mceusb.c 53 KB

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  1. // SPDX-License-Identifier: GPL-2.0-or-later
  2. /*
  3. * Driver for USB Windows Media Center Ed. eHome Infrared Transceivers
  4. *
  5. * Copyright (c) 2010-2011, Jarod Wilson <jarod@redhat.com>
  6. *
  7. * Based on the original lirc_mceusb and lirc_mceusb2 drivers, by Dan
  8. * Conti, Martin Blatter and Daniel Melander, the latter of which was
  9. * in turn also based on the lirc_atiusb driver by Paul Miller. The
  10. * two mce drivers were merged into one by Jarod Wilson, with transmit
  11. * support for the 1st-gen device added primarily by Patrick Calhoun,
  12. * with a bit of tweaks by Jarod. Debugging improvements and proper
  13. * support for what appears to be 3rd-gen hardware added by Jarod.
  14. * Initial port from lirc driver to ir-core drivery by Jarod, based
  15. * partially on a port to an earlier proposed IR infrastructure by
  16. * Jon Smirl, which included enhancements and simplifications to the
  17. * incoming IR buffer parsing routines.
  18. *
  19. * Updated in July of 2011 with the aid of Microsoft's official
  20. * remote/transceiver requirements and specification document, found at
  21. * download.microsoft.com, title
  22. * Windows-Media-Center-RC-IR-Collection-Green-Button-Specification-03-08-2011-V2.pdf
  23. */
  24. #include <linux/device.h>
  25. #include <linux/module.h>
  26. #include <linux/slab.h>
  27. #include <linux/workqueue.h>
  28. #include <linux/usb.h>
  29. #include <linux/usb/input.h>
  30. #include <media/rc-core.h>
  31. #define DRIVER_VERSION "1.95"
  32. #define DRIVER_AUTHOR "Jarod Wilson <jarod@redhat.com>"
  33. #define DRIVER_DESC "Windows Media Center Ed. eHome Infrared Transceiver " \
  34. "device driver"
  35. #define DRIVER_NAME "mceusb"
  36. #define USB_TX_TIMEOUT 1000 /* in milliseconds */
  37. #define USB_CTRL_MSG_SZ 2 /* Size of usb ctrl msg on gen1 hw */
  38. #define MCE_G1_INIT_MSGS 40 /* Init messages on gen1 hw to throw out */
  39. /* MCE constants */
  40. #define MCE_IRBUF_SIZE 128 /* TX IR buffer length */
  41. #define MCE_TIME_UNIT 50 /* Approx 50us resolution */
  42. #define MCE_PACKET_SIZE 31 /* Max length of packet (with header) */
  43. #define MCE_IRDATA_HEADER (0x80 + MCE_PACKET_SIZE - 1)
  44. /* Actual format is 0x80 + num_bytes */
  45. #define MCE_IRDATA_TRAILER 0x80 /* End of IR data */
  46. #define MCE_MAX_CHANNELS 2 /* Two transmitters, hardware dependent? */
  47. #define MCE_DEFAULT_TX_MASK 0x03 /* Vals: TX1=0x01, TX2=0x02, ALL=0x03 */
  48. #define MCE_PULSE_BIT 0x80 /* Pulse bit, MSB set == PULSE else SPACE */
  49. #define MCE_PULSE_MASK 0x7f /* Pulse mask */
  50. #define MCE_MAX_PULSE_LENGTH 0x7f /* Longest transmittable pulse symbol */
  51. /*
  52. * The interface between the host and the IR hardware is command-response
  53. * based. All commands and responses have a consistent format, where a lead
  54. * byte always identifies the type of data following it. The lead byte has
  55. * a port value in the 3 highest bits and a length value in the 5 lowest
  56. * bits.
  57. *
  58. * The length field is overloaded, with a value of 11111 indicating that the
  59. * following byte is a command or response code, and the length of the entire
  60. * message is determined by the code. If the length field is not 11111, then
  61. * it specifies the number of bytes of port data that follow.
  62. */
  63. #define MCE_CMD 0x1f
  64. #define MCE_PORT_IR 0x4 /* (0x4 << 5) | MCE_CMD = 0x9f */
  65. #define MCE_PORT_SYS 0x7 /* (0x7 << 5) | MCE_CMD = 0xff */
  66. #define MCE_PORT_SER 0x6 /* 0xc0 through 0xdf flush & 0x1f bytes */
  67. #define MCE_PORT_MASK 0xe0 /* Mask out command bits */
  68. /* Command port headers */
  69. #define MCE_CMD_PORT_IR 0x9f /* IR-related cmd/rsp */
  70. #define MCE_CMD_PORT_SYS 0xff /* System (non-IR) device cmd/rsp */
  71. /* Commands that set device state (2-4 bytes in length) */
  72. #define MCE_CMD_RESET 0xfe /* Reset device, 2 bytes */
  73. #define MCE_CMD_RESUME 0xaa /* Resume device after error, 2 bytes */
  74. #define MCE_CMD_SETIRCFS 0x06 /* Set tx carrier, 4 bytes */
  75. #define MCE_CMD_SETIRTIMEOUT 0x0c /* Set timeout, 4 bytes */
  76. #define MCE_CMD_SETIRTXPORTS 0x08 /* Set tx ports, 3 bytes */
  77. #define MCE_CMD_SETIRRXPORTEN 0x14 /* Set rx ports, 3 bytes */
  78. #define MCE_CMD_FLASHLED 0x23 /* Flash receiver LED, 2 bytes */
  79. /* Commands that query device state (all 2 bytes, unless noted) */
  80. #define MCE_CMD_GETIRCFS 0x07 /* Get carrier */
  81. #define MCE_CMD_GETIRTIMEOUT 0x0d /* Get timeout */
  82. #define MCE_CMD_GETIRTXPORTS 0x13 /* Get tx ports */
  83. #define MCE_CMD_GETIRRXPORTEN 0x15 /* Get rx ports */
  84. #define MCE_CMD_GETPORTSTATUS 0x11 /* Get tx port status, 3 bytes */
  85. #define MCE_CMD_GETIRNUMPORTS 0x16 /* Get number of ports */
  86. #define MCE_CMD_GETWAKESOURCE 0x17 /* Get wake source */
  87. #define MCE_CMD_GETEMVER 0x22 /* Get emulator interface version */
  88. #define MCE_CMD_GETDEVDETAILS 0x21 /* Get device details (em ver2 only) */
  89. #define MCE_CMD_GETWAKESUPPORT 0x20 /* Get wake details (em ver2 only) */
  90. #define MCE_CMD_GETWAKEVERSION 0x18 /* Get wake pattern (em ver2 only) */
  91. /* Misc commands */
  92. #define MCE_CMD_NOP 0xff /* No operation */
  93. /* Responses to commands (non-error cases) */
  94. #define MCE_RSP_EQIRCFS 0x06 /* tx carrier, 4 bytes */
  95. #define MCE_RSP_EQIRTIMEOUT 0x0c /* rx timeout, 4 bytes */
  96. #define MCE_RSP_GETWAKESOURCE 0x17 /* wake source, 3 bytes */
  97. #define MCE_RSP_EQIRTXPORTS 0x08 /* tx port mask, 3 bytes */
  98. #define MCE_RSP_EQIRRXPORTEN 0x14 /* rx port mask, 3 bytes */
  99. #define MCE_RSP_GETPORTSTATUS 0x11 /* tx port status, 7 bytes */
  100. #define MCE_RSP_EQIRRXCFCNT 0x15 /* rx carrier count, 4 bytes */
  101. #define MCE_RSP_EQIRNUMPORTS 0x16 /* number of ports, 4 bytes */
  102. #define MCE_RSP_EQWAKESUPPORT 0x20 /* wake capabilities, 3 bytes */
  103. #define MCE_RSP_EQWAKEVERSION 0x18 /* wake pattern details, 6 bytes */
  104. #define MCE_RSP_EQDEVDETAILS 0x21 /* device capabilities, 3 bytes */
  105. #define MCE_RSP_EQEMVER 0x22 /* emulator interface ver, 3 bytes */
  106. #define MCE_RSP_FLASHLED 0x23 /* success flashing LED, 2 bytes */
  107. /* Responses to error cases, must send MCE_CMD_RESUME to clear them */
  108. #define MCE_RSP_CMD_ILLEGAL 0xfe /* illegal command for port, 2 bytes */
  109. #define MCE_RSP_TX_TIMEOUT 0x81 /* tx timed out, 2 bytes */
  110. /* Misc commands/responses not defined in the MCE remote/transceiver spec */
  111. #define MCE_CMD_SIG_END 0x01 /* End of signal */
  112. #define MCE_CMD_PING 0x03 /* Ping device */
  113. #define MCE_CMD_UNKNOWN 0x04 /* Unknown */
  114. #define MCE_CMD_UNKNOWN2 0x05 /* Unknown */
  115. #define MCE_CMD_UNKNOWN3 0x09 /* Unknown */
  116. #define MCE_CMD_UNKNOWN4 0x0a /* Unknown */
  117. #define MCE_CMD_G_REVISION 0x0b /* Get hw/sw revision */
  118. #define MCE_CMD_UNKNOWN5 0x0e /* Unknown */
  119. #define MCE_CMD_UNKNOWN6 0x0f /* Unknown */
  120. #define MCE_CMD_UNKNOWN8 0x19 /* Unknown */
  121. #define MCE_CMD_UNKNOWN9 0x1b /* Unknown */
  122. #define MCE_CMD_NULL 0x00 /* These show up various places... */
  123. /* if buf[i] & MCE_PORT_MASK == 0x80 and buf[i] != MCE_CMD_PORT_IR,
  124. * then we're looking at a raw IR data sample */
