rcar_canfd.c 67 KB

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  1. // SPDX-License-Identifier: GPL-2.0+
  2. /* Renesas R-Car CAN FD device driver
  3. *
  4. * Copyright (C) 2015 Renesas Electronics Corp.
  5. */
  6. /* The R-Car CAN FD controller can operate in either one of the below two modes
  7. * - CAN FD only mode
  8. * - Classical CAN (CAN 2.0) only mode
  9. *
  10. * This driver puts the controller in CAN FD only mode by default. In this
  11. * mode, the controller acts as a CAN FD node that can also interoperate with
  12. * CAN 2.0 nodes.
  13. *
  14. * To switch the controller to Classical CAN (CAN 2.0) only mode, add
  15. * "renesas,no-can-fd" optional property to the device tree node. A h/w reset is
  16. * also required to switch modes.
  17. *
  18. * Note: The h/w manual register naming convention is clumsy and not acceptable
  19. * to use as it is in the driver. However, those names are added as comments
  20. * wherever it is modified to a readable name.
  21. */
  22. #include <linux/bitfield.h>
  23. #include <linux/bitmap.h>
  24. #include <linux/bitops.h>
  25. #include <linux/can/dev.h>
  26. #include <linux/clk.h>
  27. #include <linux/errno.h>
  28. #include <linux/ethtool.h>
  29. #include <linux/interrupt.h>
  30. #include <linux/iopoll.h>
  31. #include <linux/kernel.h>
  32. #include <linux/module.h>
  33. #include <linux/moduleparam.h>
  34. #include <linux/netdevice.h>
  35. #include <linux/of.h>
  36. #include <linux/phy/phy.h>
  37. #include <linux/platform_device.h>
  38. #include <linux/reset.h>
  39. #include <linux/types.h>
  40. #define RCANFD_DRV_NAME "rcar_canfd"
  41. /* Global register bits */
  42. /* RSCFDnCFDGRMCFG */
  43. #define RCANFD_GRMCFG_RCMC BIT(0)
  44. /* RSCFDnCFDGCFG / RSCFDnGCFG */
  45. #define RCANFD_GCFG_EEFE BIT(6)
  46. #define RCANFD_GCFG_CMPOC BIT(5) /* CAN FD only */
  47. #define RCANFD_GCFG_DCS BIT(4)
  48. #define RCANFD_GCFG_DCE BIT(1)
  49. #define RCANFD_GCFG_TPRI BIT(0)
  50. /* RSCFDnCFDGCTR / RSCFDnGCTR */
  51. #define RCANFD_GCTR_TSRST BIT(16)
  52. #define RCANFD_GCTR_CFMPOFIE BIT(11) /* CAN FD only */
  53. #define RCANFD_GCTR_THLEIE BIT(10)
  54. #define RCANFD_GCTR_MEIE BIT(9)
  55. #define RCANFD_GCTR_DEIE BIT(8)
  56. #define RCANFD_GCTR_GSLPR BIT(2)
  57. #define RCANFD_GCTR_GMDC_MASK (0x3)
  58. #define RCANFD_GCTR_GMDC_GOPM (0x0)
  59. #define RCANFD_GCTR_GMDC_GRESET (0x1)
  60. #define RCANFD_GCTR_GMDC_GTEST (0x2)
  61. /* RSCFDnCFDGSTS / RSCFDnGSTS */
  62. #define RCANFD_GSTS_GRAMINIT BIT(3)
  63. #define RCANFD_GSTS_GSLPSTS BIT(2)
  64. #define RCANFD_GSTS_GHLTSTS BIT(1)
  65. #define RCANFD_GSTS_GRSTSTS BIT(0)
  66. /* Non-operational status */
  67. #define RCANFD_GSTS_GNOPM (BIT(0) | BIT(1) | BIT(2) | BIT(3))
  68. /* RSCFDnCFDGERFL / RSCFDnGERFL */
  69. #define RCANFD_GERFL_EEF GENMASK(23, 16)
  70. #define RCANFD_GERFL_CMPOF BIT(3) /* CAN FD only */
  71. #define RCANFD_GERFL_THLES BIT(2)
  72. #define RCANFD_GERFL_MES BIT(1)
  73. #define RCANFD_GERFL_DEF BIT(0)
  74. #define RCANFD_GERFL_ERR(gpriv, x) \
  75. ({\
  76. typeof(gpriv) (_gpriv) = (gpriv); \
  77. ((x) & ((FIELD_PREP(RCANFD_GERFL_EEF, (_gpriv)->channels_mask)) | \
