OpenCores
URL https://opencores.org/ocsvn/openrisc/openrisc/trunk

Subversion Repositories openrisc

[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [doc/] [html/] [ref/] [usbs-start-tx.html] - Blame information for rev 615

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
>Sending Data to the Host</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="Receiving Data from the Host"
26
HREF="usbs-start-rx.html"><LINK
27
REL="NEXT"
28
TITLE="Halted Endpoints"
29
HREF="usbs-halt.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="usbs-start-rx.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-halt.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-START-TX">Sending Data to the Host</H1
83
><DIV
84
CLASS="REFNAMEDIV"
85
><A
86
NAME="AEN16386"
87
></A
88
><H2
89
>Name</H2
90
><TT
91
CLASS="FUNCTION"
92
>usbs_start_tx_buffer</TT
93
>&nbsp;--&nbsp;Sending Data to the Host</DIV
94
><DIV
95
CLASS="REFSYNOPSISDIV"
96
><A
97
NAME="AEN16390"><H2
98
>Synopsis</H2
99
><DIV
100
CLASS="FUNCSYNOPSIS"
101
><A
102
NAME="AEN16391"><P
103
></P
104
><TABLE
105
BORDER="5"
106
BGCOLOR="#E0E0F0"
107
WIDTH="70%"
108
><TR
109
><TD
110
><PRE
111
CLASS="FUNCSYNOPSISINFO"
112
>#include &lt;cyg/io/usb/usbs.h&gt;</PRE
113
></TD
114
></TR
115
></TABLE
116
><P
117
><CODE
118
><CODE
119
CLASS="FUNCDEF"
120
>void usbs_start_tx_buffer</CODE
121
>(usbs_tx_endpoint* ep, const unsigned char* buffer, int length, void (*)(void*,int) complete_fn, void * complete_data);</CODE
122
></P
123
><P
124
><CODE
125
><CODE
126
CLASS="FUNCDEF"
127
>void usbs_start_tx</CODE
128
>(usbs_tx_endpoint* ep);</CODE
129
></P
130
><P
131
></P
132
></DIV
133
></DIV
134
><DIV
135
CLASS="REFSECT1"
136
><A
137
NAME="AEN16411"
138
></A
139
><H2
140
><TT
141
CLASS="FUNCTION"
142
>Description</TT
143
></H2
144
><P
145
><TT
146
CLASS="FUNCTION"
147
>usbs_start_tx_buffer</TT
148
> is a USB-specific function
149
to transfer data from peripheral to host. It can be used for bulk,
150
interrupt or isochronous transfers, but not for control messages;
151
instead those involve manipulating the <A
152
HREF="usbs-control.html"
153
><SPAN
154
CLASS="STRUCTNAME"
155
>usbs_control_endpoint</SPAN
156
></A
157
>
158
data structure directly. The function takes five arguments:</P
159
><P
160
></P
161
><OL
162
TYPE="1"
163
><LI
164
><P
165
>The first argument identifies the specific endpoint that should be
166
used. Different USB devices will support different sets of endpoints
167
and the device driver will provide appropriate data structures. The
168
device driver's documentation should be consulted for details of which
169
endpoints are available.</P
170
></LI
171
><LI
172
><P
173
>The <TT
174
CLASS="PARAMETER"
175
><I
176
>buffer</I
177
></TT
178
> and <TT
179
CLASS="PARAMETER"
180
><I
181
>length</I
182
></TT
183
>
184
arguments control the actual transfer. USB device drivers are not
185
allowed to modify the buffer during the transfer, so the data can
186
reside in read-only memory. The transfer will be for all the data
187
specified, and it is the responsibility of higher-level code to make
188
sure that the host is expecting this amount of data. For isochronous
189
transfers the USB specification imposes an upper bound of 1023 bytes,
190
but a smaller limit may be set in the <A
191
HREF="usbs-enum.html#AEN16179"
192
>enumeration data</A
193
>. Interrupt
194
transfers have an upper bound of 64 bytes or less, as per the
195
enumeration data. Bulk transfers are more complicated because they can
196
involve multiple 64-byte packets plus a terminating packet of less
197
than 64 bytes, so the basic USB specification does not impose an upper
198
limit on the total transfer size. Instead it is left to higher-level
199
protocols to specify an appropriate upper bound. If the peripheral
200
attempts to send more data than the host is willing to accept then the
201
resulting behaviour is undefined and may well depend on the specific
202
host operating system being used.</P
203
><P
204
>For bulk transfers, the USB device driver or the underlying hardware
205
will automatically split the transfer up into the appropriate number
206
of full-size 64-byte packets plus a single terminating packet, which
207
may be 0 bytes.</P
208
></LI
209
><LI
210
