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  1. /* USB EHCI Host for Teensy 3.6
  2. * Copyright 2017 Paul Stoffregen (paul@pjrc.com)
  3. *
  4. * Permission is hereby granted, free of charge, to any person obtaining a
  5. * copy of this software and associated documentation files (the
  6. * "Software"), to deal in the Software without restriction, including
  7. * without limitation the rights to use, copy, modify, merge, publish,
  8. * distribute, sublicense, and/or sell copies of the Software, and to
  9. * permit persons to whom the Software is furnished to do so, subject to
  10. * the following conditions:
  11. *
  12. * The above copyright notice and this permission notice shall be included
  13. * in all copies or substantial portions of the Software.
  14. *
  15. * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
  16. * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
  17. * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
  18. * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
  19. * CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
  20. * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
  21. * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
  22. *
  23. * Note: special thanks to the Linux kernel for the CH341's method of operation, particularly how the baud rate is encoded.
  24. */
  25. #include <Arduino.h>
  26. #include "USBHost_t36.h" // Read this header first for key info
  27. #define print USBHost::print_
  28. #define println USBHost::println_
  29. //#define ENABLE_DEBUG_PINS
  30. #ifdef ENABLE_DEBUG_PINS
  31. #define debugDigitalToggle(pin) {digitalWriteFast(pin, !digitalReadFast(pin));}
  32. #define debugDigitalWrite(pin, state) {digitalWriteFast(pin, state);}
  33. #else
  34. #define debugDigitalToggle(pin) {;}
  35. #define debugDigitalWrite(pin, state) {;}
  36. #endif
  37. /************************************************************/
  38. // Define mapping VID/PID - to Serial Device type.
  39. /************************************************************/
  40. USBSerialBase::product_vendor_mapping_t USBSerialBase::pid_vid_mapping[] = {
  41. // FTDI mappings.
  42. {0x0403, 0x6001, USBSerialBase::FTDI, 0},
  43. {0x0403, 0x8088, USBSerialBase::FTDI, 1}, // 2 devices try to claim at interface level
  44. // PL2303
  45. {0x67B,0x2303, USBSerialBase::PL2303, 0},
  46. // CH341
  47. {0x4348, 0x5523, USBSerialBase::CH341, 0},
  48. {0x1a86, 0x7523, USBSerialBase::CH341, 0 },
  49. {0x1a86, 0x5523, USBSerialBase::CH341, 0 },
  50. // Silex CP210...
  51. {0x10c4, 0xea60, USBSerialBase::CP210X, 0 }
  52. };
  53. /************************************************************/
  54. // Initialization and claiming of devices & interfaces
  55. /************************************************************/
  56. void USBSerialBase::init()
  57. {
  58. contribute_Pipes(mypipes, sizeof(mypipes)/sizeof(Pipe_t));
  59. contribute_Transfers(mytransfers, sizeof(mytransfers)/sizeof(Transfer_t));
  60. contribute_String_Buffers(mystring_bufs, sizeof(mystring_bufs)/sizeof(strbuf_t));
  61. driver_ready_for_device(this);
  62. format_ = USBHOST_SERIAL_8N1;
  63. }
  64. bool USBSerialBase::claim(Device_t *dev, int type, const uint8_t *descriptors, uint32_t len)
  65. {
  66. print("USBSerial(", _max_rxtx, DEC);
  67. println(")claim this=", (uint32_t)this, HEX);
  68. print("vid=", dev->idVendor, HEX);
  69. print(", pid=", dev->idProduct, HEX);
  70. print(", bDeviceClass = ", dev->bDeviceClass);
  71. print(", bDeviceSubClass = ", dev->bDeviceSubClass);
  72. println(", bDeviceProtocol = ", dev->bDeviceProtocol);
  73. print_hexbytes(descriptors, len);
  74. //---------------------------------------------------------------------------
  75. // Lets try to map CDCACM devices only at device level
  76. if ((dev->bDeviceClass == 2) && (dev->bDeviceSubClass == 0)) {
  77. if (type != 0) return false;
  78. // It is a communication device see if we can extract the data...
  79. // Try some ttyACM types?
  80. // This code may be similar to MIDI code.
  81. // But first pass see if we can simply look at the interface...
  82. // Lets walk through end points and see if we
  83. // can find an RX and TX bulk transfer end point.
  84. // 0 1 2 3 4 5 6 7 8 *9 10 1 2 3 *4 5 6 7 *8 9 20 1 2 *3 4 5 6 7 8 9*30 1 2 3 4 5 6 7 8 *9 40 1 2 3 4 5 *6 7 8 9 50 1 2
  85. // USB2AX
  86. //09 04 00 00 01 02 02 01 00 05 24 00 10 01 04 24 02 06 05 24 06 00 01 07 05 82 03 08 00 FF 09 04 01 00 02 0A 00 00 00 07 05 04 02 10 00 01 07 05 83 02 10 00 01
  87. //09 04 01 00 02 0A 00 00 00 07 05 04 02 10 00 01 07 05 83 02 10 00 01
  88. // Teensy 3.6
  89. //09 04 00 00 01 02 02 01 00 05 24 00 10 01 05 24 01 01 01 04 24 02 06 05 24 06 00 01 07 05 82 03 10 00 40 09 04 01 00 02 0A 00 00 00 07 05 03 02 40 00 00 07 05 84 02 40 00 00
  90. //09 04 01 00 02 0A 00 00 00 07 05 03 02 40 00 00 07 05 84 02 40 00 00
  91. const uint8_t *p = descriptors;
  92. const uint8_t *end = p + len;
  93. if (p[0] != 9 || p[1] != 4) return false; // interface descriptor
  94. //println(" bInterfaceClass=", p[5]);
  95. //println(" bInterfaceSubClass=", p[6]);
  96. if (p[5] != 2) return false; // bInterfaceClass: 2 Communications
  97. if (p[6] != 2) return false; // bInterfaceSubClass: 2 serial
  98. p += 9;
  99. println(" Interface is Serial");
  100. uint8_t rx_ep = 0;
  101. uint8_t tx_ep = 0;
  102. uint16_t rx_size = 0;
  103. uint16_t tx_size = 0;
  104. interface = 0; // clear out any interface numbers passed in.
  105. while (p < end) {
  106. len = *p;
  107. if (len < 4) return false;
  108. if (p + len > end) return false; // reject if beyond end of data
  109. uint32_t type = p[1];
  110. //println("type: ", type);
  111. // Unlike Audio, we need to look at Interface as our endpoints are after them...
  112. if (type == 4 ) { // Interface - lets remember it's number...
  113. interface = p[2];
  114. println(" Interface: ", interface);
  115. }
  116. else if (type == 0x24) { // 0x24 = CS_INTERFACE,
  117. uint32_t subtype = p[2];
  118. print(" CS_INTERFACE - subtype: ", subtype);
  119. if (len >= 4) print(" ", p[3], HEX);
  120. if (len >= 5) print(" ", p[4], HEX);
  121. if (len >= 6) print(" ", p[5], HEX);
  122. switch (subtype) {
  123. case 0: println(" - Header Functional Descriptor"); break;
  124. case 1: println(" - Call Management Functional"); break;
  125. case 2: println(" - Abstract Control Management"); break;
  126. case 4: println(" - Telephone Ringer"); break;
  127. case 6: println(" - union Functional"); break;
  128. default: println(" - ??? other"); break;
  129. }
  130. // First pass ignore...