  78. RCANFD_GERFL_MES | ((_gpriv)->fdmode ? RCANFD_GERFL_CMPOF : 0))); \
  79. })
  80. /* AFL Rx rules registers */
  81. /* RSCFDnCFDGAFLECTR / RSCFDnGAFLECTR */
  82. #define RCANFD_GAFLECTR_AFLDAE BIT(8)
  83. #define RCANFD_GAFLECTR_AFLPN(gpriv, page_num) ((page_num) & (gpriv)->info->max_aflpn)
  84. /* RSCFDnCFDGAFLIDj / RSCFDnGAFLIDj */
  85. #define RCANFD_GAFLID_GAFLLB BIT(29)
  86. /* RSCFDnCFDGAFLP1_j / RSCFDnGAFLP1_j */
  87. #define RCANFD_GAFLP1_GAFLFDP(x) (1 << (x))
  88. /* Channel register bits */
  89. /* RSCFDnCmCFG - Classical CAN only */
  90. #define RCANFD_CFG_SJW GENMASK(25, 24)
  91. #define RCANFD_CFG_TSEG2 GENMASK(22, 20)
  92. #define RCANFD_CFG_TSEG1 GENMASK(19, 16)
  93. #define RCANFD_CFG_BRP GENMASK(9, 0)
  94. /* RSCFDnCFDCmNCFG - CAN FD only */
  95. #define RCANFD_NCFG_NBRP GENMASK(9, 0)
  96. /* RSCFDnCFDCmCTR / RSCFDnCmCTR */
  97. #define RCANFD_CCTR_CTME BIT(24)
  98. #define RCANFD_CCTR_ERRD BIT(23)
  99. #define RCANFD_CCTR_BOM_MASK (0x3 << 21)
  100. #define RCANFD_CCTR_BOM_ISO (0x0 << 21)
  101. #define RCANFD_CCTR_BOM_BENTRY (0x1 << 21)
  102. #define RCANFD_CCTR_BOM_BEND (0x2 << 21)
  103. #define RCANFD_CCTR_TDCVFIE BIT(19)
  104. #define RCANFD_CCTR_SOCOIE BIT(18)
  105. #define RCANFD_CCTR_EOCOIE BIT(17)
  106. #define RCANFD_CCTR_TAIE BIT(16)
  107. #define RCANFD_CCTR_ALIE BIT(15)
  108. #define RCANFD_CCTR_BLIE BIT(14)
  109. #define RCANFD_CCTR_OLIE BIT(13)
  110. #define RCANFD_CCTR_BORIE BIT(12)
  111. #define RCANFD_CCTR_BOEIE BIT(11)
  112. #define RCANFD_CCTR_EPIE BIT(10)
  113. #define RCANFD_CCTR_EWIE BIT(9)
  114. #define RCANFD_CCTR_BEIE BIT(8)
  115. #define RCANFD_CCTR_CSLPR BIT(2)
  116. #define RCANFD_CCTR_CHMDC_MASK (0x3)
  117. #define RCANFD_CCTR_CHDMC_COPM (0x0)
  118. #define RCANFD_CCTR_CHDMC_CRESET (0x1)
  119. #define RCANFD_CCTR_CHDMC_CHLT (0x2)
  120. /* RSCFDnCFDCmSTS / RSCFDnCmSTS */
  121. #define RCANFD_CSTS_COMSTS BIT(7)
  122. #define RCANFD_CSTS_RECSTS BIT(6)
  123. #define RCANFD_CSTS_TRMSTS BIT(5)
  124. #define RCANFD_CSTS_BOSTS BIT(4)
  125. #define RCANFD_CSTS_EPSTS BIT(3)
  126. #define RCANFD_CSTS_SLPSTS BIT(2)
  127. #define RCANFD_CSTS_HLTSTS BIT(1)
  128. #define RCANFD_CSTS_CRSTSTS BIT(0)
  129. #define RCANFD_CSTS_TECCNT(x) (((x) >> 24) & 0xff)
  130. #define RCANFD_CSTS_RECCNT(x) (((x) >> 16) & 0xff)
  131. /* RSCFDnCFDCmERFL / RSCFDnCmERFL */
  132. #define RCANFD_CERFL_ADERR BIT(14)
  133. #define RCANFD_CERFL_B0ERR BIT(13)
  134. #define RCANFD_CERFL_B1ERR BIT(12)
  135. #define RCANFD_CERFL_CERR BIT(11)
  136. #define RCANFD_CERFL_AERR BIT(10)
  137. #define RCANFD_CERFL_FERR BIT(9)
  138. #define RCANFD_CERFL_SERR BIT(8)
  139. #define RCANFD_CERFL_ALF BIT(7)
  140. #define RCANFD_CERFL_BLF BIT(6)
  141. #define RCANFD_CERFL_OVLF BIT(5)
  142. #define RCANFD_CERFL_BORF BIT(4)
  143. #define RCANFD_CERFL_BOEF BIT(3)
  144. #define RCANFD_CERFL_EPF BIT(2)
  145. #define RCANFD_CERFL_EWF BIT(1)
  146. #define RCANFD_CERFL_BEF BIT(0)
  147. #define RCANFD_CERFL_ERR(x) ((x) & (0x7fff)) /* above bits 14:0 */
  148. /* RSCFDnCFDCmDCFG */
  149. #define RCANFD_DCFG_DBRP GENMASK(7, 0)