  125. #define MCE_COMMAND_IRDATA 0x80
  126. #define MCE_PACKET_LENGTH_MASK 0x1f /* Packet length mask */
  127. #define VENDOR_PHILIPS 0x0471
  128. #define VENDOR_SMK 0x0609
  129. #define VENDOR_TATUNG 0x1460
  130. #define VENDOR_GATEWAY 0x107b
  131. #define VENDOR_SHUTTLE 0x1308
  132. #define VENDOR_SHUTTLE2 0x051c
  133. #define VENDOR_MITSUMI 0x03ee
  134. #define VENDOR_TOPSEED 0x1784
  135. #define VENDOR_RICAVISION 0x179d
  136. #define VENDOR_ITRON 0x195d
  137. #define VENDOR_FIC 0x1509
  138. #define VENDOR_LG 0x043e
  139. #define VENDOR_MICROSOFT 0x045e
  140. #define VENDOR_FORMOSA 0x147a
  141. #define VENDOR_FINTEK 0x1934
  142. #define VENDOR_PINNACLE 0x2304
  143. #define VENDOR_ECS 0x1019
  144. #define VENDOR_WISTRON 0x0fb8
  145. #define VENDOR_COMPRO 0x185b
  146. #define VENDOR_NORTHSTAR 0x04eb
  147. #define VENDOR_REALTEK 0x0bda
  148. #define VENDOR_TIVO 0x105a
  149. #define VENDOR_CONEXANT 0x0572
  150. #define VENDOR_TWISTEDMELON 0x2596
  151. #define VENDOR_HAUPPAUGE 0x2040
  152. #define VENDOR_PCTV 0x2013
  153. #define VENDOR_ADAPTEC 0x03f3
  154. enum mceusb_model_type {
  155. MCE_GEN2 = 0, /* Most boards */
  156. MCE_GEN1,
  157. MCE_GEN3,
  158. MCE_GEN3_BROKEN_IRTIMEOUT,
  159. MCE_GEN2_TX_INV,
  160. MCE_GEN2_TX_INV_RX_GOOD,
  161. POLARIS_EVK,
  162. CX_HYBRID_TV,
  163. MULTIFUNCTION,
  164. TIVO_KIT,
  165. MCE_GEN2_NO_TX,
  166. HAUPPAUGE_CX_HYBRID_TV,
  167. EVROMEDIA_FULL_HYBRID_FULLHD,
  168. ASTROMETA_T2HYBRID,
  169. };
  170. struct mceusb_model {
  171. u32 mce_gen1:1;
  172. u32 mce_gen2:1;
  173. u32 mce_gen3:1;
  174. u32 tx_mask_normal:1;
  175. u32 no_tx:1;
  176. u32 broken_irtimeout:1;
  177. /*
  178. * 2nd IR receiver (short-range, wideband) for learning mode:
  179. * 0, absent 2nd receiver (rx2)
  180. * 1, rx2 present
  181. * 2, rx2 which under counts IR carrier cycles
  182. */
  183. u32 rx2;
  184. int ir_intfnum;
  185. const char *rc_map; /* Allow specify a per-board map */
  186. const char *name; /* per-board name */
  187. };
  188. static const struct mceusb_model mceusb_model[] = {
  189. [MCE_GEN1] = {
  190. .mce_gen1 = 1,
  191. .tx_mask_normal = 1,
  192. .rx2 = 2,
  193. },
  194. [MCE_GEN2] = {
  195. .mce_gen2 = 1,
  196. .rx2 = 2,
  197. },
  198. [MCE_GEN2_NO_TX] = {
  199. .mce_gen2 = 1,
  200. .no_tx = 1,
  201. },
  202. [MCE_GEN2_TX_INV] = {
  203. .mce_gen2 = 1,
  204. .tx_mask_normal = 1,
  205. .rx2 = 1,
  206. },
  207. [MCE_GEN2_TX_INV_RX_GOOD] = {
  208. .mce_gen2 = 1,
  209. .tx_mask_normal = 1,
  210. .rx2 = 2,
  211. },
  212. [MCE_GEN3] = {
  213. .mce_gen3 = 1,
  214. .tx_mask_normal = 1,
  215. .rx2 = 2,
  216. },
  217. [MCE_GEN3_BROKEN_IRTIMEOUT] = {
  218. .mce_gen3 = 1,
  219. .tx_mask_normal = 1,
  220. .rx2 = 2,
  221. .broken_irtimeout = 1
  222. },
  223. [POLARIS_EVK] = {
  224. /*
  225. * In fact, the EVK is shipped without
  226. * remotes, but we should have something handy,
  227. * to allow testing it
  228. */
  229. .name = "Conexant Hybrid TV (cx231xx) MCE IR",
  230. .rx2 = 2,
  231. },
  232. [CX_HYBRID_TV] = {
  233. .no_tx = 1, /* tx isn't wired up at all */
  234. .name = "Conexant Hybrid TV (cx231xx) MCE IR",
  235. },
  236. [HAUPPAUGE_CX_HYBRID_TV] = {
  237. .no_tx = 1, /* eeprom says it has no tx */
  238. .name = "Conexant Hybrid TV (cx231xx) MCE IR no TX",
  239. },
  240. [MULTIFUNCTION] = {
  241. .mce_gen2 = 1,
  242. .ir_intfnum = 2,
  243. .rx2 = 2,
  244. },
  245. [TIVO_KIT] = {
  246. .mce_gen2 = 1,
  247. .rc_map = RC_MAP_TIVO,
  248. .rx2 = 2,
  249. },
  250. [EVROMEDIA_FULL_HYBRID_FULLHD] = {
  251. .name = "Evromedia USB Full Hybrid Full HD",
  252. .no_tx = 1,
  253. .rc_map = RC_MAP_MSI_DIGIVOX_III,
  254. },
  255. [ASTROMETA_T2HYBRID] = {
  256. .name = "Astrometa T2Hybrid",
  257. .no_tx = 1,
  258. .rc_map = RC_MAP_ASTROMETA_T2HYBRID,
  259. }
  260. };
  261. static const struct usb_device_id mceusb_dev_table[] = {
  262. /* Original Microsoft MCE IR Transceiver (often HP-branded) */
  263. { USB_DEVICE(VENDOR_MICROSOFT, 0x006d),
  264. .driver_info = MCE_GEN1 },
  265. /* Philips Infrared Transceiver - Sahara branded */
  266. { USB_DEVICE(VENDOR_PHILIPS, 0x0608) },
  267. /* Philips Infrared Transceiver - HP branded */
  268. { USB_DEVICE(VENDOR_PHILIPS, 0x060c),
  269. .driver_info = MCE_GEN2_TX_INV },
  270. /* Philips SRM5100 */
  271. { USB_DEVICE(VENDOR_PHILIPS, 0x060d) },
  272. /* Philips Infrared Transceiver - Omaura */
  273. { USB_DEVICE(VENDOR_PHILIPS, 0x060f) },
  274. /* Philips Infrared Transceiver - Spinel plus */
  275. { USB_DEVICE(VENDOR_PHILIPS, 0x0613) },
  276. /* Philips eHome Infrared Transceiver */
  277. { USB_DEVICE(VENDOR_PHILIPS, 0x0815) },
  278. /* Philips/Spinel plus IR transceiver for ASUS */
  279. { USB_DEVICE(VENDOR_PHILIPS, 0x206c) },
  280. /* Philips/Spinel plus IR transceiver for ASUS */
  281. { USB_DEVICE(VENDOR_PHILIPS, 0x2088) },
  282. /* Philips IR transceiver (Dell branded) */
  283. { USB_DEVICE(VENDOR_PHILIPS, 0x2093),
  284. .driver_info = MCE_GEN2_TX_INV },
  285. /* Realtek MCE IR Receiver and card reader */
  286. { USB_DEVICE(VENDOR_REALTEK, 0x0161),
  287. .driver_info = MULTIFUNCTION },
  288. /* SMK/Toshiba G83C0004D410 */
  289. { USB_DEVICE(VENDOR_SMK, 0x031d),
  290. .driver_info = MCE_GEN2_TX_INV_RX_GOOD },
  291. /* SMK eHome Infrared Transceiver (Sony VAIO) */
  292. { USB_DEVICE(VENDOR_SMK, 0x0322),
  293. .driver_info = MCE_GEN2_TX_INV },
  294. /* bundled with Hauppauge PVR-150 */
  295. { USB_DEVICE(VENDOR_SMK, 0x0334),
  296. .driver_info = MCE_GEN2_TX_INV },
  297. /* SMK eHome Infrared Transceiver */
  298. { USB_DEVICE(VENDOR_SMK, 0x0338) },
  299. /* SMK/I-O Data GV-MC7/RCKIT Receiver */
  300. { USB_DEVICE(VENDOR_SMK, 0x0353),
  301. .driver_info = MCE_GEN2_NO_TX },
  302. /* SMK RXX6000 Infrared Receiver */
  303. { USB_DEVICE(VENDOR_SMK, 0x0357),
  304. .driver_info = MCE_GEN2_NO_TX },
  305. /* Tatung eHome Infrared Transceiver */
  306. { USB_DEVICE(VENDOR_TATUNG, 0x9150) },
  307. /* Shuttle eHome Infrared Transceiver */
  308. { USB_DEVICE(VENDOR_SHUTTLE, 0xc001) },
  309. /* Shuttle eHome Infrared Transceiver */
  310. { USB_DEVICE(VENDOR_SHUTTLE2, 0xc001) },
  311. /* Gateway eHome Infrared Transceiver */
  312. { USB_DEVICE(VENDOR_GATEWAY, 0x3009) },
  313. /* Mitsumi */
  314. { USB_DEVICE(VENDOR_MITSUMI, 0x2501) },
  315. /* Topseed eHome Infrared Transceiver */
  316. { USB_DEVICE(VENDOR_TOPSEED, 0x0001),
  317. .driver_info = MCE_GEN2_TX_INV },
  318. /* Topseed HP eHome Infrared Transceiver */
  319. { USB_DEVICE(VENDOR_TOPSEED, 0x0006),
  320. .driver_info = MCE_GEN2_TX_INV },
  321. /* Topseed eHome Infrared Transceiver */
  322. { USB_DEVICE(VENDOR_TOPSEED, 0x0007),
  323. .driver_info = MCE_GEN2_TX_INV },
  324. /* Topseed eHome Infrared Transceiver */
  325. { USB_DEVICE(VENDOR_TOPSEED, 0x0008),
  326. .driver_info = MCE_GEN3 },
  327. /* Topseed eHome Infrared Transceiver */
  328. { USB_DEVICE(VENDOR_TOPSEED, 0x000a),
  329. .driver_info = MCE_GEN2_TX_INV },
  330. /* Topseed eHome Infrared Transceiver */
  331. { USB_DEVICE(VENDOR_TOPSEED, 0x0011),
  332. .driver_info = MCE_GEN3_BROKEN_IRTIMEOUT },
  333. /* Ricavision internal Infrared Transceiver */
  334. { USB_DEVICE(VENDOR_RICAVISION, 0x0010) },
  335. /* Itron ione Libra Q-11 */
  336. { USB_DEVICE(VENDOR_ITRON, 0x7002) },
