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drv_sdio.c

drv_sdio.c 17 KB
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  1. /*
    2. 

  2.  * File      : drv_sdio.c
    3. 

  3.  * Copyright (c) 2006-2021, RT-Thread Development Team
    4. 

  4.  *
    5. 

  5.  * SPDX-License-Identifier: Apache-2.0
    6. 

  6.  *
    7. 

  7.  * Change Logs:
    8. 

  8.  * Date           Author         Notes
    9. 

  9.  * 2019-07-29     zdzn           first version
    10. 

  10.  */
    11. 

  11. 

  12. #include "drv_sdio.h"
    13. 

  13. #include "raspi.h"
    14. 

  14. 

  15. static rt_uint32_t sdCommandTable[] = {
    16. 

  16.     SD_CMD_INDEX(0),
    17. 

  17.     SD_CMD_RESERVED(1),
    18. 

  18.     SD_CMD_INDEX(2) | SD_RESP_R2,
    19. 

  19.     SD_CMD_INDEX(3) | SD_RESP_R1,
    20. 

  20.     SD_CMD_INDEX(4),
    21. 

  21.     SD_CMD_RESERVED(5), //SD_CMD_INDEX(5) | SD_RESP_R4,
    22. 

  22.     SD_CMD_INDEX(6) | SD_RESP_R1,
    23. 

  23.     SD_CMD_INDEX(7) | SD_RESP_R1b,
    24. 

  24.     SD_CMD_INDEX(8) | SD_RESP_R1,
    25. 

  25.     SD_CMD_INDEX(9) | SD_RESP_R2,
    26. 

  26.     SD_CMD_INDEX(10) | SD_RESP_R2,
    27. 

  27.     SD_CMD_INDEX(11) | SD_RESP_R1,
    28. 

  28.     SD_CMD_INDEX(12) | SD_RESP_R1b | SD_CMD_TYPE_ABORT,
    29. 

  29.     SD_CMD_INDEX(13) | SD_RESP_R1,
    30. 

  30.     SD_CMD_RESERVED(14),
    31. 

  31.     SD_CMD_INDEX(15),
    32. 

  32.     SD_CMD_INDEX(16) | SD_RESP_R1,
    33. 

  33.     SD_CMD_INDEX(17) | SD_RESP_R1 | SD_DATA_READ,
    34. 

  34.     SD_CMD_INDEX(18) | SD_RESP_R1 | SD_DATA_READ | SD_CMD_MULTI_BLOCK | SD_CMD_BLKCNT_EN,
    35. 

  35.     SD_CMD_INDEX(19) | SD_RESP_R1 | SD_DATA_READ,
    36. 

  36.     SD_CMD_INDEX(20) | SD_RESP_R1b,
    37. 

  37.     SD_CMD_RESERVED(21),
    38. 

  38.     SD_CMD_RESERVED(22),
    39. 

  39.     SD_CMD_INDEX(23) | SD_RESP_R1,
    40. 

  40.     SD_CMD_INDEX(24) | SD_RESP_R1 | SD_DATA_WRITE,
    41. 

  41.     SD_CMD_INDEX(25) | SD_RESP_R1 | SD_DATA_WRITE | SD_CMD_MULTI_BLOCK | SD_CMD_BLKCNT_EN,
    42. 

  42.     SD_CMD_INDEX(26) | SD_RESP_R1 | SD_DATA_WRITE, //add
    43. 

  43.     SD_CMD_INDEX(27) | SD_RESP_R1 | SD_DATA_WRITE,
    44. 

  44.     SD_CMD_INDEX(28) | SD_RESP_R1b,
    45. 

  45.     SD_CMD_INDEX(29) | SD_RESP_R1b,
    46. 

  46.     SD_CMD_INDEX(30) | SD_RESP_R1 | SD_DATA_READ,
    47. 

  47.     SD_CMD_RESERVED(31),
    48. 

  48.     SD_CMD_INDEX(32) | SD_RESP_R1,
    49. 

  49.     SD_CMD_INDEX(33) | SD_RESP_R1,
    50. 

  50.     SD_CMD_RESERVED(34),
    51. 

  51.     SD_CMD_INDEX(35) | SD_RESP_R1, //add
    52. 

  52.     SD_CMD_INDEX(36) | SD_RESP_R1, //add
    53. 

  53.     SD_CMD_RESERVED(37),
    54. 

  54.     SD_CMD_INDEX(38) | SD_RESP_R1b,
    55. 

  55.     SD_CMD_INDEX(39) | SD_RESP_R4, //add
    56. 

  56.     SD_CMD_INDEX(40) | SD_RESP_R5, //add
    57. 

  57.     SD_CMD_INDEX(41) | SD_RESP_R3, //add, mov from harbote
    58. 

  58.     SD_CMD_RESERVED(42) | SD_RESP_R1,
    59. 

  59.     SD_CMD_RESERVED(43),
    60. 

  60.     SD_CMD_RESERVED(44),
    61. 