  150. /* RSCFDnCFDCmFDCFG */
  151. #define RCANFD_GEN4_FDCFG_CLOE BIT(30)
  152. #define RCANFD_GEN4_FDCFG_FDOE BIT(28)
  153. #define RCANFD_FDCFG_TDCO GENMASK(23, 16)
  154. #define RCANFD_FDCFG_TDCE BIT(9)
  155. #define RCANFD_FDCFG_TDCOC BIT(8)
  156. /* RSCFDnCFDCmFDSTS */
  157. #define RCANFD_FDSTS_SOC GENMASK(31, 24)
  158. #define RCANFD_FDSTS_EOC GENMASK(23, 16)
  159. #define RCANFD_GEN4_FDSTS_TDCVF BIT(15)
  160. #define RCANFD_GEN4_FDSTS_PNSTS GENMASK(13, 12)
  161. #define RCANFD_FDSTS_SOCO BIT(9)
  162. #define RCANFD_FDSTS_EOCO BIT(8)
  163. #define RCANFD_FDSTS_TDCVF BIT(7)
  164. #define RCANFD_FDSTS_TDCR GENMASK(7, 0)
  165. /* RSCFDnCFDRFCCx */
  166. #define RCANFD_RFCC_RFIM BIT(12)
  167. #define RCANFD_RFCC_RFDC(x) (((x) & 0x7) << 8)
  168. #define RCANFD_RFCC_RFPLS(x) (((x) & 0x7) << 4)
  169. #define RCANFD_RFCC_RFIE BIT(1)
  170. #define RCANFD_RFCC_RFE BIT(0)
  171. /* RSCFDnCFDRFSTSx */
  172. #define RCANFD_RFSTS_RFIF BIT(3)
  173. #define RCANFD_RFSTS_RFMLT BIT(2)
  174. #define RCANFD_RFSTS_RFFLL BIT(1)
  175. #define RCANFD_RFSTS_RFEMP BIT(0)
  176. /* RSCFDnCFDRFIDx */
  177. #define RCANFD_RFID_RFIDE BIT(31)
  178. #define RCANFD_RFID_RFRTR BIT(30)
  179. /* RSCFDnCFDRFPTRx */
  180. #define RCANFD_RFPTR_RFDLC(x) (((x) >> 28) & 0xf)
  181. /* RSCFDnCFDRFFDSTSx */
  182. #define RCANFD_RFFDSTS_RFFDF BIT(2)
  183. #define RCANFD_RFFDSTS_RFBRS BIT(1)
  184. #define RCANFD_RFFDSTS_RFESI BIT(0)
  185. /* Common FIFO bits */
  186. /* RSCFDnCFDCFCCk */
  187. #define RCANFD_CFCC_CFTML(gpriv, cftml) \
  188. ({\
  189. typeof(gpriv) (_gpriv) = (gpriv); \
  190. (((cftml) & (_gpriv)->info->max_cftml) << (_gpriv)->info->sh->cftml); \
  191. })
  192. #define RCANFD_CFCC_CFM(gpriv, x) (((x) & 0x3) << (gpriv)->info->sh->cfm)
  193. #define RCANFD_CFCC_CFIM BIT(12)
  194. #define RCANFD_CFCC_CFDC(gpriv, x) (((x) & 0x7) << (gpriv)->info->sh->cfdc)
  195. #define RCANFD_CFCC_CFPLS(x) (((x) & 0x7) << 4)
  196. #define RCANFD_CFCC_CFTXIE BIT(2)
  197. #define RCANFD_CFCC_CFE BIT(0)
  198. /* RSCFDnCFDCFSTSk */
  199. #define RCANFD_CFSTS_CFMC(x) (((x) >> 8) & 0xff)
  200. #define RCANFD_CFSTS_CFTXIF BIT(4)
  201. #define RCANFD_CFSTS_CFMLT BIT(2)
  202. #define RCANFD_CFSTS_CFFLL BIT(1)
  203. #define RCANFD_CFSTS_CFEMP BIT(0)
  204. /* RSCFDnCFDCFIDk */
  205. #define RCANFD_CFID_CFIDE BIT(31)
  206. #define RCANFD_CFID_CFRTR BIT(30)
  207. /* RSCFDnCFDCFPTRk */
  208. #define RCANFD_CFPTR_CFDLC(x) (((x) & 0xf) << 28)
  209. /* RSCFDnCFDCFFDCSTSk */
  210. #define RCANFD_CFFDCSTS_CFFDF BIT(2)
  211. #define RCANFD_CFFDCSTS_CFBRS BIT(1)
  212. #define RCANFD_CFFDCSTS_CFESI BIT(0)
  213. /* This controller supports either Classical CAN only mode or CAN FD only mode.
  214. * These modes are supported in two separate set of register maps & names.
  215. * However, some of the register offsets are common for both modes. Those
  216. * offsets are listed below as Common registers.
  217. *
  218. * The CAN FD only mode specific registers & Classical CAN only mode specific
  219. * registers are listed separately. Their register names starts with
  220. * RCANFD_F_xxx & RCANFD_C_xxx respectively.