  337. /* FIC eHome Infrared Transceiver */
  338. { USB_DEVICE(VENDOR_FIC, 0x9242) },
  339. /* LG eHome Infrared Transceiver */
  340. { USB_DEVICE(VENDOR_LG, 0x9803) },
  341. /* Microsoft MCE Infrared Transceiver */
  342. { USB_DEVICE(VENDOR_MICROSOFT, 0x00a0) },
  343. /* Formosa eHome Infrared Transceiver */
  344. { USB_DEVICE(VENDOR_FORMOSA, 0xe015) },
  345. /* Formosa21 / eHome Infrared Receiver */
  346. { USB_DEVICE(VENDOR_FORMOSA, 0xe016) },
  347. /* Formosa aim / Trust MCE Infrared Receiver */
  348. { USB_DEVICE(VENDOR_FORMOSA, 0xe017),
  349. .driver_info = MCE_GEN2_NO_TX },
  350. /* Formosa Industrial Computing / Beanbag Emulation Device */
  351. { USB_DEVICE(VENDOR_FORMOSA, 0xe018) },
  352. /* Formosa21 / eHome Infrared Receiver */
  353. { USB_DEVICE(VENDOR_FORMOSA, 0xe03a) },
  354. /* Formosa Industrial Computing AIM IR605/A */
  355. { USB_DEVICE(VENDOR_FORMOSA, 0xe03c) },
  356. /* Formosa Industrial Computing */
  357. { USB_DEVICE(VENDOR_FORMOSA, 0xe03e) },
  358. /* Formosa Industrial Computing */
  359. { USB_DEVICE(VENDOR_FORMOSA, 0xe042) },
  360. /* Fintek eHome Infrared Transceiver (HP branded) */
  361. { USB_DEVICE(VENDOR_FINTEK, 0x5168),
  362. .driver_info = MCE_GEN2_TX_INV },
  363. /* Fintek eHome Infrared Transceiver */
  364. { USB_DEVICE(VENDOR_FINTEK, 0x0602) },
  365. /* Fintek eHome Infrared Transceiver (in the AOpen MP45) */
  366. { USB_DEVICE(VENDOR_FINTEK, 0x0702) },
  367. /* Pinnacle Remote Kit */
  368. { USB_DEVICE(VENDOR_PINNACLE, 0x0225),
  369. .driver_info = MCE_GEN3 },
  370. /* Elitegroup Computer Systems IR */
  371. { USB_DEVICE(VENDOR_ECS, 0x0f38) },
  372. /* Wistron Corp. eHome Infrared Receiver */
  373. { USB_DEVICE(VENDOR_WISTRON, 0x0002) },
  374. /* Compro K100 */
  375. { USB_DEVICE(VENDOR_COMPRO, 0x3020) },
  376. /* Compro K100 v2 */
  377. { USB_DEVICE(VENDOR_COMPRO, 0x3082) },
  378. /* Northstar Systems, Inc. eHome Infrared Transceiver */
  379. { USB_DEVICE(VENDOR_NORTHSTAR, 0xe004) },
  380. /* TiVo PC IR Receiver */
  381. { USB_DEVICE(VENDOR_TIVO, 0x2000),
  382. .driver_info = TIVO_KIT },
  383. /* Conexant Hybrid TV "Shelby" Polaris SDK */
  384. { USB_DEVICE(VENDOR_CONEXANT, 0x58a1),
  385. .driver_info = POLARIS_EVK },
  386. /* Conexant Hybrid TV RDU253S Polaris */
  387. { USB_DEVICE(VENDOR_CONEXANT, 0x58a5),
  388. .driver_info = CX_HYBRID_TV },
  389. /* Twisted Melon Inc. - Manta Mini Receiver */
  390. { USB_DEVICE(VENDOR_TWISTEDMELON, 0x8008) },
  391. /* Twisted Melon Inc. - Manta Pico Receiver */
  392. { USB_DEVICE(VENDOR_TWISTEDMELON, 0x8016) },
  393. /* Twisted Melon Inc. - Manta Transceiver */
  394. { USB_DEVICE(VENDOR_TWISTEDMELON, 0x8042) },
  395. /* Hauppauge WINTV-HVR-HVR 930C-HD - based on cx231xx */
  396. { USB_DEVICE(VENDOR_HAUPPAUGE, 0xb130),
  397. .driver_info = HAUPPAUGE_CX_HYBRID_TV },
  398. { USB_DEVICE(VENDOR_HAUPPAUGE, 0xb131),
  399. .driver_info = HAUPPAUGE_CX_HYBRID_TV },
  400. { USB_DEVICE(VENDOR_HAUPPAUGE, 0xb138),
  401. .driver_info = HAUPPAUGE_CX_HYBRID_TV },
  402. { USB_DEVICE(VENDOR_HAUPPAUGE, 0xb139),
  403. .driver_info = HAUPPAUGE_CX_HYBRID_TV },
  404. /* Hauppauge WinTV-HVR-935C - based on cx231xx */
  405. { USB_DEVICE(VENDOR_HAUPPAUGE, 0xb151),
  406. .driver_info = HAUPPAUGE_CX_HYBRID_TV },
  407. /* Hauppauge WinTV-HVR-955Q - based on cx231xx */
  408. { USB_DEVICE(VENDOR_HAUPPAUGE, 0xb123),
  409. .driver_info = HAUPPAUGE_CX_HYBRID_TV },
  410. /* Hauppauge WinTV-HVR-975 - based on cx231xx */
  411. { USB_DEVICE(VENDOR_HAUPPAUGE, 0xb150),
  412. .driver_info = HAUPPAUGE_CX_HYBRID_TV },
  413. { USB_DEVICE(VENDOR_PCTV, 0x0259),
  414. .driver_info = HAUPPAUGE_CX_HYBRID_TV },
  415. { USB_DEVICE(VENDOR_PCTV, 0x025e),
  416. .driver_info = HAUPPAUGE_CX_HYBRID_TV },
  417. /* Adaptec / HP eHome Receiver */
  418. { USB_DEVICE(VENDOR_ADAPTEC, 0x0094) },
  419. /* Evromedia USB Full Hybrid Full HD */
  420. { USB_DEVICE(0x1b80, 0xd3b2),
  421. .driver_info = EVROMEDIA_FULL_HYBRID_FULLHD },
  422. /* Astrometa T2hybrid */
  423. { USB_DEVICE(0x15f4, 0x0135),
  424. .driver_info = ASTROMETA_T2HYBRID },
  425. /* Terminating entry */
  426. { }
  427. };
  428. /* data structure for each usb transceiver */
  429. struct mceusb_dev {
  430. /* ir-core bits */
  431. struct rc_dev *rc;
  432. /* optional features we can enable */
  433. bool carrier_report_enabled;
  434. bool wideband_rx_enabled; /* aka learning mode, short-range rx */
  435. /* core device bits */
  436. struct device *dev;
  437. /* usb */
  438. struct usb_device *usbdev;
  439. struct usb_interface *usbintf;
  440. struct urb *urb_in;
  441. unsigned int pipe_in;
  442. struct usb_endpoint_descriptor *usb_ep_out;
  443. unsigned int pipe_out;
  444. /* buffers and dma */
  445. unsigned char *buf_in;
  446. unsigned int len_in;
  447. dma_addr_t dma_in;
  448. enum {
  449. CMD_HEADER = 0,
  450. SUBCMD,
  451. CMD_DATA,
  452. PARSE_IRDATA,
  453. } parser_state;
  454. u8 cmd, rem; /* Remaining IR data bytes in packet */
  455. struct {
  456. u32 connected:1;
  457. u32 tx_mask_normal:1;
  458. u32 microsoft_gen1:1;
  459. u32 no_tx:1;
  460. u32 rx2;
  461. } flags;
  462. /* transmit support */
  463. u32 carrier;
  464. unsigned char tx_mask;
  465. char phys[64];
  466. enum mceusb_model_type model;
  467. bool need_reset; /* flag to issue a device resume cmd */
  468. u8 emver; /* emulator interface version */
  469. u8 num_txports; /* number of transmit ports */
  470. u8 num_rxports; /* number of receive sensors */
  471. u8 txports_cabled; /* bitmask of transmitters with cable */
  472. u8 rxports_active; /* bitmask of active receive sensors */
  473. bool learning_active; /* wideband rx is active */
  474. /* receiver carrier frequency detection support */
  475. u32 pulse_tunit; /* IR pulse "on" cumulative time units */
  476. u32 pulse_count; /* pulse "on" count in measurement interval */
  477. /*
  478. * support for async error handler mceusb_deferred_kevent()
  479. * where usb_clear_halt(), usb_reset_configuration(),
  480. * usb_reset_device(), etc. must be done in process context
  481. */
  482. struct work_struct kevent;
  483. unsigned long kevent_flags;
  484. # define EVENT_TX_HALT 0
  485. # define EVENT_RX_HALT 1
  486. # define EVENT_RST_PEND 31
  487. };
  488. /* MCE Device Command Strings, generally a port and command pair */
  489. static char DEVICE_RESUME[] = {MCE_CMD_NULL, MCE_CMD_PORT_SYS,
  490. MCE_CMD_RESUME};
  491. static char GET_REVISION[] = {MCE_CMD_PORT_SYS, MCE_CMD_G_REVISION};
  492. static char GET_EMVER[] = {MCE_CMD_PORT_SYS, MCE_CMD_GETEMVER};
  493. static char GET_WAKEVERSION[] = {MCE_CMD_PORT_SYS, MCE_CMD_GETWAKEVERSION};
  494. static char FLASH_LED[] = {MCE_CMD_PORT_SYS, MCE_CMD_FLASHLED};
  495. static char GET_UNKNOWN2[] = {MCE_CMD_PORT_IR, MCE_CMD_UNKNOWN2};
  496. static char GET_CARRIER_FREQ[] = {MCE_CMD_PORT_IR, MCE_CMD_GETIRCFS};
  497. static char GET_RX_TIMEOUT[] = {MCE_CMD_PORT_IR, MCE_CMD_GETIRTIMEOUT};
  498. static char GET_NUM_PORTS[] = {MCE_CMD_PORT_IR, MCE_CMD_GETIRNUMPORTS};
  499. static char GET_TX_BITMASK[] = {MCE_CMD_PORT_IR, MCE_CMD_GETIRTXPORTS};
  500. static char GET_RX_SENSOR[] = {MCE_CMD_PORT_IR, MCE_CMD_GETIRRXPORTEN};
  501. /* sub in desired values in lower byte or bytes for full command */
  502. /* FIXME: make use of these for transmit.