  131. } else if (type == 5) {
  132. // endpoint descriptor
  133. if (p[0] < 7) return false; // at least 7 bytes
  134. if (p[3] == 2) { // First try ignore the first one which is interrupt...
  135. println(" Endpoint: ", p[2], HEX);
  136. switch (p[2] & 0xF0) {
  137. case 0x80:
  138. // IN endpoint
  139. if (rx_ep == 0) {
  140. rx_ep = p[2] & 0x0F;
  141. rx_size = p[4] | (p[5] << 8);
  142. println(" rx_size = ", rx_size);
  143. }
  144. break;
  145. case 0x00:
  146. // OUT endpoint
  147. if (tx_ep == 0) {
  148. tx_ep = p[2];
  149. tx_size = p[4] | (p[5] << 8);
  150. println(" tx_size = ", tx_size);
  151. }
  152. break;
  153. default:
  154. println(" invalid end point: ", p[2]);
  155. return false;
  156. }
  157. }
  158. } else {
  159. println(" Unknown type: ", type);
  160. return false; // unknown
  161. }
  162. p += len;
  163. }
  164. print(" exited loop rx:", rx_ep);
  165. println(", tx:", tx_ep);
  166. if (!rx_ep || !tx_ep) return false; // did not get our two end points
  167. if (!init_buffers(rx_size, tx_size)) return false;
  168. println(" rx buffer size:", rxsize);
  169. println(" tx buffer size:", txsize);
  170. rxpipe = new_Pipe(dev, 2, rx_ep & 15, 1, rx_size);
  171. if (!rxpipe) return false;
  172. txpipe = new_Pipe(dev, 2, tx_ep, 0, tx_size);
  173. if (!txpipe) {
  174. // TODO: free rxpipe
  175. return false;
  176. }
  177. sertype = CDCACM;
  178. rxpipe->callback_function = rx_callback;
  179. queue_Data_Transfer(rxpipe, rx1, (rx_size < 64)? rx_size : 64, this);
  180. rxstate = 1;
  181. if (rx_size > 128) {
  182. queue_Data_Transfer(rxpipe, rx2, rx_size, this);
  183. rxstate = 3;
  184. }
  185. txstate = 0;
  186. txpipe->callback_function = tx_callback;
  187. baudrate = 115200;
  188. // Wish I could just call Control to do the output... Maybe can defer until the user calls begin()
  189. // control requires that device is setup which is not until this call completes...
  190. println("Control - CDCACM DTR...");
  191. // Need to setup the data the line coding data
  192. mk_setup(setup, 0x21, 0x22, 3, 0, 0);
  193. queue_Control_Transfer(dev, &setup, NULL, this);
  194. control_queued = true;
  195. pending_control = 0x0; // Maybe don't need to do...
  196. return true;
  197. }
  198. //---------------------------------------------------------------------------
  199. // Else lets see if this is a PID/VID we know something about.
  200. // See if the vendor_id:product_id is in our list of products.
  201. sertype = UNKNOWN;
  202. for (uint8_t i = 0; i < (sizeof(pid_vid_mapping)/sizeof(pid_vid_mapping[0])); i++) {
  203. if ((dev->idVendor == pid_vid_mapping[i].idVendor) && (dev->idProduct == pid_vid_mapping[i].idProduct)) {
  204. sertype = pid_vid_mapping[i].sertype;
  205. if (pid_vid_mapping[i].claim_at_type != type) {
  206. println("Serial device wants to map at interface level");
  207. return false;
  208. }
  209. break;
  210. }
  211. }
  212. if (sertype == UNKNOWN) {
  213. // Not in our list see if CDCACM type...
  214. // only at the Interface level
  215. if (type != 1) return false;
  216. // TTYACM: <Composit device>
  217. //
  218. // We first tried to claim a simple ttyACM device like a teensy who is configured
  219. // only as Serial at the device level like what was done for midi
  220. //
  221. // However some devices are a compisit of multiple Interfaces, so see if this Interface
  222. // is of the CDC Interface class and 0 for SubClass and protocol
  223. // Todo: some of this can maybe be combined with the Whole device code above.
  224. if (descriptors[0] != 9 || descriptors[1] != 4) return false; // interface descriptor
  225. if (descriptors[4] < 2) return false; // less than 2 end points
  226. if (descriptors[5] != 0xA) return false; // bInterfaceClass, 0xa = CDC data
  227. if (descriptors[6] != 0) return false; // bInterfaceSubClass
  228. if (descriptors[7] != 0) return false; // bInterfaceProtocol
  229. sertype = CDCACM;
  230. // Lets see if we can fold in the ACM stuff here...
  231. }
  232. // Lets try to locate the end points. Code is common across these devices
  233. println("len = ", len);
  234. uint8_t count_end_points = descriptors[4];
  235. if (count_end_points < 2) return false; // not enough end points
  236. if (len < 23) return false;
  237. if (descriptors[0] != 9) return false; // length 9
  238. // Lets walk through end points and see if we
  239. // can find an RX and TX bulk transfer end point.
  240. //Example vid=67B, pid=2303
  241. // 0 1 2 3 4 5 6 7 8 9 10 1 2 3 4 5 6 7 8 9 20 1 2 3 4 5 6 7 8 9
  242. //09 04 00 00 03 FF 00 00 00 07 05 81 03 0A 00 01 07 05 02 02 40 00 00 07 05 83 02 40 00 00
  243. // lets see about FTD2232H
  244. //09 04 00 00 02 FF FF FF 02 07 05 81 02 00 02 00 07 05 02 02 00 02 00 09 04 01 00 02 FF FF FF 02 07 05 83 02 00 02 00 07 05 04 02 00 02 00
  245. //09 04 01 00 02 FF FF FF 02 07 05 83 02 00 02 00 07 05 04 02 00 02 00
  246. uint32_t rxep = 0;
  247. uint32_t txep = 0;
  248. uint16_t rx_size = 0;
  249. uint16_t tx_size = 0;
  250. uint32_t descriptor_index = 9;
  251. while (count_end_points-- && ((rxep == 0) || txep == 0)) {
  252. if (descriptors[descriptor_index] != 7) return false; // length 7
  253. if (descriptors[descriptor_index+1] != 5) return false; // ep desc
  254. uint16_t ep_size = descriptors[descriptor_index+4] + (uint16_t)(descriptors[descriptor_index+5] << 8);
  255. if ((descriptors[descriptor_index+3] == 2)
  256. && (ep_size <= _max_rxtx) && (ep_size >= _min_rxtx)) {
  257. // have a bulk EP size
  258. if (descriptors[descriptor_index+2] & 0x80 ) {
  259. rxep = descriptors[descriptor_index+2];
  260. rx_size = ep_size;
  261. } else {
  262. txep = descriptors[descriptor_index+2];
  263. tx_size = ep_size;
  264. }
  265. }
  266. descriptor_index += 7; // setup to look at next one...
  267. }
  268. // Try to verify the end points.