  61.     SD_CMD_RESERVED(45),
    62. 

  62.     SD_CMD_RESERVED(46),
    63. 

  63.     SD_CMD_RESERVED(47),
    64. 

  64.     SD_CMD_RESERVED(48),
    65. 

  65.     SD_CMD_RESERVED(49),
    66. 

  66.     SD_CMD_RESERVED(50),
    67. 

  67.     SD_CMD_INDEX(51) | SD_RESP_R1 | SD_DATA_READ,
    68. 

  68.     SD_CMD_RESERVED(52),
    69. 

  69.     SD_CMD_RESERVED(53),
    70. 

  70.     SD_CMD_RESERVED(54),
    71. 

  71.     SD_CMD_INDEX(55) | SD_RESP_R3,
    72. 

  72.     SD_CMD_INDEX(56) | SD_RESP_R1 | SD_CMD_ISDATA,
    73. 

  73.     SD_CMD_RESERVED(57),
    74. 

  74.     SD_CMD_RESERVED(58),
    75. 

  75.     SD_CMD_RESERVED(59),
    76. 

  76.     SD_CMD_RESERVED(60),
    77. 

  77.     SD_CMD_RESERVED(61),
    78. 

  78.     SD_CMD_RESERVED(62),
    79. 

  79.     SD_CMD_RESERVED(63)
    80. 

  80. };
    81. 

  81. 

  82. static inline rt_uint32_t read32(rt_uint32_t addr)
    83. 

  83. {
    84. 

  84.     return (*((volatile unsigned int*)((rt_uint64_t)addr)));
    85. 

  85.     //return (*((volatile rt_uint64_t *)(((long))addr)));
    86. 

  86. }
    87. 

  87. 

  88. static inline void write32(rt_uint32_t addr, rt_uint32_t value)
    89. 

  89. {
    90. 

  90.     (*((volatile unsigned int*)((rt_uint64_t)addr))) = value;
    91. 

  91.     //*((volatile rt_uint64_t *)(((long))addr)) = value;
    92. 

  92. }
    93. 

  93. 

  94. rt_err_t sd_int(struct sdhci_pdata_t * pdat, unsigned int mask)
    95. 

  95. {
    96. 

  96.     unsigned int r;
    97. 

  97.     unsigned int m = mask | INT_ERROR_MASK;
    98. 

  98.     int cnt = 1000000;
    99. 

  99.     while (!(read32(pdat->virt + EMMC_INTERRUPT) & (m | INT_ERROR_MASK)) && cnt--)
    100. 

  100.         DELAY_MICROS(1);
    101. 

  101.     r = read32(pdat->virt + EMMC_INTERRUPT);
    102. 

  102.     if (cnt <= 0 || (r & INT_CMD_TIMEOUT) || (r & INT_DATA_TIMEOUT))
    103. 

  103.     {
    104. 

  104.         write32(pdat->virt + EMMC_INTERRUPT, r);
    105. 

  105.         //qemu maybe can not use sdcard
    106. 

  106.         //rt_kprintf("send cmd/data timeout wait for %x int: %x, status: %x\n",mask, r, read32(pdat->virt + EMMC_STATUS));
    107. 

  107.         //return -RT_ETIMEOUT;
    108. 

  108.     }
    109. 

  109.     else if (r & INT_ERROR_MASK)
    110. 

  110.     {
    111. 

  111.         write32(pdat->virt + EMMC_INTERRUPT, r);
    112. 

  112.         rt_kprintf("send cmd/data error %x -> %x\n",r, read32(pdat->virt + EMMC_INTERRUPT));
    113. 

  113.         return -RT_ERROR;
    114. 

  114.     }
    115. 

  115.     write32(pdat->virt + EMMC_INTERRUPT, mask);
    116. 

  116.     return RT_EOK;
    117. 

  117. }
    118. 

  118. 

  119. rt_err_t sd_status(struct sdhci_pdata_t * pdat, unsigned int mask)
    120. 

  120. {
    121. 

  121.     int cnt = 500000;
    122. 

  122.     while ((read32(pdat->virt + EMMC_STATUS) & mask) && !(read32(pdat->virt + EMMC_INTERRUPT) & INT_ERROR_MASK) && cnt--)
    123. 

  123.         DELAY_MICROS(1);
    124. 

  124.     if (cnt <= 0)
    125. 

  125.     {
    126. 