  221. */
  222. /* Common registers */
  223. /* RSCFDnCFDCmNCFG / RSCFDnCmCFG */
  224. #define RCANFD_CCFG(m) (0x0000 + (0x10 * (m)))
  225. /* RSCFDnCFDCmCTR / RSCFDnCmCTR */
  226. #define RCANFD_CCTR(m) (0x0004 + (0x10 * (m)))
  227. /* RSCFDnCFDCmSTS / RSCFDnCmSTS */
  228. #define RCANFD_CSTS(m) (0x0008 + (0x10 * (m)))
  229. /* RSCFDnCFDCmERFL / RSCFDnCmERFL */
  230. #define RCANFD_CERFL(m) (0x000C + (0x10 * (m)))
  231. /* RSCFDnCFDGCFG / RSCFDnGCFG */
  232. #define RCANFD_GCFG (0x0084)
  233. /* RSCFDnCFDGCTR / RSCFDnGCTR */
  234. #define RCANFD_GCTR (0x0088)
  235. /* RSCFDnCFDGCTS / RSCFDnGCTS */
  236. #define RCANFD_GSTS (0x008c)
  237. /* RSCFDnCFDGERFL / RSCFDnGERFL */
  238. #define RCANFD_GERFL (0x0090)
  239. /* RSCFDnCFDGTSC / RSCFDnGTSC */
  240. #define RCANFD_GTSC (0x0094)
  241. /* RSCFDnCFDGAFLECTR / RSCFDnGAFLECTR */
  242. #define RCANFD_GAFLECTR (0x0098)
  243. /* RSCFDnCFDGAFLCFG / RSCFDnGAFLCFG */
  244. #define RCANFD_GAFLCFG(w) (0x009c + (0x04 * (w)))
  245. /* RSCFDnCFDRMNB / RSCFDnRMNB */
  246. #define RCANFD_RMNB (0x00a4)
  247. /* RSCFDnCFDRMND / RSCFDnRMND */
  248. #define RCANFD_RMND(y) (0x00a8 + (0x04 * (y)))
  249. /* RSCFDnCFDRFCCx / RSCFDnRFCCx */
  250. #define RCANFD_RFCC(gpriv, x) ((gpriv)->info->regs->rfcc + (0x04 * (x)))
  251. /* RSCFDnCFDRFSTSx / RSCFDnRFSTSx */
  252. #define RCANFD_RFSTS(gpriv, x) (RCANFD_RFCC(gpriv, x) + 0x20)
  253. /* RSCFDnCFDRFPCTRx / RSCFDnRFPCTRx */
  254. #define RCANFD_RFPCTR(gpriv, x) (RCANFD_RFCC(gpriv, x) + 0x40)
  255. /* Common FIFO Control registers */
  256. /* RSCFDnCFDCFCCx / RSCFDnCFCCx */
  257. #define RCANFD_CFCC(gpriv, ch, idx) \
  258. ((gpriv)->info->regs->cfcc + (0x0c * (ch)) + (0x04 * (idx)))
  259. /* RSCFDnCFDCFSTSx / RSCFDnCFSTSx */
  260. #define RCANFD_CFSTS(gpriv, ch, idx) \
  261. ((gpriv)->info->regs->cfsts + (0x0c * (ch)) + (0x04 * (idx)))
  262. /* RSCFDnCFDCFPCTRx / RSCFDnCFPCTRx */
  263. #define RCANFD_CFPCTR(gpriv, ch, idx) \
  264. ((gpriv)->info->regs->cfpctr + (0x0c * (ch)) + (0x04 * (idx)))
  265. /* RSCFDnCFDGRMCFG */
  266. #define RCANFD_GRMCFG (0x04fc)
  267. /* RSCFDnCFDGAFLIDj / RSCFDnGAFLIDj */
  268. #define RCANFD_GAFLID(offset, j) ((offset) + (0x10 * (j)))
  269. /* RSCFDnCFDGAFLMj / RSCFDnGAFLMj */
  270. #define RCANFD_GAFLM(offset, j) ((offset) + 0x04 + (0x10 * (j)))
  271. /* RSCFDnCFDGAFLP0j / RSCFDnGAFLP0j */
  272. #define RCANFD_GAFLP0(offset, j) ((offset) + 0x08 + (0x10 * (j)))
  273. /* RSCFDnCFDGAFLP1j / RSCFDnGAFLP1j */
  274. #define RCANFD_GAFLP1(offset, j) ((offset) + 0x0c + (0x10 * (j)))
  275. /* Classical CAN only mode register map */
  276. /* RSCFDnGAFLXXXj offset */
  277. #define RCANFD_C_GAFL_OFFSET (0x0500)
  278. /* RSCFDnRFXXx -> RCANFD_C_RFXX(x) */
  279. #define RCANFD_C_RFOFFSET (0x0e00)
  280. #define RCANFD_C_RFID(x) (RCANFD_C_RFOFFSET + (0x10 * (x)))
  281. #define RCANFD_C_RFPTR(x) (RCANFD_C_RFOFFSET + 0x04 + (0x10 * (x)))
  282. #define RCANFD_C_RFDF(x, df) \
  283. (RCANFD_C_RFOFFSET + 0x08 + (0x10 * (x)) + (0x04 * (df)))
  284. /* RSCFDnCFXXk -> RCANFD_C_CFXX(ch, k) */
  285. #define RCANFD_C_CFOFFSET (0x0e80)
  286. #define RCANFD_C_CFID(ch, idx) \
  287. (RCANFD_C_CFOFFSET + (0x30 * (ch)) + (0x10 * (idx)))
  288. #define RCANFD_C_CFPTR(ch, idx) \
  289. (RCANFD_C_CFOFFSET + 0x04 + (0x30 * (ch)) + (0x10 * (idx)))
  290. #define RCANFD_C_CFDF(ch, idx, df) \
  291. (RCANFD_C_CFOFFSET + 0x08 + (0x30 * (ch)) + (0x10 * (idx)) + (0x04 * (df)))
  292. /* R-Car Gen4 Classical and CAN FD mode specific register map */
  293. #define RCANFD_GEN4_GAFL_OFFSET (0x1800)
  294. /* CAN FD mode specific register map */
  295. /* RSCFDnCFDCmXXX -> gpriv->fcbase[m].xxx */
  296. struct rcar_canfd_f_c {
  297. u32 dcfg;
  298. u32 cfdcfg;
  299. u32 cfdctr;
  300. u32 cfdsts;
  301. u32 cfdcrc;
  302. u32 pad[3];
  303. };
  304. /* RSCFDnCFDGAFLXXXj offset */
  305. #define RCANFD_F_GAFL_OFFSET (0x1000)
  306. /* RSCFDnCFDRFXXx -> RCANFD_F_RFXX(x) */
