OpenCores
URL https://opencores.org/ocsvn/openrisc_2011-10-31/openrisc_2011-10-31/trunk

Subversion Repositories openrisc_2011-10-31

[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [doc/] [html/] [ref/] [usbs-intro.html] - Blame information for rev 482

Go to most recent revision | Details | Compare with Previous | View Log

Line No. Rev Author Line
1 28 unneback
<!-- Copyright (C) 2003 Red Hat, Inc.                                -->
2
<!-- This material may be distributed only subject to the terms      -->
3
<!-- and conditions set forth in the Open Publication License, v1.0  -->
4
<!-- or later (the latest version is presently available at          -->
5
<!-- http://www.opencontent.org/openpub/).                           -->
6
<!-- Distribution of the work or derivative of the work in any       -->
7
<!-- standard (paper) book form is prohibited unless prior           -->
8
<!-- permission is obtained from the copyright holder.               -->
9
<HTML
10
><HEAD
11
><TITLE
12
>Introduction</TITLE
13
><meta name="MSSmartTagsPreventParsing" content="TRUE">
14
<META
15
NAME="GENERATOR"
16
CONTENT="Modular DocBook HTML Stylesheet Version 1.76b+
17
"><LINK
18
REL="HOME"
19
TITLE="eCos Reference Manual"
20
HREF="ecos-ref.html"><LINK
21
REL="UP"
22
TITLE="eCos USB Slave Support"
23
HREF="io-usb-slave.html"><LINK
24
REL="PREVIOUS"
25
TITLE="eCos USB Slave Support"
26
HREF="io-usb-slave.html"><LINK
27
REL="NEXT"
28
TITLE="USB Enumeration Data"
29
HREF="usbs-enum.html"></HEAD
30
><BODY
31
CLASS="REFENTRY"
32
BGCOLOR="#FFFFFF"
33
TEXT="#000000"
34
LINK="#0000FF"
35
VLINK="#840084"
36
ALINK="#0000FF"
37
><DIV
38
CLASS="NAVHEADER"
39
><TABLE
40
SUMMARY="Header navigation table"
41
WIDTH="100%"
42
BORDER="0"
43
CELLPADDING="0"
44
CELLSPACING="0"
45
><TR
46
><TH
47
COLSPAN="3"
48
ALIGN="center"
49
>eCos Reference Manual</TH
50
></TR
51
><TR
52
><TD
53
WIDTH="10%"
54
ALIGN="left"
55
VALIGN="bottom"
56
><A
57
HREF="io-usb-slave.html"
58
ACCESSKEY="P"
59
>Prev</A
60
></TD
61
><TD
62
WIDTH="80%"
63
ALIGN="center"
64
VALIGN="bottom"
65
></TD
66
><TD
67
WIDTH="10%"
68
ALIGN="right"
69
VALIGN="bottom"
70
><A
71
HREF="usbs-enum.html"
72
ACCESSKEY="N"
73
>Next</A
74
></TD
75
></TR
76
></TABLE
77
><HR
78
ALIGN="LEFT"
79
WIDTH="100%"></DIV
80
><H1
81
><A
82
NAME="USBS-INTRO">Introduction</H1
83
><DIV
84
CLASS="REFNAMEDIV"
85
><A
86
NAME="AEN16043"
87
></A
88
><H2
89
>Name</H2
90
>Introduction&nbsp;--&nbsp;eCos support for USB slave devices</DIV
91
><DIV
92
CLASS="REFSECT1"
93
><A
94
NAME="AEN16046"
95
></A
96
><H2
97
>Introduction</H2
98
><P
99
>The eCos USB slave support allows developers to produce USB
100
peripherals. It consists of a number of different eCos packages:</P
101
><P
102
></P
103
><OL
104
TYPE="1"
105
><LI
106
><P
107
>Device drivers for specific implementations of USB slave hardware, for
108
example the on-chip USB Device Controller provided by the Intel SA1110
109
processor. A typical USB peripheral will only provide one USB slave
110
port and therefore only one such device driver package will be needed.
111
Usually the device driver package will be loaded automatically when
112
you create an eCos configuration for target hardware that has a USB
113
slave device. If you select a target which does have a USB slave
114
device but no USB device driver is loaded, this implies that no such
115
device driver is currently available.</P
116
></LI
117
><LI
118
><P
119
>The common USB slave package. This serves two purposes. It defines the
120
API that specific device drivers should implement. It also provides
121
various utilities that will be needed by most USB device drivers and
122
applications, such as handlers for standard control messages.