  126.         return -RT_ETIMEOUT;
    127. 

  127.     }
    128. 

  128.     else if (read32(pdat->virt + EMMC_INTERRUPT) & INT_ERROR_MASK)
    129. 

  129.     {
    130. 

  130.         return  -RT_ERROR;
    131. 

  131.     }
    132. 

  132. 

  133.     return RT_EOK;
    134. 

  134. }
    135. 

  135. 

  136. static rt_err_t raspi_transfer_command(struct sdhci_pdata_t * pdat, struct sdhci_cmd_t * cmd)
    137. 

  137. {
    138. 

  138.     rt_uint32_t cmdidx;
    139. 

  139.     rt_err_t ret = RT_EOK;
    140. 

  140.     ret = sd_status(pdat, SR_CMD_INHIBIT);
    141. 

  141.     if (ret)
    142. 

  142.     {
    143. 

  143.         rt_kprintf("ERROR: EMMC busy %d\n", ret);
    144. 

  144.         return ret;
    145. 

  145.     }
    146. 

  146. 

  147.     cmdidx = sdCommandTable[cmd->cmdidx];
    148. 

  148.     if (cmdidx == 0xFFFFFFFF)
    149. 

  149.         return -RT_EINVAL;
    150. 

  150.     if (cmd->datarw == DATA_READ)
    151. 

  151.         cmdidx |= SD_DATA_READ;
    152. 

  152.     if (cmd->datarw == DATA_WRITE)
    153. 

  153.         cmdidx |= SD_DATA_WRITE;
    154. 

  154.     mmcsd_dbg("transfer cmd %x(%d) %x %x\n", cmdidx, cmd->cmdidx, cmd->cmdarg, read32(pdat->virt + EMMC_INTERRUPT));
    155. 

  155.     write32(pdat->virt + EMMC_INTERRUPT,read32(pdat->virt + EMMC_INTERRUPT));
    156. 

  156.     write32(pdat->virt + EMMC_ARG1, cmd->cmdarg);
    157. 

  157.     write32(pdat->virt + EMMC_CMDTM, cmdidx);
    158. 

  158.     if (cmd->cmdidx == SD_APP_OP_COND)
    159. 

  159.         DELAY_MICROS(1000);
    160. 

  160.     else if ((cmd->cmdidx == SD_SEND_IF_COND) || (cmd->cmdidx == APP_CMD))
    161. 

  161.         DELAY_MICROS(100);
    162. 

  162.     ret = sd_int(pdat, INT_CMD_DONE);
    163. 

  163.     if (ret)
    164. 

  164.     {
    165. 

  165.         return ret;
    166. 

  166.     }
    167. 

  167.     if (cmd->resptype & RESP_MASK)
    168. 

  168.     {
    169. 

  169. 

  170.         if (cmd->resptype & RESP_R2)
    171. 

  171.         {
    172. 

  172.             rt_uint32_t resp[4];
    173. 

  173.             resp[0] = read32(pdat->virt + EMMC_RESP0);
    174. 

  174.             resp[1] = read32(pdat->virt + EMMC_RESP1);
    175. 

  175.             resp[2] = read32(pdat->virt + EMMC_RESP2);
    176. 

  176.             resp[3] = read32(pdat->virt + EMMC_RESP3);
    177. 

  177.             if (cmd->resptype == RESP_R2)
    178. 

  178.             {
    179. 

  179.                 cmd->response[0] = resp[3]<<8 |((resp[2]>>24)&0xff);
    180. 

  180.                 cmd->response[1] = resp[2]<<8 |((resp[1]>>24)&0xff);
    181. 

  181.                 cmd->response[2] = resp[1]<<8 |((resp[0]>>24)&0xff);
    182. 

  182.                 cmd->response[3] = resp[0]<<8 ;
    183. 

  183.             }
    184. 

  184.             else
    185. 

  185.             {
    186. 

  186.                 cmd->response[0] = resp[0];
    187. 

  187.                 cmd->response[1] = resp[1];
    188. 

  188.                 cmd->response[2] = resp[2];
    189. 

  189.                 cmd->response[3] = resp[3];
    190. 

  190.             }
    191. 

  191.         }
    192. 

  192.         else
    193. 

  193.             cmd->response[0] = read32(pdat->virt + EMMC_RESP0);
    194. 

  194.     }
    195. 

  195.     mmcsd_dbg("response: %x: %x %x %x %x (%x, %x)\n", cmd->resptype, cmd->response[0], cmd->response[1], cmd->response[2], cmd->response[3], read32(pdat->virt + EMMC_STATUS),read32(pdat->virt + EMMC_INTERRUPT));
    196. 