  269. if (!check_rxtx_ep(rxep, txep)) return false;
  270. print("USBSerial, rxep=", rxep & 15);
  271. print("(", rx_size);
  272. print("), txep=", txep);
  273. print("(", tx_size);
  274. println(")");
  275. if (!init_buffers(rx_size, tx_size)) return false;
  276. println(" rx buffer size:", rxsize);
  277. println(" tx buffer size:", txsize);
  278. rxpipe = new_Pipe(dev, 2, rxep & 15, 1, rx_size);
  279. if (!rxpipe) return false;
  280. txpipe = new_Pipe(dev, 2, txep, 0, tx_size);
  281. if (!txpipe) {
  282. //free_Pipe(rxpipe);
  283. return false;
  284. }
  285. rxpipe->callback_function = rx_callback;
  286. queue_Data_Transfer(rxpipe, rx1, rx_size, this);
  287. rxstate = 1;
  288. txstate = 0;
  289. txpipe->callback_function = tx_callback;
  290. baudrate = 115200;
  291. // Now do specific setup per type
  292. switch (sertype) {
  293. //---------------------------------------------------------------------
  294. // FTDI
  295. case FTDI:
  296. {
  297. pending_control = 0x0F;
  298. mk_setup(setup, 0x40, 0, 0, 0, 0); // reset port
  299. queue_Control_Transfer(dev, &setup, NULL, this);
  300. control_queued = true;
  301. return true;
  302. }
  303. //------------------------------------------------------------------------
  304. // Prolific
  305. // TODO: Note: there are probably more vendor/product pairs.. Maybe should create table of them
  306. case PL2303:
  307. {
  308. // First attempt keep it simple...
  309. println("PL2303: readRegister(0x04)");
  310. // Need to setup the data the line coding data
  311. mk_setup(setup, 0xC0, 0x1, 0x8484, 0, 1);
  312. queue_Control_Transfer(dev, &setup, setupdata, this);
  313. control_queued = true;
  314. setup_state = 1; // We are at step one of setup...
  315. pending_control = 0x3f;
  316. return true;
  317. }
  318. //------------------------------------------------------------------------
  319. // CH341
  320. case CH341:
  321. {
  322. println("CH341: 0xC0, 0x5f, 0, 0, 8");
  323. // Need to setup the data the line coding data
  324. mk_setup(setup, 0xC0, 0x5f, 0, 0, sizeof(setupdata));
  325. queue_Control_Transfer(dev, &setup, setupdata, this);
  326. control_queued = true;
  327. setup_state = 1; // We are at step one of setup...
  328. pending_control = 0x7f;
  329. return true;
  330. }
  331. //------------------------------------------------------------------------
  332. // CP210X
  333. case CP210X:
  334. {
  335. println("CP210X: 0x41, 0x11, 0, 0, 0 - reset port");
  336. // Need to setup the data the line coding data
  337. mk_setup(setup, 0x41, 0x11, 0, 0, 0);
  338. queue_Control_Transfer(dev, &setup, NULL, this);
  339. control_queued = true;
  340. setup_state = 1; // We are at step one of setup...
  341. pending_control = 0xf;
  342. return true;
  343. }
  344. case CDCACM:
  345. {
  346. println("Control - CDCACM LINE_CODING");
  347. setupdata[0] = 0; // Setup baud rate 115200 - 0x1C200
  348. setupdata[1] = 0xc2;
  349. setupdata[2] = 0x1;
  350. setupdata[3] = 0;
  351. setupdata[4] = 0; // 0 - 1 stop bit, 1 - 1.5 stop bits, 2 - 2 stop bits
  352. setupdata[5] = 0; // 0 - None, 1 - Odd, 2 - Even, 3 - Mark, 4 - Space
  353. setupdata[6] = 8; // Data bits (5, 6, 7, 8 or 16)
  354. mk_setup(setup, 0x21, 0x20, 0, 0, 7);
  355. queue_Control_Transfer(dev, &setup, setupdata, this);
  356. pending_control = 0x04; // Maybe don't need to do...
  357. control_queued = true;
  358. return true;
  359. }
  360. //------------------------------------------------------------------------
  361. // PID:VID - not in our product list.
  362. default:
  363. break;
  364. }
  365. return false;
  366. }
  367. // check if two legal endpoints, 1 receive & 1 transmit
  368. bool USBSerialBase::check_rxtx_ep(uint32_t &rxep, uint32_t &txep)
  369. {
  370. if ((rxep & 0x0F) == 0) return false;
  371. if ((txep & 0x0F) == 0) return false;
  372. uint32_t rxdir = rxep & 0xF0;
  373. uint32_t txdir = txep & 0xF0;
  374. if (rxdir == 0x80 && txdir == 0x00) {
  375. return true;
  376. }
  377. if (rxdir == 0x00 && txdir == 0x80) {
  378. std::swap(rxep, txep);
  379. return true;
  380. }
  381. return false;
  382. }
  383. // initialize buffer sizes and pointers
  384. bool USBSerialBase::init_buffers(uint32_t rsize, uint32_t tsize)
  385. {
  386. // buffer must be able to hold 2 of each packet, plus buffer
  387. // space to hold RX and TX data.
  388. if (_big_buffer_size < (rsize + tsize) * 3 + 2) return false;
  389. rx1 = (uint8_t *)_bigBuffer;
  390. rx2 = rx1 + rsize;
  391. tx1 = rx2 + rsize;
  392. tx2 = tx1 + tsize;
  393. rxbuf = tx2 + tsize;
  394. // FIXME: this assume 50-50 split - not true when rsize != tsize
  395. rxsize = (_big_buffer_size - (rsize + tsize) * 2) / 2;
  396. txsize = rxsize;
  397. txbuf = rxbuf + rxsize;
  398. rxhead = 0;
  399. rxtail = 0;
  400. txhead = 0;
  401. txtail = 0;
  402. rxstate = 0;
  403. return true;
  404. }
  405. void USBSerialBase::disconnect()
  406. {
  407. }
  408. void USBSerialBase::control(const Transfer_t *transfer)
  409. {
  410. println("control callback (serial) ", pending_control, HEX);
  411. control_queued = false;
  412. // We will split this up by Serial type, maybe different functions?
  413. //-------------------------------------------------------------------------
  414. // First FTDI
  415. if (sertype == FTDI) {
  416. if (pending_control & 1) {
  417. pending_control &= ~1;
  418. // set data format
  419. uint16_t ftdi_format = format_ & 0xf; // This should give us the number of bits.
