mtk-sd.c 98 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /*
  3. * Copyright (c) 2014-2015, 2022 MediaTek Inc.
  4. * Author: Chaotian.Jing <chaotian.jing@mediatek.com>
  5. */
  6. #include <linux/module.h>
  7. #include <linux/bitfield.h>
  8. #include <linux/bitops.h>
  9. #include <linux/clk.h>
  10. #include <linux/delay.h>
  11. #include <linux/dma-mapping.h>
  12. #include <linux/iopoll.h>
  13. #include <linux/ioport.h>
  14. #include <linux/irq.h>
  15. #include <linux/of.h>
  16. #include <linux/pinctrl/consumer.h>
  17. #include <linux/platform_device.h>
  18. #include <linux/pm.h>
  19. #include <linux/pm_runtime.h>
  20. #include <linux/pm_wakeirq.h>
  21. #include <linux/regulator/consumer.h>
  22. #include <linux/slab.h>
  23. #include <linux/spinlock.h>
  24. #include <linux/interrupt.h>
  25. #include <linux/reset.h>
  26. #include <linux/mmc/card.h>
  27. #include <linux/mmc/core.h>
  28. #include <linux/mmc/host.h>
  29. #include <linux/mmc/mmc.h>
  30. #include <linux/mmc/sd.h>
  31. #include <linux/mmc/sdio.h>
  32. #include <linux/mmc/slot-gpio.h>
  33. #include "cqhci.h"
  34. #include "mmc_hsq.h"
  35. #define MAX_BD_NUM 1024
  36. #define MSDC_NR_CLOCKS 3
  37. /*--------------------------------------------------------------------------*/
  38. /* Common Definition */
  39. /*--------------------------------------------------------------------------*/
  40. #define MSDC_BUS_1BITS 0x0
  41. #define MSDC_BUS_4BITS 0x1
  42. #define MSDC_BUS_8BITS 0x2
  43. #define MSDC_BURST_64B 0x6
  44. /*--------------------------------------------------------------------------*/
  45. /* Register Offset */
  46. /*--------------------------------------------------------------------------*/
  47. #define MSDC_CFG 0x0
  48. #define MSDC_IOCON 0x04
  49. #define MSDC_PS 0x08
  50. #define MSDC_INT 0x0c
  51. #define MSDC_INTEN 0x10
  52. #define MSDC_FIFOCS 0x14
  53. #define SDC_CFG 0x30
  54. #define SDC_CMD 0x34
  55. #define SDC_ARG 0x38
  56. #define SDC_STS 0x3c
  57. #define SDC_RESP0 0x40
  58. #define SDC_RESP1 0x44
  59. #define SDC_RESP2 0x48
  60. #define SDC_RESP3 0x4c
  61. #define SDC_BLK_NUM 0x50
  62. #define SDC_ADV_CFG0 0x64
  63. #define MSDC_NEW_RX_CFG 0x68
  64. #define EMMC_IOCON 0x7c
  65. #define SDC_ACMD_RESP 0x80
  66. #define DMA_SA_H4BIT 0x8c
  67. #define MSDC_DMA_SA 0x90
  68. #define MSDC_DMA_CTRL 0x98
  69. #define MSDC_DMA_CFG 0x9c
  70. #define MSDC_PATCH_BIT 0xb0
  71. #define MSDC_PATCH_BIT1 0xb4
  72. #define MSDC_PATCH_BIT2 0xb8
  73. #define MSDC_PAD_TUNE 0xec
  74. #define MSDC_PAD_TUNE0 0xf0
  75. #define PAD_DS_TUNE 0x188
  76. #define PAD_CMD_TUNE 0x18c
  77. #define EMMC51_CFG0 0x204
  78. #define EMMC50_CFG0 0x208
  79. #define EMMC50_CFG1 0x20c
  80. #define EMMC50_CFG2 0x21c
  81. #define EMMC50_CFG3 0x220
  82. #define SDC_FIFO_CFG 0x228
  83. #define CQHCI_SETTING 0x7fc
  84. /*--------------------------------------------------------------------------*/
  85. /* Top Pad Register Offset */
  86. /*--------------------------------------------------------------------------*/
  87. #define EMMC_TOP_CONTROL 0x00
  88. #define EMMC_TOP_CMD 0x04
  89. #define EMMC50_PAD_DS_TUNE 0x0c
  90. #define LOOP_TEST_CONTROL 0x30
  91. /*--------------------------------------------------------------------------*/
  92. /* Register Mask */
  93. /*--------------------------------------------------------------------------*/
  94. /* MSDC_CFG mask */
  95. #define MSDC_CFG_MODE BIT(0) /* RW */
  96. #define MSDC_CFG_CKPDN BIT(1) /* RW */
  97. #define MSDC_CFG_RST BIT(2) /* RW */
  98. #define MSDC_CFG_PIO BIT(3) /* RW */
  99. #define MSDC_CFG_CKDRVEN BIT(4) /* RW */
  100. #define MSDC_CFG_BV18SDT BIT(5) /* RW */
  101. #define MSDC_CFG_BV18PSS BIT(6) /* R */
  102. #define MSDC_CFG_CKSTB BIT(7) /* R */
  103. #define MSDC_CFG_CKDIV GENMASK(15, 8) /* RW */
  104. #define MSDC_CFG_CKMOD GENMASK(17, 16) /* RW */
  105. #define MSDC_CFG_HS400_CK_MODE BIT(18) /* RW */
  106. #define MSDC_CFG_HS400_CK_MODE_EXTRA BIT(22) /* RW */
  107. #define MSDC_CFG_CKDIV_EXTRA GENMASK(19, 8) /* RW */
  108. #define MSDC_CFG_CKMOD_EXTRA GENMASK(21, 20) /* RW */
  109. /* MSDC_IOCON mask */
  110. #define MSDC_IOCON_SDR104CKS BIT(0) /* RW */
  111. #define MSDC_IOCON_RSPL BIT(1) /* RW */
  112. #define MSDC_IOCON_DSPL BIT(2) /* RW */
  113. #define MSDC_IOCON_DDLSEL BIT(3) /* RW */
  114. #define MSDC_IOCON_DDR50CKD BIT(4) /* RW */
  115. #define MSDC_IOCON_DSPLSEL BIT(5) /* RW */
  116. #define MSDC_IOCON_W_DSPL BIT(8) /* RW */
  117. #define MSDC_IOCON_D0SPL BIT(16) /* RW */
  118. #define MSDC_IOCON_D1SPL BIT(17) /* RW */
  119. #define MSDC_IOCON_D2SPL BIT(18) /* RW */
  120. #define MSDC_IOCON_D3SPL BIT(19) /* RW */
  121. #define MSDC_IOCON_D4SPL BIT(20) /* RW */
  122. #define MSDC_IOCON_D5SPL BIT(21) /* RW */
  123. #define MSDC_IOCON_D6SPL BIT(22) /* RW */
  124. #define MSDC_IOCON_D7SPL BIT(23) /* RW */
  125. #define MSDC_IOCON_RISCSZ GENMASK(25, 24) /* RW */
  126. /* MSDC_PS mask */
  127. #define MSDC_PS_CDEN BIT(0) /* RW */
  128. #define MSDC_PS_CDSTS BIT(1) /* R */
  129. #define MSDC_PS_CDDEBOUNCE GENMASK(15, 12) /* RW */
  130. #define MSDC_PS_DAT GENMASK(23, 16) /* R */
  131. #define MSDC_PS_DATA1 BIT(17) /* R */
  132. #define MSDC_PS_CMD BIT(24) /* R */
  133. #define MSDC_PS_WP BIT(31) /* R */
  134. /* MSDC_INT mask */
  135. #define MSDC_INT_MMCIRQ BIT(0) /* W1C */
  136. #define MSDC_INT_CDSC BIT(1) /* W1C */
  137. #define MSDC_INT_ACMDRDY BIT(3) /* W1C */
  138. #define MSDC_INT_ACMDTMO BIT(4) /* W1C */
  139. #define MSDC_INT_ACMDCRCERR BIT(5) /* W1C */
  140. #define MSDC_INT_DMAQ_EMPTY BIT(6) /* W1C */
  141. #define MSDC_INT_SDIOIRQ BIT(7) /* W1C */
  142. #define MSDC_INT_CMDRDY BIT(8) /* W1C */
  143. #define MSDC_INT_CMDTMO BIT(9) /* W1C */
  144. #define MSDC_INT_RSPCRCERR BIT(10) /* W1C */
  145. #define MSDC_INT_CSTA BIT(11) /* R */
  146. #define MSDC_INT_XFER_COMPL BIT(12) /* W1C */
  147. #define MSDC_INT_DXFER_DONE BIT(13) /* W1C */
  148. #define MSDC_INT_DATTMO BIT(14) /* W1C */
  149. #define MSDC_INT_DATCRCERR BIT(15) /* W1C */
  150. #define MSDC_INT_ACMD19_DONE BIT(16) /* W1C */
  151. #define MSDC_INT_DMA_BDCSERR BIT(17) /* W1C */
  152. #define MSDC_INT_DMA_GPDCSERR BIT(18) /* W1C */
  153. #define MSDC_INT_DMA_PROTECT BIT(19) /* W1C */
  154. #define MSDC_INT_CMDQ BIT(28) /* W1C */
  155. /* MSDC_INTEN mask */
  156. #define MSDC_INTEN_MMCIRQ BIT(0) /* RW */
  157. #define MSDC_INTEN_CDSC BIT(1) /* RW */
  158. #define MSDC_INTEN_ACMDRDY BIT(3) /* RW */
  159. #define MSDC_INTEN_ACMDTMO BIT(4) /* RW */
  160. #define MSDC_INTEN_ACMDCRCERR BIT(5) /* RW */
  161. #define MSDC_INTEN_DMAQ_EMPTY BIT(6) /* RW */
  162. #define MSDC_INTEN_SDIOIRQ BIT(7) /* RW */
  163. #define MSDC_INTEN_CMDRDY BIT(8) /* RW */
  164. #define MSDC_INTEN_CMDTMO BIT(9) /* RW */
  165. #define MSDC_INTEN_RSPCRCERR BIT(10) /* RW */
  166. #define MSDC_INTEN_CSTA BIT(11) /* RW */
  167. #define MSDC_INTEN_XFER_COMPL BIT(12) /* RW */
  168. #define MSDC_INTEN_DXFER_DONE BIT(13) /* RW */
  169. #define MSDC_INTEN_DATTMO BIT(14) /* RW */
  170. #define MSDC_INTEN_DATCRCERR BIT(15) /* RW */
  171. #define MSDC_INTEN_ACMD19_DONE BIT(16) /* RW */
  172. #define MSDC_INTEN_DMA_BDCSERR BIT(17) /* RW */
  173. #define MSDC_INTEN_DMA_GPDCSERR BIT(18) /* RW */
  174. #define MSDC_INTEN_DMA_PROTECT BIT(19) /* RW */
  175. /* MSDC_FIFOCS mask */
  176. #define MSDC_FIFOCS_RXCNT GENMASK(7, 0) /* R */
  177. #define MSDC_FIFOCS_TXCNT GENMASK(23, 16) /* R */
  178. #define MSDC_FIFOCS_CLR BIT(31) /* RW */
  179. /* SDC_CFG mask */
  180. #define SDC_CFG_SDIOINTWKUP BIT(0) /* RW */
  181. #define SDC_CFG_INSWKUP BIT(1) /* RW */
  182. #define SDC_CFG_WRDTOC GENMASK(14, 2) /* RW */
  183. #define SDC_CFG_BUSWIDTH GENMASK(17, 16) /* RW */
  184. #define SDC_CFG_SDIO BIT(19) /* RW */
  185. #define SDC_CFG_SDIOIDE BIT(20) /* RW */
  186. #define SDC_CFG_INTATGAP BIT(21) /* RW */
  187. #define SDC_CFG_DTOC GENMASK(31, 24) /* RW */
  188. /* SDC_STS mask */
  189. #define SDC_STS_SDCBUSY BIT(0) /* RW */
  190. #define SDC_STS_CMDBUSY BIT(1) /* RW */
  191. #define SDC_STS_SWR_COMPL BIT(31) /* RW */
  192. /* SDC_ADV_CFG0 mask */
  193. #define SDC_DAT1_IRQ_TRIGGER BIT(19) /* RW */
  194. #define SDC_RX_ENHANCE_EN BIT(20) /* RW */
  195. #define SDC_NEW_TX_EN BIT(31) /* RW */
  196. /* MSDC_NEW_RX_CFG mask */
  197. #define MSDC_NEW_RX_PATH_SEL BIT(0) /* RW */
  198. /* DMA_SA_H4BIT mask */
  199. #define DMA_ADDR_HIGH_4BIT GENMASK(3, 0) /* RW */
  200. /* MSDC_DMA_CTRL mask */
  201. #define MSDC_DMA_CTRL_START BIT(0) /* W */
  202. #define MSDC_DMA_CTRL_STOP BIT(1) /* W */
  203. #define MSDC_DMA_CTRL_RESUME BIT(2) /* W */
  204. #define MSDC_DMA_CTRL_MODE BIT(8) /* RW */
  205. #define MSDC_DMA_CTRL_LASTBUF BIT(10) /* RW */
  206. #define MSDC_DMA_CTRL_BRUSTSZ GENMASK(14, 12) /* RW */
  207. /* MSDC_DMA_CFG mask */
  208. #define MSDC_DMA_CFG_STS BIT(0) /* R */
  209. #define MSDC_DMA_CFG_DECSEN BIT(1) /* RW */
  210. #define MSDC_DMA_CFG_AHBHPROT2 BIT(9) /* RW */
  211. #define MSDC_DMA_CFG_ACTIVEEN BIT(13) /* RW */
  212. #define MSDC_DMA_CFG_CS12B16B BIT(16) /* RW */
  213. /* MSDC_PATCH_BIT mask */
  214. #define MSDC_PATCH_BIT_ODDSUPP BIT(1) /* RW */
  215. #define MSDC_PATCH_BIT_DIS_WRMON BIT(2) /* RW */
  216. #define MSDC_PATCH_BIT_RD_DAT_SEL BIT(3) /* RW */
  217. #define MSDC_PATCH_BIT_DESCUP_SEL BIT(6) /* RW */
  218. #define MSDC_INT_DAT_LATCH_CK_SEL GENMASK(9, 7)
  219. #define MSDC_CKGEN_MSDC_DLY_SEL GENMASK(14, 10)
  220. #define MSDC_PATCH_BIT_IODSSEL BIT(16) /* RW */
  221. #define MSDC_PATCH_BIT_IOINTSEL BIT(17) /* RW */
  222. #define MSDC_PATCH_BIT_BUSYDLY GENMASK(21, 18) /* RW */
  223. #define MSDC_PATCH_BIT_WDOD GENMASK(25, 22) /* RW */
  224. #define MSDC_PATCH_BIT_IDRTSEL BIT(26) /* RW */
  225. #define MSDC_PATCH_BIT_CMDFSEL BIT(27) /* RW */
  226. #define MSDC_PATCH_BIT_INTDLSEL BIT(28) /* RW */
  227. #define MSDC_PATCH_BIT_SPCPUSH BIT(29) /* RW */
  228. #define MSDC_PATCH_BIT_DECRCTMO BIT(30) /* RW */
  229. /* MSDC_PATCH_BIT1 mask */
  230. #define MSDC_PB1_WRDAT_CRC_TACNTR GENMASK(2, 0) /* RW */
  231. #define MSDC_PATCH_BIT1_CMDTA GENMASK(5, 3) /* RW */
  232. #define MSDC_PB1_BUSY_CHECK_SEL BIT(7) /* RW */
  233. #define MSDC_PATCH_BIT1_STOP_DLY GENMASK(11, 8) /* RW */
  234. #define MSDC_PB1_DDR_CMD_FIX_SEL BIT(14) /* RW */
  235. #define MSDC_PB1_SINGLE_BURST BIT(16) /* RW */
  236. #define MSDC_PB1_RSVD20 GENMASK(18, 17) /* RW */
  237. #define MSDC_PB1_AUTO_SYNCST_CLR BIT(19) /* RW */
  238. #define MSDC_PB1_MARK_POP_WATER BIT(20) /* RW */
  239. #define MSDC_PB1_LP_DCM_EN BIT(21) /* RW */
  240. #define MSDC_PB1_RSVD3 BIT(22) /* RW */
  241. #define MSDC_PB1_AHB_GDMA_HCLK BIT(23) /* RW */
  242. #define MSDC_PB1_MSDC_CLK_ENFEAT GENMASK(31, 24) /* RW */
  243. /* MSDC_PATCH_BIT2 mask */
  244. #define MSDC_PATCH_BIT2_CFGRESP BIT(15) /* RW */
  245. #define MSDC_PATCH_BIT2_CFGCRCSTS BIT(28) /* RW */
  246. #define MSDC_PB2_SUPPORT_64G BIT(1) /* RW */
  247. #define MSDC_PB2_RESPWAIT GENMASK(3, 2) /* RW */
  248. #define MSDC_PB2_RESPSTSENSEL GENMASK(18, 16) /* RW */
  249. #define MSDC_PB2_POP_EN_CNT GENMASK(23, 20) /* RW */
  250. #define MSDC_PB2_CFGCRCSTSEDGE BIT(25) /* RW */
  251. #define MSDC_PB2_CRCSTSENSEL GENMASK(31, 29) /* RW */
  252. #define MSDC_PAD_TUNE_DATWRDLY GENMASK(4, 0) /* RW */
  253. #define MSDC_PAD_TUNE_DATRRDLY GENMASK(12, 8) /* RW */
  254. #define MSDC_PAD_TUNE_DATRRDLY2 GENMASK(12, 8) /* RW */
  255. #define MSDC_PAD_TUNE_CMDRDLY GENMASK(20, 16) /* RW */
  256. #define MSDC_PAD_TUNE_CMDRDLY2 GENMASK(20, 16) /* RW */
  257. #define MSDC_PAD_TUNE_CMDRRDLY GENMASK(26, 22) /* RW */
  258. #define MSDC_PAD_TUNE_CLKTDLY GENMASK(31, 27) /* RW */
  259. #define MSDC_PAD_TUNE_RXDLYSEL BIT(15) /* RW */
  260. #define MSDC_PAD_TUNE_RD_SEL BIT(13) /* RW */
  261. #define MSDC_PAD_TUNE_CMD_SEL BIT(21) /* RW */
  262. #define MSDC_PAD_TUNE_RD2_SEL BIT(13) /* RW */
  263. #define MSDC_PAD_TUNE_CMD2_SEL BIT(21) /* RW */
  264. #define PAD_DS_TUNE_DLY_SEL BIT(0) /* RW */
  265. #define PAD_DS_TUNE_DLY2_SEL BIT(1) /* RW */
  266. #define PAD_DS_TUNE_DLY1 GENMASK(6, 2) /* RW */
  267. #define PAD_DS_TUNE_DLY2 GENMASK(11, 7) /* RW */
  268. #define PAD_DS_TUNE_DLY3 GENMASK(16, 12) /* RW */
  269. #define PAD_CMD_TUNE_RX_DLY3 GENMASK(5, 1) /* RW */
  270. /* EMMC51_CFG0 mask */
  271. #define CMDQ_RDAT_CNT GENMASK(21, 12) /* RW */
  272. #define EMMC50_CFG_PADCMD_LATCHCK BIT(0) /* RW */
  273. #define EMMC50_CFG_CRCSTS_EDGE BIT(3) /* RW */
  274. #define EMMC50_CFG_CFCSTS_SEL BIT(4) /* RW */
  275. #define EMMC50_CFG_CMD_RESP_SEL BIT(9) /* RW */
  276. /* EMMC50_CFG1 mask */
  277. #define EMMC50_CFG1_DS_CFG BIT(28) /* RW */
  278. /* EMMC50_CFG2 mask */
  279. #define EMMC50_CFG2_AXI_SET_LEN GENMASK(27, 24) /* RW */
  280. #define EMMC50_CFG3_OUTS_WR GENMASK(4, 0) /* RW */
  281. #define SDC_FIFO_CFG_WRVALIDSEL BIT(24) /* RW */
  282. #define SDC_FIFO_CFG_RDVALIDSEL BIT(25) /* RW */
  283. /* CQHCI_SETTING */
  284. #define CQHCI_RD_CMD_WND_SEL BIT(14) /* RW */
  285. #define CQHCI_WR_CMD_WND_SEL BIT(15) /* RW */
  286. /* EMMC_TOP_CONTROL mask */
  287. #define PAD_RXDLY_SEL BIT(0) /* RW */
  288. #define DELAY_EN BIT(1) /* RW */
  289. #define PAD_DAT_RD_RXDLY2 GENMASK(6, 2) /* RW */
  290. #define PAD_DAT_RD_RXDLY GENMASK(11, 7) /* RW */
  291. #define PAD_DAT_RD_RXDLY2_SEL BIT(12) /* RW */
  292. #define PAD_DAT_RD_RXDLY_SEL BIT(13) /* RW */
  293. #define DATA_K_VALUE_SEL BIT(14) /* RW */
  294. #define SDC_RX_ENH_EN BIT(15) /* TW */
  295. /* EMMC_TOP_CMD mask */
  296. #define PAD_CMD_RXDLY2 GENMASK(4, 0) /* RW */
  297. #define PAD_CMD_RXDLY GENMASK(9, 5) /* RW */
  298. #define PAD_CMD_RD_RXDLY2_SEL BIT(10) /* RW */
  299. #define PAD_CMD_RD_RXDLY_SEL BIT(11) /* RW */
  300. #define PAD_CMD_TX_DLY GENMASK(16, 12) /* RW */
  301. /* EMMC50_PAD_DS_TUNE mask */
  302. #define PAD_DS_DLY_SEL BIT(16) /* RW */
  303. #define PAD_DS_DLY2_SEL BIT(15) /* RW */
  304. #define PAD_DS_DLY1 GENMASK(14, 10) /* RW */
  305. #define PAD_DS_DLY3 GENMASK(4, 0) /* RW */
  306. /* LOOP_TEST_CONTROL mask */
  307. #define TEST_LOOP_DSCLK_MUX_SEL BIT(0) /* RW */
  308. #define TEST_LOOP_LATCH_MUX_SEL BIT(1) /* RW */
  309. #define LOOP_EN_SEL_CLK BIT(20) /* RW */
  310. #define TEST_HS400_CMD_LOOP_MUX_SEL BIT(31) /* RW */
  311. #define REQ_CMD_EIO BIT(0)