  196.     return ret;
    197. 

  197. }
    198. 

  198. 

  199. static rt_err_t read_bytes(struct sdhci_pdata_t * pdat, rt_uint32_t * buf, rt_uint32_t blkcount, rt_uint32_t blksize)
    200. 

  200. {
    201. 

  201.     int c = 0;
    202. 

  202.     rt_err_t ret;
    203. 

  203.     int d;
    204. 

  204.     while (c < blkcount)
    205. 

  205.     {
    206. 

  206.         if ((ret = sd_int(pdat, INT_READ_RDY)))
    207. 

  207.         {
    208. 

  208.             rt_kprintf("timeout happens when reading block %d\n",c);
    209. 

  209.             return ret;
    210. 

  210.         }
    211. 

  211.         for (d=0; d < blksize / 4; d++)
    212. 

  212.             if (read32(pdat->virt + EMMC_STATUS) & SR_READ_AVAILABLE)
    213. 

  213.                 buf[d] = read32(pdat->virt + EMMC_DATA);
    214. 

  214.         c++;
    215. 

  215.         buf += blksize / 4;
    216. 

  216.     }
    217. 

  217.     return RT_EOK;
    218. 

  218. }
    219. 

  219. 

  220. static rt_err_t write_bytes(struct sdhci_pdata_t * pdat, rt_uint32_t * buf, rt_uint32_t blkcount, rt_uint32_t blksize)
    221. 

  221. {
    222. 

  222.     int c = 0;
    223. 

  223.     rt_err_t ret;
    224. 

  224.     int d;
    225. 

  225.     while (c < blkcount)
    226. 

  226.     {
    227. 

  227.         if ((ret = sd_int(pdat, INT_WRITE_RDY)))
    228. 

  228.         {
    229. 

  229.             return ret;
    230. 

  230.         }
    231. 

  231.         for (d=0; d < blksize / 4; d++)
    232. 

  232.             write32(pdat->virt + EMMC_DATA, buf[d]);
    233. 

  233.         c++;
    234. 

  234.         buf += blksize / 4;
    235. 

  235.     }
    236. 

  236.     if ((ret = sd_int(pdat, INT_DATA_DONE)))
    237. 

  237.     {
    238. 

  238.         return ret;
    239. 

  239.     }
    240. 

  240.     return RT_EOK;
    241. 

  241. }
    242. 

  242. 

  243. static rt_err_t raspi_transfer_data(struct sdhci_pdata_t * pdat, struct sdhci_cmd_t * cmd, struct sdhci_data_t * dat)
    244. 

  244. {
    245. 

  245.     rt_uint32_t dlen = (rt_uint32_t)(dat->blkcnt * dat->blksz);
    246. 

  246.     rt_err_t ret = sd_status(pdat, SR_DAT_INHIBIT);
    247. 

  247.     if (ret)
    248. 

  248.     {
    249. 

  249.         rt_kprintf("ERROR: EMMC busy\n");
    250. 

  250.         return ret;
    251. 

  251.     }
    252. 

  252.     if (dat->blkcnt > 1)
    253. 

  253.     {
    254. 

  254.         struct sdhci_cmd_t newcmd;
    255. 

  255.         newcmd.cmdidx = SET_BLOCK_COUNT;
    256. 

  256.         newcmd.cmdarg = dat->blkcnt;
    257. 

  257.         newcmd.resptype = RESP_R1;
    258. 

  258.         ret = raspi_transfer_command(pdat, &newcmd);
    259. 

  259.         if (ret) return ret;
    260. 

  260.     }
    261. 

  261. 

  262.     if(dlen < 512)
    263. 

  263.     {
    264. 

  264.         write32(pdat->virt + EMMC_BLKSIZECNT, dlen | 1 << 16);
    265. 

  265.     }
    266. 

  266.     else
    267. 

  267.     {
    268. 

  268.         write32(pdat->virt + EMMC_BLKSIZECNT, 512 | (dat->blkcnt) << 16);
    269. 

  269.     }
    270. 

  270.     if (dat->flag & DATA_DIR_READ)
    271. 

  271.     {
    272. 

  272.         cmd->datarw = DATA_READ;
    273. 

  273.         ret = raspi_transfer_command(pdat, cmd);
    274. 

  274.         if (ret) return ret;
    275. 

  275.         mmcsd_dbg("read_block %d, %d\n", dat->blkcnt, dat->blksz );
    276. 

  276.         ret = read_bytes(pdat, (rt_uint32_t *)dat->buf, dat->blkcnt, dat->blksz);
    277. 

  277.     }
    278. 

  278.     else if (dat->flag & DATA_DIR_WRITE)
    279. 

  279.     {
    280. 