><P
211
><TT
212
CLASS="FUNCTION"
213
>usbs_start_tx_buffer</TT
214
> is non-blocking. It merely
215
starts the transmit operation, and does not wait for completion. At
216
some later point the USB device driver will invoke the completion
217
function parameter with two arguments: the completion data defined by
218
the last parameter, and a result field. This result will be either an
219
error code &lt; <TT
220
CLASS="LITERAL"
221
>0</TT
222
>, or the amount of data
223
transferred which should correspond to the
224
<TT
225
CLASS="PARAMETER"
226
><I
227
>length</I
228
></TT
229
> argument. The most likely errors are
230
<TT
231
CLASS="LITERAL"
232
>-EPIPE</TT
233
> to indicate that the connection between the
234
host and the target has been broken, and <TT
235
CLASS="LITERAL"
236
>-EAGAIN</TT
237
>
238
for when the endpoint has been <A
239
HREF="usbs-halt.html"
240
>halted</A
241
>. Specific USB device drivers may
242
define additional error conditions.</P
243
></LI
244
></OL
245
><P
246
>The normal sequence of events is that the USB device driver will
247
update the appropriate hardware registers. At some point after that
248
the host will attempt to fetch data by transmitting an IN token. Since
249
a transmit operation is now in progress the peripheral can send a
250
packet of data, and the host will generate an ACK. At this point the
251
USB hardware will generate an interrupt, and the device driver will
252
service this interrupt and arrange for a DSR to be called. Isochronous
253
and interrupt transfers involve just a single packet. However, bulk
254
transfers may involve multiple packets so the device driver has to
255
check whether there is more data to send and set things up for the
256
next packet. When the device driver DSR detects a complete transfer it
257
will inform higher-level code by invoking the supplied completion
258
function.</P
259
><P
260
>This means that the completion function will normally be invoked by a
261
DSR and not in thread context - although some USB device drivers may
262
have a different implementation. Therefore the completion function is
263
restricted in what it can do, in particular it must not make any
264
calls that will or may block such as locking a mutex or allocating
265
memory. The kernel documentation should be consulted for more details
266
of DSR's and interrupt handling generally.</P
267
><P
268
>It is possible that the completion function will be invoked before
269
<TT
270
CLASS="FUNCTION"
271
>usbs_start_tx_buffer</TT
272
> returns. Such an event would
273
be unusual because the transfer cannot happen until the next time the
274
host tries to fetch data from this peripheral, but it may happen if,
275
for example, another interrupt happens and a higher priority thread is
276
scheduled to run. Also, if the endpoint is currently halted then the
277
completion function will be invoked immediately with
278
<TT
279
CLASS="LITERAL"
280
>-EAGAIN</TT
281
>: typically this will happen in the current
282
thread rather than in a separate DSR. The completion function is
283
allowed to start another transfer immediately by calling
284
<TT
285
CLASS="FUNCTION"
286
>usbs_start_tx_buffer</TT
287
> again.</P
288
><P
289
>USB device drivers are not expected to perform any locking. It is the
290
responsibility of higher-level code to ensure that there is only one
291
transmit operation for a given endpoint in progress at any one time.
292
If there are concurrent calls to
293
<TT
294
CLASS="FUNCTION"
295
>usbs_start_tx_buffer</TT
296
> then the resulting behaviour
297
is undefined. For typical USB applications this does not present any
298
problems because only piece of code will access a given endpoint at
299
any particular time.</P
300
><P
301
>The following code fragment illustrates a very simple use of
302
<TT
303
CLASS="FUNCTION"
304
>usbs_start_tx_buffer</TT
305
> to implement a blocking
306
transmit, using a semaphore to synchronise between the foreground
307
thread and the DSR. For a simple example like this no completion data
308
is needed.</P
309
><TABLE
310
BORDER="5"
311
BGCOLOR="#E0E0F0"
312
WIDTH="70%"
313
><TR
314
><TD
315
><PRE
316
CLASS="PROGRAMLISTING"
317
>static int error_code = 0;
318
static cyg_sem_t completion_wait;
319
 
