diff options
author | Jonathan Corbet <corbet@lwn.net> | 2008-10-16 13:53:20 -0400 |
---|---|---|
committer | Jonathan Corbet <corbet@lwn.net> | 2008-10-16 13:53:20 -0400 |
commit | 7e3975617df8dd8b7fd94f14200abdec9f71729e (patch) | |
tree | c45bb9e7485ef017562980cb82b5ac027af00865 | |
parent | 58bae1f5cfd077f7f5f3af5d1ac50c3a82ac6411 (diff) |
Remove videobook.tmpl
This document describes the long-deprecated V4L1 interface. In-tree, it
can only serve to encourage developers to write drivers to the wrong API.
Remove it in favor of the V4L2 documentation which must surely show up
someday.
Acked-by: Alan Cox <alan@redhat.com>
Acked-by: Mauro Carvalho Chehab <mchehab@infradead.org>
Signed-off-by: Jonathan Corbet <corbet@lwn.net>
-rw-r--r-- | Documentation/DocBook/Makefile | 2 | ||||
-rw-r--r-- | Documentation/DocBook/videobook.tmpl | 1654 |
2 files changed, 1 insertions, 1655 deletions
diff --git a/Documentation/DocBook/Makefile b/Documentation/DocBook/Makefile index 1615350b7b53..fabc06466b93 100644 --- a/Documentation/DocBook/Makefile +++ b/Documentation/DocBook/Makefile | |||
@@ -6,7 +6,7 @@ | |||
6 | # To add a new book the only step required is to add the book to the | 6 | # To add a new book the only step required is to add the book to the |
7 | # list of DOCBOOKS. | 7 | # list of DOCBOOKS. |
8 | 8 | ||
9 | DOCBOOKS := wanbook.xml z8530book.xml mcabook.xml videobook.xml \ | 9 | DOCBOOKS := wanbook.xml z8530book.xml mcabook.xml \ |
10 | kernel-hacking.xml kernel-locking.xml deviceiobook.xml \ | 10 | kernel-hacking.xml kernel-locking.xml deviceiobook.xml \ |
11 | procfs-guide.xml writing_usb_driver.xml networking.xml \ | 11 | procfs-guide.xml writing_usb_driver.xml networking.xml \ |
12 | kernel-api.xml filesystems.xml lsm.xml usb.xml kgdb.xml \ | 12 | kernel-api.xml filesystems.xml lsm.xml usb.xml kgdb.xml \ |
diff --git a/Documentation/DocBook/videobook.tmpl b/Documentation/DocBook/videobook.tmpl deleted file mode 100644 index 0bc25949b668..000000000000 --- a/Documentation/DocBook/videobook.tmpl +++ /dev/null | |||
@@ -1,1654 +0,0 @@ | |||
1 | <?xml version="1.0" encoding="UTF-8"?> | ||
2 | <!DOCTYPE book PUBLIC "-//OASIS//DTD DocBook XML V4.1.2//EN" | ||
3 | "http://www.oasis-open.org/docbook/xml/4.1.2/docbookx.dtd" []> | ||
4 | |||
5 | <book id="V4LGuide"> | ||
6 | <bookinfo> | ||
7 | <title>Video4Linux Programming</title> | ||
8 | |||
9 | <authorgroup> | ||
10 | <author> | ||
11 | <firstname>Alan</firstname> | ||
12 | <surname>Cox</surname> | ||
13 | <affiliation> | ||
14 | <address> | ||
15 | <email>alan@redhat.com</email> | ||
16 | </address> | ||
17 | </affiliation> | ||
18 | </author> | ||
19 | </authorgroup> | ||
20 | |||
21 | <copyright> | ||
22 | <year>2000</year> | ||
23 | <holder>Alan Cox</holder> | ||
24 | </copyright> | ||
25 | |||
26 | <legalnotice> | ||
27 | <para> | ||
28 | This documentation is free software; you can redistribute | ||
29 | it and/or modify it under the terms of the GNU General Public | ||
30 | License as published by the Free Software Foundation; either | ||
31 | version 2 of the License, or (at your option) any later | ||
32 | version. | ||
33 | </para> | ||
34 | |||
35 | <para> | ||
36 | This program is distributed in the hope that it will be | ||
37 | useful, but WITHOUT ANY WARRANTY; without even the implied | ||
38 | warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. | ||
39 | See the GNU General Public License for more details. | ||
40 | </para> | ||
41 | |||
42 | <para> | ||
43 | You should have received a copy of the GNU General Public | ||
44 | License along with this program; if not, write to the Free | ||
45 | Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, | ||
46 | MA 02111-1307 USA | ||
47 | </para> | ||
48 | |||
49 | <para> | ||
50 | For more details see the file COPYING in the source | ||
51 | distribution of Linux. | ||
52 | </para> | ||
53 | </legalnotice> | ||
54 | </bookinfo> | ||
55 | |||
56 | <toc></toc> | ||
57 | |||
58 | <chapter id="intro"> | ||
59 | <title>Introduction</title> | ||
60 | <para> | ||
61 | Parts of this document first appeared in Linux Magazine under a | ||
62 | ninety day exclusivity. | ||
63 | </para> | ||
64 | <para> | ||
65 | Video4Linux is intended to provide a common programming interface | ||
66 | for the many TV and capture cards now on the market, as well as | ||
67 | parallel port and USB video cameras. Radio, teletext decoders and | ||
68 | vertical blanking data interfaces are also provided. | ||
69 | </para> | ||
70 | </chapter> | ||
71 | <chapter id="radio"> | ||
72 | <title>Radio Devices</title> | ||
73 | <para> | ||
74 | There are a wide variety of radio interfaces available for PC's, and these | ||
75 | are generally very simple to program. The biggest problem with supporting | ||
76 | such devices is normally extracting documentation from the vendor. | ||
77 | </para> | ||
78 | <para> | ||
79 | The radio interface supports a simple set of control ioctls standardised | ||
80 | across all radio and tv interfaces. It does not support read or write, which | ||
81 | are used for video streams. The reason radio cards do not allow you to read | ||
82 | the audio stream into an application is that without exception they provide | ||
83 | a connection on to a soundcard. Soundcards can be used to read the radio | ||
84 | data just fine. | ||
85 | </para> | ||
86 | <sect1 id="registerradio"> | ||
87 | <title>Registering Radio Devices</title> | ||
88 | <para> | ||
89 | The Video4linux core provides an interface for registering devices. The | ||
90 | first step in writing our radio card driver is to register it. | ||
91 | </para> | ||
92 | <programlisting> | ||
93 | |||
94 | |||
95 | static struct video_device my_radio | ||
96 | { | ||
97 | "My radio", | ||
98 | VID_TYPE_TUNER, | ||
99 | radio_open. | ||
100 | radio_close, | ||
101 | NULL, /* no read */ | ||
102 | NULL, /* no write */ | ||
103 | NULL, /* no poll */ | ||
104 | radio_ioctl, | ||
105 | NULL, /* no special init function */ | ||
106 | NULL /* no private data */ | ||
107 | }; | ||
108 | |||
109 | |||
110 | </programlisting> | ||
111 | <para> | ||
112 | This declares our video4linux device driver interface. The VID_TYPE_ value | ||
113 | defines what kind of an interface we are, and defines basic capabilities. | ||
114 | </para> | ||
115 | <para> | ||
116 | The only defined value relevant for a radio card is VID_TYPE_TUNER which | ||
117 | indicates that the device can be tuned. Clearly our radio is going to have some | ||
118 | way to change channel so it is tuneable. | ||
119 | </para> | ||
120 | <para> | ||
121 | We declare an open and close routine, but we do not need read or write, | ||
122 | which are used to read and write video data to or from the card itself. As | ||
123 | we have no read or write there is no poll function. | ||
124 | </para> | ||
125 | <para> | ||
126 | The private initialise function is run when the device is registered. In | ||
127 | this driver we've already done all the work needed. The final pointer is a | ||
128 | private data pointer that can be used by the device driver to attach and | ||
129 | retrieve private data structures. We set this field "priv" to NULL for | ||
130 | the moment. | ||
131 | </para> | ||
132 | <para> | ||
133 | Having the structure defined is all very well but we now need to register it | ||
134 | with the kernel. | ||
135 | </para> | ||
136 | <programlisting> | ||
137 | |||
138 | |||
139 | static int io = 0x320; | ||
140 | |||
141 | int __init myradio_init(struct video_init *v) | ||
142 | { | ||
143 | if(!request_region(io, MY_IO_SIZE, "myradio")) | ||
144 | { | ||
145 | printk(KERN_ERR | ||
146 | "myradio: port 0x%03X is in use.\n", io); | ||
147 | return -EBUSY; | ||
148 | } | ||
149 | |||
150 | if(video_device_register(&my_radio, VFL_TYPE_RADIO)==-1) { | ||
151 | release_region(io, MY_IO_SIZE); | ||
152 | return -EINVAL; | ||
153 | } | ||
154 | return 0; | ||
155 | } | ||
156 | |||
157 | </programlisting> | ||
158 | <para> | ||
159 | The first stage of the initialisation, as is normally the case, is to check | ||
160 | that the I/O space we are about to fiddle with doesn't belong to some other | ||
161 | driver. If it is we leave well alone. If the user gives the address of the | ||
162 | wrong device then we will spot this. These policies will generally avoid | ||
163 | crashing the machine. | ||
164 | </para> | ||
165 | <para> | ||
166 | Now we ask the Video4Linux layer to register the device for us. We hand it | ||
167 | our carefully designed video_device structure and also tell it which group | ||
168 | of devices we want it registered with. In this case VFL_TYPE_RADIO. | ||
169 | </para> | ||