  280.         cmd->datarw = DATA_WRITE;
    281. 

  281.         ret = raspi_transfer_command(pdat, cmd);
    282. 

  282.         if (ret) return ret;
    283. 

  283.         mmcsd_dbg("write_block %d, %d", dat->blkcnt, dat->blksz );
    284. 

  284.         ret = write_bytes(pdat, (rt_uint32_t *)dat->buf, dat->blkcnt, dat->blksz);
    285. 

  285.     }
    286. 

  286.     return ret;
    287. 

  287. }
    288. 

  288. 

  289. static rt_err_t sdhci_transfer(struct sdhci_t * sdhci, struct sdhci_cmd_t * cmd, struct sdhci_data_t * dat)
    290. 

  290. {
    291. 

  291.     struct sdhci_pdata_t * pdat = (struct sdhci_pdata_t *)sdhci->priv;
    292. 

  292.     if (!dat)
    293. 

  293.         return raspi_transfer_command(pdat, cmd);
    294. 

  294. 

  295.     return raspi_transfer_data(pdat, cmd, dat);
    296. 

  296. }
    297. 

  297. 

  298. static void mmc_request_send(struct rt_mmcsd_host *host, struct rt_mmcsd_req *req)
    299. 

  299. {
    300. 

  300.     struct sdhci_t *sdhci = (struct sdhci_t *)host->private_data;
    301. 

  301.     struct sdhci_cmd_t cmd;
    302. 

  302.     struct sdhci_cmd_t stop;
    303. 

  303.     struct sdhci_data_t dat;
    304. 

  304.     rt_memset(&cmd, 0, sizeof(struct sdhci_cmd_t));
    305. 

  305.     rt_memset(&stop, 0, sizeof(struct sdhci_cmd_t));
    306. 

  306.     rt_memset(&dat, 0, sizeof(struct sdhci_data_t));
    307. 

  307. 

  308.     cmd.cmdidx = req->cmd->cmd_code;
    309. 

  309.     cmd.cmdarg = req->cmd->arg;
    310. 

  310.     cmd.resptype =resp_type(req->cmd);
    311. 

  311.     if (req->data)
    312. 

  312.     {
    313. 

  313.         dat.buf = (rt_uint8_t *)req->data->buf;
    314. 

  314.         dat.flag = req->data->flags;
    315. 

  315.         dat.blksz = req->data->blksize;
    316. 

  316.         dat.blkcnt = req->data->blks;
    317. 

  317. 

  318.         req->cmd->err = sdhci_transfer(sdhci, &cmd, &dat);
    319. 

  319.     }
    320. 

  320.     else
    321. 

  321.     {
    322. 

  322.         req->cmd->err = sdhci_transfer(sdhci, &cmd, RT_NULL);
    323. 

  323.     }
    324. 

  324. 

  325.     req->cmd->resp[3] = cmd.response[3];
    326. 

  326.     req->cmd->resp[2] = cmd.response[2];
    327. 

  327.     req->cmd->resp[1] = cmd.response[1];
    328. 

  328.     req->cmd->resp[0] = cmd.response[0];
    329. 

  329. 

  330.     if (req->stop)
    331. 

  331.     {
    332. 

  332.         stop.cmdidx = req->stop->cmd_code;
    333. 

  333.         stop.cmdarg = req->stop->arg;
    334. 

  334.         cmd.resptype =resp_type(req->stop);
    335. 

  335.         req->stop->err = sdhci_transfer(sdhci, &stop, RT_NULL);
    336. 

  336.     }
    337. 

  337. 

  338.     mmcsd_req_complete(host);
    339. 

  339. }
    340. 

  340. 

  341. rt_int32_t mmc_card_status(struct rt_mmcsd_host *host)
    342. 

  342. {
    343. 

  343.     return 0;
    344. 

  344. }
    345. 

  345. 

  346. void mmc_enable_irq(struct rt_mmcsd_host *host, rt_int32_t en)
    347. 

  347. {
    348. 

  348. 

  349. }
    350. 

  350. 

  351. static rt_err_t sdhci_detect(struct sdhci_t * sdhci)
    352. 

  352. {
    353. 

  353.     return RT_EOK;
    354. 

  354. }
    355. 

  355. 

  356. static rt_err_t sdhci_setwidth(struct sdhci_t * sdhci, rt_uint32_t width)
    357. 

  357. {
    358. 

  358.     rt_uint32_t temp = 0;
    359. 

  359.     struct sdhci_pdata_t * pdat = (struct sdhci_pdata_t *)sdhci->priv;
    360. 

  360.     if (width == MMCSD_BUS_WIDTH_4)
    361. 

  361.     {
    362. 