  420. // now lets extract the parity from our encoding
  421. ftdi_format |= (format_ & 0xe0) << 3; // they encode bits 9-11
  422. // See if two stop bits
  423. if (format_ & 0x100) ftdi_format |= (0x2 << 11);
  424. mk_setup(setup, 0x40, 4, ftdi_format, 0, 0); // data format 8N1
  425. queue_Control_Transfer(device, &setup, NULL, this);
  426. control_queued = true;
  427. return;
  428. }
  429. // set baud rate
  430. if (pending_control & 2) {
  431. pending_control &= ~2;
  432. uint32_t baudval = 3000000 / baudrate;
  433. mk_setup(setup, 0x40, 3, baudval, 0, 0);
  434. queue_Control_Transfer(device, &setup, NULL, this);
  435. control_queued = true;
  436. return;
  437. }
  438. // configure flow control
  439. if (pending_control & 4) {
  440. pending_control &= ~4;
  441. mk_setup(setup, 0x40, 2, 0, 1, 0);
  442. queue_Control_Transfer(device, &setup, NULL, this);
  443. control_queued = true;
  444. return;
  445. }
  446. // set DTR
  447. if (pending_control & 8) {
  448. pending_control &= ~8;
  449. mk_setup(setup, 0x40, 1, 0x0101, 0, 0);
  450. queue_Control_Transfer(device, &setup, NULL, this);
  451. control_queued = true;
  452. return;
  453. }
  454. // clear DTR
  455. if (pending_control & 0x80) {
  456. pending_control &= ~0x80;
  457. println("FTDI clear DTR");
  458. mk_setup(setup, 0x40, 1, 0x0100, 0, 0);
  459. queue_Control_Transfer(device, &setup, NULL, this);
  460. control_queued = true;
  461. return;
  462. }
  463. }
  464. //-------------------------------------------------------------------------
  465. // Now CDCACM
  466. if (sertype == CDCACM) {
  467. if (pending_control & 2) {
  468. pending_control &= ~2;
  469. // Should probably use data structure, but that may depend on byte ordering...
  470. setupdata[0] = (baudrate) & 0xff; // Setup baud rate 115200 - 0x1C200
  471. setupdata[1] = (baudrate >> 8) & 0xff;
  472. setupdata[2] = (baudrate >> 16) & 0xff;
  473. setupdata[3] = (baudrate >> 24) & 0xff;
  474. setupdata[4] = (format_ & 0x100)? 2 : 0; // 0 - 1 stop bit, 1 - 1.5 stop bits, 2 - 2 stop bits
  475. setupdata[5] = (format_ & 0xe0) >> 5; // 0 - None, 1 - Odd, 2 - Even, 3 - Mark, 4 - Space
  476. setupdata[6] = format_ & 0x1f; // Data bits (5, 6, 7, 8 or 16)
  477. print("CDCACM setup: ");
  478. print_hexbytes(&setupdata, 7);
  479. mk_setup(setup, 0x21, 0x20, 0, 0, 7);
  480. queue_Control_Transfer(device, &setup, setupdata, this);
  481. control_queued = true;
  482. return;
  483. }
  484. // configure flow control
  485. if (pending_control & 4) {
  486. pending_control &= ~4;
  487. println("Control - 0x21,0x22, 0x3");
  488. // Need to setup the data the line coding data
  489. mk_setup(setup, 0x21, 0x22, 3, 0, 0);
  490. queue_Control_Transfer(device, &setup, NULL, this);
  491. control_queued = true;
  492. return;
  493. }
  494. if (pending_control & 0x80) {
  495. pending_control &= ~0x80;
  496. println("Control - 0x21,0x22, 0x0 - clear DTR");
  497. // Need to setup the data the line coding data
  498. mk_setup(setup, 0x21, 0x22, 0, 0, 0);
  499. queue_Control_Transfer(device, &setup, NULL, this);
  500. control_queued = true;
  501. return;
  502. }
  503. }
  504. //-------------------------------------------------------------------------
  505. // Now PL2303 - Which appears to be a little more complicated
  506. if (sertype == PL2303) {
  507. if (pending_control & 1) {
  508. // Still in larger setup state mode
  509. switch (setup_state) {
  510. case 1:
  511. println("PL2303: writeRegister(0x04, 0x00)");
  512. mk_setup(setup, 0x40, 1, 0x0404, 0, 0); //
  513. queue_Control_Transfer(device, &setup, NULL, this);
  514. setup_state = 2;
  515. control_queued = true;
  516. return;
  517. case 2:
  518. println("PL2303: readRegister(0x04)");
  519. mk_setup(setup, 0xC0, 0x1, 0x8484, 0, 1);
  520. queue_Control_Transfer(device, &setup, setupdata, this);
  521. control_queued = true;
  522. setup_state = 3;
  523. return;
  524. case 3:
  525. println("PL2303: v1 = readRegister(0x03)");
  526. mk_setup(setup, 0xC0, 0x1, 0x8383, 0, 1);
  527. queue_Control_Transfer(device, &setup, setupdata, this);
  528. control_queued = true;
  529. setup_state = 4;
  530. return;
  531. case 4:
  532. println("PL2303: readRegister(0x04)");
  533. // Do we need this value long term or we could just leave in setup data?
  534. pl2303_v1 = setupdata[0]; // save the first bye of version
  535. mk_setup(setup, 0xC0, 0x1, 0x8484, 0, 1);
  536. queue_Control_Transfer(device, &setup, setupdata, this);
  537. control_queued = true;
  538. setup_state = 5;
  539. return;
  540. case 5:
  541. println("PL2303: writeRegister(0x04, 0x01)");
  542. mk_setup(setup, 0x40, 1, 0x0404, 1, 0); //
  543. queue_Control_Transfer(device, &setup, NULL, this);
  544. setup_state = 6;
  545. control_queued = true;
  546. return;
  547. case 6:
  548. println("PL2303: readRegister(0x04)");
  549. mk_setup(setup, 0xC0, 0x1, 0x8484, 0, 1);
  550. queue_Control_Transfer(device, &setup, setupdata, this);
  551. control_queued = true;
  552. setup_state = 7;
  553. return;
  554. case 7:
  555. println("PL2303: v2 = readRegister(0x03)");
  556. mk_setup(setup, 0xC0, 0x1, 0x8383, 0, 1);
  557. queue_Control_Transfer(device, &setup, setupdata, this);
  558. control_queued = true;
  559. setup_state = 8;
  560. return;
  561. case 8:
  562. pl2303_v2 = setupdata[0]; // save the first bye of version
  563. print(" PL2303 Version ", pl2303_v1, HEX);
  564. println(":", pl2303_v2, HEX);
  565. println("PL2303: writeRegister(0, 1)");
  566. mk_setup(setup, 0x40, 1, 0, 1, 0); //
  567. queue_Control_Transfer(device, &setup, NULL, this);
  568. setup_state = 9;
  569. control_queued = true;
  570. return;
  571. case 9:
  572. println("PL2303: writeRegister(1, 0)");
  573. mk_setup(setup, 0x40, 1, 1, 0, 0); //
  574. queue_Control_Transfer(device, &setup, NULL, this);
  575. setup_state = 10;
  576. control_queued = true;
  577. return;
  578. case 10:
  579. println("PL2303: writeRegister(2, 44)");
  580. mk_setup(setup, 0x40, 1, 2, 0x44, 0); //
  581. queue_Control_Transfer(device, &setup, NULL, this);
  582. setup_state = 11;
  583. control_queued = true;
  584. return;
  585. case 11:
  586. println("PL2303: writeRegister(8, 0)");
  587. mk_setup(setup, 0x40, 1, 8, 0, 0); //
  588. queue_Control_Transfer(device, &setup, NULL, this);
  589. setup_state = 12;
  590. control_queued = true;
  591. return;
  592. case 12:
  593. println("PL2303: writeRegister(9, 0)");
  594. mk_setup(setup, 0x40, 1, 9, 0, 0); //
  595. queue_Control_Transfer(device, &setup, NULL, this);
  596. setup_state = 13;
  597. control_queued = true;
  598. return;
  599. case 13:
  600. println("PL2303: Read current Baud/control");
  601. mk_setup(setup, 0xA1, 0x21, 0, 0, 7);
  602. queue_Control_Transfer(device, &setup, setupdata, this);
  603. control_queued = true;
  604. break;
  605. }
  606. pending_control &= ~1; // We are finally going to leave this list and join the rest
  607. if (control_queued) return;
  608. }
  609. // set baud rate
  610. if (pending_control & 2) {
  611. pending_control &= ~2;
  612. // See what the read returned earlier
  613. print("PL2303: Returned configuration data: ");
  614. print_hexbytes(setupdata, 7);
  615. // Should probably use data structure, but that may depend on byte ordering...