  307. #define RCANFD_F_RFOFFSET(gpriv) ((gpriv)->info->regs->rfoffset)
  308. #define RCANFD_F_RFID(gpriv, x) (RCANFD_F_RFOFFSET(gpriv) + (0x80 * (x)))
  309. #define RCANFD_F_RFPTR(gpriv, x) (RCANFD_F_RFOFFSET(gpriv) + 0x04 + (0x80 * (x)))
  310. #define RCANFD_F_RFFDSTS(gpriv, x) (RCANFD_F_RFOFFSET(gpriv) + 0x08 + (0x80 * (x)))
  311. #define RCANFD_F_RFDF(gpriv, x, df) \
  312. (RCANFD_F_RFOFFSET(gpriv) + 0x0c + (0x80 * (x)) + (0x04 * (df)))
  313. /* RSCFDnCFDCFXXk -> RCANFD_F_CFXX(ch, k) */
  314. #define RCANFD_F_CFOFFSET(gpriv) ((gpriv)->info->regs->cfoffset)
  315. #define RCANFD_F_CFID(gpriv, ch, idx) \
  316. (RCANFD_F_CFOFFSET(gpriv) + (0x180 * (ch)) + (0x80 * (idx)))
  317. #define RCANFD_F_CFPTR(gpriv, ch, idx) \
  318. (RCANFD_F_CFOFFSET(gpriv) + 0x04 + (0x180 * (ch)) + (0x80 * (idx)))
  319. #define RCANFD_F_CFFDCSTS(gpriv, ch, idx) \
  320. (RCANFD_F_CFOFFSET(gpriv) + 0x08 + (0x180 * (ch)) + (0x80 * (idx)))
  321. #define RCANFD_F_CFDF(gpriv, ch, idx, df) \
  322. (RCANFD_F_CFOFFSET(gpriv) + 0x0c + (0x180 * (ch)) + (0x80 * (idx)) + \
  323. (0x04 * (df)))
  324. /* Constants */
  325. #define RCANFD_FIFO_DEPTH 8 /* Tx FIFO depth */
  326. #define RCANFD_NAPI_WEIGHT 8 /* Rx poll quota */
  327. #define RCANFD_NUM_CHANNELS 8 /* Eight channels max */
  328. #define RCANFD_GAFL_PAGENUM(entry) ((entry) / 16)
  329. #define RCANFD_CHANNEL_NUMRULES 1 /* only one rule per channel */
  330. /* Rx FIFO is a global resource of the controller. There are 8 such FIFOs
  331. * available. Each channel gets a dedicated Rx FIFO (i.e.) the channel
  332. * number is added to RFFIFO index.
  333. */
  334. #define RCANFD_RFFIFO_IDX 0
  335. /* Tx/Rx or Common FIFO is a per channel resource. Each channel has 3 Common
  336. * FIFOs dedicated to them. Use the first (index 0) FIFO out of the 3 for Tx.
  337. */
  338. #define RCANFD_CFFIFO_IDX 0
  339. struct rcar_canfd_global;
  340. struct rcar_canfd_regs {
  341. u16 rfcc; /* RX FIFO Configuration/Control Register */
  342. u16 cfcc; /* Common FIFO Configuration/Control Register */
  343. u16 cfsts; /* Common FIFO Status Register */
  344. u16 cfpctr; /* Common FIFO Pointer Control Register */
  345. u16 coffset; /* Channel Data Bitrate Configuration Register */
  346. u16 rfoffset; /* Receive FIFO buffer access ID register */
  347. u16 cfoffset; /* Transmit/receive FIFO buffer access ID register */
  348. };
  349. struct rcar_canfd_shift_data {
  350. u8 ntseg2; /* Nominal Bit Rate Time Segment 2 Control */
  351. u8 ntseg1; /* Nominal Bit Rate Time Segment 1 Control */
  352. u8 nsjw; /* Nominal Bit Rate Resynchronization Jump Width Control */
  353. u8 dtseg2; /* Data Bit Rate Time Segment 2 Control */
  354. u8 dtseg1; /* Data Bit Rate Time Segment 1 Control */
  355. u8 cftml; /* Common FIFO TX Message Buffer Link */
  356. u8 cfm; /* Common FIFO Mode */
  357. u8 cfdc; /* Common FIFO Depth Configuration */
  358. };
  359. struct rcar_canfd_hw_info {
  360. const struct can_bittiming_const *nom_bittiming;
  361. const struct can_bittiming_const *data_bittiming;
  362. const struct can_tdc_const *tdc_const;
  363. const struct rcar_canfd_regs *regs;
  364. const struct rcar_canfd_shift_data *sh;
  365. u8 rnc_field_width;
  366. u8 max_aflpn;
  367. u8 max_cftml;
  368. u8 max_channels;
  369. u8 postdiv;
  370. /* hardware features */
  371. unsigned shared_global_irqs:1; /* Has shared global irqs */
  372. unsigned multi_channel_irqs:1; /* Has multiple channel irqs */
  373. unsigned ch_interface_mode:1; /* Has channel interface mode */
  374. unsigned shared_can_regs:1; /* Has shared classical can registers */
  375. unsigned external_clk:1; /* Has external clock */
  376. };
  377. /* Channel priv data */
  378. struct rcar_canfd_channel {
  379. struct can_priv can; /* Must be the first member */
  380. struct net_device *ndev;
  381. struct rcar_canfd_global *gpriv; /* Controller reference */