  312. #define REQ_CMD_TMO BIT(1)
  313. #define REQ_DAT_ERR BIT(2)
  314. #define REQ_STOP_EIO BIT(3)
  315. #define REQ_STOP_TMO BIT(4)
  316. #define REQ_CMD_BUSY BIT(5)
  317. #define MSDC_PREPARE_FLAG BIT(0)
  318. #define MSDC_ASYNC_FLAG BIT(1)
  319. #define MSDC_MMAP_FLAG BIT(2)
  320. #define MTK_MMC_AUTOSUSPEND_DELAY 50
  321. #define CMD_TIMEOUT (HZ/10 * 5) /* 100ms x5 */
  322. #define DAT_TIMEOUT (HZ * 5) /* 1000ms x5 */
  323. #define DEFAULT_DEBOUNCE (8) /* 8 cycles CD debounce */
  324. #define TUNING_REG2_FIXED_OFFEST 4
  325. #define PAD_DELAY_HALF 32 /* PAD delay cells */
  326. #define PAD_DELAY_FULL 64
  327. /*--------------------------------------------------------------------------*/
  328. /* Descriptor Structure */
  329. /*--------------------------------------------------------------------------*/
  330. struct mt_gpdma_desc {
  331. u32 gpd_info;
  332. #define GPDMA_DESC_HWO BIT(0)
  333. #define GPDMA_DESC_BDP BIT(1)
  334. #define GPDMA_DESC_CHECKSUM GENMASK(15, 8)
  335. #define GPDMA_DESC_INT BIT(16)
  336. #define GPDMA_DESC_NEXT_H4 GENMASK(27, 24)
  337. #define GPDMA_DESC_PTR_H4 GENMASK(31, 28)
  338. u32 next;
  339. u32 ptr;
  340. u32 gpd_data_len;
  341. #define GPDMA_DESC_BUFLEN GENMASK(15, 0)
  342. #define GPDMA_DESC_EXTLEN GENMASK(23, 16)
  343. u32 arg;
  344. u32 blknum;
  345. u32 cmd;
  346. };
  347. struct mt_bdma_desc {
  348. u32 bd_info;
  349. #define BDMA_DESC_EOL BIT(0)
  350. #define BDMA_DESC_CHECKSUM GENMASK(15, 8)
  351. #define BDMA_DESC_BLKPAD BIT(17)
  352. #define BDMA_DESC_DWPAD BIT(18)
  353. #define BDMA_DESC_NEXT_H4 GENMASK(27, 24)
  354. #define BDMA_DESC_PTR_H4 GENMASK(31, 28)
  355. u32 next;
  356. u32 ptr;
  357. u32 bd_data_len;
  358. #define BDMA_DESC_BUFLEN GENMASK(15, 0)
  359. #define BDMA_DESC_BUFLEN_EXT GENMASK(23, 0)
  360. };
  361. struct msdc_dma {
  362. struct scatterlist *sg; /* I/O scatter list */
  363. struct mt_gpdma_desc *gpd; /* pointer to gpd array */
  364. struct mt_bdma_desc *bd; /* pointer to bd array */
  365. dma_addr_t gpd_addr; /* the physical address of gpd array */
  366. dma_addr_t bd_addr; /* the physical address of bd array */
  367. };
  368. struct msdc_save_para {
  369. u32 msdc_cfg;
  370. u32 iocon;
  371. u32 sdc_cfg;
  372. u32 pad_tune;
  373. u32 patch_bit0;
  374. u32 patch_bit1;
  375. u32 patch_bit2;
  376. u32 pad_ds_tune;
  377. u32 pad_cmd_tune;
  378. u32 emmc50_cfg0;
  379. u32 emmc50_cfg3;
  380. u32 sdc_fifo_cfg;
  381. u32 emmc_top_control;
  382. u32 emmc_top_cmd;
  383. u32 emmc50_pad_ds_tune;
  384. u32 loop_test_control;
  385. };
  386. struct mtk_mmc_compatible {
  387. u8 clk_div_bits;
  388. bool recheck_sdio_irq;
  389. bool hs400_tune; /* only used for MT8173 */
  390. bool needs_top_base;
  391. u32 pad_tune_reg;
  392. bool async_fifo;
  393. bool data_tune;
  394. bool busy_check;
  395. bool stop_clk_fix;
  396. u8 stop_dly_sel;
  397. u8 pop_en_cnt;
  398. bool enhance_rx;
  399. bool support_64g;
  400. bool use_internal_cd;
  401. bool support_new_tx;
  402. bool support_new_rx;
  403. };
  404. struct msdc_tune_para {
  405. u32 iocon;
  406. u32 pad_tune;
  407. u32 pad_cmd_tune;
  408. u32 emmc_top_control;
  409. u32 emmc_top_cmd;
  410. };
  411. struct msdc_delay_phase {
  412. u8 maxlen;
  413. u8 start;
  414. u8 final_phase;
  415. };
  416. struct msdc_host {
  417. struct device *dev;
  418. const struct mtk_mmc_compatible *dev_comp;
  419. int cmd_rsp;
  420. spinlock_t lock;
  421. struct mmc_request *mrq;
  422. struct mmc_command *cmd;
  423. struct mmc_data *data;
  424. int error;
  425. void __iomem *base; /* host base address */
  426. void __iomem *top_base; /* host top register base address */
  427. struct msdc_dma dma; /* dma channel */
  428. u64 dma_mask;
  429. u32 timeout_ns; /* data timeout ns */
  430. u32 timeout_clks; /* data timeout clks */
  431. struct pinctrl *pinctrl;
  432. struct pinctrl_state *pins_default;
  433. struct pinctrl_state *pins_uhs;
  434. struct pinctrl_state *pins_eint;
  435. struct delayed_work req_timeout;
  436. int irq; /* host interrupt */
  437. int eint_irq; /* interrupt from sdio device for waking up system */
  438. struct reset_control *reset;
  439. struct clk *src_clk; /* msdc source clock */
  440. struct clk *h_clk; /* msdc h_clk */
  441. struct clk *bus_clk; /* bus clock which used to access register */
  442. struct clk *src_clk_cg; /* msdc source clock control gate */
  443. struct clk *sys_clk_cg; /* msdc subsys clock control gate */
  444. struct clk *crypto_clk; /* msdc crypto clock control gate */
  445. struct clk_bulk_data bulk_clks[MSDC_NR_CLOCKS];
  446. u32 mclk; /* mmc subsystem clock frequency */
  447. u32 src_clk_freq; /* source clock frequency */
  448. unsigned char timing;
  449. bool vqmmc_enabled;
  450. u32 latch_ck;
  451. u32 hs400_ds_delay;
  452. u32 hs400_ds_dly3;
  453. u32 hs200_cmd_int_delay; /* cmd internal delay for HS200/SDR104 */
  454. u32 hs400_cmd_int_delay; /* cmd internal delay for HS400 */
  455. u32 tuning_step;
  456. bool hs400_cmd_resp_sel_rising;
  457. /* cmd response sample selection for HS400 */
  458. bool hs400_mode; /* current eMMC will run at hs400 mode */
  459. bool hs400_tuning; /* hs400 mode online tuning */
  460. bool internal_cd; /* Use internal card-detect logic */
  461. bool cqhci; /* support eMMC hw cmdq */
  462. bool hsq_en; /* Host Software Queue is enabled */
  463. struct msdc_save_para save_para; /* used when gate HCLK */
  464. struct msdc_tune_para def_tune_para; /* default tune setting */
  465. struct msdc_tune_para saved_tune_para; /* tune result of CMD21/CMD19 */
  466. struct cqhci_host *cq_host;
  467. u32 cq_ssc1_time;
  468. };
  469. static const struct mtk_mmc_compatible mt2701_compat = {
  470. .clk_div_bits = 12,
  471. .recheck_sdio_irq = true,
  472. .hs400_tune = false,
  473. .pad_tune_reg = MSDC_PAD_TUNE0,
  474. .async_fifo = true,
  475. .data_tune = true,
  476. .busy_check = false,
  477. .stop_clk_fix = false,
  478. .enhance_rx = false,
  479. .support_64g = false,
  480. };
  481. static const struct mtk_mmc_compatible mt2712_compat = {
  482. .clk_div_bits = 12,
  483. .recheck_sdio_irq = false,
  484. .hs400_tune = false,
  485. .pad_tune_reg = MSDC_PAD_TUNE0,
  486. .async_fifo = true,
  487. .data_tune = true,
  488. .busy_check = true,
  489. .stop_clk_fix = true,
  490. .stop_dly_sel = 3,
  491. .enhance_rx = true,
  492. .support_64g = true,
  493. };
  494. static const struct mtk_mmc_compatible mt6779_compat = {
  495. .clk_div_bits = 12,
  496. .recheck_sdio_irq = false,
  497. .hs400_tune = false,
  498. .pad_tune_reg = MSDC_PAD_TUNE0,
  499. .async_fifo = true,
  500. .data_tune = true,
  501. .busy_check = true,
  502. .stop_clk_fix = true,
  503. .stop_dly_sel = 3,
  504. .enhance_rx = true,
  505. .support_64g = true,
  506. };
  507. static const struct mtk_mmc_compatible mt6795_compat = {
  508. .clk_div_bits = 8,
  509. .recheck_sdio_irq = false,
  510. .hs400_tune = true,
  511. .pad_tune_reg = MSDC_PAD_TUNE,
  512. .async_fifo = false,
  513. .data_tune = false,
  514. .busy_check = false,
  515. .stop_clk_fix = false,
  516. .enhance_rx = false,
  517. .support_64g = false,
  518. };
  519. static const struct mtk_mmc_compatible mt7620_compat = {
  520. .clk_div_bits = 8,
  521. .recheck_sdio_irq = true,
  522. .hs400_tune = false,
  523. .pad_tune_reg = MSDC_PAD_TUNE,
  524. .async_fifo = false,
  525. .data_tune = false,
  526. .busy_check = false,
  527. .stop_clk_fix = false,
  528. .enhance_rx = false,
  529. .use_internal_cd = true,
  530. };
  531. static const struct mtk_mmc_compatible mt7622_compat = {
  532. .clk_div_bits = 12,
  533. .recheck_sdio_irq = true,
  534. .hs400_tune = false,
  535. .pad_tune_reg = MSDC_PAD_TUNE0,
  536. .async_fifo = true,
  537. .data_tune = true,
  538. .busy_check = true,
  539. .stop_clk_fix = true,
  540. .stop_dly_sel = 3,
  541. .enhance_rx = true,
  542. .support_64g = false,
  543. };
  544. static const struct mtk_mmc_compatible mt7986_compat = {
  545. .clk_div_bits = 12,
  546. .recheck_sdio_irq = true,
  547. .hs400_tune = false,
  548. .needs_top_base = true,
  549. .pad_tune_reg = MSDC_PAD_TUNE0,
  550. .async_fifo = true,
  551. .data_tune = true,
  552. .busy_check = true,
  553. .stop_clk_fix = true,
  554. .stop_dly_sel = 3,
  555. .enhance_rx = true,
  556. .support_64g = true,
  557. };
  558. static const struct mtk_mmc_compatible mt8135_compat = {
  559. .clk_div_bits = 8,
  560. .recheck_sdio_irq = true,
  561. .hs400_tune = false,
  562. .pad_tune_reg = MSDC_PAD_TUNE,
  563. .async_fifo = false,
  564. .data_tune = false,
  565. .busy_check = false,
  566. .stop_clk_fix = false,
  567. .enhance_rx = false,
  568. .support_64g = false,
  569. };
  570. static const struct mtk_mmc_compatible mt8173_compat = {
  571. .clk_div_bits = 8,
  572. .recheck_sdio_irq = true,
  573. .hs400_tune = true,
  574. .pad_tune_reg = MSDC_PAD_TUNE,
  575. .async_fifo = false,
  576. .data_tune = false,
  577. .busy_check = false,
  578. .stop_clk_fix = false,
  579. .enhance_rx = false,
  580. .support_64g = false,
  581. };
  582. static const struct mtk_mmc_compatible mt8183_compat = {
  583. .clk_div_bits = 12,
  584. .recheck_sdio_irq = false,
  585. .hs400_tune = false,
  586. .needs_top_base = true,
  587. .pad_tune_reg = MSDC_PAD_TUNE0,
  588. .async_fifo = true,
  589. .data_tune = true,
  590. .busy_check = true,
  591. .stop_clk_fix = true,
  592. .stop_dly_sel = 3,
  593. .enhance_rx = true,
  594. .support_64g = true,
  595. };
  596. static const struct mtk_mmc_compatible mt8516_compat = {
  597. .clk_div_bits = 12,
  598. .recheck_sdio_irq = true,
  599. .hs400_tune = false,
  600. .pad_tune_reg = MSDC_PAD_TUNE0,
  601. .async_fifo = true,
  602. .data_tune = true,
  603. .busy_check = true,
  604. .stop_clk_fix = true,
  605. .stop_dly_sel = 3,
  606. };
  607. static const struct mtk_mmc_compatible mt8196_compat = {
  608. .clk_div_bits = 12,
  609. .recheck_sdio_irq = false,
  610. .hs400_tune = false,
  611. .needs_top_base = true,
  612. .pad_tune_reg = MSDC_PAD_TUNE0,
  613. .async_fifo = true,
  614. .data_tune = true,
  615. .busy_check = true,
  616. .stop_clk_fix = true,
  617. .stop_dly_sel = 1,
  618. .pop_en_cnt = 2,
  619. .enhance_rx = true,
  620. .support_64g = true,
  621. .support_new_tx = true,
  622. .support_new_rx = true,
  623. };
  624. static const struct of_device_id msdc_of_ids[] = {
  625. { .compatible = "mediatek,mt2701-mmc", .data = &mt2701_compat},
  626. { .compatible = "mediatek,mt2712-mmc", .data = &mt2712_compat},
  627. { .compatible = "mediatek,mt6779-mmc", .data = &mt6779_compat},
  628. { .compatible = "mediatek,mt6795-mmc", .data = &mt6795_compat},
  629. { .compatible = "mediatek,mt7620-mmc", .data = &mt7620_compat},
  630. { .compatible = "mediatek,mt7622-mmc", .data = &mt7622_compat},
  631. { .compatible = "mediatek,mt7986-mmc", .data = &mt7986_compat},
  632. { .compatible = "mediatek,mt7988-mmc", .data = &mt7986_compat},
  633. { .compatible = "mediatek,mt8135-mmc", .data = &mt8135_compat},
  634. { .compatible = "mediatek,mt8173-mmc", .data = &mt8173_compat},
  635. { .compatible = "mediatek,mt8183-mmc", .data = &mt8183_compat},
  636. { .compatible = "mediatek,mt8196-mmc", .data = &mt8196_compat},
  637. { .compatible = "mediatek,mt8516-mmc", .data = &mt8516_compat},
  638. {}
  639. };
  640. MODULE_DEVICE_TABLE(of, msdc_of_ids);
  641. static void sdr_set_bits(void __iomem *reg, u32 bs)
  642. {
  643. u32 val = readl(reg);
  644. val |= bs;
  645. writel(val, reg);
  646. }
  647. static void sdr_clr_bits(void __iomem *reg, u32 bs)
  648. {
  649. u32 val = readl(reg);
  650. val &= ~bs;
  651. writel(val, reg);
  652. }
  653. static void sdr_set_field(void __iomem *reg, u32 field, u32 val)
  654. {
  655. unsigned int tv = readl(reg);
  656. tv &= ~field;
  657. tv |= ((val) << (ffs((unsigned int)field) - 1));
  658. writel(tv, reg);
  659. }
  660. static void sdr_get_field(void __iomem *reg, u32 field, u32 *val)
  661. {
  662. unsigned int tv = readl(reg);
  663. *val = ((tv & field) >> (ffs((unsigned int)field) - 1));
  664. }
  665. static void msdc_reset_hw(struct msdc_host *host)
  666. {
  667. u32 val;
  668. sdr_set_bits(host->base + MSDC_CFG, MSDC_CFG_RST);
  669. readl_poll_timeout_atomic(host->base + MSDC_CFG, val, !(val & MSDC_CFG_RST), 0, 0);
  670. sdr_set_bits(host->base + MSDC_FIFOCS, MSDC_FIFOCS_CLR);
  671. readl_poll_timeout_atomic(host->base + MSDC_FIFOCS, val,
  672. !(val & MSDC_FIFOCS_CLR), 0, 0);
  673. val = readl(host->base + MSDC_INT);
  674. writel(val, host->base + MSDC_INT);
  675. }
  676. static void msdc_cmd_next(struct msdc_host *host,
  677. struct mmc_request *mrq, struct mmc_command *cmd);
  678. static void __msdc_enable_sdio_irq(struct msdc_host *host, int enb);
  679. static const u32 cmd_ints_mask = MSDC_INTEN_CMDRDY | MSDC_INTEN_RSPCRCERR |
  680. MSDC_INTEN_CMDTMO | MSDC_INTEN_ACMDRDY |
  681. MSDC_INTEN_ACMDCRCERR | MSDC_INTEN_ACMDTMO;
  682. static const u32 data_ints_mask = MSDC_INTEN_XFER_COMPL | MSDC_INTEN_DATTMO |
  683. MSDC_INTEN_DATCRCERR | MSDC_INTEN_DMA_BDCSERR |
  684. MSDC_INTEN_DMA_GPDCSERR | MSDC_INTEN_DMA_PROTECT;
  685. static u8 msdc_dma_calcs(u8 *buf, u32 len)
  686. {
  687. u32 i, sum = 0;
  688. for (i = 0; i < len; i++)
  689. sum += buf[i];
  690. return 0xff - (u8) sum;
  691. }
  692. static inline void msdc_dma_setup(struct msdc_host *host, struct msdc_dma *dma,
  693. struct mmc_data *data)
  694. {
  695. unsigned int j, dma_len;
  696. dma_addr_t dma_address;
  697. u32 dma_ctrl;
  698. struct scatterlist *sg;
  699. struct mt_gpdma_desc *gpd;
  700. struct mt_bdma_desc *bd;
  701. sg = data->sg;
  702. gpd = dma->gpd;
  703. bd = dma->bd;
  704. /* modify gpd */
  705. gpd->gpd_info |= GPDMA_DESC_HWO;
  706. gpd->gpd_info |= GPDMA_DESC_BDP;
  707. /* need to clear first. use these bits to calc checksum */
  708. gpd->gpd_info &= ~GPDMA_DESC_CHECKSUM;
  709. gpd->gpd_info |= msdc_dma_calcs((u8 *) gpd, 16) << 8;
  710. /* modify bd */
  711. for_each_sg(data->sg, sg, data->sg_count, j) {
  712. dma_address = sg_dma_address(sg);
  713. dma_len = sg_dma_len(sg);
  714. /* init bd */
  715. bd[j].bd_info &= ~BDMA_DESC_BLKPAD;
  716. bd[j].bd_info &= ~BDMA_DESC_DWPAD;
