).
2939	*/
2940	if (hcd->driver->reset) {
2941	retval = hcd->driver->reset(hcd);
2942	if (retval < `0`) {
2943	dev_err(hcd->self.controller, "can't setup: %d\n",
2944	retval);
2945	goto err_hcd_driver_setup;
2946	}
2947	}
2948	hcd->rh_pollable = `1`;
2949
2950	retval = usb_phy_roothub_calibrate(phy_roothub: hcd->phy_roothub);
2951	if (retval)
2952	goto err_hcd_driver_setup;
2953
2954	/ NOTE: root hub and controller capabilities may not be the same /
2955	if (device_can_wakeup(dev: hcd->self.controller)
2956	&& device_can_wakeup(dev: &hcd->self.root_hub->dev))
2957	dev_dbg(hcd->self.controller, "supports USB remote wakeup\n");
2958
2959	/ initialize BHs /
2960	init_giveback_urb_bh(bh: &hcd->high_prio_bh);
2961	hcd->high_prio_bh.high_prio = true;
2962	init_giveback_urb_bh(bh: &hcd->low_prio_bh);
2963
2964	/ enable irqs just before we start the controller,*
2965	* if the BIOS provides legacy PCI irqs.
2966	*/
2967	if (usb_hcd_is_primary_hcd(hcd) && irqnum) {
2968	retval = usb_hcd_request_irqs(hcd, irqnum, irqflags);
2969	if (retval)
2970	goto err_request_irq;
2971	}
2972
2973	hcd->state = HC_STATE_RUNNING;
2974	retval = hcd->driver->start(hcd);
2975	if (retval < `0`) {
2976	dev_err(hcd->self.controller, "startup error %d\n", retval);
2977	goto err_hcd_driver_start;
2978	}
2979
2980	/ starting here, usbcore will pay attention to the shared HCD roothub /
2981	shared_hcd = hcd->shared_hcd;
2982	if (!usb_hcd_is_primary_hcd(hcd) && shared_hcd && HCD_DEFER_RH_REGISTER(shared_hcd)) {
2983	retval = register_root_hub(hcd: shared_hcd);
2984	if (retval != `0`)
2985	goto err_register_root_hub;
2986
2987	if (shared_hcd->uses_new_polling && HCD_POLL_RH(shared_hcd))
2988	usb_hcd_poll_rh_status(shared_hcd);
2989	}
2990
2991	/ starting here, usbcore will pay attention to this root hub /
2992	if (!HCD_DEFER_RH_REGISTER(hcd)) {
2993	retval = register_root_hub(hcd);
2994	if (retval != `0`)
2995	goto err_register_root_hub;
2996
2997	if (hcd->uses_new_polling && HCD_POLL_RH(hcd))
2998	usb_hcd_poll_rh_status(hcd);
2999	}
3000
3001	return retval;
3002
3003	err_register_root_hub:
3004	usb_stop_hcd(hcd);
3005	err_hcd_driver_start:
3006	if (usb_hcd_is_primary_hcd(hcd) && hcd->irq > `0`)
3007	free_irq(irqnum, hcd);
3008	err_request_irq:
3009	err_hcd_driver_setup:
3010	err_set_rh_speed:
3011	usb_put_invalidate_rhdev(hcd);
3012	err_allocate_root_hub:
3013	usb_deregister_bus(bus: &hcd->self);
3014	err_register_bus:
3015	hcd_buffer_destroy(hcd);
3016	err_create_buf:
3017	usb_phy_roothub_power_off(phy_roothub: hcd->phy_roothub);
3018	err_usb_phy_roothub_power_on:
3019	usb_phy_roothub_exit(phy_roothub: hcd->phy_roothub);
3020
3021	return retval;
3022	}
3023	EXPORT_SYMBOL_GPL(usb_add_hcd);
3024
3025	/**
3026	* usb_remove_hcd - shutdown processing for generic HCDs
3027	* @hcd: the usb_hcd structure to remove
3028	*
3029	* Context: task context, might sleep.
3030	*
3031	* Disconnects the root hub, then reverses the effects of usb_add_hcd(),
3032	* invoking the HCD's stop() method.
3033	*/
3034	void usb_remove_hcd(struct usb_hcd *hcd)
3035	{
3036	struct usb_device *rhdev;
3037	bool rh_registered;
3038
3039	if (!hcd) {
3040	pr_debug("%s: hcd is NULL\n", __func__);
3041	return;
3042	}
3043	rhdev = hcd->self.root_hub;
3044
3045	dev_info(hcd->self.controller, "remove, state %x\n", hcd->state);
3046
3047	usb_get_dev(dev: rhdev);
3048	clear_bit(HCD_FLAG_RH_RUNNING, addr: &hcd->flags);
3049	if (HC_IS_RUNNING (hcd->state))
3050	hcd->state = HC_STATE_QUIESCING;
3051
3052	dev_dbg(hcd->self.controller, "roothub graceful disconnect\n");
3053	spin_lock_irq (lock: &hcd_root_hub_lock);
3054	rh_registered = hcd->rh_registered;
3055	hcd->rh_registered = `0`;
3056	spin_unlock_irq (lock: &hcd_root_hub_lock);
3057
3058	#ifdef CONFIG_PM
3059	cancel_work_sync(work: &hcd->wakeup_work);
3060	#endif
3061	cancel_work_sync(work: &hcd->died_work);
3062
3063	mutex_lock(lock: &usb_bus_idr_lock);
3064	if (rh_registered)
3065	usb_disconnect(&rhdev); / Sets rhdev to NULL /
3066	mutex_unlock(lock: &usb_bus_idr_lock);
3067
3068	/*
3069	* flush_work() isn't needed here because:
3070	* - driver's disconnect() called from usb_disconnect() should
3071	* make sure its URBs are completed during the disconnect()
3072	* callback
3073	*
3074	* - it is too late to run complete() here since driver may have
3075	* been removed already now
3076	*/
3077
3078	/ Prevent any more root-hub status calls from the timer.*
3079	* The HCD might still restart the timer (if a port status change
3080	* interrupt occurs), but usb_hcd_poll_rh_status() won't invoke
3081	* the hub_status_data() callback.