  616. setupdata[0] = (baudrate) & 0xff; // Setup baud rate 115200 - 0x1C200
  617. setupdata[1] = (baudrate >> 8) & 0xff;
  618. setupdata[2] = (baudrate >> 16) & 0xff;
  619. setupdata[3] = (baudrate >> 24) & 0xff;
  620. setupdata[4] = (format_ & 0x100)? 2 : 0; // 0 - 1 stop bit, 1 - 1.5 stop bits, 2 - 2 stop bits
  621. setupdata[5] = (format_ & 0xe0) >> 5; // 0 - None, 1 - Odd, 2 - Even, 3 - Mark, 4 - Space
  622. setupdata[6] = format_ & 0x1f; // Data bits (5, 6, 7, 8 or 16)
  623. print("PL2303: Set baud/control: ", baudrate, HEX);
  624. print(" = ");
  625. print_hexbytes(&setupdata, 7);
  626. mk_setup(setup, 0x21, 0x20, 0, 0, 7);
  627. queue_Control_Transfer(device, &setup, setupdata, this);
  628. control_queued = true;
  629. return;
  630. }
  631. if (pending_control & 4) {
  632. pending_control &= ~4;
  633. println("PL2303: writeRegister(0, 0)");
  634. mk_setup(setup, 0x40, 1, 0, 0, 0); //
  635. queue_Control_Transfer(device, &setup, NULL, this);
  636. control_queued = true;
  637. return;
  638. }
  639. if (pending_control & 8) {
  640. pending_control &= ~8;
  641. println("PL2303: Read current Baud/control");
  642. memset(setupdata, 0, sizeof(setupdata)); // clear it to see if we read it...
  643. mk_setup(setup, 0xA1, 0x21, 0, 0, 7);
  644. queue_Control_Transfer(device, &setup, setupdata, this);
  645. control_queued = true;
  646. }
  647. if (pending_control & 0x10) {
  648. pending_control &= ~0x10;
  649. print("PL2303: Returned configuration data: ");
  650. print_hexbytes(setupdata, 7);
  651. // This sets the control lines (0x1=DTR, 0x2=RTS)
  652. println("PL2303: 0x21, 0x22, 0x3");
  653. mk_setup(setup, 0x21, 0x22, 3, 0, 0); //
  654. queue_Control_Transfer(device, &setup, NULL, this);
  655. control_queued = true;
  656. return;
  657. }
  658. if (pending_control & 0x20) {
  659. pending_control &= ~0x20;
  660. println("PL2303: 0x21, 0x22, 0x3");
  661. mk_setup(setup, 0x21, 0x22, 3, 0, 0); //
  662. queue_Control_Transfer(device, &setup, NULL, this);
  663. control_queued = true;
  664. }
  665. if (pending_control & 0x80) {
  666. pending_control &= ~0x80;
  667. println("PL2303: 0x21, 0x22, 0x0"); // Clear DTR/RTS
  668. mk_setup(setup, 0x21, 0x22, 0, 0, 0); //
  669. queue_Control_Transfer(device, &setup, NULL, this);
  670. control_queued = true;
  671. }
  672. }
  673. if (sertype == CH341) {
  674. #if 0
  675. print(" Transfer: ");
  676. print_hexbytes(&transfer->setup, sizeof(setup_t));
  677. if (transfer->length) {
  678. print(" data: ");
  679. print_hexbytes(transfer->buffer, transfer->length);
  680. }
  681. #endif
  682. if (pending_control & 1) {
  683. // Still in larger setup state mode
  684. switch (setup_state) {
  685. case 1:
  686. print(" Returned: ");
  687. print_hexbytes(transfer->buffer, transfer->length);
  688. println("CH341: 40, a1, 0, 0, 0");
  689. mk_setup(setup, 0x40, 0xa1, 0, 0, 0); //
  690. queue_Control_Transfer(device, &setup, NULL, this);
  691. setup_state = 2;
  692. control_queued = true;
  693. return;
  694. case 2:
  695. ch341_setBaud(0); // send the first byte of the baud rate
  696. control_queued = true;
  697. setup_state = 3;
  698. return;
  699. case 3:
  700. ch341_setBaud(1); // send the second byte of the baud rate
  701. control_queued = true;
  702. setup_state = 4;
  703. return;
  704. case 4:
  705. println("CH341: c0, 95, 2518, 0, 8");
  706. mk_setup(setup, 0xc0, 0x95, 0x2518, 0, sizeof(setup)); //
  707. queue_Control_Transfer(device, &setup, setupdata, this);
  708. setup_state = 5;
  709. control_queued = true;
  710. return;
  711. case 5:
  712. print(" Returned: ");
  713. print_hexbytes(transfer->buffer, transfer->length);
  714. println("CH341: 40, 0x9a, 0x2518, 0x0050, 0");
  715. mk_setup(setup, 0x40, 0x9a, 0x2518, 0x0050, 0); //
  716. queue_Control_Transfer(device, &setup, NULL, this);
  717. setup_state = 6;
  718. control_queued = true;
  719. return;
  720. case 6:
  721. println("CH341: c0, 95, 0x706, 0, 8 - get status");
  722. mk_setup(setup, 0xc0, 0x95, 0x706, 0, sizeof(setup)); //
  723. queue_Control_Transfer(device, &setup, setupdata, this);
  724. setup_state = 7;
  725. control_queued = true;
  726. return;
  727. case 7:
  728. print(" Returned: ");
  729. print_hexbytes(transfer->buffer, transfer->length);
  730. println("CH341: 40, 0xa1, 0x501f, 0xd90a, 0");
  731. mk_setup(setup, 0x40, 0xa1, 0x501f, 0xd90a, 0); //
  732. queue_Control_Transfer(device, &setup, NULL, this);
  733. setup_state = 8;
  734. control_queued = true;
  735. break;
  736. }
  737. pending_control &= ~1; // We are finally going to leave this list and join the rest
  738. if (control_queued) return;
  739. }
  740. // set baud rate
  741. if (pending_control & 2) {
  742. pending_control &= ~2;
  743. ch341_setBaud(0); // send the first byte of the baud rate
  744. control_queued = true;
  745. return;
  746. }
  747. if (pending_control & 4) {
  748. pending_control &= ~4;
  749. ch341_setBaud(1); // send the first byte of the baud rate
  750. control_queued = true;
  751. return;
  752. }
  753. if (pending_control & 8) {
  754. pending_control &= ~8;
  755. uint16_t ch341_format;
  756. switch (format_) {
  757. default:
  758. // These values were observed when used on PC... Need to flush out others.
