[GitHub/mt8127/android_kernel_alcatel_ttab.git] / Documentation / usb / URB.txt

Revised: 2000-Dec-05.
Again:   2002-Jul-06
Again:   2005-Sep-19

    NOTE:

    The USB subsystem now has a substantial section in "The Linux Kernel API"
    guide (in Documentation/DocBook), generated from the current source
    code.  This particular documentation file isn't particularly current or
    complete; don't rely on it except for a quick overview.


1.1. Basic concept or 'What is an URB?'

The basic idea of the new driver is message passing, the message itself is 
called USB Request Block, or URB for short. 

- An URB consists of all relevant information to execute any USB transaction 
  and deliver the data and status back. 

- Execution of an URB is inherently an asynchronous operation, i.e. the 
  usb_submit_urb(urb) call returns immediately after it has successfully
  queued the requested action.

- Transfers for one URB can be canceled with usb_unlink_urb(urb) at any time. 

- Each URB has a completion handler, which is called after the action
  has been successfully completed or canceled. The URB also contains a
  context-pointer for passing information to the completion handler.

- Each endpoint for a device logically supports a queue of requests.
  You can fill that queue, so that the USB hardware can still transfer
  data to an endpoint while your driver handles completion of another.
  This maximizes use of USB bandwidth, and supports seamless streaming
  of data to (or from) devices when using periodic transfer modes.


1.2. The URB structure

Some of the fields in an URB are:

struct urb
{
// (IN) device and pipe specify the endpoint queue
	struct usb_device *dev;         // pointer to associated USB device
	unsigned int pipe;              // endpoint information

	unsigned int transfer_flags;    // ISO_ASAP, SHORT_NOT_OK, etc.

// (IN) all urbs need completion routines
	void *context;                  // context for completion routine
	void (*complete)(struct urb *); // pointer to completion routine

// (OUT) status after each completion
	int status;                     // returned status

// (IN) buffer used for data transfers
	void *transfer_buffer;          // associated data buffer
	int transfer_buffer_length;     // data buffer length
	int number_of_packets;          // size of iso_frame_desc

// (OUT) sometimes only part of CTRL/BULK/INTR transfer_buffer is used
	int actual_length;              // actual data buffer length

// (IN) setup stage for CTRL (pass a struct usb_ctrlrequest)
	unsigned char* setup_packet;    // setup packet (control only)

// Only for PERIODIC transfers (ISO, INTERRUPT)
    // (IN/OUT) start_frame is set unless ISO_ASAP isn't set
	int start_frame;                // start frame
	int interval;                   // polling interval

    // ISO only: packets are only "best effort"; each can have errors
	int error_count;                // number of errors
	struct usb_iso_packet_descriptor iso_frame_desc[0];
};

Your driver must create the "pipe" value using values from the appropriate
endpoint descriptor in an interface that it's claimed.


1.3. How to get an URB?

URBs are allocated with the following call

	struct urb *usb_alloc_urb(int isoframes, int mem_flags)

Return value is a pointer to the allocated URB, 0 if allocation failed.
The parameter isoframes specifies the number of isochronous transfer frames
you want to schedule. For CTRL/BULK/INT, use 0.  The mem_flags parameter
holds standard memory allocation flags, letting you control (among other
things) whether the underlying code may block or not.

To free an URB, use

	void usb_free_urb(struct urb *urb)

You may free an urb that you've submitted, but which hasn't yet been
returned to you in a completion callback.  It will automatically be
deallocated when it is no longer in use.


1.4. What has to be filled in?

Depending on the type of transaction, there are some inline functions 
defined in <linux/usb.h> to simplify the initialization, such as
fill_control_urb() and fill_bulk_urb().  In general, they need the usb
device pointer, the pipe (usual format from usb.h), the transfer buffer,
the desired transfer length, the completion  handler, and its context. 
Take a look at the some existing drivers to see how they're used.

Flags:
For ISO there are two startup behaviors: Specified start_frame or ASAP.
For ASAP set URB_ISO_ASAP in transfer_flags.

If short packets should NOT be tolerated, set URB_SHORT_NOT_OK in 
transfer_flags.


1.5. How to submit an URB?

Just call

	int usb_submit_urb(struct urb *urb, int mem_flags)

The mem_flags parameter, such as SLAB_ATOMIC, controls memory allocation,
such as whether the lower levels may block when memory is tight.

