usb 11 KB

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  1. .TH USB 2
  2. .SH NAME
  3. usbcmd,
  4. classname,
  5. closedev,
  6. configdev,
  7. devctl,
  8. finddevs,
  9. loaddevstr,
  10. matchdevcsp,
  11. opendev,
  12. opendevdata,
  13. openep,
  14. startdevs,
  15. unstall,
  16. class,
  17. subclass,
  18. proto,
  19. CSP \- USB device driver library
  20. .SH SYNOPSIS
  21. .EX
  22. .ta 8n +8n +8n +8n +8n +8n +8n
  23. #include <u.h>
  24. #include <libc.h>
  25. #include <thread.h>
  26. #include "../lib/usb.h"
  27. .sp 0.3v
  28. struct Dev {
  29. Ref;
  30. char* dir; /* path for the endpoint dir */
  31. int id; /* usb id for device or ep. number */
  32. int dfd; /* descriptor for the data file */
  33. int cfd; /* descriptor for the control file */
  34. int maxpkt; /* cached from usb description */
  35. Usbdev* usb; /* USB description */
  36. void* aux; /* for the device driver */
  37. void (*free)(void*); /* idem. to release aux */
  38. };
  39. .sp 0.3v
  40. struct Usbdev {
  41. ulong csp; /* USB class/subclass/proto */
  42. int vid; /* vendor id */
  43. int did; /* product (device) id */
  44. int dno; /* device release number */
  45. char* vendor;
  46. char* product;
  47. char* serial;
  48. int ls; /* low speed */
  49. int class; /* from descriptor */
  50. int nconf; /* from descriptor */
  51. Conf* conf[Nconf]; /* configurations */
  52. Ep* ep[Nep]; /* all endpoints in device */
  53. Desc* ddesc[Nddesc]; /* (raw) device specific descriptors */
  54. };
  55. .sp 0.3v
  56. struct Ep {
  57. uchar addr; /* endpt address */
  58. uchar dir; /* direction, Ein/Eout */
  59. uchar type; /* Econtrol, Eiso, Ebulk, Eintr */
  60. uchar isotype; /* Eunknown, Easync, Eadapt, Esync */
  61. int id;
  62. int maxpkt; /* max. packet size */
  63. Conf* conf; /* the endpoint belongs to */
  64. Iface* iface; /* the endpoint belongs to */
  65. };
  66. .sp 0.3v
  67. struct Altc {
  68. int attrib;
  69. int interval;
  70. void* aux; /* for the driver program */
  71. };
  72. .sp 0.3v
  73. struct Iface {
  74. int id; /* interface number */
  75. ulong csp; /* USB class/subclass/proto */
  76. Altc* altc[Naltc];
  77. Ep* ep[Nep];
  78. void* aux; /* for the driver program */
  79. };
  80. .sp 0.3v
  81. struct Conf {
  82. int cval; /* value for set configuration */
  83. int attrib;
  84. int milliamps; /* maximum power in this config. */
  85. Iface* iface[Niface]; /* up to 16 interfaces */
  86. };
  87. .sp 0.3v
  88. struct Desc {
  89. Conf* conf; /* where this descriptor was read */
  90. Iface* iface; /* last iface before desc in conf. */
  91. Ep* ep; /* last endpt before desc in conf. */
  92. Altc* altc; /* last alt.c. before desc in conf. */
  93. DDesc data; /* unparsed standard USB descriptor */
  94. };
  95. .sp 0.3v
  96. struct DDesc {
  97. uchar bLength;
  98. uchar bDescriptorType;
  99. uchar bbytes[1];
  100. /* extra bytes allocated here to keep the rest of it */
  101. };
  102. .sp 0.3v
  103. #define Class(csp) ((csp)&0xff)
  104. #define Subclass(csp) (((csp)>>8)&0xff)
  105. #define Proto(csp) (((csp)>>16)&0xff)
  106. #define CSP(c, s, p) ((c) | ((s)<<8) | ((p)<<16))
  107. #define GET2(p) ...
  108. #define PUT2(p,v) ...
  109. #define GET4(p) ...
  110. #define PUT4(p,v) ...
  111. #define dprint if(usbdebug)fprint
  112. #define ddprint if(usbdebug > 1)fprint
  113. .sp 0.3v
  114. int Ufmt(Fmt *f);
  115. char* classname(int c);
  116. void closedev(Dev *d);
  117. int configdev(Dev *d);
  118. int devctl(Dev *dev, char *fmt, ...);
  119. void* emallocz(ulong size, int zero);
  120. char* estrdup(char *s);
  121. int finddevs(int (*matchf)(char*,void*), void *farg, char** dirs, int ndirs);
  122. char* hexstr(void *a, int n);
  123. char* loaddevstr(Dev *d, int sid);
  124. int matchdevcsp(char *info, void *a);
  125. Dev* opendev(char *fn);
  126. int opendevdata(Dev *d, int mode);
  127. Dev* openep(Dev *d, int id);
  128. void startdevs(char *args, char *argv[], int argc,
  129. int (*mf)(char*,void*), void*ma, int (*df)(Dev*,int,char**));
  130. int unstall(Dev *dev, Dev *ep, int dir);
  131. int usbcmd(Dev *d, int type, int req,
  132. int value, int index, uchar *data, int count);
  133. .sp 0.3v
  134. extern int usbdebug; /* more messages for bigger values */
  135. .EE
  136. .SH DESCRIPTION
  137. This library provides convenience structures and functions to write
  138. USB device drivers.
  139. It is not intended for user programs using USB devices.
  140. See
  141. .IR usb (3)
  142. for a description of the interfaces provided for that purpose.