  382. void __iomem *base; /* Register base address */
  383. struct phy *transceiver; /* Optional transceiver */
  384. struct napi_struct napi;
  385. u32 tx_head; /* Incremented on xmit */
  386. u32 tx_tail; /* Incremented on xmit done */
  387. u32 channel; /* Channel number */
  388. spinlock_t tx_lock; /* To protect tx path */
  389. };
  390. /* Global priv data */
  391. struct rcar_canfd_global {
  392. struct rcar_canfd_channel *ch[RCANFD_NUM_CHANNELS];
  393. void __iomem *base; /* Register base address */
  394. struct rcar_canfd_f_c __iomem *fcbase;
  395. struct platform_device *pdev; /* Respective platform device */
  396. struct clk *clkp; /* Peripheral clock */
  397. struct clk *can_clk; /* fCAN clock */
  398. struct clk *clk_ram; /* Clock RAM */
  399. unsigned long channels_mask; /* Enabled channels mask */
  400. bool extclk; /* CANFD or Ext clock */
  401. bool fdmode; /* CAN FD or Classical CAN only mode */
  402. bool fd_only_mode; /* FD-Only mode for CAN-FD */
  403. struct reset_control *rstc1;
  404. struct reset_control *rstc2;
  405. const struct rcar_canfd_hw_info *info;
  406. };
  407. /* CAN FD mode nominal rate constants */
  408. static const struct can_bittiming_const rcar_canfd_gen3_nom_bittiming_const = {
  409. .name = RCANFD_DRV_NAME,
  410. .tseg1_min = 2,
  411. .tseg1_max = 128,
  412. .tseg2_min = 2,
  413. .tseg2_max = 32,
  414. .sjw_max = 32,
  415. .brp_min = 1,
  416. .brp_max = 1024,
  417. .brp_inc = 1,
  418. };
  419. static const struct can_bittiming_const rcar_canfd_gen4_nom_bittiming_const = {
  420. .name = RCANFD_DRV_NAME,
  421. .tseg1_min = 2,
  422. .tseg1_max = 256,
  423. .tseg2_min = 2,
  424. .tseg2_max = 128,
  425. .sjw_max = 128,
  426. .brp_min = 1,
  427. .brp_max = 1024,
  428. .brp_inc = 1,
  429. };
  430. /* CAN FD mode data rate constants */
  431. static const struct can_bittiming_const rcar_canfd_gen3_data_bittiming_const = {
  432. .name = RCANFD_DRV_NAME,
  433. .tseg1_min = 2,
  434. .tseg1_max = 16,
  435. .tseg2_min = 2,
  436. .tseg2_max = 8,
  437. .sjw_max = 8,
  438. .brp_min = 1,
  439. .brp_max = 256,
  440. .brp_inc = 1,
  441. };
  442. static const struct can_bittiming_const rcar_canfd_gen4_data_bittiming_const = {
  443. .name = RCANFD_DRV_NAME,
  444. .tseg1_min = 2,
  445. .tseg1_max = 32,
  446. .tseg2_min = 2,
  447. .tseg2_max = 16,
  448. .sjw_max = 16,
  449. .brp_min = 1,
  450. .brp_max = 256,
  451. .brp_inc = 1,
  452. };
  453. /* Classical CAN mode bitrate constants */
  454. static const struct can_bittiming_const rcar_canfd_bittiming_const = {
  455. .name = RCANFD_DRV_NAME,
  456. .tseg1_min = 4,
  457. .tseg1_max = 16,
  458. .tseg2_min = 2,
  459. .tseg2_max = 8,
  460. .sjw_max = 4,
  461. .brp_min = 1,
  462. .brp_max = 1024,
  463. .brp_inc = 1,
  464. };
  465. /* CAN FD Transmission Delay Compensation constants */
  466. static const struct can_tdc_const rcar_canfd_gen3_tdc_const = {
  467. .tdcv_min = 1,
  468. .tdcv_max = 128,
  469. .tdco_min = 1,
  470. .tdco_max = 128,
  471. .tdcf_min = 0, /* Filter window not supported */
  472. .tdcf_max = 0,
  473. };
  474. static const struct can_tdc_const rcar_canfd_gen4_tdc_const = {
  475. .tdcv_min = 1,
  476. .tdcv_max = 256,
  477. .tdco_min = 1,
  478. .tdco_max = 256,
  479. .tdcf_min = 0, /* Filter window not supported */
  480. .tdcf_max = 0,
  481. };
  482. static const struct rcar_canfd_regs rcar_gen3_regs = {
  483. .rfcc = 0x00b8,
  484. .cfcc = 0x0118,
  485. .cfsts = 0x0178,
  486. .cfpctr = 0x01d8,
  487. .coffset = 0x0500,
  488. .rfoffset = 0x3000,
  489. .cfoffset = 0x3400,
  490. };
  491. static const struct rcar_canfd_regs rcar_gen4_regs = {
  492. .rfcc = 0x00c0,
  493. .cfcc = 0x0120,
  494. .cfsts = 0x01e0,
  495. .cfpctr = 0x0240,
  496. .coffset = 0x1400,
  497. .rfoffset = 0x6000,
  498. .cfoffset = 0x6400,
  499. };
  500. static const struct rcar_canfd_shift_data rcar_gen3_shift_data = {