170 | <para> | ||
171 | The types available are | ||
172 | </para> | ||
173 | <table frame="all" id="Device_Types"><title>Device Types</title> | ||
174 | <tgroup cols="3" align="left"> | ||
175 | <tbody> | ||
176 | <row> | ||
177 | <entry>VFL_TYPE_RADIO</entry><entry>/dev/radio{n}</entry><entry> | ||
178 | |||
179 | Radio devices are assigned in this block. As with all of these | ||
180 | selections the actual number assignment is done by the video layer | ||
181 | accordijng to what is free.</entry> | ||
182 | </row><row> | ||
183 | <entry>VFL_TYPE_GRABBER</entry><entry>/dev/video{n}</entry><entry> | ||
184 | Video capture devices and also -- counter-intuitively for the name -- | ||
185 | hardware video playback devices such as MPEG2 cards.</entry> | ||
186 | </row><row> | ||
187 | <entry>VFL_TYPE_VBI</entry><entry>/dev/vbi{n}</entry><entry> | ||
188 | The VBI devices capture the hidden lines on a television picture | ||
189 | that carry further information like closed caption data, teletext | ||
190 | (primarily in Europe) and now Intercast and the ATVEC internet | ||
191 | television encodings.</entry> | ||
192 | </row><row> | ||
193 | <entry>VFL_TYPE_VTX</entry><entry>/dev/vtx[n}</entry><entry> | ||
194 | VTX is 'Videotext' also known as 'Teletext'. This is a system for | ||
195 | sending numbered, 40x25, mostly textual page images over the hidden | ||
196 | lines. Unlike the /dev/vbi interfaces, this is for 'smart' decoder | ||
197 | chips. (The use of the word smart here has to be taken in context, | ||
198 | the smartest teletext chips are fairly dumb pieces of technology). | ||
199 | </entry> | ||
200 | </row> | ||
201 | </tbody> | ||
202 | </tgroup> | ||
203 | </table> | ||
204 | <para> | ||
205 | We are most definitely a radio. | ||
206 | </para> | ||
207 | <para> | ||
208 | Finally we allocate our I/O space so that nobody treads on us and return 0 | ||
209 | to signify general happiness with the state of the universe. | ||
210 | </para> | ||
211 | </sect1> | ||
212 | <sect1 id="openradio"> | ||
213 | <title>Opening And Closing The Radio</title> | ||
214 | |||
215 | <para> | ||
216 | The functions we declared in our video_device are mostly very simple. | ||
217 | Firstly we can drop in what is basically standard code for open and close. | ||
218 | </para> | ||
219 | <programlisting> | ||
220 | |||
221 | |||
222 | static int users = 0; | ||
223 | |||
224 | static int radio_open(struct video_device *dev, int flags) | ||
225 | { | ||
226 | if(users) | ||
227 | return -EBUSY; | ||
228 | users++; | ||
229 | return 0; | ||
230 | } | ||
231 | |||
232 | </programlisting> | ||
233 | <para> | ||
234 | At open time we need to do nothing but check if someone else is also using | ||
235 | the radio card. If nobody is using it we make a note that we are using it, | ||
236 | then we ensure that nobody unloads our driver on us. | ||
237 | </para> | ||
238 | <programlisting> | ||
239 | |||
240 | |||
241 | static int radio_close(struct video_device *dev) | ||
242 | { | ||
243 | users--; | ||
244 | } | ||
245 | |||
246 | </programlisting> | ||
247 | <para> | ||
248 | At close time we simply need to reduce the user count and allow the module | ||
249 | to become unloadable. | ||
250 | </para> | ||
251 | <para> | ||
252 | If you are sharp you will have noticed neither the open nor the close | ||
253 | routines attempt to reset or change the radio settings. This is intentional. | ||
254 | It allows an application to set up the radio and exit. It avoids a user | ||
255 | having to leave an application running all the time just to listen to the | ||
256 | radio. | ||
257 | </para> | ||
258 | </sect1> | ||
259 | <sect1 id="ioctlradio"> | ||
260 | <title>The Ioctl Interface</title> | ||
261 | <para> | ||
262 | This leaves the ioctl routine, without which the driver will not be | ||
263 | terribly useful to anyone. | ||
264 | </para> | ||
265 | <programlisting> | ||
266 | |||
267 | |||
268 | static int radio_ioctl(struct video_device *dev, unsigned int cmd, void *arg) | ||
269 | { | ||
270 | switch(cmd) | ||
271 | { | ||
272 | case VIDIOCGCAP: | ||
273 | { | ||
274 | struct video_capability v; | ||
275 | v.type = VID_TYPE_TUNER; | ||
276 | v.channels = 1; | ||
277 | v.audios = 1; | ||
278 | v.maxwidth = 0; | ||
279 | v.minwidth = 0; | ||
280 | v.maxheight = 0; | ||
281 | v.minheight = 0; | ||
282 | strcpy(v.name, "My Radio"); | ||
283 | if(copy_to_user(arg, &v, sizeof(v))) | ||
284 | return -EFAULT; | ||
285 | return 0; | ||
286 | } | ||
287 | |||
288 | </programlisting> | ||
289 | <para> | ||
290 | VIDIOCGCAP is the first ioctl all video4linux devices must support. It | ||
291 | allows the applications to find out what sort of a card they have found and | ||
292 | to figure out what they want to do about it. The fields in the structure are | ||
293 | </para> | ||
294 | <table frame="all" id="video_capability_fields"><title>struct video_capability fields</title> | ||
295 | <tgroup cols="2" align="left"> | ||
296 | <tbody> | ||
297 | <row> | ||
298 | <entry>name</entry><entry>The device text name. This is intended for the user.</entry> | ||
299 | </row><row> | ||
300 | <entry>channels</entry><entry>The number of different channels you can tune on | ||
301 | this card. It could even by zero for a card that has | ||
302 | no tuning capability. For our simple FM radio it is 1. | ||
303 | An AM/FM radio would report 2.</entry> | ||
304 | </row><row> | ||
305 | <entry>audios</entry><entry>The number of audio inputs on this device. For our | ||
306 | radio there is only one audio input.</entry> | ||
307 | </row><row> | ||
308 | <entry>minwidth,minheight</entry><entry>The smallest size the card is capable of capturing | ||
309 | images in. We set these to zero. Radios do not | ||
310 | capture pictures</entry> | ||
311 | </row><row> | ||
312 | <entry>maxwidth,maxheight</entry><entry>The largest image size the card is capable of | ||
313 | capturing. For our radio we report 0. | ||
314 | </entry> | ||
315 | </row><row> | ||
316 | <entry>type</entry><entry>This reports the capabilities of the device, and | ||
317 | matches the field we filled in in the struct | ||
318 | video_device when registering.</entry> | ||
319 | </row> | ||
320 | </tbody> | ||
321 | </tgroup> | ||
322 | </table> | ||
323 | <para> | ||
324 | Having filled in the fields, we use copy_to_user to copy the structure into | ||
325 | the users buffer. If the copy fails we return an EFAULT to the application | ||
326 | so that it knows it tried to feed us garbage. | ||
327 | </para> | ||
328 | <para> | ||
329 | The next pair of ioctl operations select which tuner is to be used and let | ||
330 | the application find the tuner properties. We have only a single FM band | ||
331 | tuner in our example device. | ||
332 | </para> | ||
333 | <programlisting> | ||
334 | |||
335 | |||
336 | case VIDIOCGTUNER: | ||
337 | { | ||
338 | struct video_tuner v; | ||
339 | if(copy_from_user(&v, arg, sizeof(v))!=0) | ||
340 | return -EFAULT; | ||
341 | if(v.tuner) | ||
342 | return -EINVAL; | ||
343 | v.rangelow=(87*16000); | ||
344 | v.rangehigh=(108*16000); | ||
345 | v.flags = VIDEO_TUNER_LOW; | ||
346 | v.mode = VIDEO_MODE_AUTO; | ||
347 | v.signal = 0xFFFF; | ||
348 | strcpy(v.name, "FM"); | ||
349 | if(copy_to_user(&v, arg, sizeof(v))!=0) | ||
350 | return -EFAULT; | ||
351 | return 0; | ||
352 | } | ||
353 | |||
354 | </programlisting> | ||
355 | <para> | ||
356 | The VIDIOCGTUNER ioctl allows applications to query a tuner. The application | ||
357 | sets the tuner field to the tuner number it wishes to query. The query does | ||
358 | not change the tuner that is being used, it merely enquires about the tuner | ||
359 | in question. | ||
360 | </para> | ||
361 | <para> | ||
362 | We have exactly one tuner so after copying the user buffer to our temporary | ||
363 | structure we complain if they asked for a tuner other than tuner 0. | ||
364 | </para> | ||
365 | <para> | ||
366 | The video_tuner structure has the following fields | ||
367 | </para> | ||
368 | <table frame="all" id="video_tuner_fields"><title>struct video_tuner fields</title> | ||
369 | <tgroup cols="2" align="left"> | ||
370 | <tbody> | ||
371 | <row> | ||
372 | <entry>int tuner</entry><entry>The number of the tuner in question</entry> | ||
373 | </row><row> | ||
374 | <entry>char name[32]</entry><entry>A text description of this tuner. "FM" will do fine. | ||
375 | This is intended for the application.</entry> | ||
376 | </row><row> | ||
377 | <entry>u32 flags</entry> | ||
378 | <entry>Tuner capability flags</entry> | ||
379 | </row> | ||
380 | <row> | ||
381 | <entry>u16 mode</entry><entry>The current reception mode</entry> | ||