  503. static char SET_CARRIER_FREQ[] = {MCE_CMD_PORT_IR,
  504. MCE_CMD_SETIRCFS, 0x00, 0x00};
  505. static char SET_TX_BITMASK[] = {MCE_CMD_PORT_IR, MCE_CMD_SETIRTXPORTS, 0x00};
  506. static char SET_RX_TIMEOUT[] = {MCE_CMD_PORT_IR,
  507. MCE_CMD_SETIRTIMEOUT, 0x00, 0x00};
  508. static char SET_RX_SENSOR[] = {MCE_CMD_PORT_IR,
  509. MCE_RSP_EQIRRXPORTEN, 0x00};
  510. */
  511. static int mceusb_cmd_datasize(u8 cmd, u8 subcmd)
  512. {
  513. int datasize = 0;
  514. switch (cmd) {
  515. case MCE_CMD_NULL:
  516. if (subcmd == MCE_CMD_PORT_SYS)
  517. datasize = 1;
  518. break;
  519. case MCE_CMD_PORT_SYS:
  520. switch (subcmd) {
  521. case MCE_RSP_GETPORTSTATUS:
  522. datasize = 5;
  523. break;
  524. case MCE_RSP_EQWAKEVERSION:
  525. datasize = 4;
  526. break;
  527. case MCE_CMD_G_REVISION:
  528. datasize = 4;
  529. break;
  530. case MCE_RSP_EQWAKESUPPORT:
  531. case MCE_RSP_GETWAKESOURCE:
  532. case MCE_RSP_EQDEVDETAILS:
  533. case MCE_RSP_EQEMVER:
  534. datasize = 1;
  535. break;
  536. }
  537. break;
  538. case MCE_CMD_PORT_IR:
  539. switch (subcmd) {
  540. case MCE_CMD_UNKNOWN:
  541. case MCE_RSP_EQIRCFS:
  542. case MCE_RSP_EQIRTIMEOUT:
  543. case MCE_RSP_EQIRRXCFCNT:
  544. case MCE_RSP_EQIRNUMPORTS:
  545. datasize = 2;
  546. break;
  547. case MCE_CMD_SIG_END:
  548. case MCE_RSP_EQIRTXPORTS:
  549. case MCE_RSP_EQIRRXPORTEN:
  550. datasize = 1;
  551. break;
  552. }
  553. }
  554. return datasize;
  555. }
  556. static void mceusb_dev_printdata(struct mceusb_dev *ir, u8 *buf, int buf_len,
  557. int offset, int len, bool out)
  558. {
  559. #if defined(DEBUG) || defined(CONFIG_DYNAMIC_DEBUG)
  560. char *inout;
  561. u8 cmd, subcmd, *data;
  562. struct device *dev = ir->dev;
  563. u32 carrier, period;
  564. if (offset < 0 || offset >= buf_len)
  565. return;
  566. dev_dbg(dev, "%cx data[%d]: %*ph (len=%d sz=%d)",
  567. (out ? 't' : 'r'), offset,
  568. min(len, buf_len - offset), buf + offset, len, buf_len);
  569. inout = out ? "Request" : "Got";
  570. cmd = buf[offset];
  571. subcmd = (offset + 1 < buf_len) ? buf[offset + 1] : 0;
  572. data = &buf[offset] + 2;
  573. /* Trace meaningless 0xb1 0x60 header bytes on original receiver */
  574. if (ir->flags.microsoft_gen1 && !out && !offset) {
  575. dev_dbg(dev, "MCE gen 1 header");
  576. return;
  577. }
  578. /* Trace IR data header or trailer */
  579. if (cmd != MCE_CMD_PORT_IR &&
  580. (cmd & MCE_PORT_MASK) == MCE_COMMAND_IRDATA) {
  581. if (cmd == MCE_IRDATA_TRAILER)
  582. dev_dbg(dev, "End of raw IR data");
  583. else
  584. dev_dbg(dev, "Raw IR data, %d pulse/space samples",
  585. cmd & MCE_PACKET_LENGTH_MASK);
  586. return;
  587. }
  588. /* Unexpected end of buffer? */
  589. if (offset + len > buf_len)
  590. return;
  591. /* Decode MCE command/response */
  592. switch (cmd) {
  593. case MCE_CMD_NULL:
  594. if (subcmd == MCE_CMD_NULL)
  595. break;
  596. if ((subcmd == MCE_CMD_PORT_SYS) &&
  597. (data[0] == MCE_CMD_RESUME))
  598. dev_dbg(dev, "Device resume requested");
  599. else
  600. dev_dbg(dev, "Unknown command 0x%02x 0x%02x",
  601. cmd, subcmd);
  602. break;
  603. case MCE_CMD_PORT_SYS:
  604. switch (subcmd) {
  605. case MCE_RSP_EQEMVER:
  606. if (!out)
  607. dev_dbg(dev, "Emulator interface version %x",
  608. data[0]);
  609. break;
  610. case MCE_CMD_G_REVISION:
  611. if (len == 2)
  612. dev_dbg(dev, "Get hw/sw rev?");
  613. else
  614. dev_dbg(dev, "hw/sw rev %4ph",
  615. &buf[offset + 2]);
  616. break;
  617. case MCE_CMD_RESUME:
  618. dev_dbg(dev, "Device resume requested");
  619. break;
  620. case MCE_RSP_CMD_ILLEGAL:
  621. dev_dbg(dev, "Illegal PORT_SYS command");
  622. break;
  623. case MCE_RSP_EQWAKEVERSION:
  624. if (!out)
  625. dev_dbg(dev, "Wake version, proto: 0x%02x, payload: 0x%02x, address: 0x%02x, version: 0x%02x",
  626. data[0], data[1], data[2], data[3]);
  627. break;
  628. case MCE_RSP_GETPORTSTATUS:
  629. if (!out)
  630. /* We use data1 + 1 here, to match hw labels */
  631. dev_dbg(dev, "TX port %d: blaster is%s connected",
  632. data[0] + 1, data[3] ? " not" : "");
  633. break;
  634. case MCE_CMD_FLASHLED:
  635. dev_dbg(dev, "Attempting to flash LED");
  636. break;
  637. default:
  638. dev_dbg(dev, "Unknown command 0x%02x 0x%02x",
  639. cmd, subcmd);
  640. break;
  641. }
  642. break;
  643. case MCE_CMD_PORT_IR:
  644. switch (subcmd) {
  645. case MCE_CMD_SIG_END:
  646. dev_dbg(dev, "End of signal");
  647. break;
  648. case MCE_CMD_PING:
  649. dev_dbg(dev, "Ping");
  650. break;
  651. case MCE_CMD_UNKNOWN:
  652. dev_dbg(dev, "Resp to 9f 05 of 0x%02x 0x%02x",
  653. data[0], data[1]);
  654. break;
  655. case MCE_RSP_EQIRCFS:
  656. if (!data[0] && !data[1]) {
  657. dev_dbg(dev, "%s: no carrier", inout);
  658. break;
  659. }
  660. // prescaler should make sense
  661. if (data[0] > 8)
  662. break;
  663. period = DIV_ROUND_CLOSEST((1U << data[0] * 2) *
  664. (data[1] + 1), 10);
  665. if (!period)
  666. break;
  667. carrier = USEC_PER_SEC / period;
  668. dev_dbg(dev, "%s carrier of %u Hz (period %uus)",
  669. inout, carrier, period);
  670. break;
  671. case MCE_CMD_GETIRCFS:
  672. dev_dbg(dev, "Get carrier mode and freq");
  673. break;
  674. case MCE_RSP_EQIRTXPORTS:
  675. dev_dbg(dev, "%s transmit blaster mask of 0x%02x",
  676. inout, data[0]);
  677. break;
  678. case MCE_RSP_EQIRTIMEOUT:
  679. /* value is in units of 50us, so x*50/1000 ms */
  680. period = ((data[0] << 8) | data[1]) *
  681. MCE_TIME_UNIT / 1000;
  682. dev_dbg(dev, "%s receive timeout of %d ms",
  683. inout, period);
  684. break;
  685. case MCE_CMD_GETIRTIMEOUT:
  686. dev_dbg(dev, "Get receive timeout");
  687. break;
  688. case MCE_CMD_GETIRTXPORTS:
  689. dev_dbg(dev, "Get transmit blaster mask");
  690. break;
  691. case MCE_RSP_EQIRRXPORTEN:
  692. dev_dbg(dev, "%s %s-range receive sensor in use",
  693. inout, data[0] == 0x02 ? "short" : "long");
  694. break;
  695. case MCE_CMD_GETIRRXPORTEN:
  696. /* aka MCE_RSP_EQIRRXCFCNT */
  697. if (out)
  698. dev_dbg(dev, "Get receive sensor");
  699. else
  700. dev_dbg(dev, "RX carrier cycle count: %d",
  701. ((data[0] << 8) | data[1]));
  702. break;
  703. case MCE_RSP_EQIRNUMPORTS:
  704. if (out)
  705. break;
  706. dev_dbg(dev, "Num TX ports: %x, num RX ports: %x",
  707. data[0], data[1]);
  708. break;
  709. case MCE_RSP_CMD_ILLEGAL:
  710. dev_dbg(dev, "Illegal PORT_IR command");
  711. break;
  712. case MCE_RSP_TX_TIMEOUT:
  713. dev_dbg(dev, "IR TX timeout (TX buffer underrun)");
  714. break;
  715. default:
  716. dev_dbg(dev, "Unknown command 0x%02x 0x%02x",
  717. cmd, subcmd);
  718. break;
  719. }
  720. break;
  721. default:
  722. break;
  723. }
  724. #endif
  725. }
  726. /*
  727. * Schedule work that can't be done in interrupt handlers
  728. * (mceusb_dev_recv() and mce_write_callback()) nor BH work.
  729. * Invokes mceusb_deferred_kevent() for recovering from
  730. * error events specified by the kevent bit field.
  731. */
  732. static void mceusb_defer_kevent(struct mceusb_dev *ir, int kevent)
  733. {
  734. set_bit(kevent, &ir->kevent_flags);
  735. if (test_bit(EVENT_RST_PEND, &ir->kevent_flags)) {
  736. dev_dbg(ir->dev, "kevent %d dropped pending USB Reset Device",
  737. kevent);
  738. return;
  739. }
  740. if (!schedule_work(&ir->kevent))
  741. dev_dbg(ir->dev, "kevent %d already scheduled", kevent);
  742. else
  743. dev_dbg(ir->dev, "kevent %d scheduled", kevent);
  744. }
  745. static void mce_write_callback(struct urb *urb)
  746. {
  747. if (!urb)
  748. return;
  749. complete(urb->context);
  750. }
  751. /*
  752. * Write (TX/send) data to MCE device USB endpoint out.
  753. * Used for IR blaster TX and MCE device commands.
  754. *
  755. * Return: The number of bytes written (> 0) or errno (< 0).