  362.         temp = read32((pdat->virt + EMMC_CONTROL0));
    363. 

  363.         temp |= C0_HCTL_HS_EN;
    364. 

  364.         temp |= C0_HCTL_DWITDH;   // always use 4 data lines:
    365. 

  365.         write32((pdat->virt + EMMC_CONTROL0), temp);
    366. 

  366.     }
    367. 

  367.     return RT_EOK;
    368. 

  368. }
    369. 

  369. 

  370. static rt_uint32_t sdhci_getdivider(rt_uint32_t sdHostVer, rt_uint32_t freq)
    371. 

  371. {
    372. 

  372.     rt_uint32_t divisor;
    373. 

  373.     rt_uint32_t closest = 41666666 / freq;
    374. 

  374.     rt_uint32_t shiftcount = __rt_fls(closest - 1);
    375. 

  375. 

  376. 

  377.     if (shiftcount > 0) shiftcount--;
    378. 

  378.     if (shiftcount > 7) shiftcount = 7;
    379. 

  379.     if (sdHostVer > HOST_SPEC_V2)
    380. 

  380.         divisor = closest;
    381. 

  381.     else
    382. 

  382.         divisor = (1 << shiftcount);
    383. 

  383. 

  384.     if (divisor <= 2)
    385. 

  385.     {
    386. 

  386.         divisor = 2;
    387. 

  387.         shiftcount = 0;
    388. 

  388.     }
    389. 

  389. 

  390.     rt_uint32_t hi = 0;
    391. 

  391.     if (sdHostVer > HOST_SPEC_V2)
    392. 

  392.         hi = (divisor & 0x300) >> 2;
    393. 

  393.     rt_uint32_t lo = (divisor & 0x0ff);
    394. 

  394.     rt_uint32_t cdiv = (lo << 8) + hi;
    395. 

  395.     return cdiv;
    396. 

  396. }
    397. 

  397. 

  398. static rt_err_t sdhci_setclock(struct sdhci_t * sdhci, rt_uint32_t clock)
    399. 

  399. {
    400. 

  400.     rt_uint32_t temp = 0;
    401. 

  401.     rt_uint32_t sdHostVer = 0;
    402. 

  402.     int count = 100000;
    403. 

  403.     struct sdhci_pdata_t * pdat = (struct sdhci_pdata_t *)(sdhci->priv);
    404. 

  404. 

  405.     while ((read32(pdat->virt + EMMC_STATUS) & (SR_CMD_INHIBIT | SR_DAT_INHIBIT)) && (--count))
    406. 

  406.         DELAY_MICROS(1);
    407. 

  407.     if (count <= 0)
    408. 

  408.     {
    409. 

  409.         rt_kprintf("EMMC: Set clock: timeout waiting for inhibit flags. Status %08x.\n",read32(pdat->virt + EMMC_STATUS));
    410. 

  410.         return -RT_ERROR;
    411. 

  411.     }
    412. 

  412. 

  413.     // Switch clock off.
    414. 

  414.     temp = read32((pdat->virt + EMMC_CONTROL1));
    415. 

  415.     temp &= ~C1_CLK_EN;
    416. 

  416.     write32((pdat->virt + EMMC_CONTROL1),temp);
    417. 

  417.     DELAY_MICROS(10);
    418. 

  418.     // Request the new clock setting and enable the clock
    419. 

  419.     temp = read32(pdat->virt + EMMC_SLOTISR_VER);
    420. 

  420.     sdHostVer = (temp & HOST_SPEC_NUM) >> HOST_SPEC_NUM_SHIFT;
    421. 

  421.     int cdiv = sdhci_getdivider(sdHostVer, clock);
    422. 

  422.     temp = read32((pdat->virt + EMMC_CONTROL1));
    423. 

  423.     temp = (temp & 0xffff003f) | cdiv;
    424. 

  424.     write32((pdat->virt + EMMC_CONTROL1),temp);
    425. 

  425.     DELAY_MICROS(10);
    426. 

  426. 

  427.     // Enable the clock.
    428. 

  428.     temp = read32(pdat->virt + EMMC_CONTROL1);
    429. 

  429.     temp |= C1_CLK_EN;
    430. 

  430.     write32((pdat->virt + EMMC_CONTROL1),temp);
    431. 

  431.     DELAY_MICROS(10);
    432. 

  432.     // Wait for clock to be stable.
    433. 

  433.     count = 10000;
    434. 

  434.     while (!(read32(pdat->virt + EMMC_CONTROL1) & C1_CLK_STABLE) && count--)
    435. 

  435.         DELAY_MICROS(10);
    436. 

  436.     if (count <= 0)
    437. 