382 | |||
383 | </row><row> | ||
384 | <entry>u16 signal</entry><entry>The signal strength scaled between 0 and 65535. If | ||
385 | a device cannot tell the signal strength it should | ||
386 | report 65535. Many simple cards contain only a | ||
387 | signal/no signal bit. Such cards will report either | ||
388 | 0 or 65535.</entry> | ||
389 | |||
390 | </row><row> | ||
391 | <entry>u32 rangelow, rangehigh</entry><entry> | ||
392 | The range of frequencies supported by the radio | ||
393 | or TV. It is scaled according to the VIDEO_TUNER_LOW | ||
394 | flag.</entry> | ||
395 | |||
396 | </row> | ||
397 | </tbody> | ||
398 | </tgroup> | ||
399 | </table> | ||
400 | |||
401 | <table frame="all" id="video_tuner_flags"><title>struct video_tuner flags</title> | ||
402 | <tgroup cols="2" align="left"> | ||
403 | <tbody> | ||
404 | <row> | ||
405 | <entry>VIDEO_TUNER_PAL</entry><entry>A PAL TV tuner</entry> | ||
406 | </row><row> | ||
407 | <entry>VIDEO_TUNER_NTSC</entry><entry>An NTSC (US) TV tuner</entry> | ||
408 | </row><row> | ||
409 | <entry>VIDEO_TUNER_SECAM</entry><entry>A SECAM (French) TV tuner</entry> | ||
410 | </row><row> | ||
411 | <entry>VIDEO_TUNER_LOW</entry><entry> | ||
412 | The tuner frequency is scaled in 1/16th of a KHz | ||
413 | steps. If not it is in 1/16th of a MHz steps | ||
414 | </entry> | ||
415 | </row><row> | ||
416 | <entry>VIDEO_TUNER_NORM</entry><entry>The tuner can set its format</entry> | ||
417 | </row><row> | ||
418 | <entry>VIDEO_TUNER_STEREO_ON</entry><entry>The tuner is currently receiving a stereo signal</entry> | ||
419 | </row> | ||
420 | </tbody> | ||
421 | </tgroup> | ||
422 | </table> | ||
423 | |||
424 | <table frame="all" id="video_tuner_modes"><title>struct video_tuner modes</title> | ||
425 | <tgroup cols="2" align="left"> | ||
426 | <tbody> | ||
427 | <row> | ||
428 | <entry>VIDEO_MODE_PAL</entry><entry>PAL Format</entry> | ||
429 | </row><row> | ||
430 | <entry>VIDEO_MODE_NTSC</entry><entry>NTSC Format (USA)</entry> | ||
431 | </row><row> | ||
432 | <entry>VIDEO_MODE_SECAM</entry><entry>French Format</entry> | ||
433 | </row><row> | ||
434 | <entry>VIDEO_MODE_AUTO</entry><entry>A device that does not need to do | ||
435 | TV format switching</entry> | ||
436 | </row> | ||
437 | </tbody> | ||
438 | </tgroup> | ||
439 | </table> | ||
440 | <para> | ||
441 | The settings for the radio card are thus fairly simple. We report that we | ||
442 | are a tuner called "FM" for FM radio. In order to get the best tuning | ||
443 | resolution we report VIDEO_TUNER_LOW and select tuning to 1/16th of KHz. Its | ||
444 | unlikely our card can do that resolution but it is a fair bet the card can | ||
445 | do better than 1/16th of a MHz. VIDEO_TUNER_LOW is appropriate to almost all | ||
446 | radio usage. | ||
447 | </para> | ||
448 | <para> | ||
449 | We report that the tuner automatically handles deciding what format it is | ||
450 | receiving - true enough as it only handles FM radio. Our example card is | ||
451 | also incapable of detecting stereo or signal strengths so it reports a | ||
452 | strength of 0xFFFF (maximum) and no stereo detected. | ||
453 | </para> | ||
454 | <para> | ||
455 | To finish off we set the range that can be tuned to be 87-108Mhz, the normal | ||
456 | FM broadcast radio range. It is important to find out what the card is | ||
457 | actually capable of tuning. It is easy enough to simply use the FM broadcast | ||
458 | range. Unfortunately if you do this you will discover the FM broadcast | ||
459 | ranges in the USA, Europe and Japan are all subtly different and some users | ||
460 | cannot receive all the stations they wish. | ||
461 | </para> | ||
462 | <para> | ||
463 | The application also needs to be able to set the tuner it wishes to use. In | ||
464 | our case, with a single tuner this is rather simple to arrange. | ||
465 | </para> | ||
466 | <programlisting> | ||
467 | |||
468 | case VIDIOCSTUNER: | ||
469 | { | ||
470 | struct video_tuner v; | ||
471 | if(copy_from_user(&v, arg, sizeof(v))) | ||
472 | return -EFAULT; | ||
473 | if(v.tuner != 0) | ||
474 | return -EINVAL; | ||
475 | return 0; | ||
476 | } | ||
477 | |||
478 | </programlisting> | ||
479 | <para> | ||
480 | We copy the user supplied structure into kernel memory so we can examine it. | ||
481 | If the user has selected a tuner other than zero we reject the request. If | ||
482 | they wanted tuner 0 then, surprisingly enough, that is the current tuner already. | ||
483 | </para> | ||
484 | <para> | ||
485 | The next two ioctls we need to provide are to get and set the frequency of | ||
486 | the radio. These both use an unsigned long argument which is the frequency. | ||
487 | The scale of the frequency depends on the VIDEO_TUNER_LOW flag as I | ||
488 | mentioned earlier on. Since we have VIDEO_TUNER_LOW set this will be in | ||
489 | 1/16ths of a KHz. | ||
490 | </para> | ||
491 | <programlisting> | ||
492 | |||
493 | static unsigned long current_freq; | ||
494 | |||
495 | |||
496 | |||
497 | case VIDIOCGFREQ: | ||
498 | if(copy_to_user(arg, &current_freq, | ||
499 | sizeof(unsigned long)) | ||
500 | return -EFAULT; | ||
501 | return 0; | ||
502 | |||
503 | </programlisting> | ||
504 | <para> | ||
505 | Querying the frequency in our case is relatively simple. Our radio card is | ||
506 | too dumb to let us query the signal strength so we remember our setting if | ||
507 | we know it. All we have to do is copy it to the user. | ||
508 | </para> | ||
509 | <programlisting> | ||
510 | |||
511 | |||
512 | case VIDIOCSFREQ: | ||
513 | { | ||
514 | u32 freq; | ||
515 | if(copy_from_user(arg, &freq, | ||
516 | sizeof(unsigned long))!=0) | ||
517 | return -EFAULT; | ||
518 | if(hardware_set_freq(freq)<0) | ||
519 | return -EINVAL; | ||
520 | current_freq = freq; | ||
521 | return 0; | ||
522 | } | ||
523 | |||
524 | </programlisting> | ||
525 | <para> | ||
526 | Setting the frequency is a little more complex. We begin by copying the | ||
527 | desired frequency into kernel space. Next we call a hardware specific routine | ||
528 | to set the radio up. This might be as simple as some scaling and a few | ||
529 | writes to an I/O port. For most radio cards it turns out a good deal more | ||
530 | complicated and may involve programming things like a phase locked loop on | ||
531 | the card. This is what documentation is for. | ||
532 | </para> | ||
533 | <para> | ||
534 | The final set of operations we need to provide for our radio are the | ||
535 | volume controls. Not all radio cards can even do volume control. After all | ||
536 | there is a perfectly good volume control on the sound card. We will assume | ||
537 | our radio card has a simple 4 step volume control. | ||
538 | </para> | ||
539 | <para> | ||
540 | There are two ioctls with audio we need to support | ||
541 | </para> | ||
542 | <programlisting> | ||
543 | |||
544 | static int current_volume=0; | ||
545 | |||
546 | case VIDIOCGAUDIO: | ||
547 | { | ||
548 | struct video_audio v; | ||
549 | if(copy_from_user(&v, arg, sizeof(v))) | ||
550 | return -EFAULT; | ||
551 | if(v.audio != 0) | ||
552 | return -EINVAL; | ||
553 | v.volume = 16384*current_volume; | ||
554 | v.step = 16384; | ||
555 | strcpy(v.name, "Radio"); | ||
556 | v.mode = VIDEO_SOUND_MONO; | ||
557 | v.balance = 0; | ||
558 | v.base = 0; | ||
559 | v.treble = 0; | ||
560 | |||
561 | if(copy_to_user(arg. &v, sizeof(v))) | ||
562 | return -EFAULT; | ||
563 | return 0; | ||
564 | } | ||
565 | |||
566 | </programlisting> | ||
567 | <para> | ||
568 | Much like the tuner we start by copying the user structure into kernel | ||
569 | space. Again we check if the user has asked for a valid audio input. We have | ||
570 | only input 0 and we punt if they ask for another input. | ||
571 | </para> | ||
572 | <para> | ||
573 | Then we fill in the video_audio structure. This has the following format | ||
574 | </para> | ||
575 | <table frame="all" id="video_audio_fields"><title>struct video_audio fields</title> | ||
576 | <tgroup cols="2" align="left"> | ||
577 | <tbody> | ||
578 | <row> | ||
579 | <entry>audio</entry><entry>The input the user wishes to query</entry> | ||
580 | </row><row> | ||
581 | <entry>volume</entry><entry>The volume setting on a scale of 0-65535</entry> | ||
582 | </row><row> | ||
583 | <entry>base</entry><entry>The base level on a scale of 0-65535</entry> | ||
584 | </row><row> | ||
585 | <entry>treble</entry><entry>The treble level on a scale of 0-65535</entry> | ||
586 | </row><row> | ||
587 | <entry>flags</entry><entry>The features this audio device supports | ||
588 | </entry> | ||
589 | </row><row> | ||