123
Usually this package will be loaded automatically at the same time as
124
the USB device driver.</P
125
></LI
126
><LI
127
><P
128
>The common USB package. This merely provides some information common
129
to both the host and slave sides of USB, such as details of the
130
control protocol. It is also used to place the other USB-related
131
packages appropriately in the overall configuration hierarchy. Usually
132
this package will be loaded at the same time as the USB device driver.</P
133
></LI
134
><LI
135
><P
136
>Class-specific USB support packages. These make it easier to develop
137
specific classes of USB peripheral, such as a USB-ethernet device. If
138
no suitable package is available for a given class of peripheral then
139
the USB device driver can instead be accessed directly from
140
application code. Such packages will never be loaded automatically
141
since the configuration system has no way of knowing what class of USB
142
peripheral is being developed. Instead developers have to add the
143
appropriate package or packages explicitly.</P
144
></LI
145
></OL
146
><P
147
>These packages only provide support for developing USB peripherals,
148
not USB hosts.</P
149
></DIV
150
><DIV
151
CLASS="REFSECT1"
152
><A
153
NAME="AEN16059"
154
></A
155
><H2
156
>USB Concepts</H2
157
><P
158
>Information about USB can be obtained from a number of sources
159
including the <A
160
HREF="http://www.usb.org/"
161
TARGET="_top"
162
>USB Implementers Forum
163
web site</A
164
>. Only a brief summary is provided here.</P
165
><P
166
>A USB network is asymmetrical: it consists of a single host, one or
167
more slave devices, and possibly some number of intermediate hubs. The
168
host side is significantly more complicated than the slave side.
169
Essentially, all operations are initiated by the host. For example, if
170
the host needs to receive some data from a particular USB peripheral
171
then it will send an IN token to that peripheral; the latter should
172
respond with either a NAK or with appropriate data. Similarly, when
173
the host wants to transmit data to a peripheral it will send an OUT
174
token followed by the data; the peripheral will return a NAK if it is
175
currently unable to receive more data or if there was corruption,
176
otherwise it will return an ACK. All transfers are check-summed and
177
there is a clearly-defined error recovery process. USB peripherals can
178
only interact with the host, not with each other.</P
179
><P
180
>USB supports four different types of communication: control messages,
181
interrupt transfers, isochronous transfers, and bulk transfers.
182
Control messages are further subdivided into four categories:
183
standard, class, vendor and a reserved category. All USB peripherals
184
must respond to certain standard control messages, and usually this
185
will be handled by the common USB slave package (for complicated
186
peripherals, application support will be needed). Class and vendor
187
control messages may be handled by an class-specific USB support
188
package, for example the USB-ethernet package will handle control
189
messages such as getting the MAC address or enabling/disabling
190
promiscuous mode. Alternatively, some or all of these messages will
191
have to be handled by application code.</P
192
><P
193
>Interrupt transfers are used for devices which need to be polled
194
regularly. For example, a USB keyboard might be polled once every
195
millisecond. The host will not poll the device more frequently than
196
this, so interrupt transfers are best suited to peripherals that
197
involve a relatively small amount of data. Isochronous transfers are
198
intended for multimedia-related peripherals where typically a large
199
amount of video or audio data needs to be exchanged continuously.
200
Given appropriate host support a USB peripheral can reserve some of
201
the available bandwidth. Isochronous transfers are not reliable; if a
202
particular packet is corrupted then it will just be discarded and
203
software is expected to recover from this. Bulk transfers are used for
204
everything else: after taking care of any pending control, isochronous
205
and interrupt transfers the host will use whatever bandwidth remains
206
for bulk transfers. Bulk transfers are reliable.</P
207
><P
208
>Transfers are organized into USB packets, with the details depending
209
on the transfer type. Control messages always involve an initial
210
8-byte packet from host to peripheral, optionally followed by some
211
additional packets; in theory these additional packets can be up to 64
212
bytes, but hardware may limit it to 8 bytes. Interrupt transfers
213
involve a single packet of up to 64 bytes. Isochronous transfers
214
involve a single packet of up to 1024 bytes. Bulk transfers involve
215
multiple packets. There will be some number, possibly zero, of 64-byte
216
packets. The transfer is terminated by a single packet of less than 64
217
bytes. If the transfer involves an exact multiple of 64 bytes than the
218
final packet will be 0 bytes, consisting of just a header and checksum
219
which typically will be generated by the hardware. There is no
220
pre-defined limit on the size of a bulk transfer. Instead higher-level
221
protocols are expected to handle this, so for a USB-ethernet
222
peripheral the protocol could impose a limit of 1514 bytes of data
223
plus maybe some additional protocol overhead.</P
224
><P
225
>Transfers from the host to a peripheral are addressed not just to that
226
peripheral but to a specific endpoint within that peripheral.