  759. case USBHOST_SERIAL_8N1: ch341_format = 0xc3; break;
  760. case USBHOST_SERIAL_7E1: ch341_format = 0xda; break;
  761. case USBHOST_SERIAL_7O1: ch341_format = 0xca; break;
  762. case USBHOST_SERIAL_8N2: ch341_format = 0xc7; break;
  763. }
  764. println("CH341: 40, 0x9a, 0x2518: ", ch341_format, HEX);
  765. mk_setup(setup, 0x40, 0x9a, 0x2518, ch341_format, 0); //
  766. queue_Control_Transfer(device, &setup, NULL, this);
  767. control_queued = true;
  768. return;
  769. }
  770. if (pending_control & 0x10) {
  771. pending_control &= ~0x10;
  772. // This is setting handshake need to figure out what...
  773. // 0x20=DTR, 0x40=RTS send ~ of values.
  774. println("CH341: 0x40, 0xa4, 0xff9f, 0, 0 - Handshake");
  775. mk_setup(setup, 0x40, 0xa4, 0xff9f, 0, 0); //
  776. queue_Control_Transfer(device, &setup, NULL, this);
  777. control_queued = true;
  778. return;
  779. }
  780. if (pending_control & 0x20) {
  781. pending_control &= ~0x20;
  782. // This is setting handshake need to figure out what...
  783. println("CH341: c0, 95, 0x706, 0, 8 - get status");
  784. mk_setup(setup, 0xc0, 0x95, 0x706, 0, sizeof(setup)); //
  785. queue_Control_Transfer(device, &setup, setupdata, this);
  786. control_queued = true;
  787. return;
  788. }
  789. if (pending_control & 0x40) {
  790. pending_control &= ~0x40;
  791. print(" Returned: ");
  792. print_hexbytes(transfer->buffer, transfer->length);
  793. println("CH341: 0x40, 0x9a, 0x2727, 0, 0");
  794. mk_setup(setup, 0x40, 0x9a, 0x2727, 0, 0); //
  795. queue_Control_Transfer(device, &setup, NULL, this);
  796. return;
  797. }
  798. if (pending_control & 0x80) {
  799. pending_control &= ~0x80;
  800. println("CH341: 0x40, 0xa4, 0xffff, 0, 0 - Handshake");
  801. mk_setup(setup, 0x40, 0xa4, 0xffff, 0, 0); //
  802. queue_Control_Transfer(device, &setup, NULL, this);
  803. control_queued = true;
  804. return;
  805. }
  806. }
  807. //-------------------------------------------------------------------------
  808. // First CP210X
  809. if (sertype == CP210X) {
  810. if (pending_control & 1) {
  811. pending_control &= ~1;
  812. // set data format
  813. uint16_t cp210x_format = (format_ & 0xf) << 8; // This should give us the number of bits.
  814. // now lets extract the parity from our encoding bits 5-7 and in theres 4-7
  815. cp210x_format |= (format_ & 0xe0) >> 1; // they encode bits 9-11
  816. // See if two stop bits
  817. if (format_ & 0x100) cp210x_format |= 2;
  818. mk_setup(setup, 0x41, 3, cp210x_format, 0, 0); // data format 8N1
  819. println("CP210x setup, 0x41, 3, cp210x_format ",cp210x_format, HEX);
  820. queue_Control_Transfer(device, &setup, NULL, this);
  821. control_queued = true;
  822. return;
  823. }
  824. // set baud rate
  825. if (pending_control & 2) {
  826. pending_control &= ~2;
  827. setupdata[0] = (baudrate) & 0xff; // Setup baud rate 115200 - 0x1C200
  828. setupdata[1] = (baudrate >> 8) & 0xff;
  829. setupdata[2] = (baudrate >> 16) & 0xff;
  830. setupdata[3] = (baudrate >> 24) & 0xff;
  831. mk_setup(setup, 0x40, 0x1e, 0, 0, 4);
  832. println("CP210x Set Baud 0x40, 0x1e");
  833. queue_Control_Transfer(device, &setup, setupdata, this);
  834. control_queued = true;
  835. return;
  836. }
  837. // Appears to be an enable command
  838. if (pending_control & 4) {
  839. pending_control &= ~4;
  840. memset(setupdata, 0, sizeof(setupdata)); // clear out the data
  841. println("CP210x 0x41, 0, 1");
  842. mk_setup(setup, 0x41, 0, 1, 0, 0);
  843. queue_Control_Transfer(device, &setup, NULL, this);
  844. control_queued = true;
  845. return;
  846. }
  847. // MHS_REQUEST
  848. if (pending_control & 8) {
  849. pending_control &= ~0x88;
  850. mk_setup(setup, 0x41, 7, 0x0303, 0, 0);
  851. queue_Control_Transfer(device, &setup, NULL, this);
  852. control_queued = true;
  853. println("CP210x 0x41, 7, 0x0303");
  854. return;
  855. }
  856. }
  857. }
  858. #define CH341_BAUDBASE_FACTOR 1532620800
  859. #define CH341_BAUDBASE_DIVMAX 3
  860. void USBSerialBase::ch341_setBaud(uint8_t byte_index) {
  861. if (byte_index == 0) {
  862. uint32_t factor;
  863. uint16_t divisor;
  864. factor = (CH341_BAUDBASE_FACTOR / baudrate);
  865. divisor = CH341_BAUDBASE_DIVMAX;
  866. while ((factor > 0xfff0) && divisor) {
  867. factor >>= 3;
  868. divisor--;
  869. }
  870. factor = 0x10000 - factor;
  871. factor = (factor & 0xff00) | divisor;
  872. setupdata[0] = factor & 0xff; // save away the low byte for 2nd message
  873. println("CH341: 40, 0x9a, 0x1312... (Baud word 0):", factor, HEX);
  874. mk_setup(setup, 0x40, 0x9a, 0x1312, factor, 0); //
  875. } else {
  876. // Second packet use the byte we saved away during the calculation above
  877. println("CH341: 40, 0x9a, 0x0f2c... (Baud word 1):", setupdata[0], HEX);
  878. mk_setup(setup, 0x40, 0x9a, 0x0f2c, setupdata[0], 0); //
  879. }
  880. queue_Control_Transfer(device, &setup, setupdata, this);
  881. control_queued = true;
  882. }
  883. /************************************************************/
  884. // Interrupt-based Data Movement
  885. /************************************************************/
  886. void USBSerialBase::rx_callback(const Transfer_t *transfer)
  887. {
  888. if (!transfer->driver) return;
  889. ((USBSerial *)(transfer->driver))->rx_data(transfer);
  890. }
  891. void USBSerialBase::tx_callback(const Transfer_t *transfer)
  892. {
  893. if (!transfer->driver) return;
  894. ((USBSerial *)(transfer->driver))->tx_data(transfer);
  895. }
  896. void USBSerialBase::rx_data(const Transfer_t *transfer)
  897. {
  898. uint32_t len = transfer->length - ((transfer->qtd.token >> 16) & 0x7FFF);
  899. debugDigitalToggle(6);
  900. // first update rxstate bitmask, since buffer is no longer queued
  901. if (transfer->buffer == rx1) {
  902. rxstate &= 0xFE;
  903. } else if (transfer->buffer == rx2) {
  904. rxstate &= 0xFD;
  905. }
  906. // get start of data and actual length
  907. const uint8_t *p = (const uint8_t *)transfer->buffer;
  908. if (sertype == FTDI) {
  909. if (len >= 2) {
  910. p += 2;
  911. len -= 2;
  912. } else {
  913. len = 0;
  914. }
  915. }
  916. if (len > 0) {
  917. print("rx token: ", transfer->qtd.token, HEX);
  918. print(" transfer length: ", transfer->length, DEC);
  919. print(" len:", len, DEC);
  920. print(" - ", *p, HEX);
  921. println(" ", *(p+1), HEX);
  922. print("rx: ");
  923. print_hexbytes(p, len);
  924. }
  925. // Copy data from packet buffer to circular buffer.