  756. */
  757. static int mce_write(struct mceusb_dev *ir, u8 *data, int size)
  758. {
  759. int ret;
  760. struct urb *urb;
  761. struct device *dev = ir->dev;
  762. unsigned char *buf_out;
  763. struct completion tx_done;
  764. unsigned long expire;
  765. unsigned long ret_wait;
  766. mceusb_dev_printdata(ir, data, size, 0, size, true);
  767. urb = usb_alloc_urb(0, GFP_KERNEL);
  768. if (unlikely(!urb)) {
  769. dev_err(dev, "Error: mce write couldn't allocate urb");
  770. return -ENOMEM;
  771. }
  772. buf_out = kmalloc(size, GFP_KERNEL);
  773. if (!buf_out) {
  774. usb_free_urb(urb);
  775. return -ENOMEM;
  776. }
  777. init_completion(&tx_done);
  778. /* outbound data */
  779. if (usb_endpoint_xfer_int(ir->usb_ep_out))
  780. usb_fill_int_urb(urb, ir->usbdev, ir->pipe_out,
  781. buf_out, size, mce_write_callback, &tx_done,
  782. ir->usb_ep_out->bInterval);
  783. else
  784. usb_fill_bulk_urb(urb, ir->usbdev, ir->pipe_out,
  785. buf_out, size, mce_write_callback, &tx_done);
  786. memcpy(buf_out, data, size);
  787. ret = usb_submit_urb(urb, GFP_KERNEL);
  788. if (ret) {
  789. dev_err(dev, "Error: mce write submit urb error = %d", ret);
  790. kfree(buf_out);
  791. usb_free_urb(urb);
  792. return ret;
  793. }
  794. expire = msecs_to_jiffies(USB_TX_TIMEOUT);
  795. ret_wait = wait_for_completion_timeout(&tx_done, expire);
  796. if (!ret_wait) {
  797. dev_err(dev, "Error: mce write timed out (expire = %lu (%dms))",
  798. expire, USB_TX_TIMEOUT);
  799. usb_kill_urb(urb);
  800. ret = (urb->status == -ENOENT ? -ETIMEDOUT : urb->status);
  801. } else {
  802. ret = urb->status;
  803. }
  804. if (ret >= 0)
  805. ret = urb->actual_length; /* bytes written */
  806. switch (urb->status) {
  807. /* success */
  808. case 0:
  809. break;
  810. case -ECONNRESET:
  811. case -ENOENT:
  812. case -EILSEQ:
  813. case -ESHUTDOWN:
  814. break;
  815. case -EPIPE:
  816. dev_err(ir->dev, "Error: mce write urb status = %d (TX HALT)",
  817. urb->status);
  818. mceusb_defer_kevent(ir, EVENT_TX_HALT);
  819. break;
  820. default:
  821. dev_err(ir->dev, "Error: mce write urb status = %d",
  822. urb->status);
  823. break;
  824. }
  825. dev_dbg(dev, "tx done status = %d (wait = %lu, expire = %lu (%dms), urb->actual_length = %d, urb->status = %d)",
  826. ret, ret_wait, expire, USB_TX_TIMEOUT,
  827. urb->actual_length, urb->status);
  828. kfree(buf_out);
  829. usb_free_urb(urb);
  830. return ret;
  831. }
  832. static void mce_command_out(struct mceusb_dev *ir, u8 *data, int size)
  833. {
  834. int rsize = sizeof(DEVICE_RESUME);
  835. if (ir->need_reset) {
  836. ir->need_reset = false;
  837. mce_write(ir, DEVICE_RESUME, rsize);
  838. msleep(10);
  839. }
  840. mce_write(ir, data, size);
  841. msleep(10);
  842. }
  843. /*
  844. * Transmit IR out the MCE device IR blaster port(s).
  845. *
  846. * Convert IR pulse/space sequence from LIRC to MCE format.
  847. * Break up a long IR sequence into multiple parts (MCE IR data packets).
  848. *
  849. * u32 txbuf[] consists of IR pulse, space, ..., and pulse times in usec.
  850. * Pulses and spaces are implicit by their position.
  851. * The first IR sample, txbuf[0], is always a pulse.
  852. *
  853. * u8 irbuf[] consists of multiple IR data packets for the MCE device.
  854. * A packet is 1 u8 MCE_IRDATA_HEADER and up to 30 u8 IR samples.
  855. * An IR sample is 1-bit pulse/space flag with 7-bit time
  856. * in MCE time units (50usec).
  857. *
  858. * Return: The number of IR samples sent (> 0) or errno (< 0).
  859. */
  860. static int mceusb_tx_ir(struct rc_dev *dev, unsigned *txbuf, unsigned count)
  861. {
  862. struct mceusb_dev *ir = dev->priv;
  863. u8 cmdbuf[3] = { MCE_CMD_PORT_IR, MCE_CMD_SETIRTXPORTS, 0x00 };
  864. u8 irbuf[MCE_IRBUF_SIZE];
  865. int ircount = 0;
  866. unsigned int irsample;
  867. int i, length, ret;
  868. /* Send the set TX ports command */
  869. cmdbuf[2] = ir->tx_mask;
  870. mce_command_out(ir, cmdbuf, sizeof(cmdbuf));
  871. /* Generate mce IR data packet */
  872. for (i = 0; i < count; i++) {
  873. irsample = txbuf[i] / MCE_TIME_UNIT;
  874. /* loop to support long pulses/spaces > 6350us (127*50us) */
  875. while (irsample > 0) {
  876. /* Insert IR header every 30th entry */
  877. if (ircount % MCE_PACKET_SIZE == 0) {
  878. /* Room for IR header and one IR sample? */
  879. if (ircount >= MCE_IRBUF_SIZE - 1) {
  880. /* Send near full buffer */
  881. ret = mce_write(ir, irbuf, ircount);
  882. if (ret < 0)
  883. return ret;
  884. ircount = 0;
  885. }
  886. irbuf[ircount++] = MCE_IRDATA_HEADER;
  887. }
  888. /* Insert IR sample */
  889. if (irsample <= MCE_MAX_PULSE_LENGTH) {
  890. irbuf[ircount] = irsample;
  891. irsample = 0;
  892. } else {
  893. irbuf[ircount] = MCE_MAX_PULSE_LENGTH;
  894. irsample -= MCE_MAX_PULSE_LENGTH;
  895. }
  896. /*
  897. * Even i = IR pulse
  898. * Odd i = IR space
  899. */
  900. irbuf[ircount] |= (i & 1 ? 0 : MCE_PULSE_BIT);
  901. ircount++;
  902. /* IR buffer full? */
  903. if (ircount >= MCE_IRBUF_SIZE) {
  904. /* Fix packet length in last header */
  905. length = ircount % MCE_PACKET_SIZE;
  906. if (length > 0)
  907. irbuf[ircount - length] -=
  908. MCE_PACKET_SIZE - length;
  909. /* Send full buffer */
  910. ret = mce_write(ir, irbuf, ircount);
  911. if (ret < 0)
  912. return ret;
  913. ircount = 0;
  914. }
  915. }
  916. } /* after for loop, 0 <= ircount < MCE_IRBUF_SIZE */
  917. /* Fix packet length in last header */
  918. length = ircount % MCE_PACKET_SIZE;
  919. if (length > 0)
  920. irbuf[ircount - length] -= MCE_PACKET_SIZE - length;
  921. /* Append IR trailer (0x80) to final partial (or empty) IR buffer */
  922. irbuf[ircount++] = MCE_IRDATA_TRAILER;
  923. /* Send final buffer */
  924. ret = mce_write(ir, irbuf, ircount);
  925. if (ret < 0)
  926. return ret;
  927. return count;
  928. }
  929. /* Sets active IR outputs -- mce devices typically have two */
  930. static int mceusb_set_tx_mask(struct rc_dev *dev, u32 mask)
  931. {
  932. struct mceusb_dev *ir = dev->priv;
  933. /* return number of transmitters */
  934. int emitters = ir->num_txports ? ir->num_txports : 2;
  935. if (mask >= (1 << emitters))
  936. return emitters;
  937. if (ir->flags.tx_mask_normal)
  938. ir->tx_mask = mask;
  939. else
  940. ir->tx_mask = (mask != MCE_DEFAULT_TX_MASK ?
  941. mask ^ MCE_DEFAULT_TX_MASK : mask) << 1;
  942. return 0;
  943. }
  944. /* Sets the send carrier frequency and mode */
  945. static int mceusb_set_tx_carrier(struct rc_dev *dev, u32 carrier)
  946. {
  947. struct mceusb_dev *ir = dev->priv;
  948. int clk = 10000000;
  949. int prescaler = 0, divisor = 0;
  950. unsigned char cmdbuf[4] = { MCE_CMD_PORT_IR,
  951. MCE_CMD_SETIRCFS, 0x00, 0x00 };
  952. /* Carrier has changed */
  953. if (ir->carrier != carrier) {
  954. if (carrier == 0) {
  955. ir->carrier = carrier;
  956. cmdbuf[2] = MCE_CMD_SIG_END;
  957. cmdbuf[3] = MCE_IRDATA_TRAILER;
  958. dev_dbg(ir->dev, "disabling carrier modulation");
  959. mce_command_out(ir, cmdbuf, sizeof(cmdbuf));
  960. return 0;
  961. }
  962. for (prescaler = 0; prescaler < 4; ++prescaler) {
  963. divisor = (clk >> (2 * prescaler)) / carrier;
  964. if (divisor <= 0xff) {
  965. ir->carrier = carrier;
  966. cmdbuf[2] = prescaler;
  967. cmdbuf[3] = divisor;
  968. dev_dbg(ir->dev, "requesting %u HZ carrier",
  969. carrier);
  970. /* Transmit new carrier to mce device */
  971. mce_command_out(ir, cmdbuf, sizeof(cmdbuf));
  972. return 0;
  973. }
  974. }
  975. return -EINVAL;
  976. }
  977. return 0;
  978. }
  979. static int mceusb_set_timeout(struct rc_dev *dev, unsigned int timeout)
  980. {
  981. u8 cmdbuf[4] = { MCE_CMD_PORT_IR, MCE_CMD_SETIRTIMEOUT, 0, 0 };
  982. struct mceusb_dev *ir = dev->priv;
  983. unsigned int units;
  984. units = DIV_ROUND_UP(timeout, MCE_TIME_UNIT);
  985. cmdbuf[2] = units >> 8;
  986. cmdbuf[3] = units;
  987. mce_command_out(ir, cmdbuf, sizeof(cmdbuf));
  988. /* get receiver timeout value */
  989. mce_command_out(ir, GET_RX_TIMEOUT, sizeof(GET_RX_TIMEOUT));
  990. return 0;
  991. }
  992. /*
  993. * Select or deselect the 2nd receiver port.
  994. * Second receiver is learning mode, wide-band, short-range receiver.
  995. * Only one receiver (long or short range) may be active at a time.
  996. */
  997. static int mceusb_set_rx_wideband(struct rc_dev *dev, int enable)
  998. {
  999. struct mceusb_dev *ir = dev->priv;
  1000. unsigned char cmdbuf[3] = { MCE_CMD_PORT_IR,
  1001. MCE_CMD_SETIRRXPORTEN, 0x00 };
  1002. dev_dbg(ir->dev, "select %s-range receive sensor",
  1003. enable ? "short" : "long");
  1004. if (enable) {
  1005. ir->wideband_rx_enabled = true;
  1006. cmdbuf[2] = 2; /* port 2 is short range receiver */
  1007. } else {
  1008. ir->wideband_rx_enabled = false;
  1009. cmdbuf[2] = 1; /* port 1 is long range receiver */
  1010. }
  1011. mce_command_out(ir, cmdbuf, sizeof(cmdbuf));
  1012. /* response from device sets ir->learning_active */
  1013. return 0;
  1014. }
  1015. /*
  1016. * Enable/disable receiver carrier frequency pass through reporting.
  1017. * Only the short-range receiver has carrier frequency measuring capability.
  1018. * Implicitly select this receiver when enabling carrier frequency reporting.