590 | <entry>name</entry><entry>A text name to display to the user. We picked | ||
591 | "Radio" as it explains things quite nicely.</entry> | ||
592 | </row><row> | ||
593 | <entry>mode</entry><entry>The current reception mode for the audio | ||
594 | |||
595 | We report MONO because our card is too stupid to know if it is in | ||
596 | mono or stereo. | ||
597 | </entry> | ||
598 | </row><row> | ||
599 | <entry>balance</entry><entry>The stereo balance on a scale of 0-65535, 32768 is | ||
600 | middle.</entry> | ||
601 | </row><row> | ||
602 | <entry>step</entry><entry>The step by which the volume control jumps. This is | ||
603 | used to help make it easy for applications to set | ||
604 | slider behaviour.</entry> | ||
605 | </row> | ||
606 | </tbody> | ||
607 | </tgroup> | ||
608 | </table> | ||
609 | |||
610 | <table frame="all" id="video_audio_flags"><title>struct video_audio flags</title> | ||
611 | <tgroup cols="2" align="left"> | ||
612 | <tbody> | ||
613 | <row> | ||
614 | <entry>VIDEO_AUDIO_MUTE</entry><entry>The audio is currently muted. We | ||
615 | could fake this in our driver but we | ||
616 | choose not to bother.</entry> | ||
617 | </row><row> | ||
618 | <entry>VIDEO_AUDIO_MUTABLE</entry><entry>The input has a mute option</entry> | ||
619 | </row><row> | ||
620 | <entry>VIDEO_AUDIO_TREBLE</entry><entry>The input has a treble control</entry> | ||
621 | </row><row> | ||
622 | <entry>VIDEO_AUDIO_BASS</entry><entry>The input has a base control</entry> | ||
623 | </row> | ||
624 | </tbody> | ||
625 | </tgroup> | ||
626 | </table> | ||
627 | |||
628 | <table frame="all" id="video_audio_modes"><title>struct video_audio modes</title> | ||
629 | <tgroup cols="2" align="left"> | ||
630 | <tbody> | ||
631 | <row> | ||
632 | <entry>VIDEO_SOUND_MONO</entry><entry>Mono sound</entry> | ||
633 | </row><row> | ||
634 | <entry>VIDEO_SOUND_STEREO</entry><entry>Stereo sound</entry> | ||
635 | </row><row> | ||
636 | <entry>VIDEO_SOUND_LANG1</entry><entry>Alternative language 1 (TV specific)</entry> | ||
637 | </row><row> | ||
638 | <entry>VIDEO_SOUND_LANG2</entry><entry>Alternative language 2 (TV specific)</entry> | ||
639 | </row> | ||
640 | </tbody> | ||
641 | </tgroup> | ||
642 | </table> | ||
643 | <para> | ||
644 | Having filled in the structure we copy it back to user space. | ||
645 | </para> | ||
646 | <para> | ||
647 | The VIDIOCSAUDIO ioctl allows the user to set the audio parameters in the | ||
648 | video_audio structure. The driver does its best to honour the request. | ||
649 | </para> | ||
650 | <programlisting> | ||
651 | |||
652 | case VIDIOCSAUDIO: | ||
653 | { | ||
654 | struct video_audio v; | ||
655 | if(copy_from_user(&v, arg, sizeof(v))) | ||
656 | return -EFAULT; | ||
657 | if(v.audio) | ||
658 | return -EINVAL; | ||
659 | current_volume = v/16384; | ||
660 | hardware_set_volume(current_volume); | ||
661 | return 0; | ||
662 | } | ||
663 | |||
664 | </programlisting> | ||
665 | <para> | ||
666 | In our case there is very little that the user can set. The volume is | ||
667 | basically the limit. Note that we could pretend to have a mute feature | ||
668 | by rewriting this to | ||
669 | </para> | ||
670 | <programlisting> | ||
671 | |||
672 | case VIDIOCSAUDIO: | ||
673 | { | ||
674 | struct video_audio v; | ||
675 | if(copy_from_user(&v, arg, sizeof(v))) | ||
676 | return -EFAULT; | ||
677 | if(v.audio) | ||
678 | return -EINVAL; | ||
679 | current_volume = v/16384; | ||
680 | if(v.flags&VIDEO_AUDIO_MUTE) | ||
681 | hardware_set_volume(0); | ||
682 | else | ||
683 | hardware_set_volume(current_volume); | ||
684 | current_muted = v.flags & | ||
685 | VIDEO_AUDIO_MUTE; | ||
686 | return 0; | ||
687 | } | ||
688 | |||
689 | </programlisting> | ||
690 | <para> | ||
691 | This with the corresponding changes to the VIDIOCGAUDIO code to report the | ||
692 | state of the mute flag we save and to report the card has a mute function, | ||
693 | will allow applications to use a mute facility with this card. It is | ||
694 | questionable whether this is a good idea however. User applications can already | ||
695 | fake this themselves and kernel space is precious. | ||
696 | </para> | ||
697 | <para> | ||
698 | We now have a working radio ioctl handler. So we just wrap up the function | ||
699 | </para> | ||
700 | <programlisting> | ||
701 | |||
702 | |||
703 | } | ||
704 | return -ENOIOCTLCMD; | ||
705 | } | ||
706 | |||
707 | </programlisting> | ||
708 | <para> | ||
709 | and pass the Video4Linux layer back an error so that it knows we did not | ||
710 | understand the request we got passed. | ||
711 | </para> | ||
712 | </sect1> | ||
713 | <sect1 id="modradio"> | ||
714 | <title>Module Wrapper</title> | ||
715 | <para> | ||
716 | Finally we add in the usual module wrapping and the driver is done. | ||
717 | </para> | ||
718 | <programlisting> | ||
719 | |||
720 | #ifndef MODULE | ||
721 | |||
722 | static int io = 0x300; | ||
723 | |||
724 | #else | ||
725 | |||
726 | static int io = -1; | ||
727 | |||
728 | #endif | ||
729 | |||
730 | MODULE_AUTHOR("Alan Cox"); | ||
731 | MODULE_DESCRIPTION("A driver for an imaginary radio card."); | ||
732 | module_param(io, int, 0444); | ||
733 | MODULE_PARM_DESC(io, "I/O address of the card."); | ||
734 | |||
735 | static int __init init(void) | ||
736 | { | ||
737 | if(io==-1) | ||
738 | { | ||
739 | printk(KERN_ERR | ||
740 | "You must set an I/O address with io=0x???\n"); | ||
741 | return -EINVAL; | ||
742 | } | ||
743 | return myradio_init(NULL); | ||
744 | } | ||
745 | |||
746 | static void __exit cleanup(void) | ||
747 | { | ||
748 | video_unregister_device(&my_radio); | ||
749 | release_region(io, MY_IO_SIZE); | ||
750 | } | ||
751 | |||
752 | module_init(init); | ||
753 | module_exit(cleanup); | ||
754 | |||
755 | </programlisting> | ||
756 | <para> | ||
757 | In this example we set the IO base by default if the driver is compiled into | ||
758 | the kernel: you can still set it using "my_radio.irq" if this file is called <filename>my_radio.c</filename>. For the module we require the | ||
759 | user sets the parameter. We set io to a nonsense port (-1) so that we can | ||
760 | tell if the user supplied an io parameter or not. | ||
761 | </para> | ||
762 | <para> | ||
763 | We use MODULE_ defines to give an author for the card driver and a | ||
764 | description. We also use them to declare that io is an integer and it is the | ||
765 | address of the card, and can be read by anyone from sysfs. | ||
766 | </para> | ||
767 | <para> | ||
768 | The clean-up routine unregisters the video_device we registered, and frees | ||
769 | up the I/O space. Note that the unregister takes the actual video_device | ||
770 | structure as its argument. Unlike the file operations structure which can be | ||
771 | shared by all instances of a device a video_device structure as an actual | ||
772 | instance of the device. If you are registering multiple radio devices you | ||
773 | need to fill in one structure per device (most likely by setting up a | ||
774 | template and copying it to each of the actual device structures). | ||
775 | </para> | ||
776 | </sect1> | ||
777 | </chapter> | ||
778 | <chapter id="Video_Capture_Devices"> | ||
779 | <title>Video Capture Devices</title> | ||
780 | <sect1 id="introvid"> | ||
781 | <title>Video Capture Device Types</title> | ||
782 | <para> | ||
783 | The video capture devices share the same interfaces as radio devices. In | ||
784 | order to explain the video capture interface I will use the example of a | ||
785 | camera that has no tuners or audio input. This keeps the example relatively | ||
786 | clean. To get both combine the two driver examples. | ||
787 | </para> | ||
788 | <para> | ||
789 | Video capture devices divide into four categories. A little technology | ||
790 | backgrounder. Full motion video even at television resolution (which is | ||
791 | actually fairly low) is pretty resource-intensive. You are continually | ||
792 | passing megabytes of data every second from the capture card to the display. | ||
793 | several alternative approaches have emerged because copying this through the | ||
794 | processor and the user program is a particularly bad idea . | ||
795 | </para> | ||
796 | <para> | ||
797 | The first is to add the television image onto the video output directly. | ||
798 | This is also how some 3D cards work. These basic cards can generally drop the | ||
799 | video into any chosen rectangle of the display. Cards like this, which | ||
800 | include most mpeg1 cards that used the feature connector, aren't very | ||
801 | friendly in a windowing environment. They don't understand windows or | ||