3082	*/
3083	usb_stop_hcd(hcd);
3084
3085	if (usb_hcd_is_primary_hcd(hcd)) {
3086	if (hcd->irq > `0`)
3087	free_irq(hcd->irq, hcd);
3088	}
3089
3090	usb_deregister_bus(bus: &hcd->self);
3091	hcd_buffer_destroy(hcd);
3092
3093	usb_phy_roothub_power_off(phy_roothub: hcd->phy_roothub);
3094	usb_phy_roothub_exit(phy_roothub: hcd->phy_roothub);
3095
3096	usb_put_invalidate_rhdev(hcd);
3097	hcd->flags = `0`;
3098	}
3099	EXPORT_SYMBOL_GPL(usb_remove_hcd);
3100
3101	void
3102	usb_hcd_platform_shutdown(struct platform_device *dev)
3103	{
3104	struct usb_hcd *hcd = platform_get_drvdata(pdev: dev);
3105
3106	/ No need for pm_runtime_put(), we're shutting down /
3107	pm_runtime_get_sync(dev: &dev->dev);
3108
3109	if (hcd->driver->shutdown)
3110	hcd->driver->shutdown(hcd);
3111	}
3112	EXPORT_SYMBOL_GPL(usb_hcd_platform_shutdown);
3113
3114	int usb_hcd_setup_local_mem(struct usb_hcd *hcd, phys_addr_t phys_addr,
3115	dma_addr_t dma, size_t size)
3116	{
3117	int err;
3118	void *local_mem;
3119
3120	hcd->localmem_pool = devm_gen_pool_create(dev: hcd->self.sysdev, min_alloc_order: `4`,
3121	nid: dev_to_node(dev: hcd->self.sysdev),
3122	name: dev_name(dev: hcd->self.sysdev));
3123	if (IS_ERR(ptr: hcd->localmem_pool))
3124	return PTR_ERR(ptr: hcd->localmem_pool);
3125
3126	/*
3127	* if a physical SRAM address was passed, map it, otherwise
3128	* allocate system memory as a buffer.
3129	*/
3130	if (phys_addr)
3131	local_mem = devm_memremap(dev: hcd->self.sysdev, offset: phys_addr,
3132	size, flags: MEMREMAP_WC);
3133	else
3134	local_mem = dmam_alloc_attrs(dev: hcd->self.sysdev, size, dma_handle: &dma,
3135	GFP_KERNEL,
3136	DMA_ATTR_WRITE_COMBINE);
3137
3138	if (IS_ERR_OR_NULL(ptr: local_mem)) {
3139	if (!local_mem)
3140	return -ENOMEM;
3141
3142	return PTR_ERR(ptr: local_mem);
3143	}
3144
3145	/*
3146	* Here we pass a dma_addr_t but the arg type is a phys_addr_t.
3147	* It's not backed by system memory and thus there's no kernel mapping
3148	* for it.
3149	*/
3150	err = gen_pool_add_virt(pool: hcd->localmem_pool, addr: (unsigned long)local_mem,
3151	phys: dma, size, nid: dev_to_node(dev: hcd->self.sysdev));
3152	if (err < `0`) {
3153	dev_err(hcd->self.sysdev, "gen_pool_add_virt failed with %d\n",
3154	err);
3155	return err;
3156	}
3157
3158	return `0`;
3159	}
3160	EXPORT_SYMBOL_GPL(usb_hcd_setup_local_mem);
3161
3162	/-------------------------------------------------------------------------/
3163
3164	#if IS_ENABLED(CONFIG_USB_MON)
3165
3166	const struct usb_mon_operations *mon_ops;
3167
3168	/*
3169	* The registration is unlocked.
3170	* We do it this way because we do not want to lock in hot paths.
3171	*
3172	* Notice that the code is minimally error-proof. Because usbmon needs
3173	* symbols from usbcore, usbcore gets referenced and cannot be unloaded first.
3174	*/
3175
3176	int usb_mon_register(const struct usb_mon_operations *ops)
3177	{
3178
3179	if (mon_ops)
3180	return -EBUSY;
3181
3182	mon_ops = ops;
3183	mb();
3184	return `0`;
3185	}
3186	EXPORT_SYMBOL_GPL (usb_mon_register);
3187
3188	void usb_mon_deregister (void)
3189	{
3190
3191	if (mon_ops == NULL) {
3192	printk(KERN_ERR "USB: monitor was not registered\n");
3193	return;
3194	}
3195	mon_ops = NULL;
3196	mb();
3197	}
3198	EXPORT_SYMBOL_GPL (usb_mon_deregister);
3199
3200	#endif /* CONFIG_USB_MON \|\| CONFIG_USB_MON_MODULE */
3201

Browse the source code of Linux/drivers/usb/core/hcd.c