  1019. */
  1020. static int mceusb_set_rx_carrier_report(struct rc_dev *dev, int enable)
  1021. {
  1022. struct mceusb_dev *ir = dev->priv;
  1023. unsigned char cmdbuf[3] = { MCE_CMD_PORT_IR,
  1024. MCE_CMD_SETIRRXPORTEN, 0x00 };
  1025. dev_dbg(ir->dev, "%s short-range receiver carrier reporting",
  1026. enable ? "enable" : "disable");
  1027. if (enable) {
  1028. ir->carrier_report_enabled = true;
  1029. if (!ir->learning_active) {
  1030. cmdbuf[2] = 2; /* port 2 is short range receiver */
  1031. mce_command_out(ir, cmdbuf, sizeof(cmdbuf));
  1032. }
  1033. } else {
  1034. ir->carrier_report_enabled = false;
  1035. /*
  1036. * Revert to normal (long-range) receiver only if the
  1037. * wideband (short-range) receiver wasn't explicitly
  1038. * enabled.
  1039. */
  1040. if (ir->learning_active && !ir->wideband_rx_enabled) {
  1041. cmdbuf[2] = 1; /* port 1 is long range receiver */
  1042. mce_command_out(ir, cmdbuf, sizeof(cmdbuf));
  1043. }
  1044. }
  1045. return 0;
  1046. }
  1047. /*
  1048. * Handle PORT_SYS/IR command response received from the MCE device.
  1049. *
  1050. * Assumes single response with all its data (not truncated)
  1051. * in buf_in[]. The response itself determines its total length
  1052. * (mceusb_cmd_datasize() + 2) and hence the minimum size of buf_in[].
  1053. *
  1054. * We don't do anything but print debug spew for many of the command bits
  1055. * we receive from the hardware, but some of them are useful information
  1056. * we want to store so that we can use them.
  1057. */
  1058. static void mceusb_handle_command(struct mceusb_dev *ir, u8 *buf_in)
  1059. {
  1060. u8 cmd = buf_in[0];
  1061. u8 subcmd = buf_in[1];
  1062. u8 *hi = &buf_in[2]; /* read only when required */
  1063. u8 *lo = &buf_in[3]; /* read only when required */
  1064. struct ir_raw_event rawir = {};
  1065. u32 carrier_cycles;
  1066. u32 cycles_fix;
  1067. if (cmd == MCE_CMD_PORT_SYS) {
  1068. switch (subcmd) {
  1069. /* the one and only 5-byte return value command */
  1070. case MCE_RSP_GETPORTSTATUS:
  1071. if (buf_in[5] == 0 && *hi < 8)
  1072. ir->txports_cabled |= 1 << *hi;
  1073. break;
  1074. /* 1-byte return value commands */
  1075. case MCE_RSP_EQEMVER:
  1076. ir->emver = *hi;
  1077. break;
  1078. /* No return value commands */
  1079. case MCE_RSP_CMD_ILLEGAL:
  1080. ir->need_reset = true;
  1081. break;
  1082. default:
  1083. break;
  1084. }
  1085. return;
  1086. }
  1087. if (cmd != MCE_CMD_PORT_IR)
  1088. return;
  1089. switch (subcmd) {
  1090. /* 2-byte return value commands */
  1091. case MCE_RSP_EQIRTIMEOUT:
  1092. ir->rc->timeout = (*hi << 8 | *lo) * MCE_TIME_UNIT;
  1093. break;
  1094. case MCE_RSP_EQIRNUMPORTS:
  1095. ir->num_txports = *hi;
  1096. ir->num_rxports = *lo;
  1097. break;
  1098. case MCE_RSP_EQIRRXCFCNT:
  1099. /*
  1100. * The carrier cycle counter can overflow and wrap around
  1101. * without notice from the device. So frequency measurement
  1102. * will be inaccurate with long duration IR.
  1103. *
  1104. * The long-range (non learning) receiver always reports
  1105. * zero count so we always ignore its report.
  1106. */
  1107. if (ir->carrier_report_enabled && ir->learning_active &&
  1108. ir->pulse_tunit > 0) {
  1109. carrier_cycles = (*hi << 8 | *lo);
  1110. /*
  1111. * Adjust carrier cycle count by adding
  1112. * 1 missed count per pulse "on"
  1113. */
  1114. cycles_fix = ir->flags.rx2 == 2 ? ir->pulse_count : 0;
  1115. rawir.carrier_report = 1;
  1116. rawir.carrier = (1000000u / MCE_TIME_UNIT) *
  1117. (carrier_cycles + cycles_fix) /
  1118. ir->pulse_tunit;
  1119. dev_dbg(ir->dev, "RX carrier frequency %u Hz (pulse count = %u, cycles = %u, duration = %u, rx2 = %u)",
  1120. rawir.carrier, ir->pulse_count, carrier_cycles,
  1121. ir->pulse_tunit, ir->flags.rx2);
  1122. ir_raw_event_store(ir->rc, &rawir);
  1123. }
  1124. break;
  1125. /* 1-byte return value commands */
  1126. case MCE_RSP_EQIRTXPORTS:
  1127. ir->tx_mask = *hi;
  1128. break;
  1129. case MCE_RSP_EQIRRXPORTEN:
  1130. ir->learning_active = ((*hi & 0x02) == 0x02);
  1131. if (ir->rxports_active != *hi) {
  1132. dev_info(ir->dev, "%s-range (0x%x) receiver active",
  1133. ir->learning_active ? "short" : "long", *hi);
  1134. ir->rxports_active = *hi;
  1135. }
  1136. break;
  1137. /* No return value commands */
  1138. case MCE_RSP_CMD_ILLEGAL:
  1139. case MCE_RSP_TX_TIMEOUT:
  1140. ir->need_reset = true;
  1141. break;
  1142. default:
  1143. break;
  1144. }
  1145. }
  1146. static void mceusb_process_ir_data(struct mceusb_dev *ir, int buf_len)
  1147. {
  1148. struct ir_raw_event rawir = {};
  1149. bool event = false;
  1150. int i = 0;
  1151. /* skip meaningless 0xb1 0x60 header bytes on orig receiver */
  1152. if (ir->flags.microsoft_gen1)
  1153. i = 2;
  1154. /* if there's no data, just return now */
  1155. if (buf_len <= i)
  1156. return;
  1157. for (; i < buf_len; i++) {
  1158. switch (ir->parser_state) {
  1159. case SUBCMD:
  1160. ir->rem = mceusb_cmd_datasize(ir->cmd, ir->buf_in[i]);
  1161. mceusb_dev_printdata(ir, ir->buf_in, buf_len, i - 1,
  1162. ir->rem + 2, false);
  1163. if (i + ir->rem < buf_len)
  1164. mceusb_handle_command(ir, &ir->buf_in[i - 1]);
  1165. ir->parser_state = CMD_DATA;
  1166. break;
  1167. case PARSE_IRDATA:
  1168. ir->rem--;
  1169. rawir.pulse = ((ir->buf_in[i] & MCE_PULSE_BIT) != 0);
  1170. rawir.duration = (ir->buf_in[i] & MCE_PULSE_MASK);
  1171. if (unlikely(!rawir.duration)) {
  1172. dev_dbg(ir->dev, "nonsensical irdata %02x with duration 0",
  1173. ir->buf_in[i]);
  1174. break;
  1175. }
  1176. if (rawir.pulse) {
  1177. ir->pulse_tunit += rawir.duration;
  1178. ir->pulse_count++;
  1179. }
  1180. rawir.duration *= MCE_TIME_UNIT;
  1181. dev_dbg(ir->dev, "Storing %s %u us (%02x)",
  1182. rawir.pulse ? "pulse" : "space",
  1183. rawir.duration, ir->buf_in[i]);
  1184. if (ir_raw_event_store_with_filter(ir->rc, &rawir))
  1185. event = true;
  1186. break;
  1187. case CMD_DATA:
  1188. ir->rem--;
  1189. break;
  1190. case CMD_HEADER:
  1191. ir->cmd = ir->buf_in[i];
  1192. if ((ir->cmd == MCE_CMD_PORT_IR) ||
  1193. ((ir->cmd & MCE_PORT_MASK) !=
  1194. MCE_COMMAND_IRDATA)) {
  1195. /*
  1196. * got PORT_SYS, PORT_IR, or unknown
  1197. * command response prefix
  1198. */
  1199. ir->parser_state = SUBCMD;
  1200. continue;
  1201. }
  1202. /*
  1203. * got IR data prefix (0x80 + num_bytes)
  1204. * decode MCE packets of the form {0x83, AA, BB, CC}
  1205. * IR data packets can span USB messages
  1206. */
  1207. ir->rem = (ir->cmd & MCE_PACKET_LENGTH_MASK);
  1208. mceusb_dev_printdata(ir, ir->buf_in, buf_len,
  1209. i, ir->rem + 1, false);
  1210. if (ir->rem) {
  1211. ir->parser_state = PARSE_IRDATA;
  1212. } else {
  1213. struct ir_raw_event ev = {
  1214. .timeout = 1,
  1215. .duration = ir->rc->timeout
  1216. };
  1217. if (ir_raw_event_store_with_filter(ir->rc,
  1218. &ev))
  1219. event = true;
  1220. ir->pulse_tunit = 0;
  1221. ir->pulse_count = 0;
  1222. }
  1223. break;
  1224. }
  1225. if (ir->parser_state != CMD_HEADER && !ir->rem)
  1226. ir->parser_state = CMD_HEADER;
  1227. }
  1228. /*
  1229. * Accept IR data spanning multiple rx buffers.
  1230. * Reject MCE command response spanning multiple rx buffers.