  926. // Assume the buffer will always have space, since we
  927. // check before queuing the buffers
  928. uint32_t head = rxhead;
  929. uint32_t tail = rxtail;
  930. if (++head >= rxsize) head = 0;
  931. uint32_t avail;
  932. if (len > 0) {
  933. //print("head=", head);
  934. //print(", tail=", tail);
  935. avail = rxsize - head;
  936. //print(", avail=", avail);
  937. //println(", rxsize=", rxsize);
  938. if (avail > len) avail = len;
  939. memcpy(rxbuf + head, p, avail);
  940. if (len <= avail) {
  941. head += avail - 1;
  942. if (head >= rxsize) head = 0;
  943. } else {
  944. head = len - avail - 1;
  945. memcpy(rxbuf, p + avail, head + 1);
  946. }
  947. rxhead = head;
  948. }
  949. // TODO: can be this more efficient? We know from above which
  950. // buffer is no longer queued, so possible skip most of this work?
  951. rx_queue_packets(head, tail);
  952. }
  953. // re-queue packet buffer(s) if possible
  954. void USBSerialBase::rx_queue_packets(uint32_t head, uint32_t tail)
  955. {
  956. uint32_t avail;
  957. if (head >= tail) {
  958. avail = rxsize - 1 - head + tail;
  959. } else {
  960. avail = tail - head - 1;
  961. }
  962. uint32_t packetsize = rx2 - rx1;
  963. if (avail >= packetsize) {
  964. if ((rxstate & 0x01) == 0) {
  965. queue_Data_Transfer(rxpipe, rx1, packetsize, this);
  966. rxstate |= 0x01;
  967. } else if ((rxstate & 0x02) == 0) {
  968. queue_Data_Transfer(rxpipe, rx2, packetsize, this);
  969. rxstate |= 0x02;
  970. }
  971. if ((rxstate & 0x03) != 0x03 && avail >= packetsize * 2) {
  972. if ((rxstate & 0x01) == 0) {
  973. queue_Data_Transfer(rxpipe, rx1, packetsize, this);
  974. rxstate |= 0x01;
  975. } else if ((rxstate & 0x02) == 0) {
  976. queue_Data_Transfer(rxpipe, rx2, packetsize, this);
  977. rxstate |= 0x02;
  978. }
  979. }
  980. }
  981. }
  982. void USBSerialBase::tx_data(const Transfer_t *transfer)
  983. {
  984. uint32_t mask;
  985. uint8_t *p = (uint8_t *)transfer->buffer;
  986. debugDigitalWrite(5, HIGH);
  987. if (p == tx1) {
  988. println("tx1:");
  989. mask = 1;
  990. //txstate &= 0xFE;
  991. } else if (p == tx2) {
  992. println("tx2:");
  993. mask = 2;
  994. //txstate &= 0xFD;
  995. } else {
  996. debugDigitalWrite(5, LOW);
  997. return; // should never happen
  998. }
  999. // check how much more data remains in the transmit buffer
  1000. uint32_t head = txhead;
  1001. uint32_t tail = txtail;
  1002. uint32_t count;
  1003. if (head >= tail) {
  1004. count = head - tail;
  1005. } else {
  1006. count = txsize + head - tail;
  1007. }
  1008. uint32_t packetsize = tx2 - tx1;
  1009. // Only output full packets unless the flush bit was set.
  1010. if ((count == 0) || ((count < packetsize) && ((txstate & 0x4) == 0) )) {
  1011. // not enough data in buffer to fill a full packet
  1012. txstate &= ~(mask | 4); // turn off that transfer and make sure the flush bit is not set
  1013. debugDigitalWrite(5, LOW);
  1014. return;
  1015. }
  1016. // immediately transmit another full packet, if we have enough data
  1017. if (count >= packetsize) count = packetsize;
  1018. else txstate &= ~(mask | 4); // This packet will complete any outstanding flush
  1019. println("TX:moar data!!!!");
  1020. if (++tail >= txsize) tail = 0;
  1021. uint32_t n = txsize - tail;
  1022. if (n > count) n = count;
  1023. memcpy(p, txbuf + tail, n);
  1024. if (n >= count) {
  1025. tail += n - 1;
  1026. if (tail >= txsize) tail = 0;
  1027. } else {
  1028. uint32_t len = count - n;
  1029. memcpy(p + n, txbuf, len);
  1030. tail = len - 1;
  1031. }
  1032. txtail = tail;
  1033. queue_Data_Transfer(txpipe, p, count, this);
  1034. debugDigitalWrite(5, LOW);
  1035. }
  1036. void USBSerialBase::flush()
  1037. {
  1038. print("USBSerialBase::flush");
  1039. if (txhead == txtail) {
  1040. println(" - Empty");
  1041. return; // empty.
  1042. }
  1043. debugDigitalWrite(32, HIGH);
  1044. NVIC_DISABLE_IRQ(IRQ_USBHS);
  1045. txtimer.stop(); // Stop longer timer.
  1046. txtimer.start(100); // Start a mimimal timeout
  1047. // timer_event(nullptr); // Try calling direct - fails to work
  1048. NVIC_ENABLE_IRQ(IRQ_USBHS);
  1049. while (txstate & 3) ; // wait for all of the USB packets to be sent.
  1050. println(" completed");
  1051. debugDigitalWrite(32, LOW);
  1052. }
  1053. void USBSerialBase::timer_event(USBDriverTimer *whichTimer)
  1054. {
  1055. debugDigitalWrite(7, HIGH);
  1056. println("txtimer");
  1057. uint32_t count;
  1058. uint32_t head = txhead;
  1059. uint32_t tail = txtail;
  1060. if (head == tail) {
  1061. println(" *** Empty ***");
  1062. debugDigitalWrite(7, LOW);
  1063. return; // nothing to transmit
  1064. } else if (head > tail) {
  1065. count = head - tail;
  1066. } else {
  1067. count = txsize + head - tail;
  1068. }
  1069. uint8_t *p;
  1070. if ((txstate & 0x01) == 0) {
  1071. p = tx1;
  1072. txstate |= 0x01;
  1073. } else if ((txstate & 0x02) == 0) {
  1074. p = tx2;
  1075. txstate |= 0x02;
  1076. } else {
  1077. txstate |= 4; // Tell the TX code to do flush code.