  717. bd[j].ptr = lower_32_bits(dma_address);
  718. if (host->dev_comp->support_64g) {
  719. bd[j].bd_info &= ~BDMA_DESC_PTR_H4;
  720. bd[j].bd_info |= (upper_32_bits(dma_address) & 0xf)
  721. << 28;
  722. }
  723. if (host->dev_comp->support_64g) {
  724. bd[j].bd_data_len &= ~BDMA_DESC_BUFLEN_EXT;
  725. bd[j].bd_data_len |= (dma_len & BDMA_DESC_BUFLEN_EXT);
  726. } else {
  727. bd[j].bd_data_len &= ~BDMA_DESC_BUFLEN;
  728. bd[j].bd_data_len |= (dma_len & BDMA_DESC_BUFLEN);
  729. }
  730. if (j == data->sg_count - 1) /* the last bd */
  731. bd[j].bd_info |= BDMA_DESC_EOL;
  732. else
  733. bd[j].bd_info &= ~BDMA_DESC_EOL;
  734. /* checksum need to clear first */
  735. bd[j].bd_info &= ~BDMA_DESC_CHECKSUM;
  736. bd[j].bd_info |= msdc_dma_calcs((u8 *)(&bd[j]), 16) << 8;
  737. }
  738. sdr_set_field(host->base + MSDC_DMA_CFG, MSDC_DMA_CFG_DECSEN, 1);
  739. dma_ctrl = readl_relaxed(host->base + MSDC_DMA_CTRL);
  740. dma_ctrl &= ~(MSDC_DMA_CTRL_BRUSTSZ | MSDC_DMA_CTRL_MODE);
  741. dma_ctrl |= (MSDC_BURST_64B << 12 | BIT(8));
  742. writel_relaxed(dma_ctrl, host->base + MSDC_DMA_CTRL);
  743. if (host->dev_comp->support_64g)
  744. sdr_set_field(host->base + DMA_SA_H4BIT, DMA_ADDR_HIGH_4BIT,
  745. upper_32_bits(dma->gpd_addr) & 0xf);
  746. writel(lower_32_bits(dma->gpd_addr), host->base + MSDC_DMA_SA);
  747. }
  748. static void msdc_prepare_data(struct msdc_host *host, struct mmc_data *data)
  749. {
  750. if (!(data->host_cookie & MSDC_PREPARE_FLAG)) {
  751. data->sg_count = dma_map_sg(host->dev, data->sg, data->sg_len,
  752. mmc_get_dma_dir(data));
  753. if (data->sg_count)
  754. data->host_cookie |= MSDC_PREPARE_FLAG;
  755. }
  756. }
  757. static bool msdc_data_prepared(struct mmc_data *data)
  758. {
  759. return data->host_cookie & MSDC_PREPARE_FLAG;
  760. }
  761. static void msdc_unprepare_data(struct msdc_host *host, struct mmc_data *data)
  762. {
  763. if (data->host_cookie & MSDC_ASYNC_FLAG)
  764. return;
  765. if (data->host_cookie & MSDC_PREPARE_FLAG) {
  766. dma_unmap_sg(host->dev, data->sg, data->sg_len,
  767. mmc_get_dma_dir(data));
  768. data->host_cookie &= ~MSDC_PREPARE_FLAG;
  769. }
  770. }
  771. static u64 msdc_timeout_cal(struct msdc_host *host, u64 ns, u64 clks)
  772. {
  773. struct mmc_host *mmc = mmc_from_priv(host);
  774. u64 timeout;
  775. u32 clk_ns, mode = 0;
  776. if (mmc->actual_clock == 0) {
  777. timeout = 0;
  778. } else {
  779. clk_ns = 1000000000U / mmc->actual_clock;
  780. timeout = ns + clk_ns - 1;
  781. do_div(timeout, clk_ns);
  782. timeout += clks;
  783. /* in 1048576 sclk cycle unit */
  784. timeout = DIV_ROUND_UP(timeout, BIT(20));
  785. if (host->dev_comp->clk_div_bits == 8)
  786. sdr_get_field(host->base + MSDC_CFG,
  787. MSDC_CFG_CKMOD, &mode);
  788. else
  789. sdr_get_field(host->base + MSDC_CFG,
  790. MSDC_CFG_CKMOD_EXTRA, &mode);
  791. /*DDR mode will double the clk cycles for data timeout */
  792. timeout = mode >= 2 ? timeout * 2 : timeout;
  793. timeout = timeout > 1 ? timeout - 1 : 0;
  794. }
  795. return timeout;
  796. }
  797. /* clock control primitives */
  798. static void msdc_set_timeout(struct msdc_host *host, u64 ns, u64 clks)
  799. {
  800. u64 timeout;
  801. host->timeout_ns = ns;
  802. host->timeout_clks = clks;
  803. timeout = msdc_timeout_cal(host, ns, clks);
  804. sdr_set_field(host->base + SDC_CFG, SDC_CFG_DTOC,
  805. min_t(u32, timeout, 255));
  806. }
  807. static void msdc_set_busy_timeout(struct msdc_host *host, u64 ns, u64 clks)
  808. {
  809. u64 timeout;
  810. timeout = msdc_timeout_cal(host, ns, clks);
  811. sdr_set_field(host->base + SDC_CFG, SDC_CFG_WRDTOC,
  812. min_t(u32, timeout, 8191));
  813. }
  814. static void msdc_gate_clock(struct msdc_host *host)
  815. {
  816. clk_bulk_disable_unprepare(MSDC_NR_CLOCKS, host->bulk_clks);
  817. clk_disable_unprepare(host->crypto_clk);
  818. clk_disable_unprepare(host->src_clk_cg);
  819. clk_disable_unprepare(host->src_clk);
  820. clk_disable_unprepare(host->bus_clk);
  821. clk_disable_unprepare(host->h_clk);
  822. }
  823. static int msdc_ungate_clock(struct msdc_host *host)
  824. {
  825. u32 val;
  826. int ret;
  827. clk_prepare_enable(host->h_clk);
  828. clk_prepare_enable(host->bus_clk);
  829. clk_prepare_enable(host->src_clk);
  830. clk_prepare_enable(host->src_clk_cg);
  831. clk_prepare_enable(host->crypto_clk);
  832. ret = clk_bulk_prepare_enable(MSDC_NR_CLOCKS, host->bulk_clks);
  833. if (ret) {
  834. dev_err(host->dev, "Cannot enable pclk/axi/ahb clock gates\n");
  835. return ret;
  836. }
  837. return readl_poll_timeout(host->base + MSDC_CFG, val,
  838. (val & MSDC_CFG_CKSTB), 1, 20000);
  839. }
  840. static void msdc_new_tx_setting(struct msdc_host *host)
  841. {
  842. u32 val;
  843. if (!host->top_base)
  844. return;
  845. val = readl(host->top_base + LOOP_TEST_CONTROL);
  846. val |= TEST_LOOP_DSCLK_MUX_SEL;
  847. val |= TEST_LOOP_LATCH_MUX_SEL;
  848. val &= ~TEST_HS400_CMD_LOOP_MUX_SEL;
  849. switch (host->timing) {
  850. case MMC_TIMING_LEGACY:
  851. case MMC_TIMING_MMC_HS:
  852. case MMC_TIMING_SD_HS:
  853. case MMC_TIMING_UHS_SDR12:
  854. case MMC_TIMING_UHS_SDR25:
  855. case MMC_TIMING_UHS_DDR50:
  856. case MMC_TIMING_MMC_DDR52:
  857. val &= ~LOOP_EN_SEL_CLK;
  858. break;
  859. case MMC_TIMING_UHS_SDR50:
  860. case MMC_TIMING_UHS_SDR104:
  861. case MMC_TIMING_MMC_HS200:
  862. case MMC_TIMING_MMC_HS400:
  863. val |= LOOP_EN_SEL_CLK;
  864. break;
  865. default:
  866. break;
  867. }
  868. writel(val, host->top_base + LOOP_TEST_CONTROL);
  869. }
  870. static void msdc_set_mclk(struct msdc_host *host, unsigned char timing, u32 hz)
  871. {
  872. struct mmc_host *mmc = mmc_from_priv(host);
  873. u32 mode;
  874. u32 flags;
  875. u32 div;
  876. u32 sclk;
  877. u32 tune_reg = host->dev_comp->pad_tune_reg;
  878. u32 val;
  879. bool timing_changed;
  880. if (!hz) {
  881. dev_dbg(host->dev, "set mclk to 0\n");
  882. host->mclk = 0;
  883. mmc->actual_clock = 0;
  884. sdr_clr_bits(host->base + MSDC_CFG, MSDC_CFG_CKPDN);
  885. return;
  886. }
  887. if (host->timing != timing)
  888. timing_changed = true;
  889. else
  890. timing_changed = false;
  891. flags = readl(host->base + MSDC_INTEN);
  892. sdr_clr_bits(host->base + MSDC_INTEN, flags);
  893. if (host->dev_comp->clk_div_bits == 8)
  894. sdr_clr_bits(host->base + MSDC_CFG, MSDC_CFG_HS400_CK_MODE);
  895. else
  896. sdr_clr_bits(host->base + MSDC_CFG,
  897. MSDC_CFG_HS400_CK_MODE_EXTRA);
  898. if (timing == MMC_TIMING_UHS_DDR50 ||
  899. timing == MMC_TIMING_MMC_DDR52 ||
  900. timing == MMC_TIMING_MMC_HS400) {
  901. if (timing == MMC_TIMING_MMC_HS400)
  902. mode = 0x3;
  903. else
  904. mode = 0x2; /* ddr mode and use divisor */
  905. if (hz >= (host->src_clk_freq >> 2)) {
  906. div = 0; /* mean div = 1/4 */
  907. sclk = host->src_clk_freq >> 2; /* sclk = clk / 4 */
  908. } else {
  909. div = (host->src_clk_freq + ((hz << 2) - 1)) / (hz << 2);
  910. sclk = (host->src_clk_freq >> 2) / div;
  911. div = (div >> 1);
  912. }
  913. if (timing == MMC_TIMING_MMC_HS400 &&
  914. hz >= (host->src_clk_freq >> 1)) {
  915. if (host->dev_comp->clk_div_bits == 8)
  916. sdr_set_bits(host->base + MSDC_CFG,
  917. MSDC_CFG_HS400_CK_MODE);
  918. else
  919. sdr_set_bits(host->base + MSDC_CFG,
  920. MSDC_CFG_HS400_CK_MODE_EXTRA);
  921. sclk = host->src_clk_freq >> 1;
  922. div = 0; /* div is ignore when bit18 is set */
  923. }
  924. } else if (hz >= host->src_clk_freq) {
  925. mode = 0x1; /* no divisor */
  926. div = 0;
  927. sclk = host->src_clk_freq;
  928. } else {
  929. mode = 0x0; /* use divisor */
  930. if (hz >= (host->src_clk_freq >> 1)) {
  931. div = 0; /* mean div = 1/2 */
  932. sclk = host->src_clk_freq >> 1; /* sclk = clk / 2 */
  933. } else {
  934. div = (host->src_clk_freq + ((hz << 2) - 1)) / (hz << 2);
  935. sclk = (host->src_clk_freq >> 2) / div;
  936. }
  937. }
  938. sdr_clr_bits(host->base + MSDC_CFG, MSDC_CFG_CKPDN);
  939. clk_disable_unprepare(host->src_clk_cg);
  940. if (host->dev_comp->clk_div_bits == 8)
  941. sdr_set_field(host->base + MSDC_CFG,
  942. MSDC_CFG_CKMOD | MSDC_CFG_CKDIV,
  943. (mode << 8) | div);
  944. else
  945. sdr_set_field(host->base + MSDC_CFG,
  946. MSDC_CFG_CKMOD_EXTRA | MSDC_CFG_CKDIV_EXTRA,
  947. (mode << 12) | div);
  948. clk_prepare_enable(host->src_clk_cg);
  949. readl_poll_timeout(host->base + MSDC_CFG, val, (val & MSDC_CFG_CKSTB), 0, 0);
  950. sdr_set_bits(host->base + MSDC_CFG, MSDC_CFG_CKPDN);
  951. mmc->actual_clock = sclk;
  952. host->mclk = hz;
  953. host->timing = timing;
  954. /* need because clk changed. */
  955. msdc_set_timeout(host, host->timeout_ns, host->timeout_clks);
  956. sdr_set_bits(host->base + MSDC_INTEN, flags);
  957. /*
  958. * mmc_select_hs400() will drop to 50Mhz and High speed mode,
  959. * tune result of hs200/200Mhz is not suitable for 50Mhz
  960. */
  961. if (mmc->actual_clock <= 52000000) {
  962. writel(host->def_tune_para.iocon, host->base + MSDC_IOCON);
  963. if (host->top_base) {
  964. writel(host->def_tune_para.emmc_top_control,
  965. host->top_base + EMMC_TOP_CONTROL);
  966. writel(host->def_tune_para.emmc_top_cmd,
  967. host->top_base + EMMC_TOP_CMD);
  968. } else {
  969. writel(host->def_tune_para.pad_tune,
  970. host->base + tune_reg);
  971. }
  972. } else {
  973. writel(host->saved_tune_para.iocon, host->base + MSDC_IOCON);
  974. writel(host->saved_tune_para.pad_cmd_tune,
  975. host->base + PAD_CMD_TUNE);
  976. if (host->top_base) {
  977. writel(host->saved_tune_para.emmc_top_control,
  978. host->top_base + EMMC_TOP_CONTROL);
  979. writel(host->saved_tune_para.emmc_top_cmd,
  980. host->top_base + EMMC_TOP_CMD);
  981. } else {
  982. writel(host->saved_tune_para.pad_tune,
  983. host->base + tune_reg);
  984. }
  985. }
  986. if (timing == MMC_TIMING_MMC_HS400 &&
  987. host->dev_comp->hs400_tune)
  988. sdr_set_field(host->base + tune_reg,
  989. MSDC_PAD_TUNE_CMDRRDLY,
  990. host->hs400_cmd_int_delay);
  991. if (host->dev_comp->support_new_tx && timing_changed)
  992. msdc_new_tx_setting(host);
  993. dev_dbg(host->dev, "sclk: %d, timing: %d\n", mmc->actual_clock,
  994. timing);
  995. }
  996. static inline u32 msdc_cmd_find_resp(struct msdc_host *host,
  997. struct mmc_command *cmd)
  998. {
  999. u32 resp;
  1000. switch (mmc_resp_type(cmd)) {
  1001. /* Actually, R1, R5, R6, R7 are the same */
  1002. case MMC_RSP_R1:
  1003. resp = 0x1;
  1004. break;
  1005. case MMC_RSP_R1B:
  1006. case MMC_RSP_R1B_NO_CRC:
  1007. resp = 0x7;
  1008. break;
  1009. case MMC_RSP_R2:
  1010. resp = 0x2;
  1011. break;
  1012. case MMC_RSP_R3:
  1013. resp = 0x3;
  1014. break;
  1015. case MMC_RSP_NONE:
  1016. default:
  1017. resp = 0x0;
  1018. break;
  1019. }
  1020. return resp;
  1021. }
  1022. static inline u32 msdc_cmd_prepare_raw_cmd(struct msdc_host *host,
  1023. struct mmc_request *mrq, struct mmc_command *cmd)
  1024. {
  1025. struct mmc_host *mmc = mmc_from_priv(host);
  1026. /* rawcmd :
  1027. * vol_swt << 30 | auto_cmd << 28 | blklen << 16 | go_irq << 15 |
  1028. * stop << 14 | rw << 13 | dtype << 11 | rsptyp << 7 | brk << 6 | opcode
  1029. */
  1030. u32 opcode = cmd->opcode;
  1031. u32 resp = msdc_cmd_find_resp(host, cmd);
  1032. u32 rawcmd = (opcode & 0x3f) | ((resp & 0x7) << 7);
  1033. host->cmd_rsp = resp;
  1034. if ((opcode == SD_IO_RW_DIRECT && cmd->flags == (unsigned int) -1) ||
  1035. opcode == MMC_STOP_TRANSMISSION)
  1036. rawcmd |= BIT(14);
  1037. else if (opcode == SD_SWITCH_VOLTAGE)
  1038. rawcmd |= BIT(30);
  1039. else if (opcode == SD_APP_SEND_SCR ||
  1040. opcode == SD_APP_SEND_NUM_WR_BLKS ||
  1041. (opcode == SD_SWITCH && mmc_cmd_type(cmd) == MMC_CMD_ADTC) ||
  1042. (opcode == SD_APP_SD_STATUS && mmc_cmd_type(cmd) == MMC_CMD_ADTC) ||
  1043. (opcode == MMC_SEND_EXT_CSD && mmc_cmd_type(cmd) == MMC_CMD_ADTC))
  1044. rawcmd |= BIT(11);
  1045. if (cmd->data) {
  1046. struct mmc_data *data = cmd->data;
  1047. if (mmc_op_multi(opcode)) {
  1048. if (mmc_card_mmc(mmc->card) && mrq->sbc &&
  1049. !(mrq->sbc->arg & 0xFFFF0000))
  1050. rawcmd |= BIT(29); /* AutoCMD23 */
  1051. }
  1052. rawcmd |= ((data->blksz & 0xFFF) << 16);
  1053. if (data->flags & MMC_DATA_WRITE)
  1054. rawcmd |= BIT(13);
  1055. if (data->blocks > 1)
  1056. rawcmd |= BIT(12);
  1057. else
  1058. rawcmd |= BIT(11);
  1059. /* Always use dma mode */
  1060. sdr_clr_bits(host->base + MSDC_CFG, MSDC_CFG_PIO);
  1061. if (host->timeout_ns != data->timeout_ns ||
  1062. host->timeout_clks != data->timeout_clks)
  1063. msdc_set_timeout(host, data->timeout_ns,
  1064. data->timeout_clks);
  1065. writel(data->blocks, host->base + SDC_BLK_NUM);
  1066. }
  1067. return rawcmd;
  1068. }
  1069. static void msdc_start_data(struct msdc_host *host, struct mmc_command *cmd,
  1070. struct mmc_data *data)
  1071. {
  1072. bool read;
  1073. WARN_ON(host->data);
  1074. host->data = data;
  1075. read = data->flags & MMC_DATA_READ;
  1076. mod_delayed_work(system_percpu_wq, &host->req_timeout, DAT_TIMEOUT);
  1077. msdc_dma_setup(host, &host->dma, data);
  1078. sdr_set_bits(host->base + MSDC_INTEN, data_ints_mask);
  1079. sdr_set_field(host->base + MSDC_DMA_CTRL, MSDC_DMA_CTRL_START, 1);
  1080. dev_dbg(host->dev, "DMA start\n");
  1081. dev_dbg(host->dev, "%s: cmd=%d DMA data: %d blocks; read=%d\n",
  1082. __func__, cmd->opcode, data->blocks, read);
  1083. }
  1084. static int msdc_auto_cmd_done(struct msdc_host *host, int events,
  1085. struct mmc_command *cmd)
  1086. {
  1087. u32 *rsp = cmd->resp;
  1088. rsp[0] = readl(host->base + SDC_ACMD_RESP);
  1089. if (events & MSDC_INT_ACMDRDY) {
  1090. cmd->error = 0;
  1091. } else {
  1092. msdc_reset_hw(host);
  1093. if (events & MSDC_INT_ACMDCRCERR) {
  1094. cmd->error = -EILSEQ;
  1095. host->error |= REQ_STOP_EIO;
  1096. } else if (events & MSDC_INT_ACMDTMO) {
  1097. cmd->error = -ETIMEDOUT;
  1098. host->error |= REQ_STOP_TMO;
  1099. }
  1100. dev_err(host->dev,
  1101. "%s: AUTO_CMD%d arg=%08X; rsp %08X; cmd_error=%d\n",
  1102. __func__, cmd->opcode, cmd->arg, rsp[0], cmd->error);
  1103. }
  1104. return cmd->error;
  1105. }
  1106. /*
  1107. * msdc_recheck_sdio_irq - recheck whether the SDIO irq is lost
  1108. *
  1109. * Host controller may lost interrupt in some special case.