802 | clipping. The video window is always on the top of the display. | ||
803 | </para> | ||
804 | <para> | ||
805 | Chroma keying is a technique used by cards to get around this. It is an old | ||
806 | television mixing trick where you mark all the areas you wish to replace | ||
807 | with a single clear colour that isn't used in the image - TV people use an | ||
808 | incredibly bright blue while computing people often use a particularly | ||
809 | virulent purple. Bright blue occurs on the desktop. Anyone with virulent | ||
810 | purple windows has another problem besides their TV overlay. | ||
811 | </para> | ||
812 | <para> | ||
813 | The third approach is to copy the data from the capture card to the video | ||
814 | card, but to do it directly across the PCI bus. This relieves the processor | ||
815 | from doing the work but does require some smartness on the part of the video | ||
816 | capture chip, as well as a suitable video card. Programming this kind of | ||
817 | card and more so debugging it can be extremely tricky. There are some quite | ||
818 | complicated interactions with the display and you may also have to cope with | ||
819 | various chipset bugs that show up when PCI cards start talking to each | ||
820 | other. | ||
821 | </para> | ||
822 | <para> | ||
823 | To keep our example fairly simple we will assume a card that supports | ||
824 | overlaying a flat rectangular image onto the frame buffer output, and which | ||
825 | can also capture stuff into processor memory. | ||
826 | </para> | ||
827 | </sect1> | ||
828 | <sect1 id="regvid"> | ||
829 | <title>Registering Video Capture Devices</title> | ||
830 | <para> | ||
831 | This time we need to add more functions for our camera device. | ||
832 | </para> | ||
833 | <programlisting> | ||
834 | static struct video_device my_camera | ||
835 | { | ||
836 | "My Camera", | ||
837 | VID_TYPE_OVERLAY|VID_TYPE_SCALES|\ | ||
838 | VID_TYPE_CAPTURE|VID_TYPE_CHROMAKEY, | ||
839 | camera_open. | ||
840 | camera_close, | ||
841 | camera_read, /* no read */ | ||
842 | NULL, /* no write */ | ||
843 | camera_poll, /* no poll */ | ||
844 | camera_ioctl, | ||
845 | NULL, /* no special init function */ | ||
846 | NULL /* no private data */ | ||
847 | }; | ||
848 | </programlisting> | ||
849 | <para> | ||
850 | We need a read() function which is used for capturing data from | ||
851 | the card, and we need a poll function so that a driver can wait for the next | ||
852 | frame to be captured. | ||
853 | </para> | ||
854 | <para> | ||
855 | We use the extra video capability flags that did not apply to the | ||
856 | radio interface. The video related flags are | ||
857 | </para> | ||
858 | <table frame="all" id="Capture_Capabilities"><title>Capture Capabilities</title> | ||
859 | <tgroup cols="2" align="left"> | ||
860 | <tbody> | ||
861 | <row> | ||
862 | <entry>VID_TYPE_CAPTURE</entry><entry>We support image capture</entry> | ||
863 | </row><row> | ||
864 | <entry>VID_TYPE_TELETEXT</entry><entry>A teletext capture device (vbi{n])</entry> | ||
865 | </row><row> | ||
866 | <entry>VID_TYPE_OVERLAY</entry><entry>The image can be directly overlaid onto the | ||
867 | frame buffer</entry> | ||
868 | </row><row> | ||
869 | <entry>VID_TYPE_CHROMAKEY</entry><entry>Chromakey can be used to select which parts | ||
870 | of the image to display</entry> | ||
871 | </row><row> | ||
872 | <entry>VID_TYPE_CLIPPING</entry><entry>It is possible to give the board a list of | ||
873 | rectangles to draw around. </entry> | ||
874 | </row><row> | ||
875 | <entry>VID_TYPE_FRAMERAM</entry><entry>The video capture goes into the video memory | ||
876 | and actually changes it. Applications need | ||
877 | to know this so they can clean up after the | ||
878 | card</entry> | ||
879 | </row><row> | ||
880 | <entry>VID_TYPE_SCALES</entry><entry>The image can be scaled to various sizes, | ||
881 | rather than being a single fixed size.</entry> | ||
882 | </row><row> | ||
883 | <entry>VID_TYPE_MONOCHROME</entry><entry>The capture will be monochrome. This isn't a | ||
884 | complete answer to the question since a mono | ||
885 | camera on a colour capture card will still | ||
886 | produce mono output.</entry> | ||
887 | </row><row> | ||
888 | <entry>VID_TYPE_SUBCAPTURE</entry><entry>The card allows only part of its field of | ||
889 | view to be captured. This enables | ||
890 | applications to avoid copying all of a large | ||
891 | image into memory when only some section is | ||
892 | relevant.</entry> | ||
893 | </row> | ||
894 | </tbody> | ||
895 | </tgroup> | ||
896 | </table> | ||
897 | <para> | ||
898 | We set VID_TYPE_CAPTURE so that we are seen as a capture card, | ||
899 | VID_TYPE_CHROMAKEY so the application knows it is time to draw in virulent | ||
900 | purple, and VID_TYPE_SCALES because we can be resized. | ||
901 | </para> | ||
902 | <para> | ||
903 | Our setup is fairly similar. This time we also want an interrupt line | ||
904 | for the 'frame captured' signal. Not all cards have this so some of them | ||
905 | cannot handle poll(). | ||
906 | </para> | ||
907 | <programlisting> | ||
908 | |||
909 | |||
910 | static int io = 0x320; | ||
911 | static int irq = 11; | ||
912 | |||
913 | int __init mycamera_init(struct video_init *v) | ||
914 | { | ||
915 | if(!request_region(io, MY_IO_SIZE, "mycamera")) | ||
916 | { | ||
917 | printk(KERN_ERR | ||
918 | "mycamera: port 0x%03X is in use.\n", io); | ||
919 | return -EBUSY; | ||
920 | } | ||
921 | |||
922 | if(video_device_register(&my_camera, | ||
923 | VFL_TYPE_GRABBER)==-1) { | ||
924 | release_region(io, MY_IO_SIZE); | ||
925 | return -EINVAL; | ||
926 | } | ||
927 | return 0; | ||
928 | } | ||
929 | |||
930 | </programlisting> | ||
931 | <para> | ||
932 | This is little changed from the needs of the radio card. We specify | ||
933 | VFL_TYPE_GRABBER this time as we want to be allocated a /dev/video name. | ||
934 | </para> | ||
935 | </sect1> | ||
936 | <sect1 id="opvid"> | ||
937 | <title>Opening And Closing The Capture Device</title> | ||
938 | <programlisting> | ||
939 | |||
940 | |||
941 | static int users = 0; | ||
942 | |||
943 | static int camera_open(struct video_device *dev, int flags) | ||
944 | { | ||
945 | if(users) | ||
946 | return -EBUSY; | ||
947 | if(request_irq(irq, camera_irq, 0, "camera", dev)<0) | ||
948 | return -EBUSY; | ||
949 | users++; | ||
950 | return 0; | ||
951 | } | ||
952 | |||
953 | |||
954 | static int camera_close(struct video_device *dev) | ||
955 | { | ||
956 | users--; | ||
957 | free_irq(irq, dev); | ||
958 | } | ||
959 | </programlisting> | ||
960 | <para> | ||
961 | The open and close routines are also quite similar. The only real change is | ||
962 | that we now request an interrupt for the camera device interrupt line. If we | ||
963 | cannot get the interrupt we report EBUSY to the application and give up. | ||
964 | </para> | ||
965 | </sect1> | ||
966 | <sect1 id="irqvid"> | ||
967 | <title>Interrupt Handling</title> | ||
968 | <para> | ||
969 | Our example handler is for an ISA bus device. If it was PCI you would be | ||
970 | able to share the interrupt and would have set IRQF_SHARED to indicate a | ||
971 | shared IRQ. We pass the device pointer as the interrupt routine argument. We | ||
972 | don't need to since we only support one card but doing this will make it | ||
973 | easier to upgrade the driver for multiple devices in the future. | ||
974 | </para> | ||
975 | <para> | ||
976 | Our interrupt routine needs to do little if we assume the card can simply | ||
977 | queue one frame to be read after it captures it. | ||
978 | </para> | ||
979 | <programlisting> | ||
980 | |||
981 | |||
982 | static struct wait_queue *capture_wait; | ||
983 | static int capture_ready = 0; | ||
984 | |||
985 | static void camera_irq(int irq, void *dev_id, | ||
986 | struct pt_regs *regs) | ||
987 | { | ||
988 | capture_ready=1; | ||
989 | wake_up_interruptible(&capture_wait); | ||
990 | } | ||
991 | </programlisting> | ||
992 | <para> | ||
993 | The interrupt handler is nice and simple for this card as we are assuming | ||
994 | the card is buffering the frame for us. This means we have little to do but | ||
995 | wake up anybody interested. We also set a capture_ready flag, as we may | ||
996 | capture a frame before an application needs it. In this case we need to know | ||
997 | that a frame is ready. If we had to collect the frame on the interrupt life | ||
998 | would be more complex. | ||
999 | </para> | ||
1000 | <para> | ||
1001 | The two new routines we need to supply are camera_read which returns a | ||
1002 | frame, and camera_poll which waits for a frame to become ready. | ||
1003 | </para> | ||