  501. .ntseg2 = 24,
  502. .ntseg1 = 16,
  503. .nsjw = 11,
  504. .dtseg2 = 20,
  505. .dtseg1 = 16,
  506. .cftml = 20,
  507. .cfm = 16,
  508. .cfdc = 8,
  509. };
  510. static const struct rcar_canfd_shift_data rcar_gen4_shift_data = {
  511. .ntseg2 = 25,
  512. .ntseg1 = 17,
  513. .nsjw = 10,
  514. .dtseg2 = 16,
  515. .dtseg1 = 8,
  516. .cftml = 16,
  517. .cfm = 8,
  518. .cfdc = 21,
  519. };
  520. static const struct rcar_canfd_hw_info rcar_gen3_hw_info = {
  521. .nom_bittiming = &rcar_canfd_gen3_nom_bittiming_const,
  522. .data_bittiming = &rcar_canfd_gen3_data_bittiming_const,
  523. .tdc_const = &rcar_canfd_gen3_tdc_const,
  524. .regs = &rcar_gen3_regs,
  525. .sh = &rcar_gen3_shift_data,
  526. .rnc_field_width = 8,
  527. .max_aflpn = 31,
  528. .max_cftml = 15,
  529. .max_channels = 2,
  530. .postdiv = 2,
  531. .shared_global_irqs = 1,
  532. .ch_interface_mode = 0,
  533. .shared_can_regs = 0,
  534. .external_clk = 1,
  535. };
  536. static const struct rcar_canfd_hw_info rcar_gen4_hw_info = {
  537. .nom_bittiming = &rcar_canfd_gen4_nom_bittiming_const,
  538. .data_bittiming = &rcar_canfd_gen4_data_bittiming_const,
  539. .tdc_const = &rcar_canfd_gen4_tdc_const,
  540. .regs = &rcar_gen4_regs,
  541. .sh = &rcar_gen4_shift_data,
  542. .rnc_field_width = 16,
  543. .max_aflpn = 127,
  544. .max_cftml = 31,
  545. .max_channels = 8,
  546. .postdiv = 2,
  547. .shared_global_irqs = 1,
  548. .ch_interface_mode = 1,
  549. .shared_can_regs = 1,
  550. .external_clk = 1,
  551. };
  552. static const struct rcar_canfd_hw_info rzg2l_hw_info = {
  553. .nom_bittiming = &rcar_canfd_gen3_nom_bittiming_const,
  554. .data_bittiming = &rcar_canfd_gen3_data_bittiming_const,
  555. .tdc_const = &rcar_canfd_gen3_tdc_const,
  556. .regs = &rcar_gen3_regs,
  557. .sh = &rcar_gen3_shift_data,
  558. .rnc_field_width = 8,
  559. .max_aflpn = 31,
  560. .max_cftml = 15,
  561. .max_channels = 2,
  562. .postdiv = 1,
  563. .multi_channel_irqs = 1,
  564. .ch_interface_mode = 0,
  565. .shared_can_regs = 0,
  566. .external_clk = 1,
  567. };
  568. static const struct rcar_canfd_hw_info r9a09g047_hw_info = {
  569. .nom_bittiming = &rcar_canfd_gen4_nom_bittiming_const,
  570. .data_bittiming = &rcar_canfd_gen4_data_bittiming_const,
  571. .tdc_const = &rcar_canfd_gen4_tdc_const,
  572. .regs = &rcar_gen4_regs,
  573. .sh = &rcar_gen4_shift_data,
  574. .rnc_field_width = 16,
  575. .max_aflpn = 63,
  576. .max_cftml = 31,
  577. .max_channels = 6,
  578. .postdiv = 1,
  579. .multi_channel_irqs = 1,
  580. .ch_interface_mode = 1,
  581. .shared_can_regs = 1,
  582. .external_clk = 0,
  583. };
  584. static const struct rcar_canfd_hw_info r9a09g077_hw_info = {
  585. .nom_bittiming = &rcar_canfd_gen4_nom_bittiming_const,
  586. .data_bittiming = &rcar_canfd_gen4_data_bittiming_const,
  587. .tdc_const = &rcar_canfd_gen4_tdc_const,
  588. .regs = &rcar_gen4_regs,
  589. .sh = &rcar_gen4_shift_data,
  590. .rnc_field_width = 16,
  591. .max_aflpn = 15,
  592. .max_cftml = 31,
  593. .max_channels = 2,
  594. .postdiv = 1,
  595. .multi_channel_irqs = 1,
  596. .ch_interface_mode = 1,
  597. .shared_can_regs = 1,
  598. .external_clk = 1,
  599. };
  600. /* Helper functions */
  601. static inline void rcar_canfd_update(u32 mask, u32 val, u32 __iomem *reg)
  602. {
  603. u32 data = readl(reg);
  604. data &= ~mask;
  605. data |= (val & mask);
  606. writel(data, reg);
  607. }
  608. static inline u32 rcar_canfd_read(void __iomem *base, u32 offset)
  609. {
  610. return readl(base + offset);
  611. }
  612. static inline void rcar_canfd_write(void __iomem *base, u32 offset, u32 val)
  613. {
  614. writel(val, base + offset);
  615. }
  616. static void rcar_canfd_set_bit(void __iomem *base, u32 reg, u32 val)
  617. {
  618. rcar_canfd_update(val, val, base + reg);
  619. }
  620. static void rcar_canfd_clear_bit(void __iomem *base, u32 reg, u32 val)