It immediately returns, either with status 0 (request queued) or some
error code, usually caused by the following:

- Out of memory (-ENOMEM)
- Unplugged device (-ENODEV)
- Stalled endpoint (-EPIPE)
- Too many queued ISO transfers (-EAGAIN)
- Too many requested ISO frames (-EFBIG)
- Invalid INT interval (-EINVAL)
- More than one packet for INT (-EINVAL)

After submission, urb->status is -EINPROGRESS; however, you should never
look at that value except in your completion callback.

For isochronous endpoints, your completion handlers should (re)submit
URBs to the same endpoint with the ISO_ASAP flag, using multi-buffering,
to get seamless ISO streaming.


1.6. How to cancel an already running URB?

There are two ways to cancel an URB you've submitted but which hasn't
been returned to your driver yet.  For an asynchronous cancel, call

	int usb_unlink_urb(struct urb *urb)

It removes the urb from the internal list and frees all allocated
HW descriptors. The status is changed to reflect unlinking.  Note
that the URB will not normally have finished when usb_unlink_urb()
returns; you must still wait for the completion handler to be called.

To cancel an URB synchronously, call

	void usb_kill_urb(struct urb *urb)

It does everything usb_unlink_urb does, and in addition it waits
until after the URB has been returned and the completion handler
has finished.  It also marks the URB as temporarily unusable, so
that if the completion handler or anyone else tries to resubmit it
they will get a -EPERM error.  Thus you can be sure that when
usb_kill_urb() returns, the URB is totally idle.

There is a lifetime issue to consider.  An URB may complete at any
time, and the completion handler may free the URB.  If this happens
while usb_unlink_urb or usb_kill_urb is running, it will cause a
memory-access violation.  The driver is responsible for avoiding this,
which often means some sort of lock will be needed to prevent the URB
from being deallocated while it is still in use.

On the other hand, since usb_unlink_urb may end up calling the
completion handler, the handler must not take any lock that is held
when usb_unlink_urb is invoked.  The general solution to this problem
is to increment the URB's reference count while holding the lock, then
drop the lock and call usb_unlink_urb or usb_kill_urb, and then
decrement the URB's reference count.  You increment the reference
count by calling

	struct urb *usb_get_urb(struct urb *urb)

(ignore the return value; it is the same as the argument) and
decrement the reference count by calling usb_free_urb.  Of course,
none of this is necessary if there's no danger of the URB being freed
by the completion handler.


1.7. What about the completion handler?

The handler is of the following type:

	typedef void (*usb_complete_t)(struct urb *, struct pt_regs *)

I.e., it gets the URB that caused the completion call, plus the
register values at the time of the corresponding interrupt (if any).
In the completion handler, you should have a look at urb->status to
detect any USB errors. Since the context parameter is included in the URB,
you can pass information to the completion handler. 

Note that even when an error (or unlink) is reported, data may have been
transferred.  That's because USB transfers are packetized; it might take
sixteen packets to transfer your 1KByte buffer, and ten of them might
have transferred successfully before the completion was called.


NOTE:  ***** WARNING *****
NEVER SLEEP IN A COMPLETION HANDLER.  These are normally called
during hardware interrupt processing.  If you can, defer substantial
work to a tasklet (bottom half) to keep system latencies low.  You'll
probably need to use spinlocks to protect data structures you manipulate
in completion handlers.


1.8. How to do isochronous (ISO) transfers?

For ISO transfers you have to fill a usb_iso_packet_descriptor structure,
allocated at the end of the URB by usb_alloc_urb(n,mem_flags), for each
packet you want to schedule.   You also have to set urb->interval to say
how often to make transfers; it's often one per frame (which is once
every microframe for highspeed devices).  The actual interval used will
be a power of two that's no bigger than what you specify.

The usb_submit_urb() call modifies urb->interval to the implemented interval
value that is less than or equal to the requested interval value.  If
ISO_ASAP scheduling is used, urb->start_frame is also updated.

For each entry you have to specify the data offset for this frame (base is
transfer_buffer), and the length you want to write/expect to read.
After completion, actual_length contains the actual transferred length and 
status contains the resulting status for the ISO transfer for this frame.
It is allowed to specify a varying length from frame to frame (e.g. for
audio synchronisation/adaptive transfer rates). You can also use the length 
0 to omit one or more frames (striping).