1004 | <programlisting> | ||
1005 | |||
1006 | |||
1007 | static int camera_poll(struct video_device *dev, | ||
1008 | struct file *file, struct poll_table *wait) | ||
1009 | { | ||
1010 | poll_wait(file, &capture_wait, wait); | ||
1011 | if(capture_read) | ||
1012 | return POLLIN|POLLRDNORM; | ||
1013 | return 0; | ||
1014 | } | ||
1015 | |||
1016 | </programlisting> | ||
1017 | <para> | ||
1018 | Our wait queue for polling is the capture_wait queue. This will cause the | ||
1019 | task to be woken up by our camera_irq routine. We check capture_read to see | ||
1020 | if there is an image present and if so report that it is readable. | ||
1021 | </para> | ||
1022 | </sect1> | ||
1023 | <sect1 id="rdvid"> | ||
1024 | <title>Reading The Video Image</title> | ||
1025 | <programlisting> | ||
1026 | |||
1027 | |||
1028 | static long camera_read(struct video_device *dev, char *buf, | ||
1029 | unsigned long count) | ||
1030 | { | ||
1031 | struct wait_queue wait = { current, NULL }; | ||
1032 | u8 *ptr; | ||
1033 | int len; | ||
1034 | int i; | ||
1035 | |||
1036 | add_wait_queue(&capture_wait, &wait); | ||
1037 | |||
1038 | while(!capture_ready) | ||
1039 | { | ||
1040 | if(file->flags&O_NDELAY) | ||
1041 | { | ||
1042 | remove_wait_queue(&capture_wait, &wait); | ||
1043 | current->state = TASK_RUNNING; | ||
1044 | return -EWOULDBLOCK; | ||
1045 | } | ||
1046 | if(signal_pending(current)) | ||
1047 | { | ||
1048 | remove_wait_queue(&capture_wait, &wait); | ||
1049 | current->state = TASK_RUNNING; | ||
1050 | return -ERESTARTSYS; | ||
1051 | } | ||
1052 | schedule(); | ||
1053 | current->state = TASK_INTERRUPTIBLE; | ||
1054 | } | ||
1055 | remove_wait_queue(&capture_wait, &wait); | ||
1056 | current->state = TASK_RUNNING; | ||
1057 | |||
1058 | </programlisting> | ||
1059 | <para> | ||
1060 | The first thing we have to do is to ensure that the application waits until | ||
1061 | the next frame is ready. The code here is almost identical to the mouse code | ||
1062 | we used earlier in this chapter. It is one of the common building blocks of | ||
1063 | Linux device driver code and probably one which you will find occurs in any | ||
1064 | drivers you write. | ||
1065 | </para> | ||
1066 | <para> | ||
1067 | We wait for a frame to be ready, or for a signal to interrupt our waiting. If a | ||
1068 | signal occurs we need to return from the system call so that the signal can | ||
1069 | be sent to the application itself. We also check to see if the user actually | ||
1070 | wanted to avoid waiting - ie if they are using non-blocking I/O and have other things | ||
1071 | to get on with. | ||
1072 | </para> | ||
1073 | <para> | ||
1074 | Next we copy the data from the card to the user application. This is rarely | ||
1075 | as easy as our example makes out. We will add capture_w, and capture_h here | ||
1076 | to hold the width and height of the captured image. We assume the card only | ||
1077 | supports 24bit RGB for now. | ||
1078 | </para> | ||
1079 | <programlisting> | ||
1080 | |||
1081 | |||
1082 | |||
1083 | capture_ready = 0; | ||
1084 | |||
1085 | ptr=(u8 *)buf; | ||
1086 | len = capture_w * 3 * capture_h; /* 24bit RGB */ | ||
1087 | |||
1088 | if(len>count) | ||
1089 | len=count; /* Doesn't all fit */ | ||
1090 | |||
1091 | for(i=0; i<len; i++) | ||
1092 | { | ||
1093 | put_user(inb(io+IMAGE_DATA), ptr); | ||
1094 | ptr++; | ||
1095 | } | ||
1096 | |||
1097 | hardware_restart_capture(); | ||
1098 | |||
1099 | return i; | ||
1100 | } | ||
1101 | |||
1102 | </programlisting> | ||
1103 | <para> | ||
1104 | For a real hardware device you would try to avoid the loop with put_user(). | ||
1105 | Each call to put_user() has a time overhead checking whether the accesses to user | ||
1106 | space are allowed. It would be better to read a line into a temporary buffer | ||
1107 | then copy this to user space in one go. | ||
1108 | </para> | ||
1109 | <para> | ||
1110 | Having captured the image and put it into user space we can kick the card to | ||
1111 | get the next frame acquired. | ||
1112 | </para> | ||
1113 | </sect1> | ||
1114 | <sect1 id="iocvid"> | ||
1115 | <title>Video Ioctl Handling</title> | ||
1116 | <para> | ||
1117 | As with the radio driver the major control interface is via the ioctl() | ||
1118 | function. Video capture devices support the same tuner calls as a radio | ||
1119 | device and also support additional calls to control how the video functions | ||
1120 | are handled. In this simple example the card has no tuners to avoid making | ||
1121 | the code complex. | ||
1122 | </para> | ||
1123 | <programlisting> | ||
1124 | |||
1125 | |||
1126 | |||
1127 | static int camera_ioctl(struct video_device *dev, unsigned int cmd, void *arg) | ||
1128 | { | ||
1129 | switch(cmd) | ||
1130 | { | ||
1131 | case VIDIOCGCAP: | ||
1132 | { | ||
1133 | struct video_capability v; | ||
1134 | v.type = VID_TYPE_CAPTURE|\ | ||
1135 | VID_TYPE_CHROMAKEY|\ | ||
1136 | VID_TYPE_SCALES|\ | ||
1137 | VID_TYPE_OVERLAY; | ||
1138 | v.channels = 1; | ||
1139 | v.audios = 0; | ||
1140 | v.maxwidth = 640; | ||
1141 | v.minwidth = 16; | ||
1142 | v.maxheight = 480; | ||
1143 | v.minheight = 16; | ||
1144 | strcpy(v.name, "My Camera"); | ||
1145 | if(copy_to_user(arg, &v, sizeof(v))) | ||
1146 | return -EFAULT; | ||
1147 | return 0; | ||
1148 | } | ||
1149 | |||
1150 | |||
1151 | </programlisting> | ||
1152 | <para> | ||
1153 | The first ioctl we must support and which all video capture and radio | ||
1154 | devices are required to support is VIDIOCGCAP. This behaves exactly the same | ||
1155 | as with a radio device. This time, however, we report the extra capabilities | ||
1156 | we outlined earlier on when defining our video_dev structure. | ||
1157 | </para> | ||
1158 | <para> | ||
1159 | We now set the video flags saying that we support overlay, capture, | ||
1160 | scaling and chromakey. We also report size limits - our smallest image is | ||
1161 | 16x16 pixels, our largest is 640x480. | ||
1162 | </para> | ||
1163 | <para> | ||
1164 | To keep things simple we report no audio and no tuning capabilities at all. | ||
1165 | </para> | ||
1166 | <programlisting> | ||
1167 | |||
1168 | case VIDIOCGCHAN: | ||
1169 | { | ||
1170 | struct video_channel v; | ||
1171 | if(copy_from_user(&v, arg, sizeof(v))) | ||
1172 | return -EFAULT; | ||
1173 | if(v.channel != 0) | ||
1174 | return -EINVAL; | ||
1175 | v.flags = 0; | ||
1176 | v.tuners = 0; | ||
1177 | v.type = VIDEO_TYPE_CAMERA; | ||
1178 | v.norm = VIDEO_MODE_AUTO; | ||
1179 | strcpy(v.name, "Camera Input");break; | ||
1180 | if(copy_to_user(&v, arg, sizeof(v))) | ||
1181 | return -EFAULT; | ||
1182 | return 0; | ||
1183 | } | ||
1184 | |||
1185 | |||
1186 | </programlisting> | ||
1187 | <para> | ||
1188 | This follows what is very much the standard way an ioctl handler looks | ||
1189 | in Linux. We copy the data into a kernel space variable and we check that the | ||
1190 | request is valid (in this case that the input is 0). Finally we copy the | ||
1191 | camera info back to the user. | ||
1192 | </para> | ||
1193 | <para> | ||
1194 | The VIDIOCGCHAN ioctl allows a user to ask about video channels (that is | ||
1195 | inputs to the video card). Our example card has a single camera input. The | ||
1196 | fields in the structure are | ||
1197 | </para> | ||
1198 | <table frame="all" id="video_channel_fields"><title>struct video_channel fields</title> | ||
1199 | <tgroup cols="2" align="left"> | ||
1200 | <tbody> | ||
1201 | <row> | ||
1202 | |||
1203 | <entry>channel</entry><entry>The channel number we are selecting</entry> | ||
1204 | </row><row> | ||
1205 | <entry>name</entry><entry>The name for this channel. This is intended | ||
1206 | to describe the port to the user. | ||
1207 | Appropriate names are therefore things like | ||
1208 | "Camera" "SCART input"</entry> | ||
1209 | </row><row> | ||
1210 | <entry>flags</entry><entry>Channel properties</entry> | ||
1211 | </row><row> | ||
1212 | <entry>type</entry><entry>Input type</entry> | ||
1213 | </row><row> | ||
1214 | <entry>norm</entry><entry>The current television encoding being used | ||
1215 | if relevant for this channel. | ||
1216 | </entry> | ||
1217 | </row> | ||
1218 | </tbody> | ||
1219 | </tgroup> | ||
1220 | </table> | ||
1221 | <table frame="all" id="video_channel_flags"><title>struct video_channel flags</title> | ||
1222 | <tgroup cols="2" align="left"> | ||
1223 | <tbody> | ||
1224 | <row> | ||
1225 | <entry>VIDEO_VC_TUNER</entry><entry>Channel has a tuner.</entry> | ||
1226 | </row><row> | ||
1227 | <entry>VIDEO_VC_AUDIO</entry><entry>Channel has audio.</entry> | ||
1228 | </row> | ||
1229 | </tbody> | ||