  1110. * Add SDIO irq recheck mechanism to make sure all interrupts
  1111. * can be processed immediately
  1112. */
  1113. static void msdc_recheck_sdio_irq(struct msdc_host *host)
  1114. {
  1115. struct mmc_host *mmc = mmc_from_priv(host);
  1116. u32 reg_int, reg_inten, reg_ps;
  1117. if (mmc->caps & MMC_CAP_SDIO_IRQ) {
  1118. reg_inten = readl(host->base + MSDC_INTEN);
  1119. if (reg_inten & MSDC_INTEN_SDIOIRQ) {
  1120. reg_int = readl(host->base + MSDC_INT);
  1121. reg_ps = readl(host->base + MSDC_PS);
  1122. if (!(reg_int & MSDC_INT_SDIOIRQ ||
  1123. reg_ps & MSDC_PS_DATA1)) {
  1124. __msdc_enable_sdio_irq(host, 0);
  1125. sdio_signal_irq(mmc);
  1126. }
  1127. }
  1128. }
  1129. }
  1130. static void msdc_track_cmd_data(struct msdc_host *host, struct mmc_command *cmd)
  1131. {
  1132. if (host->error &&
  1133. ((!mmc_op_tuning(cmd->opcode) && !host->hs400_tuning) ||
  1134. cmd->error == -ETIMEDOUT))
  1135. dev_warn(host->dev, "%s: cmd=%d arg=%08X; host->error=0x%08X\n",
  1136. __func__, cmd->opcode, cmd->arg, host->error);
  1137. }
  1138. static void msdc_request_done(struct msdc_host *host, struct mmc_request *mrq)
  1139. {
  1140. struct mmc_host *mmc = mmc_from_priv(host);
  1141. unsigned long flags;
  1142. bool hsq_req_done;
  1143. /*
  1144. * No need check the return value of cancel_delayed_work, as only ONE
  1145. * path will go here!
  1146. */
  1147. cancel_delayed_work(&host->req_timeout);
  1148. /*
  1149. * If the request was handled from Host Software Queue, there's almost
  1150. * nothing to do here, and we also don't need to reset mrq as any race
  1151. * condition would not have any room to happen, since HSQ stores the
  1152. * "scheduled" mrqs in an internal array of mrq slots anyway.
  1153. * However, if the controller experienced an error, we still want to
  1154. * reset it as soon as possible.
  1155. *
  1156. * Note that non-HSQ requests will still be happening at times, even
  1157. * though it is enabled, and that's what is going to reset host->mrq.
  1158. * Also, msdc_unprepare_data() is going to be called by HSQ when needed
  1159. * as HSQ request finalization will eventually call the .post_req()
  1160. * callback of this driver which, in turn, unprepares the data.
  1161. */
  1162. hsq_req_done = host->hsq_en ? mmc_hsq_finalize_request(mmc, mrq) : false;
  1163. if (hsq_req_done) {
  1164. if (host->error)
  1165. msdc_reset_hw(host);
  1166. return;
  1167. }
  1168. spin_lock_irqsave(&host->lock, flags);
  1169. host->mrq = NULL;
  1170. spin_unlock_irqrestore(&host->lock, flags);
  1171. msdc_track_cmd_data(host, mrq->cmd);
  1172. if (mrq->data)
  1173. msdc_unprepare_data(host, mrq->data);
  1174. if (host->error)
  1175. msdc_reset_hw(host);
  1176. mmc_request_done(mmc, mrq);
  1177. if (host->dev_comp->recheck_sdio_irq)
  1178. msdc_recheck_sdio_irq(host);
  1179. }
  1180. /* returns true if command is fully handled; returns false otherwise */
  1181. static bool msdc_cmd_done(struct msdc_host *host, int events,
  1182. struct mmc_request *mrq, struct mmc_command *cmd)
  1183. {
  1184. bool done = false;
  1185. bool sbc_error;
  1186. unsigned long flags;
  1187. u32 *rsp;
  1188. if (mrq->sbc && cmd == mrq->cmd &&
  1189. (events & (MSDC_INT_ACMDRDY | MSDC_INT_ACMDCRCERR
  1190. | MSDC_INT_ACMDTMO)))
  1191. msdc_auto_cmd_done(host, events, mrq->sbc);
  1192. sbc_error = mrq->sbc && mrq->sbc->error;
  1193. if (!sbc_error && !(events & (MSDC_INT_CMDRDY
  1194. | MSDC_INT_RSPCRCERR
  1195. | MSDC_INT_CMDTMO)))
  1196. return done;
  1197. spin_lock_irqsave(&host->lock, flags);
  1198. done = !host->cmd;
  1199. host->cmd = NULL;
  1200. spin_unlock_irqrestore(&host->lock, flags);
  1201. if (done)
  1202. return true;
  1203. rsp = cmd->resp;
  1204. sdr_clr_bits(host->base + MSDC_INTEN, cmd_ints_mask);
  1205. if (cmd->flags & MMC_RSP_PRESENT) {
  1206. if (cmd->flags & MMC_RSP_136) {
  1207. rsp[0] = readl(host->base + SDC_RESP3);
  1208. rsp[1] = readl(host->base + SDC_RESP2);
  1209. rsp[2] = readl(host->base + SDC_RESP1);
  1210. rsp[3] = readl(host->base + SDC_RESP0);
  1211. } else {
  1212. rsp[0] = readl(host->base + SDC_RESP0);
  1213. }
  1214. }
  1215. if (!sbc_error && !(events & MSDC_INT_CMDRDY)) {
  1216. if ((events & MSDC_INT_CMDTMO && !host->hs400_tuning) ||
  1217. (!mmc_op_tuning(cmd->opcode) && !host->hs400_tuning))
  1218. /*
  1219. * should not clear fifo/interrupt as the tune data
  1220. * may have already come when cmd19/cmd21 gets response
  1221. * CRC error.
  1222. */
  1223. msdc_reset_hw(host);
  1224. if (events & MSDC_INT_RSPCRCERR &&
  1225. mmc_resp_type(cmd) != MMC_RSP_R1B_NO_CRC) {
  1226. cmd->error = -EILSEQ;
  1227. host->error |= REQ_CMD_EIO;
  1228. } else if (events & MSDC_INT_CMDTMO) {
  1229. cmd->error = -ETIMEDOUT;
  1230. host->error |= REQ_CMD_TMO;
  1231. }
  1232. }
  1233. if (cmd->error)
  1234. dev_dbg(host->dev,
  1235. "%s: cmd=%d arg=%08X; rsp %08X; cmd_error=%d\n",
  1236. __func__, cmd->opcode, cmd->arg, rsp[0],
  1237. cmd->error);
  1238. msdc_cmd_next(host, mrq, cmd);
  1239. return true;
  1240. }
  1241. /* It is the core layer's responsibility to ensure card status
  1242. * is correct before issue a request. but host design do below
  1243. * checks recommended.
  1244. */
  1245. static inline bool msdc_cmd_is_ready(struct msdc_host *host,
  1246. struct mmc_request *mrq, struct mmc_command *cmd)
  1247. {
  1248. u32 val;
  1249. int ret;
  1250. /* The max busy time we can endure is 20ms */
  1251. ret = readl_poll_timeout_atomic(host->base + SDC_STS, val,
  1252. !(val & SDC_STS_CMDBUSY), 1, 20000);
  1253. if (ret) {
  1254. dev_err(host->dev, "CMD bus busy detected\n");
  1255. host->error |= REQ_CMD_BUSY;
  1256. msdc_cmd_done(host, MSDC_INT_CMDTMO, mrq, cmd);
  1257. return false;
  1258. }
  1259. if (mmc_resp_type(cmd) == MMC_RSP_R1B || cmd->data) {
  1260. /* R1B or with data, should check SDCBUSY */
  1261. ret = readl_poll_timeout_atomic(host->base + SDC_STS, val,
  1262. !(val & SDC_STS_SDCBUSY), 1, 20000);
  1263. if (ret) {
  1264. dev_err(host->dev, "Controller busy detected\n");
  1265. host->error |= REQ_CMD_BUSY;
  1266. msdc_cmd_done(host, MSDC_INT_CMDTMO, mrq, cmd);
  1267. return false;
  1268. }
  1269. }
  1270. return true;
  1271. }
  1272. static void msdc_start_command(struct msdc_host *host,
  1273. struct mmc_request *mrq, struct mmc_command *cmd)
  1274. {
  1275. u32 rawcmd;
  1276. unsigned long flags;
  1277. WARN_ON(host->cmd);
  1278. host->cmd = cmd;
  1279. mod_delayed_work(system_percpu_wq, &host->req_timeout, DAT_TIMEOUT);
  1280. if (!msdc_cmd_is_ready(host, mrq, cmd))
  1281. return;
  1282. if ((readl(host->base + MSDC_FIFOCS) & MSDC_FIFOCS_TXCNT) >> 16 ||
  1283. readl(host->base + MSDC_FIFOCS) & MSDC_FIFOCS_RXCNT) {
  1284. dev_err(host->dev, "TX/RX FIFO non-empty before start of IO. Reset\n");
  1285. msdc_reset_hw(host);
  1286. }
  1287. cmd->error = 0;
  1288. rawcmd = msdc_cmd_prepare_raw_cmd(host, mrq, cmd);
  1289. spin_lock_irqsave(&host->lock, flags);
  1290. sdr_set_bits(host->base + MSDC_INTEN, cmd_ints_mask);
  1291. spin_unlock_irqrestore(&host->lock, flags);
  1292. writel(cmd->arg, host->base + SDC_ARG);
  1293. writel(rawcmd, host->base + SDC_CMD);
  1294. }
  1295. static void msdc_cmd_next(struct msdc_host *host,
  1296. struct mmc_request *mrq, struct mmc_command *cmd)
  1297. {
  1298. if ((cmd->error && !host->hs400_tuning &&
  1299. !(cmd->error == -EILSEQ &&
  1300. mmc_op_tuning(cmd->opcode))) ||
  1301. (mrq->sbc && mrq->sbc->error))
  1302. msdc_request_done(host, mrq);
  1303. else if (cmd == mrq->sbc)
  1304. msdc_start_command(host, mrq, mrq->cmd);
  1305. else if (!cmd->data)
  1306. msdc_request_done(host, mrq);
  1307. else
  1308. msdc_start_data(host, cmd, cmd->data);
  1309. }
  1310. static void msdc_ops_request(struct mmc_host *mmc, struct mmc_request *mrq)
  1311. {
  1312. struct msdc_host *host = mmc_priv(mmc);
  1313. host->error = 0;
  1314. WARN_ON(!host->hsq_en && host->mrq);
  1315. host->mrq = mrq;
  1316. if (mrq->data) {
  1317. msdc_prepare_data(host, mrq->data);
  1318. if (!msdc_data_prepared(mrq->data)) {
  1319. host->mrq = NULL;
  1320. /*
  1321. * Failed to prepare DMA area, fail fast before
  1322. * starting any commands.
  1323. */
  1324. mrq->cmd->error = -ENOSPC;
  1325. mmc_request_done(mmc_from_priv(host), mrq);
  1326. return;
  1327. }
  1328. }
  1329. /* if SBC is required, we have HW option and SW option.
  1330. * if HW option is enabled, and SBC does not have "special" flags,
  1331. * use HW option, otherwise use SW option
  1332. */
  1333. if (mrq->sbc && (!mmc_card_mmc(mmc->card) ||
  1334. (mrq->sbc->arg & 0xFFFF0000)))
  1335. msdc_start_command(host, mrq, mrq->sbc);
  1336. else
  1337. msdc_start_command(host, mrq, mrq->cmd);
  1338. }
  1339. static void msdc_pre_req(struct mmc_host *mmc, struct mmc_request *mrq)
  1340. {
  1341. struct msdc_host *host = mmc_priv(mmc);
  1342. struct mmc_data *data = mrq->data;
  1343. if (!data)
  1344. return;
  1345. msdc_prepare_data(host, data);
  1346. data->host_cookie |= MSDC_ASYNC_FLAG;
  1347. }
  1348. static void msdc_post_req(struct mmc_host *mmc, struct mmc_request *mrq,
  1349. int err)
  1350. {
  1351. struct msdc_host *host = mmc_priv(mmc);
  1352. struct mmc_data *data = mrq->data;
  1353. if (!data)
  1354. return;
  1355. if (data->host_cookie) {
  1356. data->host_cookie &= ~MSDC_ASYNC_FLAG;
  1357. msdc_unprepare_data(host, data);
  1358. }
  1359. }
  1360. static void msdc_data_xfer_next(struct msdc_host *host, struct mmc_request *mrq)
  1361. {
  1362. if (mmc_op_multi(mrq->cmd->opcode) && mrq->stop && !mrq->stop->error &&
  1363. !mrq->sbc)
  1364. msdc_start_command(host, mrq, mrq->stop);
  1365. else
  1366. msdc_request_done(host, mrq);
  1367. }
  1368. static void msdc_data_xfer_done(struct msdc_host *host, u32 events,
  1369. struct mmc_request *mrq, struct mmc_data *data)
  1370. {
  1371. struct mmc_command *stop;
  1372. unsigned long flags;
  1373. bool done;
  1374. unsigned int check_data = events &
  1375. (MSDC_INT_XFER_COMPL | MSDC_INT_DATCRCERR | MSDC_INT_DATTMO
  1376. | MSDC_INT_DMA_BDCSERR | MSDC_INT_DMA_GPDCSERR
  1377. | MSDC_INT_DMA_PROTECT);
  1378. u32 val;
  1379. int ret;
  1380. spin_lock_irqsave(&host->lock, flags);
  1381. done = !host->data;
  1382. if (check_data)
  1383. host->data = NULL;
  1384. spin_unlock_irqrestore(&host->lock, flags);
  1385. if (done)
  1386. return;
  1387. stop = data->stop;
  1388. if (check_data || (stop && stop->error)) {
  1389. dev_dbg(host->dev, "DMA status: 0x%8X\n",
  1390. readl(host->base + MSDC_DMA_CFG));
  1391. sdr_set_field(host->base + MSDC_DMA_CTRL, MSDC_DMA_CTRL_STOP,
  1392. 1);
  1393. ret = readl_poll_timeout_atomic(host->base + MSDC_DMA_CTRL, val,
  1394. !(val & MSDC_DMA_CTRL_STOP), 1, 20000);
  1395. if (ret)
  1396. dev_dbg(host->dev, "DMA stop timed out\n");
  1397. ret = readl_poll_timeout_atomic(host->base + MSDC_DMA_CFG, val,
  1398. !(val & MSDC_DMA_CFG_STS), 1, 20000);
  1399. if (ret)
  1400. dev_dbg(host->dev, "DMA inactive timed out\n");
  1401. sdr_clr_bits(host->base + MSDC_INTEN, data_ints_mask);
  1402. dev_dbg(host->dev, "DMA stop\n");
  1403. if ((events & MSDC_INT_XFER_COMPL) && (!stop || !stop->error)) {
  1404. data->bytes_xfered = data->blocks * data->blksz;
  1405. } else {
  1406. dev_dbg(host->dev, "interrupt events: %x\n", events);
  1407. msdc_reset_hw(host);
  1408. host->error |= REQ_DAT_ERR;
  1409. data->bytes_xfered = 0;
  1410. if (events & MSDC_INT_DATTMO)
  1411. data->error = -ETIMEDOUT;
  1412. else if (events & MSDC_INT_DATCRCERR)
  1413. data->error = -EILSEQ;
  1414. dev_dbg(host->dev, "%s: cmd=%d; blocks=%d",
  1415. __func__, mrq->cmd->opcode, data->blocks);
  1416. dev_dbg(host->dev, "data_error=%d xfer_size=%d\n",
  1417. (int)data->error, data->bytes_xfered);
  1418. }
  1419. msdc_data_xfer_next(host, mrq);
  1420. }
  1421. }
  1422. static void msdc_set_buswidth(struct msdc_host *host, u32 width)
  1423. {
  1424. u32 val = readl(host->base + SDC_CFG);
  1425. val &= ~SDC_CFG_BUSWIDTH;
  1426. switch (width) {
  1427. default:
  1428. case MMC_BUS_WIDTH_1:
  1429. val |= (MSDC_BUS_1BITS << 16);
  1430. break;
  1431. case MMC_BUS_WIDTH_4:
  1432. val |= (MSDC_BUS_4BITS << 16);
  1433. break;
  1434. case MMC_BUS_WIDTH_8:
  1435. val |= (MSDC_BUS_8BITS << 16);
  1436. break;
  1437. }
  1438. writel(val, host->base + SDC_CFG);
  1439. dev_dbg(host->dev, "Bus Width = %d", width);
  1440. }
  1441. static int msdc_ops_switch_volt(struct mmc_host *mmc, struct mmc_ios *ios)
  1442. {
  1443. struct msdc_host *host = mmc_priv(mmc);
  1444. int ret;
  1445. if (!IS_ERR(mmc->supply.vqmmc)) {
  1446. if (ios->signal_voltage != MMC_SIGNAL_VOLTAGE_330 &&
  1447. ios->signal_voltage != MMC_SIGNAL_VOLTAGE_180) {
  1448. dev_err(host->dev, "Unsupported signal voltage!\n");
  1449. return -EINVAL;
  1450. }
  1451. ret = mmc_regulator_set_vqmmc(mmc, ios);
  1452. if (ret < 0) {
  1453. dev_dbg(host->dev, "Regulator set error %d (%d)\n",
  1454. ret, ios->signal_voltage);
  1455. return ret;
  1456. }
  1457. /* Apply different pinctrl settings for different signal voltage */
  1458. if (ios->signal_voltage == MMC_SIGNAL_VOLTAGE_180)
  1459. pinctrl_select_state(host->pinctrl, host->pins_uhs);
  1460. else
  1461. pinctrl_select_state(host->pinctrl, host->pins_default);
  1462. }
  1463. return 0;
  1464. }
  1465. static int msdc_card_busy(struct mmc_host *mmc)
  1466. {
  1467. struct msdc_host *host = mmc_priv(mmc);
  1468. u32 status = readl(host->base + MSDC_PS);
  1469. /* only check if data0 is low */
  1470. return !(status & BIT(16));
  1471. }
  1472. static void msdc_request_timeout(struct work_struct *work)
  1473. {
  1474. struct msdc_host *host = container_of(work, struct msdc_host,
  1475. req_timeout.work);
  1476. /* simulate HW timeout status */
  1477. dev_err(host->dev, "%s: aborting cmd/data/mrq\n", __func__);
  1478. if (host->mrq) {
  1479. dev_err(host->dev, "%s: aborting mrq=%p cmd=%d\n", __func__,
  1480. host->mrq, host->mrq->cmd->opcode);
  1481. if (host->cmd) {
  1482. dev_err(host->dev, "%s: aborting cmd=%d\n",
  1483. __func__, host->cmd->opcode);
  1484. msdc_cmd_done(host, MSDC_INT_CMDTMO, host->mrq,
  1485. host->cmd);
  1486. } else if (host->data) {
  1487. dev_err(host->dev, "%s: abort data: cmd%d; %d blocks\n",
  1488. __func__, host->mrq->cmd->opcode,
  1489. host->data->blocks);
  1490. msdc_data_xfer_done(host, MSDC_INT_DATTMO, host->mrq,
  1491. host->data);
  1492. }
  1493. }
  1494. }
  1495. static void __msdc_enable_sdio_irq(struct msdc_host *host, int enb)
  1496. {
  1497. if (enb) {
  1498. sdr_set_bits(host->base + MSDC_INTEN, MSDC_INTEN_SDIOIRQ);
  1499. sdr_set_bits(host->base + SDC_CFG, SDC_CFG_SDIOIDE);
  1500. if (host->dev_comp->recheck_sdio_irq)
  1501. msdc_recheck_sdio_irq(host);
  1502. } else {
  1503. sdr_clr_bits(host->base + MSDC_INTEN, MSDC_INTEN_SDIOIRQ);
  1504. sdr_clr_bits(host->base + SDC_CFG, SDC_CFG_SDIOIDE);
  1505. }
  1506. }
  1507. static void msdc_enable_sdio_irq(struct mmc_host *mmc, int enb)
  1508. {
  1509. struct msdc_host *host = mmc_priv(mmc);
  1510. unsigned long flags;
  1511. int ret;
  1512. spin_lock_irqsave(&host->lock, flags);
  1513. __msdc_enable_sdio_irq(host, enb);
  1514. spin_unlock_irqrestore(&host->lock, flags);
  1515. if (mmc_card_enable_async_irq(mmc->card) && host->pins_eint) {
  1516. if (enb) {
  1517. /*
  1518. * In dev_pm_set_dedicated_wake_irq_reverse(), eint pin will be set to
  1519. * GPIO mode. We need to restore it to SDIO DAT1 mode after that.