  1231. */
  1232. if (ir->parser_state != PARSE_IRDATA || !ir->rem)
  1233. ir->parser_state = CMD_HEADER;
  1234. if (event) {
  1235. dev_dbg(ir->dev, "processed IR data");
  1236. ir_raw_event_handle(ir->rc);
  1237. }
  1238. }
  1239. static void mceusb_dev_recv(struct urb *urb)
  1240. {
  1241. struct mceusb_dev *ir;
  1242. if (!urb)
  1243. return;
  1244. ir = urb->context;
  1245. if (!ir) {
  1246. usb_unlink_urb(urb);
  1247. return;
  1248. }
  1249. switch (urb->status) {
  1250. /* success */
  1251. case 0:
  1252. mceusb_process_ir_data(ir, urb->actual_length);
  1253. break;
  1254. case -ECONNRESET:
  1255. case -ENOENT:
  1256. case -EILSEQ:
  1257. case -EPROTO:
  1258. case -ESHUTDOWN:
  1259. usb_unlink_urb(urb);
  1260. return;
  1261. case -EPIPE:
  1262. dev_err(ir->dev, "Error: urb status = %d (RX HALT)",
  1263. urb->status);
  1264. mceusb_defer_kevent(ir, EVENT_RX_HALT);
  1265. return;
  1266. default:
  1267. dev_err(ir->dev, "Error: urb status = %d", urb->status);
  1268. break;
  1269. }
  1270. usb_submit_urb(urb, GFP_ATOMIC);
  1271. }
  1272. static void mceusb_get_emulator_version(struct mceusb_dev *ir)
  1273. {
  1274. /* If we get no reply or an illegal command reply, its ver 1, says MS */
  1275. ir->emver = 1;
  1276. mce_command_out(ir, GET_EMVER, sizeof(GET_EMVER));
  1277. }
  1278. static void mceusb_gen1_init(struct mceusb_dev *ir)
  1279. {
  1280. int ret;
  1281. struct device *dev = ir->dev;
  1282. char data[USB_CTRL_MSG_SZ];
  1283. /*
  1284. * This is a strange one. Windows issues a set address to the device
  1285. * on the receive control pipe and expect a certain value pair back
  1286. */
  1287. ret = usb_control_msg_recv(ir->usbdev, 0, USB_REQ_SET_ADDRESS,
  1288. USB_DIR_IN | USB_TYPE_VENDOR,
  1289. 0, 0, data, USB_CTRL_MSG_SZ, 3000,
  1290. GFP_KERNEL);
  1291. dev_dbg(dev, "set address - ret = %d", ret);
  1292. dev_dbg(dev, "set address - data[0] = %d, data[1] = %d",
  1293. data[0], data[1]);
  1294. /* set feature: bit rate 38400 bps */
  1295. ret = usb_control_msg_send(ir->usbdev, 0,
  1296. USB_REQ_SET_FEATURE, USB_TYPE_VENDOR,
  1297. 0xc04e, 0x0000, NULL, 0, 3000, GFP_KERNEL);
  1298. dev_dbg(dev, "set feature - ret = %d", ret);
  1299. /* bRequest 4: set char length to 8 bits */
  1300. ret = usb_control_msg_send(ir->usbdev, 0,
  1301. 4, USB_TYPE_VENDOR,
  1302. 0x0808, 0x0000, NULL, 0, 3000, GFP_KERNEL);
  1303. dev_dbg(dev, "set char length - retB = %d", ret);
  1304. /* bRequest 2: set handshaking to use DTR/DSR */
  1305. ret = usb_control_msg_send(ir->usbdev, 0,
  1306. 2, USB_TYPE_VENDOR,
  1307. 0x0000, 0x0100, NULL, 0, 3000, GFP_KERNEL);
  1308. dev_dbg(dev, "set handshake - retC = %d", ret);
  1309. /* device resume */
  1310. mce_command_out(ir, DEVICE_RESUME, sizeof(DEVICE_RESUME));
  1311. /* get hw/sw revision? */
  1312. mce_command_out(ir, GET_REVISION, sizeof(GET_REVISION));
  1313. }
  1314. static void mceusb_gen2_init(struct mceusb_dev *ir)
  1315. {
  1316. /* device resume */
  1317. mce_command_out(ir, DEVICE_RESUME, sizeof(DEVICE_RESUME));
  1318. /* get wake version (protocol, key, address) */
  1319. mce_command_out(ir, GET_WAKEVERSION, sizeof(GET_WAKEVERSION));
  1320. /* unknown what this one actually returns... */
  1321. mce_command_out(ir, GET_UNKNOWN2, sizeof(GET_UNKNOWN2));
  1322. }
  1323. static void mceusb_get_parameters(struct mceusb_dev *ir)
  1324. {
  1325. int i;
  1326. unsigned char cmdbuf[3] = { MCE_CMD_PORT_SYS,
  1327. MCE_CMD_GETPORTSTATUS, 0x00 };
  1328. /* defaults, if the hardware doesn't support querying */
  1329. ir->num_txports = 2;
  1330. ir->num_rxports = 2;
  1331. /* get number of tx and rx ports */
  1332. mce_command_out(ir, GET_NUM_PORTS, sizeof(GET_NUM_PORTS));
  1333. /* get the carrier and frequency */
  1334. mce_command_out(ir, GET_CARRIER_FREQ, sizeof(GET_CARRIER_FREQ));
  1335. if (ir->num_txports && !ir->flags.no_tx)
  1336. /* get the transmitter bitmask */
  1337. mce_command_out(ir, GET_TX_BITMASK, sizeof(GET_TX_BITMASK));
  1338. /* get receiver timeout value */
  1339. mce_command_out(ir, GET_RX_TIMEOUT, sizeof(GET_RX_TIMEOUT));
  1340. /* get receiver sensor setting */
  1341. mce_command_out(ir, GET_RX_SENSOR, sizeof(GET_RX_SENSOR));
  1342. for (i = 0; i < ir->num_txports; i++) {
  1343. cmdbuf[2] = i;
  1344. mce_command_out(ir, cmdbuf, sizeof(cmdbuf));
  1345. }
  1346. }
  1347. static void mceusb_flash_led(struct mceusb_dev *ir)
  1348. {
  1349. if (ir->emver < 2)
  1350. return;
  1351. mce_command_out(ir, FLASH_LED, sizeof(FLASH_LED));
  1352. }
  1353. /*
  1354. * Workqueue function
  1355. * for resetting or recovering device after occurrence of error events
  1356. * specified in ir->kevent bit field.
  1357. * Function runs (via schedule_work()) in non-interrupt context, for
  1358. * calls here (such as usb_clear_halt()) requiring non-interrupt context.
  1359. */
  1360. static void mceusb_deferred_kevent(struct work_struct *work)
  1361. {
  1362. struct mceusb_dev *ir =
  1363. container_of(work, struct mceusb_dev, kevent);
  1364. int status;
  1365. dev_err(ir->dev, "kevent handler called (flags 0x%lx)",
  1366. ir->kevent_flags);
  1367. if (test_bit(EVENT_RST_PEND, &ir->kevent_flags)) {
  1368. dev_err(ir->dev, "kevent handler canceled pending USB Reset Device");
  1369. return;
  1370. }
  1371. if (test_bit(EVENT_RX_HALT, &ir->kevent_flags)) {
  1372. usb_unlink_urb(ir->urb_in);
  1373. status = usb_clear_halt(ir->usbdev, ir->pipe_in);
  1374. dev_err(ir->dev, "rx clear halt status = %d", status);
  1375. if (status < 0) {
  1376. /*
  1377. * Unable to clear RX halt/stall.
  1378. * Will need to call usb_reset_device().
  1379. */
  1380. dev_err(ir->dev,
  1381. "stuck RX HALT state requires USB Reset Device to clear");
  1382. usb_queue_reset_device(ir->usbintf);
  1383. set_bit(EVENT_RST_PEND, &ir->kevent_flags);
  1384. clear_bit(EVENT_RX_HALT, &ir->kevent_flags);
  1385. /* Cancel all other error events and handlers */
  1386. clear_bit(EVENT_TX_HALT, &ir->kevent_flags);
  1387. return;
  1388. }
  1389. clear_bit(EVENT_RX_HALT, &ir->kevent_flags);
  1390. status = usb_submit_urb(ir->urb_in, GFP_KERNEL);
  1391. if (status < 0) {
  1392. dev_err(ir->dev, "rx unhalt submit urb error = %d",
  1393. status);
  1394. }
  1395. }
  1396. if (test_bit(EVENT_TX_HALT, &ir->kevent_flags)) {
  1397. status = usb_clear_halt(ir->usbdev, ir->pipe_out);
  1398. dev_err(ir->dev, "tx clear halt status = %d", status);
  1399. if (status < 0) {
  1400. /*
  1401. * Unable to clear TX halt/stall.
  1402. * Will need to call usb_reset_device().
  1403. */
  1404. dev_err(ir->dev,
  1405. "stuck TX HALT state requires USB Reset Device to clear");
  1406. usb_queue_reset_device(ir->usbintf);
  1407. set_bit(EVENT_RST_PEND, &ir->kevent_flags);
  1408. clear_bit(EVENT_TX_HALT, &ir->kevent_flags);
  1409. /* Cancel all other error events and handlers */
  1410. clear_bit(EVENT_RX_HALT, &ir->kevent_flags);
  1411. return;
  1412. }
  1413. clear_bit(EVENT_TX_HALT, &ir->kevent_flags);
  1414. }
  1415. }
  1416. static struct rc_dev *mceusb_init_rc_dev(struct mceusb_dev *ir)
  1417. {
  1418. struct usb_device *udev = ir->usbdev;
  1419. struct device *dev = ir->dev;
  1420. struct rc_dev *rc;
  1421. int ret;
  1422. rc = rc_allocate_device(RC_DRIVER_IR_RAW);
  1423. if (!rc) {
  1424. dev_err(dev, "remote dev allocation failed");
  1425. goto out;
  1426. }
  1427. usb_make_path(ir->usbdev, ir->phys, sizeof(ir->phys));
  1428. rc->device_name = mceusb_model[ir->model].name ? :
  1429. "Media Center Ed. eHome Infrared Remote Transceiver";
  1430. rc->input_phys = ir->phys;
  1431. usb_to_input_id(ir->usbdev, &rc->input_id);
  1432. rc->dev.parent = dev;
  1433. rc->priv = ir;
  1434. rc->allowed_protocols = RC_PROTO_BIT_ALL_IR_DECODER;
  1435. rc->rx_resolution = MCE_TIME_UNIT;
  1436. rc->min_timeout = MCE_TIME_UNIT;
  1437. rc->timeout = MS_TO_US(100);
  1438. if (!mceusb_model[ir->model].broken_irtimeout) {
  1439. rc->s_timeout = mceusb_set_timeout;
  1440. rc->max_timeout = 10 * IR_DEFAULT_TIMEOUT;
  1441. } else {
  1442. /*
  1443. * If we can't set the timeout using CMD_SETIRTIMEOUT, we can
  1444. * rely on software timeouts for timeouts < 100ms.