  1078. println(" *** No buffers ***");
  1079. debugDigitalWrite(7, LOW);
  1080. return; // no outgoing buffers available, try again later
  1081. }
  1082. uint32_t packetsize = tx2 - tx1;
  1083. // Possible for remaining ? packet size and not have both?
  1084. if (count > packetsize) {
  1085. txstate |= 4; // One of the active transfers will handle the remaining parts
  1086. count = packetsize;
  1087. }
  1088. if (++tail >= txsize) tail = 0;
  1089. uint32_t n = txsize - tail;
  1090. if (n > count) n = count;
  1091. memcpy(p, txbuf + tail, n);
  1092. if (n >= count) {
  1093. tail += n - 1;
  1094. if (tail >= txsize) tail = 0;
  1095. } else {
  1096. uint32_t len = count - n;
  1097. memcpy(p + n, txbuf, len);
  1098. tail = len - 1;
  1099. }
  1100. txtail = tail;
  1101. print(" TX data (", count);
  1102. print(") ");
  1103. print_hexbytes(p, count);
  1104. queue_Data_Transfer(txpipe, p, count, this);
  1105. debugDigitalWrite(7, LOW);
  1106. }
  1107. /************************************************************/
  1108. // User Functions - must disable USBHQ IRQ for EHCI access
  1109. /************************************************************/
  1110. void USBSerialBase::begin(uint32_t baud, uint32_t format)
  1111. {
  1112. NVIC_DISABLE_IRQ(IRQ_USBHS);
  1113. baudrate = baud;
  1114. bool format_changed = format != format_;
  1115. format_ = format;
  1116. switch (sertype) {
  1117. default:
  1118. case CDCACM: pending_control |= 0x6; break;
  1119. case FTDI: pending_control |= (format_changed? 0xf : 0xe); break; // Set BAUD, FLOW, DTR
  1120. case PL2303: pending_control |= 0x1e; break; // set more stuff...
  1121. case CH341: pending_control |= 0x1e; break;
  1122. case CP210X: pending_control |= 0xf; break;
  1123. }
  1124. if (!control_queued) control(NULL);
  1125. NVIC_ENABLE_IRQ(IRQ_USBHS);
  1126. // Wait until all packets have been queued before we return to caller.
  1127. while (pending_control) {
  1128. yield(); // not sure if we want to yield or what?
  1129. }
  1130. }
  1131. void USBSerialBase::end(void)
  1132. {
  1133. NVIC_DISABLE_IRQ(IRQ_USBHS);
  1134. switch (sertype) {
  1135. default:
  1136. case CDCACM: pending_control |= 0x80; break;
  1137. case FTDI: pending_control |= 0x80; break; // clear DTR
  1138. case PL2303: pending_control |= 0x80; break;
  1139. case CH341: pending_control |= 0x80; break;
  1140. }
  1141. if (!control_queued) control(NULL);
  1142. NVIC_ENABLE_IRQ(IRQ_USBHS);
  1143. // Wait until all packets have been queued before we return to caller.
  1144. while (pending_control) {
  1145. yield(); // not sure if we want to yield or what?
  1146. }
  1147. }
  1148. int USBSerialBase::available(void)
  1149. {
  1150. if (!device) return 0;
  1151. uint32_t head = rxhead;
  1152. uint32_t tail = rxtail;
  1153. if (head >= tail) return head - tail;
  1154. return rxsize + head - tail;
  1155. }
  1156. int USBSerialBase::peek(void)
  1157. {
  1158. if (!device) return -1;
  1159. if (rxhead == rxtail) return -1;
  1160. return rxbuf[rxtail];
  1161. }
  1162. int USBSerialBase::read(void)
  1163. {
  1164. if (!device) return -1;
  1165. if (rxhead == rxtail) return -1;
  1166. int c = rxbuf[rxtail];
  1167. if (++rxtail >= rxsize) rxtail = 0;
  1168. if ((rxstate & 0x03) != 0x03) {
  1169. NVIC_DISABLE_IRQ(IRQ_USBHS);
  1170. rx_queue_packets(rxhead, rxtail);
  1171. NVIC_ENABLE_IRQ(IRQ_USBHS);
  1172. }
  1173. return c;
  1174. }
  1175. int USBSerialBase::availableForWrite()
  1176. {
  1177. if (!device) return 0;
  1178. uint32_t head = txhead;
  1179. uint32_t tail = txtail;
  1180. if (head >= tail) return txsize - 1 - head + tail;
  1181. return tail - head - 1;
  1182. }
  1183. size_t USBSerialBase::write(uint8_t c)
  1184. {
  1185. if (!device) return 0;
  1186. uint32_t head = txhead;
  1187. if (++head >= txsize) head = 0;
  1188. while (txtail == head) {
  1189. // wait...
  1190. }
  1191. txbuf[head] = c;
  1192. txhead = head;
  1193. //print("head=", head);
  1194. //println(", tail=", txtail);
  1195. // if full packet in buffer and tx packet ready, queue it
  1196. NVIC_DISABLE_IRQ(IRQ_USBHS);
  1197. uint32_t tail = txtail;
  1198. if ((txstate & 0x03) != 0x03) {
  1199. // at least one packet buffer is ready to transmit
  1200. uint32_t count;
  1201. if (head >= tail) {
  1202. count = head - tail;
  1203. } else {
  1204. count = txsize + head - tail;
  1205. }
  1206. uint32_t packetsize = tx2 - tx1;
  1207. if (count >= packetsize) {
  1208. //println("txsize=", txsize);
  1209. uint8_t *p;
  1210. if ((txstate & 0x01) == 0) {
  1211. p = tx1;
  1212. txstate |= 0x01;
  1213. } else /* if ((txstate & 0x02) == 0) */ {
  1214. p = tx2;
  1215. txstate |= 0x02;
  1216. }
  1217. // copy data to packet buffer
  1218. if (++tail >= txsize) tail = 0;
  1219. uint32_t n = txsize - tail;
  1220. if (n > packetsize) n = packetsize;
  1221. //print("memcpy, offset=", tail);
  1222. //println(", len=", n);
  1223. memcpy(p, txbuf + tail, n);
  1224. if (n >= packetsize) {
  1225. tail += n - 1;
  1226. if (tail >= txsize) tail = 0;
  1227. } else {
  1228. //n = txsize - n;
  1229. uint32_t len = packetsize - n;
  1230. //println("memcpy, offset=0, len=", len);
  1231. memcpy(p + n, txbuf, len);
  1232. tail = len - 1;
  1233. }
  1234. txtail = tail;
  1235. //println("queue tx packet, newtail=", tail);
  1236. debugDigitalWrite(7, HIGH);
  1237. queue_Data_Transfer(txpipe, p, packetsize, this);
  1238. debugDigitalWrite(7, LOW);
  1239. NVIC_ENABLE_IRQ(IRQ_USBHS);
  1240. return 1;
  1241. }
  1242. }
  1243. // otherwise, set a latency timer to later transmit partial packet
  1244. txtimer.stop();
  1245. txtimer.start(write_timeout_);
  1246. NVIC_ENABLE_IRQ(IRQ_USBHS);
  1247. return 1;
  1248. }