  1520. * Since the current pinstate is pins_uhs, to ensure pinctrl select take
  1521. * affect successfully, we change the pinstate to pins_eint firstly.
  1522. */
  1523. pinctrl_select_state(host->pinctrl, host->pins_eint);
  1524. ret = dev_pm_set_dedicated_wake_irq_reverse(host->dev, host->eint_irq);
  1525. if (ret) {
  1526. dev_err(host->dev, "Failed to register SDIO wakeup irq!\n");
  1527. host->pins_eint = NULL;
  1528. pm_runtime_get_noresume(host->dev);
  1529. } else {
  1530. dev_dbg(host->dev, "SDIO eint irq: %d!\n", host->eint_irq);
  1531. }
  1532. pinctrl_select_state(host->pinctrl, host->pins_uhs);
  1533. } else {
  1534. dev_pm_clear_wake_irq(host->dev);
  1535. }
  1536. } else {
  1537. if (enb) {
  1538. /* Ensure host->pins_eint is NULL */
  1539. host->pins_eint = NULL;
  1540. pm_runtime_get_noresume(host->dev);
  1541. } else {
  1542. pm_runtime_put_noidle(host->dev);
  1543. }
  1544. }
  1545. }
  1546. static irqreturn_t msdc_cmdq_irq(struct msdc_host *host, u32 intsts)
  1547. {
  1548. struct mmc_host *mmc = mmc_from_priv(host);
  1549. int cmd_err = 0, dat_err = 0;
  1550. if (intsts & MSDC_INT_RSPCRCERR) {
  1551. cmd_err = -EILSEQ;
  1552. dev_err(host->dev, "%s: CMD CRC ERR", __func__);
  1553. } else if (intsts & MSDC_INT_CMDTMO) {
  1554. cmd_err = -ETIMEDOUT;
  1555. dev_err(host->dev, "%s: CMD TIMEOUT ERR", __func__);
  1556. }
  1557. if (intsts & MSDC_INT_DATCRCERR) {
  1558. dat_err = -EILSEQ;
  1559. dev_err(host->dev, "%s: DATA CRC ERR", __func__);
  1560. } else if (intsts & MSDC_INT_DATTMO) {
  1561. dat_err = -ETIMEDOUT;
  1562. dev_err(host->dev, "%s: DATA TIMEOUT ERR", __func__);
  1563. }
  1564. if (cmd_err || dat_err) {
  1565. dev_err(host->dev, "cmd_err = %d, dat_err = %d, intsts = 0x%x",
  1566. cmd_err, dat_err, intsts);
  1567. }
  1568. return cqhci_irq(mmc, 0, cmd_err, dat_err);
  1569. }
  1570. static irqreturn_t msdc_irq(int irq, void *dev_id)
  1571. {
  1572. struct msdc_host *host = (struct msdc_host *) dev_id;
  1573. struct mmc_host *mmc = mmc_from_priv(host);
  1574. while (true) {
  1575. struct mmc_request *mrq;
  1576. struct mmc_command *cmd;
  1577. struct mmc_data *data;
  1578. u32 events, event_mask;
  1579. spin_lock(&host->lock);
  1580. events = readl(host->base + MSDC_INT);
  1581. event_mask = readl(host->base + MSDC_INTEN);
  1582. if ((events & event_mask) & MSDC_INT_SDIOIRQ)
  1583. __msdc_enable_sdio_irq(host, 0);
  1584. /* clear interrupts */
  1585. writel(events & event_mask, host->base + MSDC_INT);
  1586. mrq = host->mrq;
  1587. cmd = host->cmd;
  1588. data = host->data;
  1589. spin_unlock(&host->lock);
  1590. if ((events & event_mask) & MSDC_INT_SDIOIRQ)
  1591. sdio_signal_irq(mmc);
  1592. if ((events & event_mask) & MSDC_INT_CDSC) {
  1593. if (host->internal_cd)
  1594. mmc_detect_change(mmc, msecs_to_jiffies(20));
  1595. events &= ~MSDC_INT_CDSC;
  1596. }
  1597. if (!(events & (event_mask & ~MSDC_INT_SDIOIRQ)))
  1598. break;
  1599. if ((mmc->caps2 & MMC_CAP2_CQE) &&
  1600. (events & MSDC_INT_CMDQ)) {
  1601. msdc_cmdq_irq(host, events);
  1602. /* clear interrupts */
  1603. writel(events, host->base + MSDC_INT);
  1604. return IRQ_HANDLED;
  1605. }
  1606. if (!mrq) {
  1607. dev_err(host->dev,
  1608. "%s: MRQ=NULL; events=%08X; event_mask=%08X\n",
  1609. __func__, events, event_mask);
  1610. WARN_ON(1);
  1611. break;
  1612. }
  1613. dev_dbg(host->dev, "%s: events=%08X\n", __func__, events);
  1614. if (cmd)
  1615. msdc_cmd_done(host, events, mrq, cmd);
  1616. else if (data)
  1617. msdc_data_xfer_done(host, events, mrq, data);
  1618. }
  1619. return IRQ_HANDLED;
  1620. }
  1621. static void msdc_init_hw(struct msdc_host *host)
  1622. {
  1623. u32 val, pb1_val, pb2_val;
  1624. u32 tune_reg = host->dev_comp->pad_tune_reg;
  1625. struct mmc_host *mmc = mmc_from_priv(host);
  1626. if (host->reset) {
  1627. reset_control_assert(host->reset);
  1628. usleep_range(10, 50);
  1629. reset_control_deassert(host->reset);
  1630. }
  1631. /* New tx/rx enable bit need to be 0->1 for hardware check */
  1632. if (host->dev_comp->support_new_tx) {
  1633. sdr_clr_bits(host->base + SDC_ADV_CFG0, SDC_NEW_TX_EN);
  1634. sdr_set_bits(host->base + SDC_ADV_CFG0, SDC_NEW_TX_EN);
  1635. msdc_new_tx_setting(host);
  1636. }
  1637. if (host->dev_comp->support_new_rx) {
  1638. sdr_clr_bits(host->base + MSDC_NEW_RX_CFG, MSDC_NEW_RX_PATH_SEL);
  1639. sdr_set_bits(host->base + MSDC_NEW_RX_CFG, MSDC_NEW_RX_PATH_SEL);
  1640. }
  1641. /* Configure to MMC/SD mode, clock free running */
  1642. sdr_set_bits(host->base + MSDC_CFG, MSDC_CFG_MODE | MSDC_CFG_CKPDN);
  1643. /* Reset */
  1644. msdc_reset_hw(host);
  1645. /* Disable and clear all interrupts */
  1646. writel(0, host->base + MSDC_INTEN);
  1647. val = readl(host->base + MSDC_INT);
  1648. writel(val, host->base + MSDC_INT);
  1649. /* Configure card detection */
  1650. if (host->internal_cd) {
  1651. sdr_set_field(host->base + MSDC_PS, MSDC_PS_CDDEBOUNCE,
  1652. DEFAULT_DEBOUNCE);
  1653. sdr_set_bits(host->base + MSDC_PS, MSDC_PS_CDEN);
  1654. sdr_set_bits(host->base + MSDC_INTEN, MSDC_INTEN_CDSC);
  1655. sdr_set_bits(host->base + SDC_CFG, SDC_CFG_INSWKUP);
  1656. } else {
  1657. sdr_clr_bits(host->base + SDC_CFG, SDC_CFG_INSWKUP);
  1658. sdr_clr_bits(host->base + MSDC_PS, MSDC_PS_CDEN);
  1659. sdr_clr_bits(host->base + MSDC_INTEN, MSDC_INTEN_CDSC);
  1660. }
  1661. if (host->top_base) {
  1662. writel(0, host->top_base + EMMC_TOP_CONTROL);
  1663. writel(0, host->top_base + EMMC_TOP_CMD);
  1664. } else {
  1665. writel(0, host->base + tune_reg);
  1666. }
  1667. writel(0, host->base + MSDC_IOCON);
  1668. sdr_set_field(host->base + MSDC_IOCON, MSDC_IOCON_DDLSEL, 0);
  1669. /*
  1670. * Patch bit 0 and 1 are completely rewritten, but for patch bit 2
  1671. * defaults are retained and, if necessary, only some bits are fixed
  1672. * up: read the PB2 register here for later usage in this function.
  1673. */
  1674. pb2_val = readl(host->base + MSDC_PATCH_BIT2);
  1675. /* Enable odd number support for 8-bit data bus */
  1676. val = MSDC_PATCH_BIT_ODDSUPP;
  1677. /* Disable SD command register write monitor */
  1678. val |= MSDC_PATCH_BIT_DIS_WRMON;
  1679. /* Issue transfer done interrupt after GPD update */
  1680. val |= MSDC_PATCH_BIT_DESCUP_SEL;
  1681. /* Extend R1B busy detection delay (in clock cycles) */
  1682. val |= FIELD_PREP(MSDC_PATCH_BIT_BUSYDLY, 15);
  1683. /* Enable CRC phase timeout during data write operation */
  1684. val |= MSDC_PATCH_BIT_DECRCTMO;
  1685. /* Set CKGEN delay to one stage */
  1686. val |= FIELD_PREP(MSDC_CKGEN_MSDC_DLY_SEL, 1);
  1687. /* First MSDC_PATCH_BIT setup is done: pull the trigger! */
  1688. writel(val, host->base + MSDC_PATCH_BIT);
  1689. /* Set wr data, crc status, cmd response turnaround period for UHS104 */
  1690. pb1_val = FIELD_PREP(MSDC_PB1_WRDAT_CRC_TACNTR, 1);
  1691. pb1_val |= FIELD_PREP(MSDC_PATCH_BIT1_CMDTA, 1);
  1692. pb1_val |= MSDC_PB1_DDR_CMD_FIX_SEL;
  1693. /* Support 'single' burst type only when AXI_LEN is 0 */
  1694. sdr_get_field(host->base + EMMC50_CFG2, EMMC50_CFG2_AXI_SET_LEN, &val);
  1695. if (!val)
  1696. pb1_val |= MSDC_PB1_SINGLE_BURST;
  1697. /* Set auto sync state clear, block gap stop clk */
  1698. pb1_val |= MSDC_PB1_RSVD20 | MSDC_PB1_AUTO_SYNCST_CLR | MSDC_PB1_MARK_POP_WATER;
  1699. /* Set low power DCM, use HCLK for GDMA, use MSDC CLK for everything else */
  1700. pb1_val |= MSDC_PB1_LP_DCM_EN | MSDC_PB1_RSVD3 |
  1701. MSDC_PB1_AHB_GDMA_HCLK | MSDC_PB1_MSDC_CLK_ENFEAT;
  1702. /* If needed, enable R1b command busy check at controller init time */
  1703. if (!host->dev_comp->busy_check)
  1704. pb1_val |= MSDC_PB1_BUSY_CHECK_SEL;
  1705. if (host->dev_comp->stop_clk_fix) {
  1706. if (host->dev_comp->stop_dly_sel)
  1707. pb1_val |= FIELD_PREP(MSDC_PATCH_BIT1_STOP_DLY,
  1708. host->dev_comp->stop_dly_sel);
  1709. if (host->dev_comp->pop_en_cnt) {
  1710. pb2_val &= ~MSDC_PB2_POP_EN_CNT;
  1711. pb2_val |= FIELD_PREP(MSDC_PB2_POP_EN_CNT,
  1712. host->dev_comp->pop_en_cnt);
  1713. }
  1714. sdr_clr_bits(host->base + SDC_FIFO_CFG, SDC_FIFO_CFG_WRVALIDSEL);
  1715. sdr_clr_bits(host->base + SDC_FIFO_CFG, SDC_FIFO_CFG_RDVALIDSEL);
  1716. }
  1717. if (host->dev_comp->async_fifo) {
  1718. /* Set CMD response timeout multiplier to 65 + (16 * 3) cycles */
  1719. pb2_val &= ~MSDC_PB2_RESPWAIT;
  1720. pb2_val |= FIELD_PREP(MSDC_PB2_RESPWAIT, 3);
  1721. /* eMMC4.5: Select async FIFO path for CMD resp and CRC status */
  1722. pb2_val &= ~MSDC_PATCH_BIT2_CFGRESP;
  1723. pb2_val |= MSDC_PATCH_BIT2_CFGCRCSTS;
  1724. if (!host->dev_comp->enhance_rx) {
  1725. /* eMMC4.5: Delay 2T for CMD resp and CRC status EN signals */
  1726. pb2_val &= ~(MSDC_PB2_RESPSTSENSEL | MSDC_PB2_CRCSTSENSEL);
  1727. pb2_val |= FIELD_PREP(MSDC_PB2_RESPSTSENSEL, 2);
  1728. pb2_val |= FIELD_PREP(MSDC_PB2_CRCSTSENSEL, 2);
  1729. } else if (host->top_base) {
  1730. sdr_set_bits(host->top_base + EMMC_TOP_CONTROL, SDC_RX_ENH_EN);
  1731. } else {
  1732. sdr_set_bits(host->base + SDC_ADV_CFG0, SDC_RX_ENHANCE_EN);
  1733. }
  1734. }
  1735. if (host->dev_comp->support_64g)
  1736. pb2_val |= MSDC_PB2_SUPPORT_64G;
  1737. /* Patch Bit 1/2 setup is done: pull the trigger! */
  1738. writel(pb1_val, host->base + MSDC_PATCH_BIT1);
  1739. writel(pb2_val, host->base + MSDC_PATCH_BIT2);
  1740. sdr_set_bits(host->base + EMMC50_CFG0, EMMC50_CFG_CFCSTS_SEL);
  1741. if (host->dev_comp->data_tune) {
  1742. if (host->top_base) {
  1743. u32 top_ctl_val = readl(host->top_base + EMMC_TOP_CONTROL);
  1744. u32 top_cmd_val = readl(host->top_base + EMMC_TOP_CMD);
  1745. top_cmd_val |= PAD_CMD_RD_RXDLY_SEL;
  1746. top_ctl_val |= PAD_DAT_RD_RXDLY_SEL;
  1747. top_ctl_val &= ~DATA_K_VALUE_SEL;
  1748. if (host->tuning_step > PAD_DELAY_HALF) {
  1749. top_cmd_val |= PAD_CMD_RD_RXDLY2_SEL;
  1750. top_ctl_val |= PAD_DAT_RD_RXDLY2_SEL;
  1751. }
  1752. writel(top_ctl_val, host->top_base + EMMC_TOP_CONTROL);
  1753. writel(top_cmd_val, host->top_base + EMMC_TOP_CMD);
  1754. } else {
  1755. sdr_set_bits(host->base + tune_reg,
  1756. MSDC_PAD_TUNE_RD_SEL |
  1757. MSDC_PAD_TUNE_CMD_SEL);
  1758. if (host->tuning_step > PAD_DELAY_HALF)
  1759. sdr_set_bits(host->base + tune_reg + TUNING_REG2_FIXED_OFFEST,
  1760. MSDC_PAD_TUNE_RD2_SEL |
  1761. MSDC_PAD_TUNE_CMD2_SEL);
  1762. }
  1763. } else {
  1764. /* choose clock tune */
  1765. if (host->top_base)
  1766. sdr_set_bits(host->top_base + EMMC_TOP_CONTROL,
  1767. PAD_RXDLY_SEL);
  1768. else
  1769. sdr_set_bits(host->base + tune_reg,
  1770. MSDC_PAD_TUNE_RXDLYSEL);
  1771. }
  1772. if (mmc->caps2 & MMC_CAP2_NO_SDIO) {
  1773. sdr_clr_bits(host->base + SDC_CFG, SDC_CFG_SDIO);
  1774. sdr_clr_bits(host->base + MSDC_INTEN, MSDC_INTEN_SDIOIRQ);
  1775. sdr_clr_bits(host->base + SDC_ADV_CFG0, SDC_DAT1_IRQ_TRIGGER);
  1776. } else {
  1777. /* Configure to enable SDIO mode, otherwise SDIO CMD5 fails */
  1778. sdr_set_bits(host->base + SDC_CFG, SDC_CFG_SDIO);
  1779. /* Config SDIO device detect interrupt function */
  1780. sdr_clr_bits(host->base + SDC_CFG, SDC_CFG_SDIOIDE);
  1781. sdr_set_bits(host->base + SDC_ADV_CFG0, SDC_DAT1_IRQ_TRIGGER);
  1782. }
  1783. /* Configure to default data timeout */
  1784. sdr_set_field(host->base + SDC_CFG, SDC_CFG_DTOC, 3);
  1785. host->def_tune_para.iocon = readl(host->base + MSDC_IOCON);
  1786. host->saved_tune_para.iocon = readl(host->base + MSDC_IOCON);
  1787. if (host->top_base) {
  1788. host->def_tune_para.emmc_top_control =
  1789. readl(host->top_base + EMMC_TOP_CONTROL);
  1790. host->def_tune_para.emmc_top_cmd =
  1791. readl(host->top_base + EMMC_TOP_CMD);
  1792. host->saved_tune_para.emmc_top_control =
  1793. readl(host->top_base + EMMC_TOP_CONTROL);
  1794. host->saved_tune_para.emmc_top_cmd =
  1795. readl(host->top_base + EMMC_TOP_CMD);
  1796. } else {
  1797. host->def_tune_para.pad_tune = readl(host->base + tune_reg);
  1798. host->saved_tune_para.pad_tune = readl(host->base + tune_reg);
  1799. }
  1800. dev_dbg(host->dev, "init hardware done!");
  1801. }
  1802. static void msdc_deinit_hw(struct msdc_host *host)
  1803. {
  1804. u32 val;
  1805. if (host->internal_cd) {
  1806. /* Disabled card-detect */
  1807. sdr_clr_bits(host->base + MSDC_PS, MSDC_PS_CDEN);
  1808. sdr_clr_bits(host->base + SDC_CFG, SDC_CFG_INSWKUP);
  1809. }
  1810. /* Disable and clear all interrupts */
  1811. writel(0, host->base + MSDC_INTEN);
  1812. val = readl(host->base + MSDC_INT);
  1813. writel(val, host->base + MSDC_INT);
  1814. }
  1815. /* init gpd and bd list in msdc_drv_probe */
  1816. static void msdc_init_gpd_bd(struct msdc_host *host, struct msdc_dma *dma)
  1817. {
  1818. struct mt_gpdma_desc *gpd = dma->gpd;
  1819. struct mt_bdma_desc *bd = dma->bd;
  1820. dma_addr_t dma_addr;
  1821. int i;
  1822. memset(gpd, 0, sizeof(struct mt_gpdma_desc) * 2);
  1823. dma_addr = dma->gpd_addr + sizeof(struct mt_gpdma_desc);
  1824. gpd->gpd_info = GPDMA_DESC_BDP; /* hwo, cs, bd pointer */
  1825. /* gpd->next is must set for desc DMA
  1826. * That's why must alloc 2 gpd structure.