  1445. */
  1446. rc->max_timeout = rc->timeout;
  1447. }
  1448. if (!ir->flags.no_tx) {
  1449. rc->s_tx_mask = mceusb_set_tx_mask;
  1450. rc->s_tx_carrier = mceusb_set_tx_carrier;
  1451. rc->tx_ir = mceusb_tx_ir;
  1452. }
  1453. if (ir->flags.rx2 > 0) {
  1454. rc->s_wideband_receiver = mceusb_set_rx_wideband;
  1455. rc->s_carrier_report = mceusb_set_rx_carrier_report;
  1456. }
  1457. rc->driver_name = DRIVER_NAME;
  1458. switch (le16_to_cpu(udev->descriptor.idVendor)) {
  1459. case VENDOR_HAUPPAUGE:
  1460. rc->map_name = RC_MAP_HAUPPAUGE;
  1461. break;
  1462. case VENDOR_PCTV:
  1463. rc->map_name = RC_MAP_PINNACLE_PCTV_HD;
  1464. break;
  1465. default:
  1466. rc->map_name = RC_MAP_RC6_MCE;
  1467. }
  1468. if (mceusb_model[ir->model].rc_map)
  1469. rc->map_name = mceusb_model[ir->model].rc_map;
  1470. ret = rc_register_device(rc);
  1471. if (ret < 0) {
  1472. dev_err(dev, "remote dev registration failed");
  1473. goto out;
  1474. }
  1475. return rc;
  1476. out:
  1477. rc_free_device(rc);
  1478. return NULL;
  1479. }
  1480. static int mceusb_dev_probe(struct usb_interface *intf,
  1481. const struct usb_device_id *id)
  1482. {
  1483. struct usb_device *dev = interface_to_usbdev(intf);
  1484. struct usb_host_interface *idesc;
  1485. struct usb_endpoint_descriptor *ep = NULL;
  1486. struct usb_endpoint_descriptor *ep_in = NULL;
  1487. struct usb_endpoint_descriptor *ep_out = NULL;
  1488. struct mceusb_dev *ir = NULL;
  1489. int pipe, maxp, i, res;
  1490. char buf[63], name[128] = "";
  1491. enum mceusb_model_type model = id->driver_info;
  1492. bool is_gen3;
  1493. bool is_microsoft_gen1;
  1494. bool tx_mask_normal;
  1495. int ir_intfnum;
  1496. dev_dbg(&intf->dev, "%s called", __func__);
  1497. idesc = intf->cur_altsetting;
  1498. is_gen3 = mceusb_model[model].mce_gen3;
  1499. is_microsoft_gen1 = mceusb_model[model].mce_gen1;
  1500. tx_mask_normal = mceusb_model[model].tx_mask_normal;
  1501. ir_intfnum = mceusb_model[model].ir_intfnum;
  1502. /* There are multi-function devices with non-IR interfaces */
  1503. if (idesc->desc.bInterfaceNumber != ir_intfnum)
  1504. return -ENODEV;
  1505. /* step through the endpoints to find first bulk in and out endpoint */
  1506. for (i = 0; i < idesc->desc.bNumEndpoints; ++i) {
  1507. ep = &idesc->endpoint[i].desc;
  1508. if (ep_in == NULL) {
  1509. if (usb_endpoint_is_bulk_in(ep)) {
  1510. ep_in = ep;
  1511. dev_dbg(&intf->dev, "acceptable bulk inbound endpoint found\n");
  1512. } else if (usb_endpoint_is_int_in(ep)) {
  1513. ep_in = ep;
  1514. ep_in->bInterval = 1;
  1515. dev_dbg(&intf->dev, "acceptable interrupt inbound endpoint found\n");
  1516. }
  1517. }
  1518. if (ep_out == NULL) {
  1519. if (usb_endpoint_is_bulk_out(ep)) {
  1520. ep_out = ep;
  1521. dev_dbg(&intf->dev, "acceptable bulk outbound endpoint found\n");
  1522. } else if (usb_endpoint_is_int_out(ep)) {
  1523. ep_out = ep;
  1524. ep_out->bInterval = 1;
  1525. dev_dbg(&intf->dev, "acceptable interrupt outbound endpoint found\n");
  1526. }
  1527. }
  1528. }
  1529. if (!ep_in || !ep_out) {
  1530. dev_dbg(&intf->dev, "required endpoints not found\n");
  1531. return -ENODEV;
  1532. }
  1533. if (usb_endpoint_xfer_int(ep_in))
  1534. pipe = usb_rcvintpipe(dev, ep_in->bEndpointAddress);
  1535. else
  1536. pipe = usb_rcvbulkpipe(dev, ep_in->bEndpointAddress);
  1537. maxp = usb_maxpacket(dev, pipe);
  1538. ir = kzalloc_obj(struct mceusb_dev);
  1539. if (!ir)
  1540. goto mem_alloc_fail;
  1541. ir->pipe_in = pipe;
  1542. ir->buf_in = usb_alloc_coherent(dev, maxp, GFP_KERNEL, &ir->dma_in);
  1543. if (!ir->buf_in)
  1544. goto buf_in_alloc_fail;
  1545. ir->urb_in = usb_alloc_urb(0, GFP_KERNEL);
  1546. if (!ir->urb_in)
  1547. goto urb_in_alloc_fail;
  1548. ir->usbintf = intf;
  1549. ir->usbdev = usb_get_dev(dev);
  1550. ir->dev = &intf->dev;
  1551. ir->len_in = maxp;
  1552. ir->flags.microsoft_gen1 = is_microsoft_gen1;
  1553. ir->flags.tx_mask_normal = tx_mask_normal;
  1554. ir->flags.no_tx = mceusb_model[model].no_tx;
  1555. ir->flags.rx2 = mceusb_model[model].rx2;
  1556. ir->model = model;
  1557. /* Saving usb interface data for use by the transmitter routine */
  1558. ir->usb_ep_out = ep_out;
  1559. if (usb_endpoint_xfer_int(ep_out))
  1560. ir->pipe_out = usb_sndintpipe(ir->usbdev,
  1561. ep_out->bEndpointAddress);
  1562. else
  1563. ir->pipe_out = usb_sndbulkpipe(ir->usbdev,
  1564. ep_out->bEndpointAddress);
  1565. if (dev->descriptor.iManufacturer
  1566. && usb_string(dev, dev->descriptor.iManufacturer,
  1567. buf, sizeof(buf)) > 0)
  1568. strscpy(name, buf, sizeof(name));
  1569. if (dev->descriptor.iProduct
  1570. && usb_string(dev, dev->descriptor.iProduct,
  1571. buf, sizeof(buf)) > 0)
  1572. snprintf(name + strlen(name), sizeof(name) - strlen(name),
  1573. " %s", buf);
  1574. /*
  1575. * Initialize async USB error handler before registering
  1576. * or activating any mceusb RX and TX functions
  1577. */
  1578. INIT_WORK(&ir->kevent, mceusb_deferred_kevent);
  1579. ir->rc = mceusb_init_rc_dev(ir);
  1580. if (!ir->rc)
  1581. goto rc_dev_fail;
  1582. /* wire up inbound data handler */
  1583. if (usb_endpoint_xfer_int(ep_in))
  1584. usb_fill_int_urb(ir->urb_in, dev, pipe, ir->buf_in, maxp,
  1585. mceusb_dev_recv, ir, ep_in->bInterval);
  1586. else
  1587. usb_fill_bulk_urb(ir->urb_in, dev, pipe, ir->buf_in, maxp,
  1588. mceusb_dev_recv, ir);
  1589. ir->urb_in->transfer_dma = ir->dma_in;
  1590. ir->urb_in->transfer_flags |= URB_NO_TRANSFER_DMA_MAP;
  1591. /* flush buffers on the device */
  1592. dev_dbg(&intf->dev, "Flushing receive buffers");
  1593. res = usb_submit_urb(ir->urb_in, GFP_KERNEL);
  1594. if (res)
  1595. dev_err(&intf->dev, "failed to flush buffers: %d", res);
  1596. /* figure out which firmware/emulator version this hardware has */
  1597. mceusb_get_emulator_version(ir);
  1598. /* initialize device */
  1599. if (ir->flags.microsoft_gen1)
  1600. mceusb_gen1_init(ir);
  1601. else if (!is_gen3)
  1602. mceusb_gen2_init(ir);
  1603. mceusb_get_parameters(ir);
  1604. mceusb_flash_led(ir);
  1605. if (!ir->flags.no_tx)
  1606. mceusb_set_tx_mask(ir->rc, MCE_DEFAULT_TX_MASK);
  1607. usb_set_intfdata(intf, ir);
  1608. /* enable wake via this device */
  1609. device_set_wakeup_capable(ir->dev, true);
  1610. device_set_wakeup_enable(ir->dev, true);
  1611. dev_info(&intf->dev, "Registered %s with mce emulator interface version %x",
  1612. name, ir->emver);
  1613. dev_info(&intf->dev, "%x tx ports (0x%x cabled) and %x rx sensors (0x%x active)",
  1614. ir->num_txports, ir->txports_cabled,
  1615. ir->num_rxports, ir->rxports_active);
  1616. return 0;
  1617. /* Error-handling path */
  1618. rc_dev_fail:
  1619. cancel_work_sync(&ir->kevent);
  1620. usb_put_dev(ir->usbdev);
  1621. usb_kill_urb(ir->urb_in);
  1622. usb_free_urb(ir->urb_in);
  1623. urb_in_alloc_fail:
  1624. usb_free_coherent(dev, maxp, ir->buf_in, ir->dma_in);
  1625. buf_in_alloc_fail:
  1626. kfree(ir);
  1627. mem_alloc_fail:
  1628. dev_err(&intf->dev, "%s: device setup failed!", __func__);
  1629. return -ENOMEM;
  1630. }
  1631. static void mceusb_dev_disconnect(struct usb_interface *intf)
  1632. {
  1633. struct usb_device *dev = interface_to_usbdev(intf);
  1634. struct mceusb_dev *ir = usb_get_intfdata(intf);
  1635. dev_dbg(&intf->dev, "%s called", __func__);
  1636. usb_set_intfdata(intf, NULL);
  1637. if (!ir)
  1638. return;
  1639. ir->usbdev = NULL;
  1640. cancel_work_sync(&ir->kevent);
  1641. rc_unregister_device(ir->rc);
  1642. usb_kill_urb(ir->urb_in);
  1643. usb_free_urb(ir->urb_in);
  1644. usb_free_coherent(dev, ir->len_in, ir->buf_in, ir->dma_in);
  1645. usb_put_dev(dev);
  1646. kfree(ir);
  1647. }
  1648. static int mceusb_dev_suspend(struct usb_interface *intf, pm_message_t message)
  1649. {
  1650. struct mceusb_dev *ir = usb_get_intfdata(intf);
  1651. dev_info(ir->dev, "suspend");
  1652. usb_kill_urb(ir->urb_in);
  1653. return 0;
  1654. }
  1655. static int mceusb_dev_resume(struct usb_interface *intf)
  1656. {
  1657. struct mceusb_dev *ir = usb_get_intfdata(intf);
  1658. dev_info(ir->dev, "resume");
  1659. if (usb_submit_urb(ir->urb_in, GFP_ATOMIC))
  1660. return -EIO;
  1661. return 0;
  1662. }
  1663. static struct usb_driver mceusb_dev_driver = {
  1664. .name = DRIVER_NAME,
  1665. .probe = mceusb_dev_probe,
  1666. .disconnect = mceusb_dev_disconnect,
  1667. .suspend = mceusb_dev_suspend,
  1668. .resume = mceusb_dev_resume,
  1669. .reset_resume = mceusb_dev_resume,
  1670. .id_table = mceusb_dev_table
  1671. };
  1672. module_usb_driver(mceusb_dev_driver);
  1673. MODULE_DESCRIPTION(DRIVER_DESC);
  1674. MODULE_AUTHOR(DRIVER_AUTHOR);
  1675. MODULE_LICENSE("GPL");
  1676. MODULE_DEVICE_TABLE(usb, mceusb_dev_table);