For scheduling you can choose your own start frame or ISO_ASAP. As explained
earlier, if you always keep at least one URB queued and your completion
keeps (re)submitting a later URB, you'll get smooth ISO streaming (if usb
bandwidth utilization allows).

If you specify your own start frame, make sure it's several frames in advance
of the current frame.  You might want this model if you're synchronizing
ISO data with some other event stream.


1.9. How to start interrupt (INT) transfers?

Interrupt transfers, like isochronous transfers, are periodic, and happen
in intervals that are powers of two (1, 2, 4 etc) units.  Units are frames
for full and low speed devices, and microframes for high speed ones.
The usb_submit_urb() call modifies urb->interval to the implemented interval
value that is less than or equal to the requested interval value.

In Linux 2.6, unlike earlier versions, interrupt URBs are not automagically
restarted when they complete.  They end when the completion handler is
called, just like other URBs.  If you want an interrupt URB to be restarted,
your completion handler must resubmit it.
Commit	Line	Data
1da177e4 LT	1	Revised: 2000-Dec-05.
1da177e4 LT	2	Again: 2002-Jul-06
0fc084ea	3	Again: 2005-Sep-19
1da177e4 LT	4
	5	NOTE:
	6
	7	The USB subsystem now has a substantial section in "The Linux Kernel API"
	8	guide (in Documentation/DocBook), generated from the current source
	9	code. This particular documentation file isn't particularly current or
	10	complete; don't rely on it except for a quick overview.
	11
	12
	13	1.1. Basic concept or 'What is an URB?'
	14
	15	The basic idea of the new driver is message passing, the message itself is
	16	called USB Request Block, or URB for short.
	17
	18	- An URB consists of all relevant information to execute any USB transaction
	19	and deliver the data and status back.
	20
	21	- Execution of an URB is inherently an asynchronous operation, i.e. the
0fc084ea AS	22	usb_submit_urb(urb) call returns immediately after it has successfully
0fc084ea AS	23	queued the requested action.
1da177e4 LT	24
	25	- Transfers for one URB can be canceled with usb_unlink_urb(urb) at any time.
	26
	27	- Each URB has a completion handler, which is called after the action
	28	has been successfully completed or canceled. The URB also contains a
	29	context-pointer for passing information to the completion handler.
	30
	31	- Each endpoint for a device logically supports a queue of requests.
	32	You can fill that queue, so that the USB hardware can still transfer
	33	data to an endpoint while your driver handles completion of another.
	34	This maximizes use of USB bandwidth, and supports seamless streaming
	35	of data to (or from) devices when using periodic transfer modes.
	36
	37
	38	1.2. The URB structure
	39
	40	Some of the fields in an URB are:
	41
	42	struct urb
	43	{
	44	// (IN) device and pipe specify the endpoint queue
	45	struct usb_device *dev; // pointer to associated USB device
	46	unsigned int pipe; // endpoint information
	47
	48	unsigned int transfer_flags; // ISO_ASAP, SHORT_NOT_OK, etc.
	49
	50	// (IN) all urbs need completion routines
	51	void *context; // context for completion routine
	52	void (complete)(struct urb ); // pointer to completion routine
	53
	54	// (OUT) status after each completion
	55	int status; // returned status
	56
	57	// (IN) buffer used for data transfers
	58	void *transfer_buffer; // associated data buffer
	59	int transfer_buffer_length; // data buffer length
	60	int number_of_packets; // size of iso_frame_desc
	61
	62	// (OUT) sometimes only part of CTRL/BULK/INTR transfer_buffer is used
	63	int actual_length; // actual data buffer length
	64
	65	// (IN) setup stage for CTRL (pass a struct usb_ctrlrequest)
	66	unsigned char* setup_packet; // setup packet (control only)
	67
	68	// Only for PERIODIC transfers (ISO, INTERRUPT)
	69	// (IN/OUT) start_frame is set unless ISO_ASAP isn't set
	70	int start_frame; // start frame
	71	int interval; // polling interval
	72
	73	// ISO only: packets are only "best effort"; each can have errors
	74	int error_count; // number of errors
	75	struct usb_iso_packet_descriptor iso_frame_desc[0];
	76	};
	77
	78	Your driver must create the "pipe" value using values from the appropriate
	79	endpoint descriptor in an interface that it's claimed.
	80
	81