  1827. */
  1828. gpd->next = lower_32_bits(dma_addr);
  1829. if (host->dev_comp->support_64g)
  1830. gpd->gpd_info |= (upper_32_bits(dma_addr) & 0xf) << 24;
  1831. dma_addr = dma->bd_addr;
  1832. gpd->ptr = lower_32_bits(dma->bd_addr); /* physical address */
  1833. if (host->dev_comp->support_64g)
  1834. gpd->gpd_info |= (upper_32_bits(dma_addr) & 0xf) << 28;
  1835. memset(bd, 0, sizeof(struct mt_bdma_desc) * MAX_BD_NUM);
  1836. for (i = 0; i < (MAX_BD_NUM - 1); i++) {
  1837. dma_addr = dma->bd_addr + sizeof(*bd) * (i + 1);
  1838. bd[i].next = lower_32_bits(dma_addr);
  1839. if (host->dev_comp->support_64g)
  1840. bd[i].bd_info |= (upper_32_bits(dma_addr) & 0xf) << 24;
  1841. }
  1842. }
  1843. static void msdc_ops_set_ios(struct mmc_host *mmc, struct mmc_ios *ios)
  1844. {
  1845. struct msdc_host *host = mmc_priv(mmc);
  1846. int ret;
  1847. msdc_set_buswidth(host, ios->bus_width);
  1848. /* Suspend/Resume will do power off/on */
  1849. switch (ios->power_mode) {
  1850. case MMC_POWER_UP:
  1851. if (!IS_ERR(mmc->supply.vmmc)) {
  1852. msdc_init_hw(host);
  1853. ret = mmc_regulator_set_ocr(mmc, mmc->supply.vmmc,
  1854. ios->vdd);
  1855. if (ret) {
  1856. dev_err(host->dev, "Failed to set vmmc power!\n");
  1857. return;
  1858. }
  1859. }
  1860. break;
  1861. case MMC_POWER_ON:
  1862. if (!IS_ERR(mmc->supply.vqmmc) && !host->vqmmc_enabled) {
  1863. ret = regulator_enable(mmc->supply.vqmmc);
  1864. if (ret)
  1865. dev_err(host->dev, "Failed to set vqmmc power!\n");
  1866. else
  1867. host->vqmmc_enabled = true;
  1868. }
  1869. break;
  1870. case MMC_POWER_OFF:
  1871. if (!IS_ERR(mmc->supply.vmmc))
  1872. mmc_regulator_set_ocr(mmc, mmc->supply.vmmc, 0);
  1873. if (!IS_ERR(mmc->supply.vqmmc) && host->vqmmc_enabled) {
  1874. regulator_disable(mmc->supply.vqmmc);
  1875. host->vqmmc_enabled = false;
  1876. }
  1877. break;
  1878. default:
  1879. break;
  1880. }
  1881. if (host->mclk != ios->clock || host->timing != ios->timing)
  1882. msdc_set_mclk(host, ios->timing, ios->clock);
  1883. }
  1884. static u64 test_delay_bit(u64 delay, u32 bit)
  1885. {
  1886. bit %= PAD_DELAY_FULL;
  1887. return delay & BIT_ULL(bit);
  1888. }
  1889. static int get_delay_len(u64 delay, u32 start_bit)
  1890. {
  1891. int i;
  1892. for (i = 0; i < (PAD_DELAY_FULL - start_bit); i++) {
  1893. if (test_delay_bit(delay, start_bit + i) == 0)
  1894. return i;
  1895. }
  1896. return PAD_DELAY_FULL - start_bit;
  1897. }
  1898. static struct msdc_delay_phase get_best_delay(struct msdc_host *host, u64 delay)
  1899. {
  1900. int start = 0, len = 0;
  1901. int start_final = 0, len_final = 0;
  1902. u8 final_phase = 0xff;
  1903. struct msdc_delay_phase delay_phase = { 0, };
  1904. if (delay == 0) {
  1905. dev_err(host->dev, "phase error: [map:%016llx]\n", delay);
  1906. delay_phase.final_phase = final_phase;
  1907. return delay_phase;
  1908. }
  1909. while (start < PAD_DELAY_FULL) {
  1910. len = get_delay_len(delay, start);
  1911. if (len_final < len) {
  1912. start_final = start;
  1913. len_final = len;
  1914. }
  1915. start += len ? len : 1;
  1916. if (!upper_32_bits(delay) && len >= 12 && start_final < 4)
  1917. break;
  1918. }
  1919. /* The rule is that to find the smallest delay cell */
  1920. if (start_final == 0)
  1921. final_phase = (start_final + len_final / 3) % PAD_DELAY_FULL;
  1922. else
  1923. final_phase = (start_final + len_final / 2) % PAD_DELAY_FULL;
  1924. dev_dbg(host->dev, "phase: [map:%016llx] [maxlen:%d] [final:%d]\n",
  1925. delay, len_final, final_phase);
  1926. delay_phase.maxlen = len_final;
  1927. delay_phase.start = start_final;
  1928. delay_phase.final_phase = final_phase;
  1929. return delay_phase;
  1930. }
  1931. static inline void msdc_set_cmd_delay(struct msdc_host *host, u32 value)
  1932. {
  1933. u32 tune_reg = host->dev_comp->pad_tune_reg;
  1934. if (host->top_base) {
  1935. u32 regval = readl(host->top_base + EMMC_TOP_CMD);
  1936. regval &= ~(PAD_CMD_RXDLY | PAD_CMD_RXDLY2);
  1937. if (value < PAD_DELAY_HALF) {
  1938. regval |= FIELD_PREP(PAD_CMD_RXDLY, value);
  1939. } else {
  1940. regval |= FIELD_PREP(PAD_CMD_RXDLY, PAD_DELAY_HALF - 1);
  1941. regval |= FIELD_PREP(PAD_CMD_RXDLY2, value - PAD_DELAY_HALF);
  1942. }
  1943. writel(regval, host->top_base + EMMC_TOP_CMD);
  1944. } else {
  1945. if (value < PAD_DELAY_HALF) {
  1946. sdr_set_field(host->base + tune_reg, MSDC_PAD_TUNE_CMDRDLY, value);
  1947. sdr_set_field(host->base + tune_reg + TUNING_REG2_FIXED_OFFEST,
  1948. MSDC_PAD_TUNE_CMDRDLY2, 0);
  1949. } else {
  1950. sdr_set_field(host->base + tune_reg, MSDC_PAD_TUNE_CMDRDLY,
  1951. PAD_DELAY_HALF - 1);
  1952. sdr_set_field(host->base + tune_reg + TUNING_REG2_FIXED_OFFEST,
  1953. MSDC_PAD_TUNE_CMDRDLY2, value - PAD_DELAY_HALF);
  1954. }
  1955. }
  1956. }
  1957. static inline void msdc_set_data_delay(struct msdc_host *host, u32 value)
  1958. {
  1959. u32 tune_reg = host->dev_comp->pad_tune_reg;
  1960. if (host->top_base) {
  1961. u32 regval = readl(host->top_base + EMMC_TOP_CONTROL);
  1962. regval &= ~(PAD_DAT_RD_RXDLY | PAD_DAT_RD_RXDLY2);
  1963. if (value < PAD_DELAY_HALF) {
  1964. regval |= FIELD_PREP(PAD_DAT_RD_RXDLY, value);
  1965. regval |= FIELD_PREP(PAD_DAT_RD_RXDLY2, value);
  1966. } else {
  1967. regval |= FIELD_PREP(PAD_DAT_RD_RXDLY, PAD_DELAY_HALF - 1);
  1968. regval |= FIELD_PREP(PAD_DAT_RD_RXDLY2, value - PAD_DELAY_HALF);
  1969. }
  1970. writel(regval, host->top_base + EMMC_TOP_CONTROL);
  1971. } else {
  1972. if (value < PAD_DELAY_HALF) {
  1973. sdr_set_field(host->base + tune_reg, MSDC_PAD_TUNE_DATRRDLY, value);
  1974. sdr_set_field(host->base + tune_reg + TUNING_REG2_FIXED_OFFEST,
  1975. MSDC_PAD_TUNE_DATRRDLY2, 0);
  1976. } else {
  1977. sdr_set_field(host->base + tune_reg, MSDC_PAD_TUNE_DATRRDLY,
  1978. PAD_DELAY_HALF - 1);
  1979. sdr_set_field(host->base + tune_reg + TUNING_REG2_FIXED_OFFEST,
  1980. MSDC_PAD_TUNE_DATRRDLY2, value - PAD_DELAY_HALF);
  1981. }
  1982. }
  1983. }
  1984. static inline void msdc_set_data_sample_edge(struct msdc_host *host, bool rising)
  1985. {
  1986. u32 value = rising ? 0 : 1;
  1987. if (host->dev_comp->support_new_rx) {
  1988. sdr_set_field(host->base + MSDC_PATCH_BIT, MSDC_PATCH_BIT_RD_DAT_SEL, value);
  1989. sdr_set_field(host->base + MSDC_PATCH_BIT2, MSDC_PB2_CFGCRCSTSEDGE, value);
  1990. } else {
  1991. sdr_set_field(host->base + MSDC_IOCON, MSDC_IOCON_DSPL, value);
  1992. sdr_set_field(host->base + MSDC_IOCON, MSDC_IOCON_W_DSPL, value);
  1993. }
  1994. }
  1995. static int msdc_tune_response(struct mmc_host *mmc, u32 opcode)
  1996. {
  1997. struct msdc_host *host = mmc_priv(mmc);
  1998. u64 rise_delay = 0, fall_delay = 0;
  1999. struct msdc_delay_phase final_rise_delay, final_fall_delay = { 0,};
  2000. struct msdc_delay_phase internal_delay_phase;
  2001. u8 final_delay, final_maxlen;
  2002. u32 internal_delay = 0;
  2003. u32 tune_reg = host->dev_comp->pad_tune_reg;
  2004. int cmd_err;
  2005. int i, j;
  2006. if (mmc->ios.timing == MMC_TIMING_MMC_HS200 ||
  2007. mmc->ios.timing == MMC_TIMING_UHS_SDR104)
  2008. sdr_set_field(host->base + tune_reg,
  2009. MSDC_PAD_TUNE_CMDRRDLY,
  2010. host->hs200_cmd_int_delay);
  2011. sdr_clr_bits(host->base + MSDC_IOCON, MSDC_IOCON_RSPL);
  2012. for (i = 0; i < host->tuning_step; i++) {
  2013. msdc_set_cmd_delay(host, i);
  2014. /*
  2015. * Using the same parameters, it may sometimes pass the test,
  2016. * but sometimes it may fail. To make sure the parameters are
  2017. * more stable, we test each set of parameters 3 times.
  2018. */
  2019. for (j = 0; j < 3; j++) {
  2020. mmc_send_tuning(mmc, opcode, &cmd_err);
  2021. if (!cmd_err) {
  2022. rise_delay |= BIT_ULL(i);
  2023. } else {
  2024. rise_delay &= ~BIT_ULL(i);
  2025. break;
  2026. }
  2027. }
  2028. }
  2029. final_rise_delay = get_best_delay(host, rise_delay);
  2030. /* if rising edge has enough margin, then do not scan falling edge */
  2031. if (final_rise_delay.maxlen >= 12 ||
  2032. (final_rise_delay.start == 0 && final_rise_delay.maxlen >= 4))
  2033. goto skip_fall;
  2034. sdr_set_bits(host->base + MSDC_IOCON, MSDC_IOCON_RSPL);
  2035. for (i = 0; i < host->tuning_step; i++) {
  2036. msdc_set_cmd_delay(host, i);
  2037. /*
  2038. * Using the same parameters, it may sometimes pass the test,
  2039. * but sometimes it may fail. To make sure the parameters are
  2040. * more stable, we test each set of parameters 3 times.
  2041. */
  2042. for (j = 0; j < 3; j++) {
  2043. mmc_send_tuning(mmc, opcode, &cmd_err);
  2044. if (!cmd_err) {
  2045. fall_delay |= BIT_ULL(i);
  2046. } else {
  2047. fall_delay &= ~BIT_ULL(i);
  2048. break;
  2049. }
  2050. }
  2051. }
  2052. final_fall_delay = get_best_delay(host, fall_delay);
  2053. skip_fall:
  2054. final_maxlen = max(final_rise_delay.maxlen, final_fall_delay.maxlen);
  2055. if (final_fall_delay.maxlen >= 12 && final_fall_delay.start < 4)
  2056. final_maxlen = final_fall_delay.maxlen;
  2057. if (final_maxlen == final_rise_delay.maxlen) {
  2058. sdr_clr_bits(host->base + MSDC_IOCON, MSDC_IOCON_RSPL);
  2059. final_delay = final_rise_delay.final_phase;
  2060. } else {
  2061. sdr_set_bits(host->base + MSDC_IOCON, MSDC_IOCON_RSPL);
  2062. final_delay = final_fall_delay.final_phase;
  2063. }
  2064. msdc_set_cmd_delay(host, final_delay);
  2065. if (host->dev_comp->async_fifo || host->hs200_cmd_int_delay)
  2066. goto skip_internal;
  2067. for (i = 0; i < host->tuning_step; i++) {
  2068. sdr_set_field(host->base + tune_reg,
  2069. MSDC_PAD_TUNE_CMDRRDLY, i);
  2070. mmc_send_tuning(mmc, opcode, &cmd_err);
  2071. if (!cmd_err)
  2072. internal_delay |= BIT_ULL(i);
  2073. }
  2074. dev_dbg(host->dev, "Final internal delay: 0x%x\n", internal_delay);
  2075. internal_delay_phase = get_best_delay(host, internal_delay);
  2076. sdr_set_field(host->base + tune_reg, MSDC_PAD_TUNE_CMDRRDLY,
  2077. internal_delay_phase.final_phase);
  2078. skip_internal:
  2079. dev_dbg(host->dev, "Final cmd pad delay: %x\n", final_delay);
  2080. return final_delay == 0xff ? -EIO : 0;
  2081. }
  2082. static int hs400_tune_response(struct mmc_host *mmc, u32 opcode)
  2083. {
  2084. struct msdc_host *host = mmc_priv(mmc);
  2085. u32 cmd_delay = 0;
  2086. struct msdc_delay_phase final_cmd_delay = { 0,};
  2087. u8 final_delay;
  2088. int cmd_err;
  2089. int i, j;
  2090. /* select EMMC50 PAD CMD tune */
  2091. sdr_set_bits(host->base + PAD_CMD_TUNE, BIT(0));
  2092. sdr_set_field(host->base + MSDC_PATCH_BIT1, MSDC_PATCH_BIT1_CMDTA, 2);
  2093. if (mmc->ios.timing == MMC_TIMING_MMC_HS200 ||
  2094. mmc->ios.timing == MMC_TIMING_UHS_SDR104)
  2095. sdr_set_field(host->base + MSDC_PAD_TUNE,
  2096. MSDC_PAD_TUNE_CMDRRDLY,
  2097. host->hs200_cmd_int_delay);
  2098. if (host->hs400_cmd_resp_sel_rising)
  2099. sdr_clr_bits(host->base + MSDC_IOCON, MSDC_IOCON_RSPL);
  2100. else
  2101. sdr_set_bits(host->base + MSDC_IOCON, MSDC_IOCON_RSPL);
  2102. for (i = 0; i < PAD_DELAY_HALF; i++) {
  2103. sdr_set_field(host->base + PAD_CMD_TUNE,
  2104. PAD_CMD_TUNE_RX_DLY3, i);
  2105. /*
  2106. * Using the same parameters, it may sometimes pass the test,
  2107. * but sometimes it may fail. To make sure the parameters are
  2108. * more stable, we test each set of parameters 3 times.
  2109. */
  2110. for (j = 0; j < 3; j++) {
  2111. mmc_send_tuning(mmc, opcode, &cmd_err);
  2112. if (!cmd_err) {
  2113. cmd_delay |= BIT(i);
  2114. } else {
  2115. cmd_delay &= ~BIT(i);
  2116. break;
  2117. }
  2118. }
  2119. }
  2120. final_cmd_delay = get_best_delay(host, cmd_delay);
  2121. sdr_set_field(host->base + PAD_CMD_TUNE, PAD_CMD_TUNE_RX_DLY3,
  2122. final_cmd_delay.final_phase);
  2123. final_delay = final_cmd_delay.final_phase;
  2124. dev_dbg(host->dev, "Final cmd pad delay: %x\n", final_delay);
  2125. return final_delay == 0xff ? -EIO : 0;
  2126. }
  2127. static int msdc_tune_data(struct mmc_host *mmc, u32 opcode)
  2128. {
  2129. struct msdc_host *host = mmc_priv(mmc);
  2130. u64 rise_delay = 0, fall_delay = 0;
  2131. struct msdc_delay_phase final_rise_delay, final_fall_delay = { 0,};
  2132. u8 final_delay, final_maxlen;
  2133. int i, ret;
  2134. sdr_set_field(host->base + MSDC_PATCH_BIT, MSDC_INT_DAT_LATCH_CK_SEL,
  2135. host->latch_ck);
  2136. msdc_set_data_sample_edge(host, true);
  2137. for (i = 0; i < host->tuning_step; i++) {
  2138. msdc_set_data_delay(host, i);
  2139. ret = mmc_send_tuning(mmc, opcode, NULL);
  2140. if (!ret)
  2141. rise_delay |= BIT_ULL(i);
  2142. }
  2143. final_rise_delay = get_best_delay(host, rise_delay);
  2144. /* if rising edge has enough margin, then do not scan falling edge */
  2145. if (final_rise_delay.maxlen >= 12 ||
  2146. (final_rise_delay.start == 0 && final_rise_delay.maxlen >= 4))
  2147. goto skip_fall;
  2148. msdc_set_data_sample_edge(host, false);
  2149. for (i = 0; i < host->tuning_step; i++) {
  2150. msdc_set_data_delay(host, i);
  2151. ret = mmc_send_tuning(mmc, opcode, NULL);
  2152. if (!ret)
  2153. fall_delay |= BIT_ULL(i);
  2154. }
  2155. final_fall_delay = get_best_delay(host, fall_delay);
  2156. skip_fall:
  2157. final_maxlen = max(final_rise_delay.maxlen, final_fall_delay.maxlen);
  2158. if (final_maxlen == final_rise_delay.maxlen) {
  2159. msdc_set_data_sample_edge(host, true);
  2160. final_delay = final_rise_delay.final_phase;
  2161. } else {
  2162. msdc_set_data_sample_edge(host, false);
  2163. final_delay = final_fall_delay.final_phase;
  2164. }
  2165. msdc_set_data_delay(host, final_delay);
  2166. dev_dbg(host->dev, "Final data pad delay: %x\n", final_delay);
  2167. return final_delay == 0xff ? -EIO : 0;
  2168. }
  2169. /*
  2170. * MSDC IP which supports data tune + async fifo can do CMD/DAT tune
  2171. * together, which can save the tuning time.