  143. For drivers that provide a file system and may be embedded into
  144. .IR usbd ,
  145. the library includes a file system implementation toolkit described in
  146. .IR usbfs (2).
  147. .PP
  148. Usb drivers rely on
  149. .IR usb (3)
  150. to perform I/O through USB as well as on
  151. .IR usbd (4)
  152. to perform the initial configuration for the device's setup endpoint.
  153. The rest of the work is up to the driver and is where this library may help.
  154. .PP
  155. In most cases, a driver locates the devices of interest and configures them
  156. by calling
  157. .I startdevs
  158. and
  159. then sets up additional endpoints as needed (by calling
  160. .IR openep )
  161. to finally perform I/O by reading and writing the
  162. data files for the endpoints.
  163. .PP
  164. An endpoint as provided by
  165. .IR usb (3)
  166. is represented by a
  167. .B Dev
  168. data structure.
  169. The setup endpoint for a
  170. device represents the USB device, because it is the means to
  171. configure and operate the device.
  172. This structure is reference counted.
  173. Functions creating
  174. .B Devs
  175. adjust the number of references to one, initially.
  176. The driver is free to call
  177. .IR incref
  178. (in
  179. .IR lock (2))
  180. to add references and
  181. .I closedev
  182. to drop references (and release resources when the last one vanishes).
  183. As an aid to the driver, the field
  184. .B aux
  185. may keep driver-specific data and the function
  186. .B free
  187. will be called (if not null) to release the
  188. .B aux
  189. structure when the reference count goes down to zero.
  190. .PP
  191. .I Dev.dir
  192. holds the path for the endpoint's directory.
  193. .PP
  194. The field
  195. .B id
  196. keeps the device number for setup endpoints and the endpoint number
  197. for all other endpoints.
  198. For example, it would be
  199. .B 3
  200. for
  201. .B /dev/usb/ep3.0
  202. and
  203. .B 1
  204. for
  205. .BR /dev/usb/ep3.1 .
  206. It is easy to remember this because the former is created to operate
  207. on the device, while the later has been created as a particular endpoint
  208. to perform I/O.
  209. .PP
  210. Fields
  211. .B dfd
  212. and
  213. .B cfd
  214. keep the data and
  215. control file descriptors, respectively.
  216. When a
  217. .B Dev
  218. is created the control file is open, initially.
  219. Opening the data
  220. file requires calling
  221. .I opendevdata
  222. with the appropriate mode.
  223. .PP
  224. When the device configuration information has been loaded (see below),
  225. .B maxpkt
  226. holds the maximum packet size (in bytes) for the endpoint and
  227. .B usb
  228. keeps the rest of the USB information.
  229. .PP
  230. Most of the information in
  231. .B usb
  232. comes from parsing
  233. various device and configuration descriptors provided by the device,
  234. by calling one of the functions described later.
  235. Only descriptors unknown
  236. to the library are kept unparsed at
  237. .B usb.ddesc
  238. as an aid for the driver
  239. (which should know how to parse them and what to do with the information).
  240. .SS Configuration
  241. .I Startdevs
  242. is a wrapper that locates devices of interest, loads their configuration
  243. information, and starts a
  244. .IR thread (2)'s
  245. .I proc
  246. for each device located so that it executes
  247. .I f
  248. as its main entry point. The entry point is called with a pointer to
  249. the
  250. .B Dev
  251. for the device it has to process,
  252. .BR argc ,
  253. and
  254. .BR argv .
  255. Devices are located either from the arguments (after options) in
  256. .IR argv ,
  257. if any,
  258. or by calling the helper function
  259. .I mf
  260. with the argument
  261. .I ma
  262. to determine (for each device available) if the device belongs to
  263. the driver or not. If the function returns -1 then the device is not for us.
  264. .PP
  265. In many cases,
  266. .I matchdevcsp
  267. may be supplied as
  268. .I mf
  269. along with a (null terminated) vector of CSP values supplied as
  270. .IR ma .
  271. This function returns 0 for any device with a CSP matching one in the
  272. vector supplied as an argument and -1 otherwise.
  273. In other cases (eg., when a particular vendor and device ids are the
  274. ones identifying the device) the driver must include its own function
  275. and supply it as an argument to
  276. .IR startdevs .
  277. The first argument of the function corresponds to the information
  278. known about the device (the second line in its
  279. .B ctl
  280. file).
  281. .I Openep
  282. creates the endpoint number
  283. .I id
  284. for the device
  285. .I d
  286. and returns a
  287. .B Dev
  288. structure to operate on it (with just the control file open).