	82	1.3. How to get an URB?
	83
	84	URBs are allocated with the following call
	85
	86	struct urb *usb_alloc_urb(int isoframes, int mem_flags)
	87
88	Return value is a pointer to the allocated URB, 0 if allocation failed.
89	The parameter isoframes specifies the number of isochronous transfer frames
90	you want to schedule. For CTRL/BULK/INT, use 0. The mem_flags parameter
91	holds standard memory allocation flags, letting you control (among other
92	things) whether the underlying code may block or not.
93
94	To free an URB, use
95
96	void usb_free_urb(struct urb *urb)
97
0fc084ea AS	98	You may free an urb that you've submitted, but which hasn't yet been
	99	returned to you in a completion callback. It will automatically be
	100	deallocated when it is no longer in use.
1da177e4 LT	101
	102
	103	1.4. What has to be filled in?
	104
	105	Depending on the type of transaction, there are some inline functions
	106	defined in <linux/usb.h> to simplify the initialization, such as
	107	fill_control_urb() and fill_bulk_urb(). In general, they need the usb
	108	device pointer, the pipe (usual format from usb.h), the transfer buffer,
	109	the desired transfer length, the completion handler, and its context.
	110	Take a look at the some existing drivers to see how they're used.
	111
	112	Flags:
	113	For ISO there are two startup behaviors: Specified start_frame or ASAP.
	114	For ASAP set URB_ISO_ASAP in transfer_flags.
	115
	116	If short packets should NOT be tolerated, set URB_SHORT_NOT_OK in
	117	transfer_flags.
	118
	119
	120	1.5. How to submit an URB?
	121
	122	Just call
	123
	124	int usb_submit_urb(struct urb *urb, int mem_flags)
	125
	126	The mem_flags parameter, such as SLAB_ATOMIC, controls memory allocation,
	127	such as whether the lower levels may block when memory is tight.
	128
	129	It immediately returns, either with status 0 (request queued) or some
	130	error code, usually caused by the following:
	131
	132	- Out of memory (-ENOMEM)
	133	- Unplugged device (-ENODEV)
	134	- Stalled endpoint (-EPIPE)
	135	- Too many queued ISO transfers (-EAGAIN)
	136	- Too many requested ISO frames (-EFBIG)
	137	- Invalid INT interval (-EINVAL)
	138	- More than one packet for INT (-EINVAL)
	139
	140	After submission, urb->status is -EINPROGRESS; however, you should never
	141	look at that value except in your completion callback.
	142
	143	For isochronous endpoints, your completion handlers should (re)submit
	144	URBs to the same endpoint with the ISO_ASAP flag, using multi-buffering,
	145	to get seamless ISO streaming.
	146
	147
	148	1.6. How to cancel an already running URB?
	149
0fc084ea AS	150	There are two ways to cancel an URB you've submitted but which hasn't
0fc084ea AS	151	been returned to your driver yet. For an asynchronous cancel, call
1da177e4 LT	152
	153	int usb_unlink_urb(struct urb *urb)
	154
	155	It removes the urb from the internal list and frees all allocated
0fc084ea AS	156	HW descriptors. The status is changed to reflect unlinking. Note
	157	that the URB will not normally have finished when usb_unlink_urb()
	158	returns; you must still wait for the completion handler to be called.
1da177e4	159
0fc084ea AS	160	To cancel an URB synchronously, call
	161
	162	void usb_kill_urb(struct urb *urb)
	163
	164	It does everything usb_unlink_urb does, and in addition it waits
	165	until after the URB has been returned and the completion handler
	166	has finished. It also marks the URB as temporarily unusable, so
	167	that if the completion handler or anyone else tries to resubmit it
	168	they will get a -EPERM error. Thus you can be sure that when
	169	usb_kill_urb() returns, the URB is totally idle.
1da177e4	170
da8bfb09 AS	171	There is a lifetime issue to consider. An URB may complete at any
	172	time, and the completion handler may free the URB. If this happens
	173	while usb_unlink_urb or usb_kill_urb is running, it will cause a
	174	memory-access violation. The driver is responsible for avoiding this,
	175	which often means some sort of lock will be needed to prevent the URB
	176	from being deallocated while it is still in use.
	177
	178	On the other hand, since usb_unlink_urb may end up calling the
	179	completion handler, the handler must not take any lock that is held
	180	when usb_unlink_urb is invoked. The general solution to this problem