  2172. */
  2173. static int msdc_tune_together(struct mmc_host *mmc, u32 opcode)
  2174. {
  2175. struct msdc_host *host = mmc_priv(mmc);
  2176. u64 rise_delay = 0, fall_delay = 0;
  2177. struct msdc_delay_phase final_rise_delay, final_fall_delay = { 0,};
  2178. u8 final_delay, final_maxlen;
  2179. int i, ret;
  2180. sdr_set_field(host->base + MSDC_PATCH_BIT, MSDC_INT_DAT_LATCH_CK_SEL,
  2181. host->latch_ck);
  2182. sdr_clr_bits(host->base + MSDC_IOCON, MSDC_IOCON_RSPL);
  2183. msdc_set_data_sample_edge(host, true);
  2184. for (i = 0; i < host->tuning_step; i++) {
  2185. msdc_set_cmd_delay(host, i);
  2186. msdc_set_data_delay(host, i);
  2187. ret = mmc_send_tuning(mmc, opcode, NULL);
  2188. if (!ret)
  2189. rise_delay |= BIT_ULL(i);
  2190. }
  2191. final_rise_delay = get_best_delay(host, rise_delay);
  2192. /* if rising edge has enough margin, then do not scan falling edge */
  2193. if (final_rise_delay.maxlen >= 12 ||
  2194. (final_rise_delay.start == 0 && final_rise_delay.maxlen >= 4))
  2195. goto skip_fall;
  2196. sdr_set_bits(host->base + MSDC_IOCON, MSDC_IOCON_RSPL);
  2197. msdc_set_data_sample_edge(host, false);
  2198. for (i = 0; i < host->tuning_step; i++) {
  2199. msdc_set_cmd_delay(host, i);
  2200. msdc_set_data_delay(host, i);
  2201. ret = mmc_send_tuning(mmc, opcode, NULL);
  2202. if (!ret)
  2203. fall_delay |= BIT_ULL(i);
  2204. }
  2205. final_fall_delay = get_best_delay(host, fall_delay);
  2206. skip_fall:
  2207. final_maxlen = max(final_rise_delay.maxlen, final_fall_delay.maxlen);
  2208. if (final_maxlen == final_rise_delay.maxlen) {
  2209. sdr_clr_bits(host->base + MSDC_IOCON, MSDC_IOCON_RSPL);
  2210. msdc_set_data_sample_edge(host, true);
  2211. final_delay = final_rise_delay.final_phase;
  2212. } else {
  2213. sdr_set_bits(host->base + MSDC_IOCON, MSDC_IOCON_RSPL);
  2214. msdc_set_data_sample_edge(host, false);
  2215. final_delay = final_fall_delay.final_phase;
  2216. }
  2217. msdc_set_cmd_delay(host, final_delay);
  2218. msdc_set_data_delay(host, final_delay);
  2219. dev_dbg(host->dev, "Final pad delay: %x\n", final_delay);
  2220. return final_delay == 0xff ? -EIO : 0;
  2221. }
  2222. static int msdc_execute_tuning(struct mmc_host *mmc, u32 opcode)
  2223. {
  2224. struct msdc_host *host = mmc_priv(mmc);
  2225. int ret;
  2226. u32 tune_reg = host->dev_comp->pad_tune_reg;
  2227. if (host->dev_comp->data_tune && host->dev_comp->async_fifo) {
  2228. ret = msdc_tune_together(mmc, opcode);
  2229. if (host->hs400_mode) {
  2230. msdc_set_data_sample_edge(host, true);
  2231. msdc_set_data_delay(host, 0);
  2232. }
  2233. goto tune_done;
  2234. }
  2235. if (host->hs400_mode &&
  2236. host->dev_comp->hs400_tune)
  2237. ret = hs400_tune_response(mmc, opcode);
  2238. else
  2239. ret = msdc_tune_response(mmc, opcode);
  2240. if (ret == -EIO) {
  2241. dev_err(host->dev, "Tune response fail!\n");
  2242. return ret;
  2243. }
  2244. if (host->hs400_mode == false) {
  2245. ret = msdc_tune_data(mmc, opcode);
  2246. if (ret == -EIO)
  2247. dev_err(host->dev, "Tune data fail!\n");
  2248. }
  2249. tune_done:
  2250. host->saved_tune_para.iocon = readl(host->base + MSDC_IOCON);
  2251. host->saved_tune_para.pad_tune = readl(host->base + tune_reg);
  2252. host->saved_tune_para.pad_cmd_tune = readl(host->base + PAD_CMD_TUNE);
  2253. if (host->top_base) {
  2254. host->saved_tune_para.emmc_top_control = readl(host->top_base +
  2255. EMMC_TOP_CONTROL);
  2256. host->saved_tune_para.emmc_top_cmd = readl(host->top_base +
  2257. EMMC_TOP_CMD);
  2258. }
  2259. return ret;
  2260. }
  2261. static int msdc_prepare_hs400_tuning(struct mmc_host *mmc, struct mmc_ios *ios)
  2262. {
  2263. struct msdc_host *host = mmc_priv(mmc);
  2264. host->hs400_mode = true;
  2265. if (host->top_base) {
  2266. if (host->hs400_ds_dly3)
  2267. sdr_set_field(host->top_base + EMMC50_PAD_DS_TUNE,
  2268. PAD_DS_DLY3, host->hs400_ds_dly3);
  2269. if (host->hs400_ds_delay)
  2270. writel(host->hs400_ds_delay,
  2271. host->top_base + EMMC50_PAD_DS_TUNE);
  2272. } else {
  2273. if (host->hs400_ds_dly3)
  2274. sdr_set_field(host->base + PAD_DS_TUNE,
  2275. PAD_DS_TUNE_DLY3, host->hs400_ds_dly3);
  2276. if (host->hs400_ds_delay)
  2277. writel(host->hs400_ds_delay, host->base + PAD_DS_TUNE);
  2278. }
  2279. /* hs400 mode must set it to 0 */
  2280. sdr_clr_bits(host->base + MSDC_PATCH_BIT2, MSDC_PATCH_BIT2_CFGCRCSTS);
  2281. /* to improve read performance, set outstanding to 2 */
  2282. sdr_set_field(host->base + EMMC50_CFG3, EMMC50_CFG3_OUTS_WR, 2);
  2283. return 0;
  2284. }
  2285. static int msdc_execute_hs400_tuning(struct mmc_host *mmc, struct mmc_card *card)
  2286. {
  2287. struct msdc_host *host = mmc_priv(mmc);
  2288. struct msdc_delay_phase dly1_delay;
  2289. u32 val, result_dly1 = 0;
  2290. u8 *ext_csd;
  2291. int i, ret;
  2292. if (host->top_base) {
  2293. sdr_set_bits(host->top_base + EMMC50_PAD_DS_TUNE,
  2294. PAD_DS_DLY_SEL);
  2295. sdr_clr_bits(host->top_base + EMMC50_PAD_DS_TUNE,
  2296. PAD_DS_DLY2_SEL);
  2297. } else {
  2298. sdr_set_bits(host->base + PAD_DS_TUNE, PAD_DS_TUNE_DLY_SEL);
  2299. sdr_clr_bits(host->base + PAD_DS_TUNE, PAD_DS_TUNE_DLY2_SEL);
  2300. }
  2301. host->hs400_tuning = true;
  2302. for (i = 0; i < PAD_DELAY_HALF; i++) {
  2303. if (host->top_base)
  2304. sdr_set_field(host->top_base + EMMC50_PAD_DS_TUNE,
  2305. PAD_DS_DLY1, i);
  2306. else
  2307. sdr_set_field(host->base + PAD_DS_TUNE,
  2308. PAD_DS_TUNE_DLY1, i);
  2309. ret = mmc_get_ext_csd(card, &ext_csd);
  2310. if (!ret) {
  2311. result_dly1 |= BIT(i);
  2312. kfree(ext_csd);
  2313. }
  2314. }
  2315. host->hs400_tuning = false;
  2316. dly1_delay = get_best_delay(host, result_dly1);
  2317. if (dly1_delay.maxlen == 0) {
  2318. dev_err(host->dev, "Failed to get DLY1 delay!\n");
  2319. goto fail;
  2320. }
  2321. if (host->top_base)
  2322. sdr_set_field(host->top_base + EMMC50_PAD_DS_TUNE,
  2323. PAD_DS_DLY1, dly1_delay.final_phase);
  2324. else
  2325. sdr_set_field(host->base + PAD_DS_TUNE,
  2326. PAD_DS_TUNE_DLY1, dly1_delay.final_phase);
  2327. if (host->top_base)
  2328. val = readl(host->top_base + EMMC50_PAD_DS_TUNE);
  2329. else
  2330. val = readl(host->base + PAD_DS_TUNE);
  2331. dev_info(host->dev, "Final PAD_DS_TUNE: 0x%x\n", val);
  2332. return 0;
  2333. fail:
  2334. dev_err(host->dev, "Failed to tuning DS pin delay!\n");
  2335. return -EIO;
  2336. }
  2337. static void msdc_hw_reset(struct mmc_host *mmc)
  2338. {
  2339. struct msdc_host *host = mmc_priv(mmc);
  2340. sdr_set_bits(host->base + EMMC_IOCON, 1);
  2341. udelay(10); /* 10us is enough */
  2342. sdr_clr_bits(host->base + EMMC_IOCON, 1);
  2343. }
  2344. static void msdc_ack_sdio_irq(struct mmc_host *mmc)
  2345. {
  2346. unsigned long flags;
  2347. struct msdc_host *host = mmc_priv(mmc);
  2348. spin_lock_irqsave(&host->lock, flags);
  2349. __msdc_enable_sdio_irq(host, 1);
  2350. spin_unlock_irqrestore(&host->lock, flags);
  2351. }
  2352. static int msdc_get_cd(struct mmc_host *mmc)
  2353. {
  2354. struct msdc_host *host = mmc_priv(mmc);
  2355. int val;
  2356. if (mmc->caps & MMC_CAP_NONREMOVABLE)
  2357. return 1;
  2358. if (!host->internal_cd)
  2359. return mmc_gpio_get_cd(mmc);
  2360. val = readl(host->base + MSDC_PS) & MSDC_PS_CDSTS;
  2361. if (mmc->caps2 & MMC_CAP2_CD_ACTIVE_HIGH)
  2362. return !!val;
  2363. else
  2364. return !val;
  2365. }
  2366. static void msdc_hs400_enhanced_strobe(struct mmc_host *mmc,
  2367. struct mmc_ios *ios)
  2368. {
  2369. struct msdc_host *host = mmc_priv(mmc);
  2370. if (ios->enhanced_strobe) {
  2371. msdc_prepare_hs400_tuning(mmc, ios);
  2372. sdr_set_field(host->base + EMMC50_CFG0, EMMC50_CFG_PADCMD_LATCHCK, 1);
  2373. sdr_set_field(host->base + EMMC50_CFG0, EMMC50_CFG_CMD_RESP_SEL, 1);
  2374. sdr_set_field(host->base + EMMC50_CFG1, EMMC50_CFG1_DS_CFG, 1);
  2375. sdr_clr_bits(host->base + CQHCI_SETTING, CQHCI_RD_CMD_WND_SEL);
  2376. sdr_clr_bits(host->base + CQHCI_SETTING, CQHCI_WR_CMD_WND_SEL);
  2377. sdr_clr_bits(host->base + EMMC51_CFG0, CMDQ_RDAT_CNT);
  2378. } else {
  2379. sdr_set_field(host->base + EMMC50_CFG0, EMMC50_CFG_PADCMD_LATCHCK, 0);
  2380. sdr_set_field(host->base + EMMC50_CFG0, EMMC50_CFG_CMD_RESP_SEL, 0);
  2381. sdr_set_field(host->base + EMMC50_CFG1, EMMC50_CFG1_DS_CFG, 0);
  2382. sdr_set_bits(host->base + CQHCI_SETTING, CQHCI_RD_CMD_WND_SEL);
  2383. sdr_set_bits(host->base + CQHCI_SETTING, CQHCI_WR_CMD_WND_SEL);
  2384. sdr_set_field(host->base + EMMC51_CFG0, CMDQ_RDAT_CNT, 0xb4);
  2385. }
  2386. }
  2387. static void msdc_cqe_cit_cal(struct msdc_host *host, u64 timer_ns)
  2388. {
  2389. struct mmc_host *mmc = mmc_from_priv(host);
  2390. struct cqhci_host *cq_host = mmc->cqe_private;
  2391. u8 itcfmul;
  2392. u64 hclk_freq, value;
  2393. /*
  2394. * On MediaTek SoCs the MSDC controller's CQE uses msdc_hclk as ITCFVAL
  2395. * so we multiply/divide the HCLK frequency by ITCFMUL to calculate the
  2396. * Send Status Command Idle Timer (CIT) value.
  2397. */
  2398. hclk_freq = (u64)clk_get_rate(host->h_clk);
  2399. itcfmul = CQHCI_ITCFMUL(cqhci_readl(cq_host, CQHCI_CAP));
  2400. switch (itcfmul) {
  2401. case 0x0:
  2402. do_div(hclk_freq, 1000);
  2403. break;
  2404. case 0x1:
  2405. do_div(hclk_freq, 100);
  2406. break;
  2407. case 0x2:
  2408. do_div(hclk_freq, 10);
  2409. break;
  2410. case 0x3:
  2411. break;
  2412. case 0x4:
  2413. hclk_freq = hclk_freq * 10;
  2414. break;
  2415. default:
  2416. host->cq_ssc1_time = 0x40;
  2417. return;
  2418. }
  2419. value = hclk_freq * timer_ns;
  2420. do_div(value, 1000000000);
  2421. host->cq_ssc1_time = value;
  2422. }
  2423. static void msdc_cqe_enable(struct mmc_host *mmc)
  2424. {
  2425. struct msdc_host *host = mmc_priv(mmc);
  2426. struct cqhci_host *cq_host = mmc->cqe_private;
  2427. /* enable cmdq irq */
  2428. writel(MSDC_INT_CMDQ, host->base + MSDC_INTEN);
  2429. /* enable busy check */
  2430. sdr_set_bits(host->base + MSDC_PATCH_BIT1, MSDC_PB1_BUSY_CHECK_SEL);
  2431. /* default write data / busy timeout 20s */
  2432. msdc_set_busy_timeout(host, 20 * 1000000000ULL, 0);
  2433. /* default read data timeout 1s */
  2434. msdc_set_timeout(host, 1000000000ULL, 0);
  2435. /* Set the send status command idle timer */
  2436. cqhci_writel(cq_host, host->cq_ssc1_time, CQHCI_SSC1);
  2437. }
  2438. static void msdc_cqe_disable(struct mmc_host *mmc, bool recovery)
  2439. {
  2440. struct msdc_host *host = mmc_priv(mmc);
  2441. unsigned int val = 0;
  2442. /* disable cmdq irq */
  2443. sdr_clr_bits(host->base + MSDC_INTEN, MSDC_INT_CMDQ);
  2444. /* disable busy check */
  2445. sdr_clr_bits(host->base + MSDC_PATCH_BIT1, MSDC_PB1_BUSY_CHECK_SEL);
  2446. val = readl(host->base + MSDC_INT);
  2447. writel(val, host->base + MSDC_INT);
  2448. if (recovery) {
  2449. sdr_set_field(host->base + MSDC_DMA_CTRL,
  2450. MSDC_DMA_CTRL_STOP, 1);
  2451. if (WARN_ON(readl_poll_timeout(host->base + MSDC_DMA_CTRL, val,
  2452. !(val & MSDC_DMA_CTRL_STOP), 1, 3000)))
  2453. return;
  2454. if (WARN_ON(readl_poll_timeout(host->base + MSDC_DMA_CFG, val,
  2455. !(val & MSDC_DMA_CFG_STS), 1, 3000)))
  2456. return;
  2457. msdc_reset_hw(host);
  2458. }
  2459. }
  2460. static void msdc_cqe_pre_enable(struct mmc_host *mmc)
  2461. {
  2462. struct cqhci_host *cq_host = mmc->cqe_private;
  2463. u32 reg;
  2464. reg = cqhci_readl(cq_host, CQHCI_CFG);
  2465. reg |= CQHCI_ENABLE;
  2466. cqhci_writel(cq_host, reg, CQHCI_CFG);
  2467. }
  2468. static void msdc_cqe_post_disable(struct mmc_host *mmc)
  2469. {
  2470. struct cqhci_host *cq_host = mmc->cqe_private;
  2471. u32 reg;
  2472. reg = cqhci_readl(cq_host, CQHCI_CFG);
  2473. reg &= ~CQHCI_ENABLE;
  2474. cqhci_writel(cq_host, reg, CQHCI_CFG);
  2475. }
  2476. static const struct mmc_host_ops mt_msdc_ops = {
  2477. .post_req = msdc_post_req,
  2478. .pre_req = msdc_pre_req,
  2479. .request = msdc_ops_request,
  2480. .set_ios = msdc_ops_set_ios,
  2481. .get_ro = mmc_gpio_get_ro,
  2482. .get_cd = msdc_get_cd,
  2483. .hs400_enhanced_strobe = msdc_hs400_enhanced_strobe,
  2484. .enable_sdio_irq = msdc_enable_sdio_irq,
  2485. .ack_sdio_irq = msdc_ack_sdio_irq,
  2486. .start_signal_voltage_switch = msdc_ops_switch_volt,
  2487. .card_busy = msdc_card_busy,
  2488. .execute_tuning = msdc_execute_tuning,
  2489. .prepare_hs400_tuning = msdc_prepare_hs400_tuning,
  2490. .execute_hs400_tuning = msdc_execute_hs400_tuning,
  2491. .card_hw_reset = msdc_hw_reset,
  2492. };
  2493. static const struct cqhci_host_ops msdc_cmdq_ops = {
  2494. .enable = msdc_cqe_enable,
  2495. .disable = msdc_cqe_disable,
  2496. .pre_enable = msdc_cqe_pre_enable,
  2497. .post_disable = msdc_cqe_post_disable,
  2498. };
  2499. static void msdc_of_property_parse(struct platform_device *pdev,
  2500. struct msdc_host *host)
  2501. {
  2502. struct mmc_host *mmc = mmc_from_priv(host);
  2503. of_property_read_u32(pdev->dev.of_node, "mediatek,latch-ck",
  2504. &host->latch_ck);
  2505. of_property_read_u32(pdev->dev.of_node, "hs400-ds-delay",
  2506. &host->hs400_ds_delay);
  2507. of_property_read_u32(pdev->dev.of_node, "mediatek,hs400-ds-dly3",
  2508. &host->hs400_ds_dly3);
  2509. of_property_read_u32(pdev->dev.of_node, "mediatek,hs200-cmd-int-delay",
  2510. &host->hs200_cmd_int_delay);
  2511. of_property_read_u32(pdev->dev.of_node, "mediatek,hs400-cmd-int-delay",
  2512. &host->hs400_cmd_int_delay);
  2513. if (of_property_read_bool(pdev->dev.of_node,
  2514. "mediatek,hs400-cmd-resp-sel-rising"))
  2515. host->hs400_cmd_resp_sel_rising = true;
  2516. else
  2517. host->hs400_cmd_resp_sel_rising = false;
  2518. if (of_property_read_u32(pdev->dev.of_node, "mediatek,tuning-step",
  2519. &host->tuning_step)) {
  2520. if (mmc->caps2 & MMC_CAP2_NO_MMC)
  2521. host->tuning_step = PAD_DELAY_FULL;
  2522. else
  2523. host->tuning_step = PAD_DELAY_HALF;
  2524. }
  2525. if (of_property_read_bool(pdev->dev.of_node,
  2526. "supports-cqe"))
  2527. host->cqhci = true;
  2528. else
  2529. host->cqhci = false;
  2530. }
  2531. static int msdc_of_clock_parse(struct platform_device *pdev,
  2532. struct msdc_host *host)
  2533. {
  2534. int ret;
  2535. host->src_clk = devm_clk_get(&pdev->dev, "source");
  2536. if (IS_ERR(host->src_clk))
  2537. return PTR_ERR(host->src_clk);
  2538. host->h_clk = devm_clk_get(&pdev->dev, "hclk");
  2539. if (IS_ERR(host->h_clk))
  2540. return PTR_ERR(host->h_clk);
  2541. host->bus_clk = devm_clk_get_optional(&pdev->dev, "bus_clk");
  2542. if (IS_ERR(host->bus_clk))
  2543. host->bus_clk = NULL;
  2544. /*source clock control gate is optional clock*/
  2545. host->src_clk_cg = devm_clk_get_optional(&pdev->dev, "source_cg");
  2546. if (IS_ERR(host->src_clk_cg))
  2547. return PTR_ERR(host->src_clk_cg);
  2548. /*
  2549. * Fallback for legacy device-trees: src_clk and HCLK use the same
  2550. * bit to control gating but they are parented to a different mux,
  2551. * hence if our intention is to gate only the source, required
  2552. * during a clk mode switch to avoid hw hangs, we need to gate
  2553. * its parent (specified as a different clock only on new DTs).