227
Similarly, the host requests incoming data from a specific endpoint
228
rather than from the peripheral as a whole. For example, a combined
229
keyboard/touchpad device could provide the keyboard events on endpoint
230
1 and the mouse events on endpoint 2. A given USB peripheral can have
231
up to 16 endpoints for incoming data and another 16 for outgoing data.
232
However, given the comparatively high speed of USB I/O this endpoint
233
addressing is typically implemented in hardware rather than software,
234
and the hardware will only implement a small number of endpoints.
235
Endpoint 0 is generally used only for control messages.</P
236
><P
237
>In practice, many of these details are irrelevant to application code
238
or to class packages. Instead, such higher-level code usually just
239
performs blocking <TT
240
CLASS="FUNCTION"
241
>read</TT
242
> and
243
<TT
244
CLASS="FUNCTION"
245
>write</TT
246
>, or non-blocking USB-specific calls, to
247
transfer data between host and target via a specific endpoint. Control
248
messages are more complicated but are usually handled by existing
249
code.</P
250
><P
251
>When a USB peripheral is plugged into the host there is an initial
252
enumeration and configuration process. The peripheral provides
253
information such as its class of device (audio, video, etc.), a
254
vendor id, which endpoints should be used for what kind of data, and
255
so on. The host OS uses this information to identify a suitable host
256
device driver. This could be a generic driver for a class of
257
peripherals, or it could be a vendor-specific driver. Assuming a
258
suitable driver is installed the host will then activate the USB
259
peripheral and perform additional application-specific initialisation.
260
For example for a USB-ethernet device this would involve obtaining an
261
ethernet MAC address. Most USB peripherals will be fairly simple, but
262
it is possible to build multifunction peripherals with multiple
263
configurations, interfaces, and alternate interface settings.</P
264
><P
265
>It is not possible for any of the eCos packages to generate all the
266
enumeration data automatically. Some of the required information such
267
as the vendor id cannot be supplied by generic packages; only by the
268
application developer. Class support code such as the USB-ethernet
269
package could in theory supply some of the information automatically,
270
but there are also hardware dependencies such as which endpoints get
271
used for incoming and outgoing ethernet frames. Instead it is the
272
responsibility of the application developer to provide all the
273
enumeration data and perform some additional initialisation. In
274
addition, the common USB slave package can handle all the standard
275
control messages for a simple USB peripheral, but for something like a
276
multifunction peripheral additional application support is needed.</P
277
><DIV
278
CLASS="NOTE"
279
><BLOCKQUOTE
280
CLASS="NOTE"
281
><P
282
><B
283
>Note: </B
284
>The initial implementation of the eCos USB slave packages involved
285
hardware that only supported control and bulk transfers, not
286
isochronous or interrupt. There may be future changes to the USB
287
code and API to allow for isochronous and interrupt transfers,
288
especially the former. Other changes may be required to support
289
different USB devices. At present there is no support for USB remote
290
wakeups, since again it is not supported by the hardware.</P
291
></BLOCKQUOTE
292
></DIV
293
></DIV
294
><DIV
295
CLASS="REFSECT1"
296
><A
297
NAME="AEN16075"
298
></A
299
><H2
300
>eCos USB I/O Facilities</H2
301
><P
302
>For protocols other than control messages, eCos provides two ways of
303
performing USB I/O. The first involves device table or devtab entries such
304
as <A
305
HREF="usbs-devtab.html"
306
><TT
307
CLASS="LITERAL"
308
>/dev/usb1r</TT
309
></A
310
>,
311
with one entry per endpoint per USB device. It is possible to
312
<TT
313
CLASS="FUNCTION"
314
>open</TT
315
> these devices and use conventional blocking
316
I/O functions such as <TT
317
CLASS="FUNCTION"
318
>read</TT
319
> and
320
<TT
321
CLASS="FUNCTION"
322
>write</TT
323
> to exchange data between host and
324
peripheral.</P
325
><P
326
>There is also a lower-level USB-specific API, consisting of functions
327
such as <A
328
HREF="usbs-start-rx.html"
329
><TT
330
CLASS="FUNCTION"
331
>usbs_start_rx_buffer</TT
332
></A
333
>.