1230 | </tgroup> | ||
1231 | </table> | ||
1232 | <table frame="all" id="video_channel_types"><title>struct video_channel types</title> | ||
1233 | <tgroup cols="2" align="left"> | ||
1234 | <tbody> | ||
1235 | <row> | ||
1236 | <entry>VIDEO_TYPE_TV</entry><entry>Television input.</entry> | ||
1237 | </row><row> | ||
1238 | <entry>VIDEO_TYPE_CAMERA</entry><entry>Fixed camera input.</entry> | ||
1239 | </row><row> | ||
1240 | <entry>0</entry><entry>Type is unknown.</entry> | ||
1241 | </row> | ||
1242 | </tbody> | ||
1243 | </tgroup> | ||
1244 | </table> | ||
1245 | <table frame="all" id="video_channel_norms"><title>struct video_channel norms</title> | ||
1246 | <tgroup cols="2" align="left"> | ||
1247 | <tbody> | ||
1248 | <row> | ||
1249 | <entry>VIDEO_MODE_PAL</entry><entry>PAL encoded Television</entry> | ||
1250 | </row><row> | ||
1251 | <entry>VIDEO_MODE_NTSC</entry><entry>NTSC (US) encoded Television</entry> | ||
1252 | </row><row> | ||
1253 | <entry>VIDEO_MODE_SECAM</entry><entry>SECAM (French) Television </entry> | ||
1254 | </row><row> | ||
1255 | <entry>VIDEO_MODE_AUTO</entry><entry>Automatic switching, or format does not | ||
1256 | matter</entry> | ||
1257 | </row> | ||
1258 | </tbody> | ||
1259 | </tgroup> | ||
1260 | </table> | ||
1261 | <para> | ||
1262 | The corresponding VIDIOCSCHAN ioctl allows a user to change channel and to | ||
1263 | request the norm is changed - for example to switch between a PAL or an NTSC | ||
1264 | format camera. | ||
1265 | </para> | ||
1266 | <programlisting> | ||
1267 | |||
1268 | |||
1269 | case VIDIOCSCHAN: | ||
1270 | { | ||
1271 | struct video_channel v; | ||
1272 | if(copy_from_user(&v, arg, sizeof(v))) | ||
1273 | return -EFAULT; | ||
1274 | if(v.channel != 0) | ||
1275 | return -EINVAL; | ||
1276 | if(v.norm != VIDEO_MODE_AUTO) | ||
1277 | return -EINVAL; | ||
1278 | return 0; | ||
1279 | } | ||
1280 | |||
1281 | |||
1282 | </programlisting> | ||
1283 | <para> | ||
1284 | The implementation of this call in our driver is remarkably easy. Because we | ||
1285 | are assuming fixed format hardware we need only check that the user has not | ||
1286 | tried to change anything. | ||
1287 | </para> | ||
1288 | <para> | ||
1289 | The user also needs to be able to configure and adjust the picture they are | ||
1290 | seeing. This is much like adjusting a television set. A user application | ||
1291 | also needs to know the palette being used so that it knows how to display | ||
1292 | the image that has been captured. The VIDIOCGPICT and VIDIOCSPICT ioctl | ||
1293 | calls provide this information. | ||
1294 | </para> | ||
1295 | <programlisting> | ||
1296 | |||
1297 | |||
1298 | case VIDIOCGPICT | ||
1299 | { | ||
1300 | struct video_picture v; | ||
1301 | v.brightness = hardware_brightness(); | ||
1302 | v.hue = hardware_hue(); | ||
1303 | v.colour = hardware_saturation(); | ||
1304 | v.contrast = hardware_brightness(); | ||
1305 | /* Not settable */ | ||
1306 | v.whiteness = 32768; | ||
1307 | v.depth = 24; /* 24bit */ | ||
1308 | v.palette = VIDEO_PALETTE_RGB24; | ||
1309 | if(copy_to_user(&v, arg, | ||
1310 | sizeof(v))) | ||
1311 | return -EFAULT; | ||
1312 | return 0; | ||
1313 | } | ||
1314 | |||
1315 | |||
1316 | </programlisting> | ||
1317 | <para> | ||
1318 | The brightness, hue, color, and contrast provide the picture controls that | ||
1319 | are akin to a conventional television. Whiteness provides additional | ||
1320 | control for greyscale images. All of these values are scaled between 0-65535 | ||
1321 | and have 32768 as the mid point setting. The scaling means that applications | ||
1322 | do not have to worry about the capability range of the hardware but can let | ||
1323 | it make a best effort attempt. | ||
1324 | </para> | ||
1325 | <para> | ||
1326 | Our depth is 24, as this is in bits. We will be returning RGB24 format. This | ||
1327 | has one byte of red, then one of green, then one of blue. This then repeats | ||
1328 | for every other pixel in the image. The other common formats the interface | ||
1329 | defines are | ||
1330 | </para> | ||
1331 | <table frame="all" id="Framebuffer_Encodings"><title>Framebuffer Encodings</title> | ||
1332 | <tgroup cols="2" align="left"> | ||
1333 | <tbody> | ||
1334 | <row> | ||
1335 | <entry>GREY</entry><entry>Linear greyscale. This is for simple cameras and the | ||
1336 | like</entry> | ||
1337 | </row><row> | ||
1338 | <entry>RGB565</entry><entry>The top 5 bits hold 32 red levels, the next six bits | ||
1339 | hold green and the low 5 bits hold blue. </entry> | ||
1340 | </row><row> | ||
1341 | <entry>RGB555</entry><entry>The top bit is clear. The red green and blue levels | ||
1342 | each occupy five bits.</entry> | ||
1343 | </row> | ||
1344 | </tbody> | ||
1345 | </tgroup> | ||
1346 | </table> | ||
1347 | <para> | ||
1348 | Additional modes are support for YUV capture formats. These are common for | ||
1349 | TV and video conferencing applications. | ||
1350 | </para> | ||
1351 | <para> | ||
1352 | The VIDIOCSPICT ioctl allows a user to set some of the picture parameters. | ||
1353 | Exactly which ones are supported depends heavily on the card itself. It is | ||
1354 | possible to support many modes and effects in software. In general doing | ||
1355 | this in the kernel is a bad idea. Video capture is a performance-sensitive | ||
1356 | application and the programs can often do better if they aren't being | ||
1357 | 'helped' by an overkeen driver writer. Thus for our device we will report | ||
1358 | RGB24 only and refuse to allow a change. | ||
1359 | </para> | ||
1360 | <programlisting> | ||
1361 | |||
1362 | |||
1363 | case VIDIOCSPICT: | ||
1364 | { | ||
1365 | struct video_picture v; | ||
1366 | if(copy_from_user(&v, arg, sizeof(v))) | ||
1367 | return -EFAULT; | ||
1368 | if(v.depth!=24 || | ||
1369 | v.palette != VIDEO_PALETTE_RGB24) | ||
1370 | return -EINVAL; | ||
1371 | set_hardware_brightness(v.brightness); | ||
1372 | set_hardware_hue(v.hue); | ||
1373 | set_hardware_saturation(v.colour); | ||
1374 | set_hardware_brightness(v.contrast); | ||
1375 | return 0; | ||
1376 | } | ||
1377 | |||
1378 | |||
1379 | </programlisting> | ||
1380 | <para> | ||
1381 | We check the user has not tried to change the palette or the depth. We do | ||
1382 | not want to carry out some of the changes and then return an error. This may | ||
1383 | confuse the application which will be assuming no change occurred. | ||
1384 | </para> | ||
1385 | <para> | ||
1386 | In much the same way as you need to be able to set the picture controls to | ||
1387 | get the right capture images, many cards need to know what they are | ||
1388 | displaying onto when generating overlay output. In some cases getting this | ||
1389 | wrong even makes a nasty mess or may crash the computer. For that reason | ||
1390 | the VIDIOCSBUF ioctl used to set up the frame buffer information may well | ||
1391 | only be usable by root. | ||
1392 | </para> | ||
1393 | <para> | ||
1394 | We will assume our card is one of the old ISA devices with feature connector | ||
1395 | and only supports a couple of standard video modes. Very common for older | ||
1396 | cards although the PCI devices are way smarter than this. | ||
1397 | </para> | ||
1398 | <programlisting> | ||
1399 | |||
1400 | |||
1401 | static struct video_buffer capture_fb; | ||
1402 | |||
1403 | case VIDIOCGFBUF: | ||
1404 | { | ||
1405 | if(copy_to_user(arg, &capture_fb, | ||
1406 | sizeof(capture_fb))) | ||
1407 | return -EFAULT; | ||
1408 | return 0; | ||
1409 | |||
1410 | } | ||
1411 | |||
1412 | |||
1413 | </programlisting> | ||
1414 | <para> | ||
1415 | We keep the frame buffer information in the format the ioctl uses. This | ||
1416 | makes it nice and easy to work with in the ioctl calls. | ||
1417 | </para> | ||
1418 | <programlisting> | ||
1419 | |||
1420 | case VIDIOCSFBUF: | ||
1421 | { | ||
1422 | struct video_buffer v; | ||
1423 | |||
1424 | if(!capable(CAP_SYS_ADMIN)) | ||
1425 | return -EPERM; | ||
1426 | |||
1427 | if(copy_from_user(&v, arg, sizeof(v))) | ||
1428 | return -EFAULT; | ||
1429 | if(v.width!=320 && v.width!=640) | ||
1430 | return -EINVAL; | ||
1431 | if(v.height!=200 && v.height!=240 | ||
1432 | && v.height!=400 | ||
1433 | && v.height !=480) | ||
1434 | return -EINVAL; | ||
1435 | memcpy(&capture_fb, &v, sizeof(v)); | ||
1436 | hardware_set_fb(&v); | ||
1437 | return 0; | ||
1438 | } | ||
1439 | |||
1440 | |||
1441 | |||
1442 | </programlisting> | ||
1443 | <para> | ||
1444 | The capable() function checks a user has the required capability. The Linux | ||
1445 | operating system has a set of about 30 capabilities indicating privileged | ||