320
static void
321
completion_fn(void* data, int result)
322
{
323
    error_code = result;
324
    cyg_semaphore_post(&amp;completion_wait);
325
}
326
 
327
int
328
blocking_transmit(usbs_tx_endpoint* ep, const unsigned char* buf, int len)
329
{
330
    error_code = 0;
331
    usbs_start_tx_buffer(ep, buf, len, &amp;completion_fn, NULL);
332
    cyg_semaphore_wait(&amp;completion_wait);
333
    return error_code;
334
}</PRE
335
></TD
336
></TR
337
></TABLE
338
><P
339
>There is also a utility function <TT
340
CLASS="FUNCTION"
341
>usbs_start</TT
342
>. This
343
can be used by code that wants to manipulate <A
344
HREF="usbs-data.html"
345
>data endpoints</A
346
> directly, specifically the
347
<TT
348
CLASS="STRUCTFIELD"
349
><I
350
>complete_fn</I
351
></TT
352
>,
353
<TT
354
CLASS="STRUCTFIELD"
355
><I
356
>complete_data</I
357
></TT
358
>,
359
<TT
360
CLASS="STRUCTFIELD"
361
><I
362
>buffer</I
363
></TT
364
> and
365
<TT
366
CLASS="STRUCTFIELD"
367
><I
368
>buffer_size</I
369
></TT
370
> fields.
371
<TT
372
CLASS="FUNCTION"
373
>usbs_start_tx</TT
374
> just calls a function supplied by
375
the device driver.</P
376
></DIV
377
><DIV
378
CLASS="NAVFOOTER"
379
><HR
380
ALIGN="LEFT"
381
WIDTH="100%"><TABLE
382
SUMMARY="Footer navigation table"
383
WIDTH="100%"
384
BORDER="0"
385
CELLPADDING="0"
386
CELLSPACING="0"
387
><TR
388
><TD
389
WIDTH="33%"
390
ALIGN="left"
391
VALIGN="top"
392
><A
393
HREF="usbs-start-rx.html"
394
ACCESSKEY="P"
395
>Prev</A
396
></TD
397
><TD
398
WIDTH="34%"
399
ALIGN="center"
400
VALIGN="top"
401
><A
402
HREF="ecos-ref.html"
403
ACCESSKEY="H"
404
>Home</A
405
></TD
406
><TD
407
WIDTH="33%"
408
ALIGN="right"
409
VALIGN="top"
410
><A
411
HREF="usbs-halt.html"
412
ACCESSKEY="N"
413
>Next</A
414
></TD
415
></TR
416
><TR
417
><TD
418
WIDTH="33%"
419
ALIGN="left"
420
VALIGN="top"
421
>Receiving Data from the Host</TD
422
><TD
423
WIDTH="34%"
424
ALIGN="center"
425
VALIGN="top"
426
><A
427
HREF="io-usb-slave.html"
428
ACCESSKEY="U"
429
>Up</A
430
></TD
431
><TD
432
WIDTH="33%"
433
ALIGN="right"
434
VALIGN="top"
435
>Halted Endpoints</TD
436
></TR
437
></TABLE
438
></DIV
439
></BODY
440
></HTML
441
>

powered by: WebSVN 2.1.0

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