  289. .PP
  290. .I Opendev
  291. creates a
  292. .B Dev
  293. for the endpoint with directory
  294. .IR fn .
  295. Usually, the endpoint is a setup endpoint representing a device. The endpoint
  296. control file is open, but the data file is not. The USB description is void.
  297. In most cases drivers call
  298. .I startdevs
  299. and
  300. .I openep
  301. and do not call this function directly.
  302. .PP
  303. .I Configdev
  304. opens the data file for the device supplied and
  305. loads and parses its configuration information.
  306. After calling it, the device is ready for I/O and the USB description in
  307. .B Dev.usb
  308. is valid.
  309. When using
  310. .IR startdevs
  311. it is not desirable to call this function (because
  312. .IR startdevs
  313. already calls it).
  314. .PP
  315. Control requests for an endpoint may be written by calling
  316. .I devctl
  317. in the style of
  318. .IR print (2).
  319. It is better not to call
  320. .I print
  321. directly because the control request should be issued as a single
  322. .I write
  323. system call.
  324. See
  325. .IR usb (3)
  326. for a list of available control requests (not to be confused with
  327. USB control transfers performed on a control endpoint).
  328. .SS Input/Output
  329. .I Opendevdata
  330. opens the data file for the device according to the given
  331. .IR mode .
  332. The mode must match that of the endpoint, doing otherwise is considered
  333. an error.
  334. Actual I/O is performed by reading/writing the descriptor kept in the
  335. .B dfd
  336. field of
  337. .BR Dev .
  338. .PP
  339. For control endpoints,
  340. it is not necessary to call
  341. .I read
  342. and
  343. .I write
  344. directly.
  345. Instead,
  346. .I usbcmd
  347. issues a USB control request to the device
  348. .I d
  349. (not to be confused with a
  350. .IR usb (3)
  351. control request sent to its control file).
  352. .I Usbcmd
  353. retries the control request several times upon failure because some devices
  354. require it.
  355. The format of requests is fixed per the USB standard:
  356. .I type
  357. is the type of request and
  358. .I req
  359. identifies the request. Arguments
  360. .I value
  361. and
  362. .I index
  363. are parameters to the request and the last two arguments,
  364. .I data
  365. and
  366. .IR count ,
  367. are similar to
  368. .I read
  369. and
  370. .I write
  371. arguments.
  372. However,
  373. .I data
  374. may be
  375. .B nil
  376. if no transfer (other than the control request) has to take place.
  377. The library header file includes numerous symbols defined to help writing
  378. the type and arguments for a request.
  379. .PP
  380. The return value from
  381. .I usbcmd
  382. is the number of bytes transferred, zero to indicate a stall and -1
  383. to indicate an error.
  384. .PP
  385. A common request is to unstall an endpoint that has been stalled
  386. due to some reason by the device (eg., when read or write indicate
  387. a count of zero bytes read or written on the endpoint). The function
  388. .I unstall
  389. does this.
  390. It is given the device that stalled the endpoint,
  391. .IR dev ,
  392. the
  393. stalled endpoint,
  394. .IR ep ,
  395. and the direction of the stall (one of
  396. .B Ein
  397. or
  398. .BR Eout ).
  399. The function takes care of notifying the device of the unstall as well
  400. as notifying the kernel.
  401. .SS Tools
  402. .I Class
  403. returns the class part of the number given, representing a CSP.
  404. .I Subclass
  405. does the same for the device subclass and
  406. .I Proto
  407. for the protocol.
  408. The counterpart is
  409. .IR CSP ,
  410. which builds a CSP from the device class, subclass, and protocol.
  411. For some classes,
  412. .I classname
  413. knows the name (for those with constants in the library header file).
  414. .PP
  415. The macros
  416. .I GET2
  417. and
  418. .I PUT2
  419. get and put a (little-endian) two-byte value and are useful to
  420. parse descriptors and replies for control requests.
  421. .PP
  422. Functions
  423. .I emallocz
  424. and
  425. .I estrdup
  426. are similar to
  427. .I mallocz
  428. and
  429. .I strdup
  430. but abort program operation upon failure.
  431. .PP
  432. The function
  433. .I Ufmt
  434. is a format routine suitable for
  435. .IR fmtinstall (2)
  436. to print a
  437. .B Dev
  438. data structure.
  439. The auxiliary
  440. .I hexstr
  441. returns a string representing a dump (in hexadecimal) of
  442. .I n
  443. bytes starting at
  444. .IR a .
  445. The string is allocated using
  446. .IR malloc (2)
  447. and memory must be released by the caller.
  448. .PP
  449. .I Loaddevstr
  450. returns the string obtained by reading the device string descriptor number
  451. .IR sid .
  452. .SH SOURCE
  453. .B /sys/src/cmd/usb/lib
  454. .SH "SEE ALSO"
  455. .IR usbfs (2),
  456. .IR usb (3),
  457. .IR usb (4),
  458. .IR usbd (4).
  459. .SH BUGS
  460. Not heavily exercised yet.