  2554. */
  2555. if (!host->src_clk_cg) {
  2556. host->src_clk_cg = clk_get_parent(host->src_clk);
  2557. if (IS_ERR(host->src_clk_cg))
  2558. return PTR_ERR(host->src_clk_cg);
  2559. }
  2560. /* If present, always enable for this clock gate */
  2561. host->sys_clk_cg = devm_clk_get_optional_enabled(&pdev->dev, "sys_cg");
  2562. if (IS_ERR(host->sys_clk_cg))
  2563. host->sys_clk_cg = NULL;
  2564. host->bulk_clks[0].id = "pclk_cg";
  2565. host->bulk_clks[1].id = "axi_cg";
  2566. host->bulk_clks[2].id = "ahb_cg";
  2567. ret = devm_clk_bulk_get_optional(&pdev->dev, MSDC_NR_CLOCKS,
  2568. host->bulk_clks);
  2569. if (ret) {
  2570. dev_err(&pdev->dev, "Cannot get pclk/axi/ahb clock gates\n");
  2571. return ret;
  2572. }
  2573. return 0;
  2574. }
  2575. static int msdc_drv_probe(struct platform_device *pdev)
  2576. {
  2577. struct mmc_host *mmc;
  2578. struct msdc_host *host;
  2579. int ret;
  2580. if (!pdev->dev.of_node) {
  2581. dev_err(&pdev->dev, "No DT found\n");
  2582. return -EINVAL;
  2583. }
  2584. /* Allocate MMC host for this device */
  2585. mmc = devm_mmc_alloc_host(&pdev->dev, sizeof(struct msdc_host));
  2586. if (!mmc)
  2587. return -ENOMEM;
  2588. host = mmc_priv(mmc);
  2589. ret = mmc_of_parse(mmc);
  2590. if (ret)
  2591. return ret;
  2592. host->base = devm_platform_ioremap_resource(pdev, 0);
  2593. if (IS_ERR(host->base))
  2594. return PTR_ERR(host->base);
  2595. host->dev_comp = of_device_get_match_data(&pdev->dev);
  2596. if (host->dev_comp->needs_top_base) {
  2597. host->top_base = devm_platform_ioremap_resource(pdev, 1);
  2598. if (IS_ERR(host->top_base))
  2599. return PTR_ERR(host->top_base);
  2600. }
  2601. ret = mmc_regulator_get_supply(mmc);
  2602. if (ret)
  2603. return ret;
  2604. ret = msdc_of_clock_parse(pdev, host);
  2605. if (ret)
  2606. return ret;
  2607. host->reset = devm_reset_control_get_optional_exclusive(&pdev->dev,
  2608. "hrst");
  2609. if (IS_ERR(host->reset))
  2610. return PTR_ERR(host->reset);
  2611. /* only eMMC has crypto property */
  2612. if (!(mmc->caps2 & MMC_CAP2_NO_MMC)) {
  2613. host->crypto_clk = devm_clk_get_optional(&pdev->dev, "crypto");
  2614. if (IS_ERR(host->crypto_clk))
  2615. return PTR_ERR(host->crypto_clk);
  2616. else if (host->crypto_clk)
  2617. mmc->caps2 |= MMC_CAP2_CRYPTO;
  2618. }
  2619. host->irq = platform_get_irq(pdev, 0);
  2620. if (host->irq < 0)
  2621. return host->irq;
  2622. host->pinctrl = devm_pinctrl_get(&pdev->dev);
  2623. if (IS_ERR(host->pinctrl))
  2624. return dev_err_probe(&pdev->dev, PTR_ERR(host->pinctrl),
  2625. "Cannot find pinctrl");
  2626. host->pins_default = pinctrl_lookup_state(host->pinctrl, "default");
  2627. if (IS_ERR(host->pins_default)) {
  2628. dev_err(&pdev->dev, "Cannot find pinctrl default!\n");
  2629. return PTR_ERR(host->pins_default);
  2630. }
  2631. host->pins_uhs = pinctrl_lookup_state(host->pinctrl, "state_uhs");
  2632. if (IS_ERR(host->pins_uhs)) {
  2633. dev_err(&pdev->dev, "Cannot find pinctrl uhs!\n");
  2634. return PTR_ERR(host->pins_uhs);
  2635. }
  2636. /* Support for SDIO eint irq ? */
  2637. if ((mmc->pm_caps & MMC_PM_WAKE_SDIO_IRQ) && (mmc->pm_caps & MMC_PM_KEEP_POWER)) {
  2638. host->eint_irq = platform_get_irq_byname_optional(pdev, "sdio_wakeup");
  2639. if (host->eint_irq > 0) {
  2640. host->pins_eint = pinctrl_lookup_state(host->pinctrl, "state_eint");
  2641. if (IS_ERR(host->pins_eint)) {
  2642. dev_err(&pdev->dev, "Cannot find pinctrl eint!\n");
  2643. host->pins_eint = NULL;
  2644. } else {
  2645. device_init_wakeup(&pdev->dev, true);
  2646. }
  2647. }
  2648. }
  2649. msdc_of_property_parse(pdev, host);
  2650. host->dev = &pdev->dev;
  2651. host->src_clk_freq = clk_get_rate(host->src_clk);
  2652. /* Set host parameters to mmc */
  2653. mmc->ops = &mt_msdc_ops;
  2654. if (host->dev_comp->clk_div_bits == 8)
  2655. mmc->f_min = DIV_ROUND_UP(host->src_clk_freq, 4 * 255);
  2656. else
  2657. mmc->f_min = DIV_ROUND_UP(host->src_clk_freq, 4 * 4095);
  2658. if (!(mmc->caps & MMC_CAP_NONREMOVABLE) &&
  2659. !mmc_host_can_gpio_cd(mmc) &&
  2660. host->dev_comp->use_internal_cd) {
  2661. /*
  2662. * Is removable but no GPIO declared, so
  2663. * use internal functionality.
  2664. */
  2665. host->internal_cd = true;
  2666. }
  2667. if (mmc->caps & MMC_CAP_SDIO_IRQ)
  2668. mmc->caps2 |= MMC_CAP2_SDIO_IRQ_NOTHREAD;
  2669. mmc->caps |= MMC_CAP_CMD23;
  2670. if (host->cqhci)
  2671. mmc->caps2 |= MMC_CAP2_CQE | MMC_CAP2_CQE_DCMD;
  2672. /* MMC core transfer sizes tunable parameters */
  2673. mmc->max_segs = MAX_BD_NUM;
  2674. if (host->dev_comp->support_64g)
  2675. mmc->max_seg_size = BDMA_DESC_BUFLEN_EXT;
  2676. else
  2677. mmc->max_seg_size = BDMA_DESC_BUFLEN;
  2678. mmc->max_blk_size = 2048;
  2679. mmc->max_req_size = 512 * 1024;
  2680. mmc->max_blk_count = mmc->max_req_size / 512;
  2681. if (host->dev_comp->support_64g)
  2682. host->dma_mask = DMA_BIT_MASK(36);
  2683. else
  2684. host->dma_mask = DMA_BIT_MASK(32);
  2685. mmc_dev(mmc)->dma_mask = &host->dma_mask;
  2686. host->timeout_clks = 3 * 1048576;
  2687. host->dma.gpd = dma_alloc_coherent(&pdev->dev,
  2688. 2 * sizeof(struct mt_gpdma_desc),
  2689. &host->dma.gpd_addr, GFP_KERNEL);
  2690. host->dma.bd = dma_alloc_coherent(&pdev->dev,
  2691. MAX_BD_NUM * sizeof(struct mt_bdma_desc),
  2692. &host->dma.bd_addr, GFP_KERNEL);
  2693. if (!host->dma.gpd || !host->dma.bd) {
  2694. ret = -ENOMEM;
  2695. goto release_mem;
  2696. }
  2697. msdc_init_gpd_bd(host, &host->dma);
  2698. INIT_DELAYED_WORK(&host->req_timeout, msdc_request_timeout);
  2699. spin_lock_init(&host->lock);
  2700. platform_set_drvdata(pdev, mmc);
  2701. ret = msdc_ungate_clock(host);
  2702. if (ret) {
  2703. dev_err(&pdev->dev, "Cannot ungate clocks!\n");
  2704. goto release_clk;
  2705. }
  2706. msdc_init_hw(host);
  2707. if (mmc->caps2 & MMC_CAP2_CQE) {
  2708. host->cq_host = devm_kzalloc(mmc->parent,
  2709. sizeof(*host->cq_host),
  2710. GFP_KERNEL);
  2711. if (!host->cq_host) {
  2712. ret = -ENOMEM;
  2713. goto release;
  2714. }
  2715. host->cq_host->caps |= CQHCI_TASK_DESC_SZ_128;
  2716. host->cq_host->mmio = host->base + 0x800;
  2717. host->cq_host->ops = &msdc_cmdq_ops;
  2718. ret = cqhci_init(host->cq_host, mmc, true);
  2719. if (ret)
  2720. goto release;
  2721. mmc->max_segs = 128;
  2722. /* cqhci 16bit length */
  2723. /* 0 size, means 65536 so we don't have to -1 here */
  2724. mmc->max_seg_size = 64 * 1024;
  2725. /* Reduce CIT to 0x40 that corresponds to 2.35us */
  2726. msdc_cqe_cit_cal(host, 2350);
  2727. } else if (mmc->caps2 & MMC_CAP2_NO_SDIO) {
  2728. /* Use HSQ on eMMC/SD (but not on SDIO) if HW CQE not supported */
  2729. struct mmc_hsq *hsq = devm_kzalloc(&pdev->dev, sizeof(*hsq), GFP_KERNEL);
  2730. if (!hsq) {
  2731. ret = -ENOMEM;
  2732. goto release;
  2733. }
  2734. ret = mmc_hsq_init(hsq, mmc);
  2735. if (ret)
  2736. goto release;
  2737. host->hsq_en = true;
  2738. }
  2739. ret = devm_request_irq(&pdev->dev, host->irq, msdc_irq,
  2740. IRQF_TRIGGER_NONE, pdev->name, host);
  2741. if (ret)
  2742. goto release;
  2743. pm_runtime_set_active(host->dev);
  2744. pm_runtime_set_autosuspend_delay(host->dev, MTK_MMC_AUTOSUSPEND_DELAY);
  2745. pm_runtime_use_autosuspend(host->dev);
  2746. pm_runtime_enable(host->dev);
  2747. ret = mmc_add_host(mmc);
  2748. if (ret)
  2749. goto end;
  2750. return 0;
  2751. end:
  2752. pm_runtime_disable(host->dev);
  2753. release:
  2754. msdc_deinit_hw(host);
  2755. release_clk:
  2756. msdc_gate_clock(host);
  2757. platform_set_drvdata(pdev, NULL);
  2758. release_mem:
  2759. device_init_wakeup(&pdev->dev, false);
  2760. if (host->dma.gpd)
  2761. dma_free_coherent(&pdev->dev,
  2762. 2 * sizeof(struct mt_gpdma_desc),
  2763. host->dma.gpd, host->dma.gpd_addr);
  2764. if (host->dma.bd)
  2765. dma_free_coherent(&pdev->dev,
  2766. MAX_BD_NUM * sizeof(struct mt_bdma_desc),
  2767. host->dma.bd, host->dma.bd_addr);
  2768. return ret;
  2769. }
  2770. static void msdc_drv_remove(struct platform_device *pdev)
  2771. {
  2772. struct mmc_host *mmc;
  2773. struct msdc_host *host;
  2774. mmc = platform_get_drvdata(pdev);
  2775. host = mmc_priv(mmc);
  2776. pm_runtime_get_sync(host->dev);
  2777. platform_set_drvdata(pdev, NULL);
  2778. mmc_remove_host(mmc);
  2779. msdc_deinit_hw(host);
  2780. msdc_gate_clock(host);
  2781. pm_runtime_disable(host->dev);
  2782. pm_runtime_put_noidle(host->dev);
  2783. dma_free_coherent(&pdev->dev,
  2784. 2 * sizeof(struct mt_gpdma_desc),
  2785. host->dma.gpd, host->dma.gpd_addr);
  2786. dma_free_coherent(&pdev->dev, MAX_BD_NUM * sizeof(struct mt_bdma_desc),
  2787. host->dma.bd, host->dma.bd_addr);
  2788. device_init_wakeup(&pdev->dev, false);
  2789. }
  2790. static void msdc_save_reg(struct msdc_host *host)
  2791. {
  2792. u32 tune_reg = host->dev_comp->pad_tune_reg;
  2793. host->save_para.msdc_cfg = readl(host->base + MSDC_CFG);
  2794. host->save_para.iocon = readl(host->base + MSDC_IOCON);
  2795. host->save_para.sdc_cfg = readl(host->base + SDC_CFG);
  2796. host->save_para.patch_bit0 = readl(host->base + MSDC_PATCH_BIT);
  2797. host->save_para.patch_bit1 = readl(host->base + MSDC_PATCH_BIT1);
  2798. host->save_para.patch_bit2 = readl(host->base + MSDC_PATCH_BIT2);
  2799. host->save_para.pad_ds_tune = readl(host->base + PAD_DS_TUNE);
  2800. host->save_para.pad_cmd_tune = readl(host->base + PAD_CMD_TUNE);
  2801. host->save_para.emmc50_cfg0 = readl(host->base + EMMC50_CFG0);
  2802. host->save_para.emmc50_cfg3 = readl(host->base + EMMC50_CFG3);
  2803. host->save_para.sdc_fifo_cfg = readl(host->base + SDC_FIFO_CFG);
  2804. if (host->top_base) {
  2805. host->save_para.emmc_top_control =
  2806. readl(host->top_base + EMMC_TOP_CONTROL);
  2807. host->save_para.emmc_top_cmd =
  2808. readl(host->top_base + EMMC_TOP_CMD);
  2809. host->save_para.emmc50_pad_ds_tune =
  2810. readl(host->top_base + EMMC50_PAD_DS_TUNE);
  2811. host->save_para.loop_test_control =
  2812. readl(host->top_base + LOOP_TEST_CONTROL);
  2813. } else {
  2814. host->save_para.pad_tune = readl(host->base + tune_reg);
  2815. }
  2816. }
  2817. static void msdc_restore_reg(struct msdc_host *host)
  2818. {
  2819. struct mmc_host *mmc = mmc_from_priv(host);
  2820. u32 tune_reg = host->dev_comp->pad_tune_reg;
  2821. if (host->dev_comp->support_new_tx) {
  2822. sdr_clr_bits(host->base + SDC_ADV_CFG0, SDC_NEW_TX_EN);
  2823. sdr_set_bits(host->base + SDC_ADV_CFG0, SDC_NEW_TX_EN);
  2824. }
  2825. if (host->dev_comp->support_new_rx) {
  2826. sdr_clr_bits(host->base + MSDC_NEW_RX_CFG, MSDC_NEW_RX_PATH_SEL);
  2827. sdr_set_bits(host->base + MSDC_NEW_RX_CFG, MSDC_NEW_RX_PATH_SEL);
  2828. }
  2829. writel(host->save_para.msdc_cfg, host->base + MSDC_CFG);
  2830. writel(host->save_para.iocon, host->base + MSDC_IOCON);
  2831. writel(host->save_para.sdc_cfg, host->base + SDC_CFG);
  2832. writel(host->save_para.patch_bit0, host->base + MSDC_PATCH_BIT);
  2833. writel(host->save_para.patch_bit1, host->base + MSDC_PATCH_BIT1);
  2834. writel(host->save_para.patch_bit2, host->base + MSDC_PATCH_BIT2);
  2835. writel(host->save_para.pad_ds_tune, host->base + PAD_DS_TUNE);
  2836. writel(host->save_para.pad_cmd_tune, host->base + PAD_CMD_TUNE);
  2837. writel(host->save_para.emmc50_cfg0, host->base + EMMC50_CFG0);
  2838. writel(host->save_para.emmc50_cfg3, host->base + EMMC50_CFG3);
  2839. writel(host->save_para.sdc_fifo_cfg, host->base + SDC_FIFO_CFG);
  2840. if (host->top_base) {
  2841. writel(host->save_para.emmc_top_control,
  2842. host->top_base + EMMC_TOP_CONTROL);
  2843. writel(host->save_para.emmc_top_cmd,
  2844. host->top_base + EMMC_TOP_CMD);
  2845. writel(host->save_para.emmc50_pad_ds_tune,
  2846. host->top_base + EMMC50_PAD_DS_TUNE);
  2847. writel(host->save_para.loop_test_control,
  2848. host->top_base + LOOP_TEST_CONTROL);
  2849. } else {
  2850. writel(host->save_para.pad_tune, host->base + tune_reg);
  2851. }
  2852. if (sdio_irq_claimed(mmc))
  2853. __msdc_enable_sdio_irq(host, 1);
  2854. }
  2855. static int msdc_runtime_suspend(struct device *dev)
  2856. {
  2857. struct mmc_host *mmc = dev_get_drvdata(dev);
  2858. struct msdc_host *host = mmc_priv(mmc);
  2859. if (host->hsq_en)
  2860. mmc_hsq_suspend(mmc);
  2861. msdc_save_reg(host);
  2862. if (sdio_irq_claimed(mmc)) {
  2863. if (host->pins_eint) {
  2864. disable_irq(host->irq);
  2865. pinctrl_select_state(host->pinctrl, host->pins_eint);
  2866. }
  2867. __msdc_enable_sdio_irq(host, 0);
  2868. }
  2869. msdc_gate_clock(host);
  2870. return 0;
  2871. }
  2872. static int msdc_runtime_resume(struct device *dev)
  2873. {
  2874. struct mmc_host *mmc = dev_get_drvdata(dev);
  2875. struct msdc_host *host = mmc_priv(mmc);
  2876. int ret;
  2877. ret = msdc_ungate_clock(host);
  2878. if (ret)
  2879. return ret;
  2880. msdc_restore_reg(host);
  2881. if (sdio_irq_claimed(mmc) && host->pins_eint) {
  2882. pinctrl_select_state(host->pinctrl, host->pins_uhs);
  2883. enable_irq(host->irq);
  2884. }
  2885. if (host->hsq_en)
  2886. mmc_hsq_resume(mmc);
  2887. return 0;
  2888. }
  2889. static int msdc_suspend(struct device *dev)
  2890. {
  2891. struct mmc_host *mmc = dev_get_drvdata(dev);
  2892. struct msdc_host *host = mmc_priv(mmc);
  2893. int ret;
  2894. u32 val;
  2895. if (mmc->caps2 & MMC_CAP2_CQE) {
  2896. ret = cqhci_suspend(mmc);
  2897. if (ret)
  2898. return ret;
  2899. val = readl(host->base + MSDC_INT);
  2900. writel(val, host->base + MSDC_INT);
  2901. }
  2902. /*
  2903. * Bump up runtime PM usage counter otherwise dev->power.needs_force_resume will
  2904. * not be marked as 1, pm_runtime_force_resume() will go out directly.
  2905. */
  2906. if (sdio_irq_claimed(mmc) && host->pins_eint)
  2907. pm_runtime_get_noresume(dev);
  2908. return pm_runtime_force_suspend(dev);
  2909. }
  2910. static int msdc_resume(struct device *dev)
  2911. {
  2912. struct mmc_host *mmc = dev_get_drvdata(dev);
  2913. struct msdc_host *host = mmc_priv(mmc);
  2914. if (sdio_irq_claimed(mmc) && host->pins_eint)
  2915. pm_runtime_put_noidle(dev);
  2916. return pm_runtime_force_resume(dev);
  2917. }
  2918. static const struct dev_pm_ops msdc_dev_pm_ops = {
  2919. SYSTEM_SLEEP_PM_OPS(msdc_suspend, msdc_resume)
  2920. RUNTIME_PM_OPS(msdc_runtime_suspend, msdc_runtime_resume, NULL)
  2921. };
  2922. static struct platform_driver mt_msdc_driver = {
  2923. .probe = msdc_drv_probe,
  2924. .remove = msdc_drv_remove,
  2925. .driver = {
  2926. .name = "mtk-msdc",
  2927. .probe_type = PROBE_PREFER_ASYNCHRONOUS,
  2928. .of_match_table = msdc_of_ids,
  2929. .pm = pm_ptr(&msdc_dev_pm_ops),
  2930. },
  2931. };
  2932. module_platform_driver(mt_msdc_driver);
  2933. MODULE_LICENSE("GPL v2");
  2934. MODULE_DESCRIPTION("MediaTek SD/MMC Card Driver");