1446 | access to services. The default set up gives the superuser (uid 0) all of | ||
1447 | them and nobody else has any. | ||
1448 | </para> | ||
1449 | <para> | ||
1450 | We check that the user has the SYS_ADMIN capability, that is they are | ||
1451 | allowed to operate as the machine administrator. We don't want anyone but | ||
1452 | the administrator making a mess of the display. | ||
1453 | </para> | ||
1454 | <para> | ||
1455 | Next we check for standard PC video modes (320 or 640 wide with either | ||
1456 | EGA or VGA depths). If the mode is not a standard video mode we reject it as | ||
1457 | not supported by our card. If the mode is acceptable we save it so that | ||
1458 | VIDIOCFBUF will give the right answer next time it is called. The | ||
1459 | hardware_set_fb() function is some undescribed card specific function to | ||
1460 | program the card for the desired mode. | ||
1461 | </para> | ||
1462 | <para> | ||
1463 | Before the driver can display an overlay window it needs to know where the | ||
1464 | window should be placed, and also how large it should be. If the card | ||
1465 | supports clipping it needs to know which rectangles to omit from the | ||
1466 | display. The video_window structure is used to describe the way the image | ||
1467 | should be displayed. | ||
1468 | </para> | ||
1469 | <table frame="all" id="video_window_fields"><title>struct video_window fields</title> | ||
1470 | <tgroup cols="2" align="left"> | ||
1471 | <tbody> | ||
1472 | <row> | ||
1473 | <entry>width</entry><entry>The width in pixels of the desired image. The card | ||
1474 | may use a smaller size if this size is not available</entry> | ||
1475 | </row><row> | ||
1476 | <entry>height</entry><entry>The height of the image. The card may use a smaller | ||
1477 | size if this size is not available.</entry> | ||
1478 | </row><row> | ||
1479 | <entry>x</entry><entry> The X position of the top left of the window. This | ||
1480 | is in pixels relative to the left hand edge of the | ||
1481 | picture. Not all cards can display images aligned on | ||
1482 | any pixel boundary. If the position is unsuitable | ||
1483 | the card adjusts the image right and reduces the | ||
1484 | width.</entry> | ||
1485 | </row><row> | ||
1486 | <entry>y</entry><entry> The Y position of the top left of the window. This | ||
1487 | is counted in pixels relative to the top edge of the | ||
1488 | picture. As with the width if the card cannot | ||
1489 | display starting on this line it will adjust the | ||
1490 | values.</entry> | ||
1491 | </row><row> | ||
1492 | <entry>chromakey</entry><entry>The colour (expressed in RGB32 format) for the | ||
1493 | chromakey colour if chroma keying is being used. </entry> | ||
1494 | </row><row> | ||
1495 | <entry>clips</entry><entry>An array of rectangles that must not be drawn | ||
1496 | over.</entry> | ||
1497 | </row><row> | ||
1498 | <entry>clipcount</entry><entry>The number of clips in this array.</entry> | ||
1499 | </row> | ||
1500 | </tbody> | ||
1501 | </tgroup> | ||
1502 | </table> | ||
1503 | <para> | ||
1504 | Each clip is a struct video_clip which has the following fields | ||
1505 | </para> | ||
1506 | <table frame="all" id="video_clip_fields"><title>video_clip fields</title> | ||
1507 | <tgroup cols="2" align="left"> | ||
1508 | <tbody> | ||
1509 | <row> | ||
1510 | <entry>x, y</entry><entry>Co-ordinates relative to the display</entry> | ||
1511 | </row><row> | ||
1512 | <entry>width, height</entry><entry>Width and height in pixels</entry> | ||
1513 | </row><row> | ||
1514 | <entry>next</entry><entry>A spare field for the application to use</entry> | ||
1515 | </row> | ||
1516 | </tbody> | ||
1517 | </tgroup> | ||
1518 | </table> | ||
1519 | <para> | ||
1520 | The driver is required to ensure it always draws in the area requested or a smaller area, and that it never draws in any of the areas that are clipped. | ||
1521 | This may well mean it has to leave alone. small areas the application wished to be | ||
1522 | drawn. | ||
1523 | </para> | ||
1524 | <para> | ||
1525 | Our example card uses chromakey so does not have to address most of the | ||
1526 | clipping. We will add a video_window structure to our global variables to | ||
1527 | remember our parameters, as we did with the frame buffer. | ||
1528 | </para> | ||
1529 | <programlisting> | ||
1530 | |||
1531 | |||
1532 | case VIDIOCGWIN: | ||
1533 | { | ||
1534 | if(copy_to_user(arg, &capture_win, | ||
1535 | sizeof(capture_win))) | ||
1536 | return -EFAULT; | ||
1537 | return 0; | ||
1538 | } | ||
1539 | |||
1540 | |||
1541 | case VIDIOCSWIN: | ||
1542 | { | ||
1543 | struct video_window v; | ||
1544 | if(copy_from_user(&v, arg, sizeof(v))) | ||
1545 | return -EFAULT; | ||
1546 | if(v.width > 640 || v.height > 480) | ||
1547 | return -EINVAL; | ||
1548 | if(v.width < 16 || v.height < 16) | ||
1549 | return -EINVAL; | ||
1550 | hardware_set_key(v.chromakey); | ||
1551 | hardware_set_window(v); | ||
1552 | memcpy(&capture_win, &v, sizeof(v)); | ||
1553 | capture_w = v.width; | ||
1554 | capture_h = v.height; | ||
1555 | return 0; | ||
1556 | } | ||
1557 | |||
1558 | |||
1559 | </programlisting> | ||
1560 | <para> | ||
1561 | Because we are using Chromakey our setup is fairly simple. Mostly we have to | ||
1562 | check the values are sane and load them into the capture card. | ||
1563 | </para> | ||
1564 | <para> | ||
1565 | With all the setup done we can now turn on the actual capture/overlay. This | ||
1566 | is done with the VIDIOCCAPTURE ioctl. This takes a single integer argument | ||
1567 | where 0 is on and 1 is off. | ||
1568 | </para> | ||
1569 | <programlisting> | ||
1570 | |||
1571 | |||
1572 | case VIDIOCCAPTURE: | ||
1573 | { | ||
1574 | int v; | ||
1575 | if(get_user(v, (int *)arg)) | ||
1576 | return -EFAULT; | ||
1577 | if(v==0) | ||
1578 | hardware_capture_off(); | ||
1579 | else | ||
1580 | { | ||
1581 | if(capture_fb.width == 0 | ||
1582 | || capture_w == 0) | ||
1583 | return -EINVAL; | ||
1584 | hardware_capture_on(); | ||
1585 | } | ||
1586 | return 0; | ||
1587 | } | ||
1588 | |||
1589 | |||
1590 | </programlisting> | ||
1591 | <para> | ||
1592 | We grab the flag from user space and either enable or disable according to | ||
1593 | its value. There is one small corner case we have to consider here. Suppose | ||
1594 | that the capture was requested before the video window or the frame buffer | ||
1595 | had been set up. In those cases there will be unconfigured fields in our | ||
1596 | card data, as well as unconfigured hardware settings. We check for this case and | ||
1597 | return an error if the frame buffer or the capture window width is zero. | ||
1598 | </para> | ||
1599 | <programlisting> | ||
1600 | |||
1601 | |||
1602 | default: | ||
1603 | return -ENOIOCTLCMD; | ||
1604 | } | ||
1605 | } | ||
1606 | </programlisting> | ||
1607 | <para> | ||
1608 | |||
1609 | We don't need to support any other ioctls, so if we get this far, it is time | ||
1610 | to tell the video layer that we don't now what the user is talking about. | ||
1611 | </para> | ||
1612 | </sect1> | ||
1613 | <sect1 id="endvid"> | ||
1614 | <title>Other Functionality</title> | ||
1615 | <para> | ||
1616 | The Video4Linux layer supports additional features, including a high | ||
1617 | performance mmap() based capture mode and capturing part of the image. | ||
1618 | These features are out of the scope of the book. You should however have enough | ||
1619 | example code to implement most simple video4linux devices for radio and TV | ||
1620 | cards. | ||
1621 | </para> | ||
1622 | </sect1> | ||
1623 | </chapter> | ||
1624 | <chapter id="bugs"> | ||
1625 | <title>Known Bugs And Assumptions</title> | ||
1626 | <para> | ||
1627 | <variablelist> | ||
1628 | <varlistentry><term>Multiple Opens</term> | ||
1629 | <listitem> | ||
1630 | <para> | ||
1631 | The driver assumes multiple opens should not be allowed. A driver | ||
1632 | can work around this but not cleanly. | ||
1633 | </para> | ||
1634 | </listitem></varlistentry> | ||
1635 | |||
1636 | <varlistentry><term>API Deficiencies</term> | ||
1637 | <listitem> | ||
1638 | <para> | ||
1639 | The existing API poorly reflects compression capable devices. There | ||
1640 | are plans afoot to merge V4L, V4L2 and some other ideas into a | ||
1641 | better interface. | ||
1642 | </para> | ||
1643 | </listitem></varlistentry> | ||
1644 | </variablelist> | ||
1645 | |||
1646 | </para> | ||
1647 | </chapter> | ||
1648 | |||
1649 | <chapter id="pubfunctions"> | ||
1650 | <title>Public Functions Provided</title> | ||
1651 | !Edrivers/media/video/v4l2-dev.c | ||
1652 | </chapter> | ||
1653 | |||
1654 | </book> | ||