	181	is to increment the URB's reference count while holding the lock, then
	182	drop the lock and call usb_unlink_urb or usb_kill_urb, and then
	183	decrement the URB's reference count. You increment the reference
	184	count by calling
	185
	186	struct urb usb_get_urb(struct urb urb)
	187
	188	(ignore the return value; it is the same as the argument) and
	189	decrement the reference count by calling usb_free_urb. Of course,
	190	none of this is necessary if there's no danger of the URB being freed
	191	by the completion handler.
	192
1da177e4 LT	193
	194	1.7. What about the completion handler?
	195
	196	The handler is of the following type:
	197
0fc084ea	198	typedef void (usb_complete_t)(struct urb , struct pt_regs *)
1da177e4	199
0fc084ea AS	200	I.e., it gets the URB that caused the completion call, plus the
0fc084ea AS	201	register values at the time of the corresponding interrupt (if any).
1da177e4 LT	202	In the completion handler, you should have a look at urb->status to
	203	detect any USB errors. Since the context parameter is included in the URB,
	204	you can pass information to the completion handler.
	205
	206	Note that even when an error (or unlink) is reported, data may have been
	207	transferred. That's because USB transfers are packetized; it might take
	208	sixteen packets to transfer your 1KByte buffer, and ten of them might
53cb4726	209	have transferred successfully before the completion was called.
1da177e4 LT	210
	211
	212	NOTE: *** WARNING ***
0fc084ea	213	NEVER SLEEP IN A COMPLETION HANDLER. These are normally called
1da177e4 LT	214	during hardware interrupt processing. If you can, defer substantial
	215	work to a tasklet (bottom half) to keep system latencies low. You'll
	216	probably need to use spinlocks to protect data structures you manipulate
	217	in completion handlers.
	218
	219
	220	1.8. How to do isochronous (ISO) transfers?
	221
	222	For ISO transfers you have to fill a usb_iso_packet_descriptor structure,
	223	allocated at the end of the URB by usb_alloc_urb(n,mem_flags), for each
	224	packet you want to schedule. You also have to set urb->interval to say
	225	how often to make transfers; it's often one per frame (which is once
	226	every microframe for highspeed devices). The actual interval used will
	227	be a power of two that's no bigger than what you specify.
	228
	229	The usb_submit_urb() call modifies urb->interval to the implemented interval
	230	value that is less than or equal to the requested interval value. If
	231	ISO_ASAP scheduling is used, urb->start_frame is also updated.
	232
	233	For each entry you have to specify the data offset for this frame (base is
	234	transfer_buffer), and the length you want to write/expect to read.
	235	After completion, actual_length contains the actual transferred length and
	236	status contains the resulting status for the ISO transfer for this frame.
	237	It is allowed to specify a varying length from frame to frame (e.g. for
	238	audio synchronisation/adaptive transfer rates). You can also use the length
	239	0 to omit one or more frames (striping).
	240
	241	For scheduling you can choose your own start frame or ISO_ASAP. As explained
	242	earlier, if you always keep at least one URB queued and your completion
	243	keeps (re)submitting a later URB, you'll get smooth ISO streaming (if usb
	244	bandwidth utilization allows).
	245
	246	If you specify your own start frame, make sure it's several frames in advance
	247	of the current frame. You might want this model if you're synchronizing
	248	ISO data with some other event stream.
	249
	250
	251	1.9. How to start interrupt (INT) transfers?
	252
	253	Interrupt transfers, like isochronous transfers, are periodic, and happen
	254	in intervals that are powers of two (1, 2, 4 etc) units. Units are frames
	255	for full and low speed devices, and microframes for high speed ones.
1da177e4 LT	256	The usb_submit_urb() call modifies urb->interval to the implemented interval
1da177e4 LT	257	value that is less than or equal to the requested interval value.
0fc084ea AS	258
	259	In Linux 2.6, unlike earlier versions, interrupt URBs are not automagically
	260	restarted when they complete. They end when the completion handler is
	261	called, just like other URBs. If you want an interrupt URB to be restarted,
	262	your completion handler must resubmit it.