  437.     {
    438. 

  438.         rt_kprintf("EMMC: ERROR: failed to get stable clock %d.\n", clock);
    439. 

  439.         return -RT_ERROR;
    440. 

  440.     }
    441. 

  441.     mmcsd_dbg("set stable clock %d.\n", clock);
    442. 

  442.     return RT_EOK;
    443. 

  443. }
    444. 

  444. 

  445. static void mmc_set_iocfg(struct rt_mmcsd_host *host, struct rt_mmcsd_io_cfg *io_cfg)
    446. 

  446. {
    447. 

  447.     struct sdhci_t * sdhci = (struct sdhci_t *)host->private_data;
    448. 

  448.     sdhci_setclock(sdhci, io_cfg->clock);
    449. 

  449.     sdhci_setwidth(sdhci, io_cfg->bus_width);
    450. 

  450. }
    451. 

  451. 

  452. static const struct rt_mmcsd_host_ops ops =
    453. 

  453. {
    454. 

  454.     mmc_request_send,
    455. 

  455.     mmc_set_iocfg,
    456. 

  456.     RT_NULL,
    457. 

  457.     RT_NULL,
    458. 

  458. };
    459. 

  459. 

  460. static void sdmmc_gpio_init()
    461. 

  461. {
    462. 

  462. //    int pin;
    463. 

  463. //    bcm283x_gpio_fsel(47,BCM283X_GPIO_FSEL_INPT);
    464. 

  464. //    bcm283x_gpio_set_pud(47, BCM283X_GPIO_PUD_UP);
    465. 

  465. //    bcm283x_peri_set_bits(BCM283X_GPIO_BASE + BCM283X_GPIO_GPHEN1, 1<<15, 1<<15);
    466. 

  466. //    for (pin = 53; pin >= 48; pin--)
    467. 

  467. //    {
    468. 

  468. //        bcm283x_gpio_fsel(pin, BCM283X_GPIO_FSEL_ALT3);
    469. 

  469. //        bcm283x_gpio_set_pud(pin, BCM283X_GPIO_PUD_UP);
    470. 

  470. //    }
    471. 

  471. }
    472. 

  472. 

  473. static rt_err_t reset_emmc(struct sdhci_pdata_t * pdat){
    474. 

  474.     rt_uint32_t temp;
    475. 

  475.     int cnt;
    476. 

  476.     write32((pdat->virt + EMMC_CONTROL0),0);
    477. 

  477.     temp = read32((pdat->virt + EMMC_CONTROL1));
    478. 

  478.     temp |= C1_SRST_HC;
    479. 

  479.     write32((pdat->virt + EMMC_CONTROL1),temp);
    480. 

  480.     cnt = 10000;
    481. 

  481.     do
    482. 

  482.     {
    483. 

  483.         DELAY_MICROS(10);
    484. 

  484.     }
    485. 

  485.     while ((read32((pdat->virt + EMMC_CONTROL1)) & C1_SRST_HC) && cnt--);
    486. 

  486.     if (cnt <= 0)
    487. 

  487.     {
    488. 

  488.         rt_kprintf("ERROR: failed to reset EMMC\n");
    489. 

  489.         return -RT_ERROR;
    490. 

  490.     }
    491. 

  491.     temp = read32((pdat->virt + EMMC_CONTROL1));
    492. 

  492.     temp |= C1_CLK_INTLEN | C1_TOUNIT_MAX;
    493. 

  493.     write32((pdat->virt + EMMC_CONTROL1),temp);
    494. 

  494.     DELAY_MICROS(10);
    495. 

  495.     return RT_EOK;
    496. 

  496. }
    497. 

  497. 

  498. #ifdef RT_MMCSD_DBG
    499. 

  499. void dump_registers(struct sdhci_pdata_t * pdat){
    500. 

  500.     rt_kprintf("EMMC registers:");
    501. 

  501.     int i = EMMC_ARG2;
    502. 

  502.     for (; i <= EMMC_CONTROL2; i += 4)
    503. 

  503.         rt_kprintf("\t%x:%x\n", i, read32(pdat->virt + i));
    504. 

  504.     rt_kprintf("\t%x:%x\n", 0x50, read32(pdat->virt + 0x50));
    505. 

  505.     rt_kprintf("\t%x:%x\n", 0x70, read32(pdat->virt + 0x70));
    506. 

  506.     rt_kprintf("\t%x:%x\n", 0x74, read32(pdat->virt + 0x74));
    507. 

  507.     rt_kprintf("\t%x:%x\n", 0x80, read32(pdat->virt + 0x80));
    508. 

  508.     rt_kprintf("\t%x:%x\n", 0x84, read32(pdat->virt + 0x84));
    509. 