334
A USB device driver will supply a data structure for each endpoint,
335
for example a <A
336
HREF="usbs-data.html"
337
><SPAN
338
CLASS="STRUCTNAME"
339
>usbs_rx_endpoint</SPAN
340
></A
341
>
342
structure for every receive endpoint. The first argument to
343
<TT
344
CLASS="FUNCTION"
345
>usbs_start_rx_buffer</TT
346
> should be a pointer to such
347
a data structure. The USB-specific API is non-blocking: the initial
348
call merely starts the transfer; some time later, once the transfer
349
has completed or has been aborted, the device driver will invoke a
350
completion function.</P
351
><P
352
>Control messages are different. With four different categories of
353
control messages including application and vendor specific ones, the
354
conventional
355
<TT
356
CLASS="FUNCTION"
357
>open</TT
358
>/<TT
359
CLASS="FUNCTION"
360
>read</TT
361
>/<TT
362
CLASS="FUNCTION"
363
>write</TT
364
>
365
model of I/O cannot easily be applied. Instead, a USB device driver
366
will supply a <A
367
HREF="usbs-control.html"
368
><SPAN
369
CLASS="STRUCTNAME"
370
>usbs_control_endpoint</SPAN
371
></A
372
>
373
data structure which can be manipulated appropriately. In practice the
374
standard control messages will usually be handled by the common USB
375
slave package, and other control messages will be handled by
376
class-specific code such as the USB-ethernet package. Typically,
377
application code remains responsible for supplying the <A
378
HREF="usbs-enum.html"
379
>enumeration data</A
380
> and for actually <A
381
HREF="usbs-start.html"
382
>starting</A
383
> up the USB device.</P
384
></DIV
385
><DIV
386
CLASS="REFSECT1"
387
><A
388
NAME="AEN16097"
389
></A
390
><H2
391
>Enabling the USB code</H2
392
><P
393
>If the target hardware contains a USB slave device then the
394
appropriate USB device driver and the common packages will typically
395
be loaded into the configuration automatically when that target is
396
selected (assuming a suitable device driver exists). However, the
397
driver will not necessarily be active. For example a processor might
398
have an on-chip USB device, but not all applications using that
399
processor will want to use USB functionality. Hence by default the USB
400
device is disabled, ensuring that applications do not suffer any
401
memory or other penalties for functionality that is not required.</P
402
><P
403
>If the application developer explicitly adds a class support package
404
such as the USB-ethernet one then this implies that the USB device is
405
actually needed, and the device will be enabled automatically.
406
However, if no suitable class package is available and the USB device
407
will instead be accessed by application code, it is necessary to
408
enable the USB device manually. Usually the easiest way to do this is
409
to enable the configuration option
410
<TT
411
CLASS="LITERAL"
412
>CYGGLO_IO_USB_SLAVE_APPLICATION</TT
413
>, and the USB device
414
driver and related packages will adjust accordingly. Alternatively,
415
the device driver may provide some configuration options to provide
416
more fine-grained control.</P
417
></DIV
418
><DIV
419
CLASS="NAVFOOTER"
420
><HR
421
ALIGN="LEFT"
422
WIDTH="100%"><TABLE
423
SUMMARY="Footer navigation table"
424
WIDTH="100%"
425
BORDER="0"
426
CELLPADDING="0"
427
CELLSPACING="0"
428
><TR
429
><TD
430
WIDTH="33%"
431
ALIGN="left"
432
VALIGN="top"
433
><A
434
HREF="io-usb-slave.html"
435
ACCESSKEY="P"
436
>Prev</A
437
></TD
438
><TD
439
WIDTH="34%"
440
ALIGN="center"
441
VALIGN="top"
442
><A
443
HREF="ecos-ref.html"
444
ACCESSKEY="H"
445
>Home</A
446
></TD
447
><TD
448
WIDTH="33%"
449
ALIGN="right"
450
VALIGN="top"
451
><A
452
HREF="usbs-enum.html"
453
ACCESSKEY="N"
454
>Next</A
455
></TD
456
></TR
457
><TR
458
><TD
459
WIDTH="33%"
460
ALIGN="left"
461
VALIGN="top"
462
>eCos USB Slave Support</TD
463
><TD
464
WIDTH="34%"
465
ALIGN="center"
466
VALIGN="top"
467
><A
468
HREF="io-usb-slave.html"
469
ACCESSKEY="U"
470
>Up</A
471
></TD
472
><TD
473
WIDTH="33%"
474
ALIGN="right"
475
VALIGN="top"
476
>USB Enumeration Data</TD
477
></TR
478
></TABLE
479
></DIV
480
></BODY
481
></HTML
482
>

powered by: WebSVN 2.1.0

© copyright 1999-2024 OpenCores.org, equivalent to Oliscience, all rights reserved. OpenCores®, registered trademark.