  509.     rt_kprintf("\t%x:%x\n", 0x88, read32(pdat->virt + 0x88));
    510. 

  510.     rt_kprintf("\t%x:%x\n", 0x8c, read32(pdat->virt + 0x8c));
    511. 

  511.     rt_kprintf("\t%x:%x\n", 0x90, read32(pdat->virt + 0x90));
    512. 

  512.     rt_kprintf("\t%x:%x\n", 0xf0, read32(pdat->virt + 0xf0));
    513. 

  513.     rt_kprintf("\t%x:%x\n", 0xfc, read32(pdat->virt + 0xfc));
    514. 

  514. }
    515. 

  515. #endif
    516. 

  516. 

  517. int raspi_sdmmc_init(void)
    518. 

  518. {
    519. 

  519.     rt_uint32_t virt;
    520. 

  520.     struct rt_mmcsd_host * host = RT_NULL;
    521. 

  521.     struct sdhci_pdata_t * pdat = RT_NULL;
    522. 

  522.     struct sdhci_t * sdhci = RT_NULL;
    523. 

  523. #ifdef BSP_USING_SDIO0
    524. 

  524.     host = mmcsd_alloc_host();
    525. 

  525.     if (!host)
    526. 

  526.     {
    527. 

  527.         rt_kprintf("alloc host failed");
    528. 

  528.         goto err;
    529. 

  529.     }
    530. 

  530. 

  531.     sdhci = rt_malloc(sizeof(struct sdhci_t));
    532. 

  532.     if (!sdhci)
    533. 

  533.     {
    534. 

  534.         rt_kprintf("alloc sdhci failed");
    535. 

  535.         goto err;
    536. 

  536.     }
    537. 

  537.     rt_memset(sdhci, 0, sizeof(struct sdhci_t));
    538. 

  538. 

  539.     sdmmc_gpio_init();
    540. 

  540.     virt = MMC0_BASE_ADDR;
    541. 

  541. 

  542.     pdat = (struct sdhci_pdata_t *)rt_malloc(sizeof(struct sdhci_pdata_t));
    543. 

  543.     RT_ASSERT(pdat != RT_NULL);
    544. 

  544. 

  545.     pdat->virt = (rt_uint32_t)virt;
    546. 

  546.     reset_emmc(pdat);
    547. 

  547. 

  548.     sdhci->name = "sd0";
    549. 

  549.     sdhci->voltages = VDD_33_34;
    550. 

  550.     sdhci->width = MMCSD_BUSWIDTH_4;
    551. 

  551.     sdhci->clock = 200 * 1000 * 1000;
    552. 

  552.     sdhci->removeable = RT_TRUE;
    553. 

  553. 

  554.     sdhci->detect = sdhci_detect;
    555. 

  555.     sdhci->setwidth = sdhci_setwidth;
    556. 

  556.     sdhci->setclock = sdhci_setclock;
    557. 

  557.     sdhci->transfer = sdhci_transfer;
    558. 

  558.     sdhci->priv = pdat;
    559. 

  559. 

  560.     host->ops = &ops;
    561. 

  561.     host->freq_min = 400000;
    562. 

  562.     host->freq_max = 50000000;
    563. 

  563.     host->valid_ocr = VDD_32_33 | VDD_33_34;
    564. 

  564.     host->flags = MMCSD_MUTBLKWRITE | MMCSD_SUP_HIGHSPEED | MMCSD_SUP_SDIO_IRQ | MMCSD_BUSWIDTH_4;
    565. 

  565.     host->max_seg_size = 2048;
    566. 

  566.     host->max_dma_segs = 10;
    567. 

  567.     host->max_blk_size = 512;
    568. 

  568.     host->max_blk_count = 4096;
    569. 

  569. 

  570.     host->private_data = sdhci;
    571. 

  571. 

  572.     write32((pdat->virt + EMMC_IRPT_EN),0xffffffff);
    573. 

  573.     write32((pdat->virt + EMMC_IRPT_MASK),0xffffffff);
    574. 

  574. #ifdef RT_MMCSD_DBG
    575. 

  575.     dump_registers(pdat);
    576. 

  576. #endif
    577. 

  577.     mmcsd_change(host);
    578. 

  578. #endif
    579. 

  579.     return RT_EOK;
    580. 

  580. 

  581. err:
    582. 

  582.     if (host)  rt_free(host);
    583. 

  583.     if (sdhci) rt_free(sdhci);
    584. 

  584. 

  585.     return -RT_EIO;
    586. 

  586. }
    587. 

  587. 

  588. INIT_DEVICE_EXPORT(raspi_sdmmc_init);
    589.