  621. {
  622. rcar_canfd_update(val, 0, base + reg);
  623. }
  624. static void rcar_canfd_update_bit(void __iomem *base, u32 reg,
  625. u32 mask, u32 val)
  626. {
  627. rcar_canfd_update(mask, val, base + reg);
  628. }
  629. static void rcar_canfd_set_bit_reg(void __iomem *addr, u32 val)
  630. {
  631. rcar_canfd_update(val, val, addr);
  632. }
  633. static void rcar_canfd_clear_bit_reg(void __iomem *addr, u32 val)
  634. {
  635. rcar_canfd_update(val, 0, addr);
  636. }
  637. static void rcar_canfd_update_bit_reg(void __iomem *addr, u32 mask, u32 val)
  638. {
  639. rcar_canfd_update(mask, val, addr);
  640. }
  641. static void rcar_canfd_get_data(struct rcar_canfd_channel *priv,
  642. struct canfd_frame *cf, u32 off)
  643. {
  644. u32 *data = (u32 *)cf->data;
  645. u32 i, lwords;
  646. lwords = DIV_ROUND_UP(cf->len, sizeof(u32));
  647. for (i = 0; i < lwords; i++)
  648. data[i] = rcar_canfd_read(priv->base, off + i * sizeof(u32));
  649. }
  650. static void rcar_canfd_put_data(struct rcar_canfd_channel *priv,
  651. struct canfd_frame *cf, u32 off)
  652. {
  653. const u32 *data = (u32 *)cf->data;
  654. u32 i, lwords;
  655. lwords = DIV_ROUND_UP(cf->len, sizeof(u32));
  656. for (i = 0; i < lwords; i++)
  657. rcar_canfd_write(priv->base, off + i * sizeof(u32), data[i]);
  658. }
  659. static void rcar_canfd_tx_failure_cleanup(struct net_device *ndev)
  660. {
  661. u32 i;
  662. for (i = 0; i < RCANFD_FIFO_DEPTH; i++)
  663. can_free_echo_skb(ndev, i, NULL);
  664. }
  665. static void rcar_canfd_set_rnc(struct rcar_canfd_global *gpriv, unsigned int ch,
  666. unsigned int num_rules)
  667. {
  668. unsigned int rnc_stride = 32 / gpriv->info->rnc_field_width;
  669. unsigned int shift = 32 - (ch % rnc_stride + 1) * gpriv->info->rnc_field_width;
  670. unsigned int w = ch / rnc_stride;
  671. u32 rnc = num_rules << shift;
  672. rcar_canfd_set_bit(gpriv->base, RCANFD_GAFLCFG(w), rnc);
  673. }
  674. static int rcar_canfd_reset_controller(struct rcar_canfd_global *gpriv)
  675. {
  676. struct device *dev = &gpriv->pdev->dev;
  677. u32 sts, ch;
  678. int err;
  679. /* Check RAMINIT flag as CAN RAM initialization takes place
  680. * after the MCU reset
  681. */
  682. err = readl_poll_timeout((gpriv->base + RCANFD_GSTS), sts,
  683. !(sts & RCANFD_GSTS_GRAMINIT), 2, 500000);
  684. if (err) {
  685. dev_dbg(dev, "global raminit failed\n");
  686. return err;
  687. }
  688. /* Transition to Global Reset mode */
  689. rcar_canfd_clear_bit(gpriv->base, RCANFD_GCTR, RCANFD_GCTR_GSLPR);
  690. rcar_canfd_update_bit(gpriv->base, RCANFD_GCTR,
  691. RCANFD_GCTR_GMDC_MASK, RCANFD_GCTR_GMDC_GRESET);
  692. /* Ensure Global reset mode */
  693. err = readl_poll_timeout((gpriv->base + RCANFD_GSTS), sts,
  694. (sts & RCANFD_GSTS_GRSTSTS), 2, 500000);
  695. if (err) {
  696. dev_dbg(dev, "global reset failed\n");
  697. return err;
  698. }
  699. /* Reset Global error flags */
  700. rcar_canfd_write(gpriv->base, RCANFD_GERFL, 0x0);
  701. /* Set the controller into appropriate mode */
  702. if (!gpriv->info->ch_interface_mode) {
  703. if (gpriv->fdmode)
  704. rcar_canfd_set_bit(gpriv->base, RCANFD_GRMCFG,
  705. RCANFD_GRMCFG_RCMC);
  706. else
  707. rcar_canfd_clear_bit(gpriv->base, RCANFD_GRMCFG,
  708. RCANFD_GRMCFG_RCMC);
  709. }
  710. /* Transition all Channels to reset mode */
  711. for_each_set_bit(ch, &gpriv->channels_mask, gpriv->info->max_channels) {
  712. rcar_canfd_clear_bit(gpriv->base,
  713. RCANFD_CCTR(ch), RCANFD_CCTR_CSLPR);
  714. rcar_canfd_update_bit(gpriv->base, RCANFD_CCTR(ch),
  715. RCANFD_CCTR_CHMDC_MASK,
  716. RCANFD_CCTR_CHDMC_CRESET);
  717. /* Ensure Channel reset mode */
  718. err = readl_poll_timeout((gpriv->base + RCANFD_CSTS(ch)), sts,
  719. (sts & RCANFD_CSTS_CRSTSTS),
  720. 2, 500000);
  721. if (err) {
  722. dev_dbg(dev, "channel %u reset failed\n", ch);
  723. return err;
  724. }
  725. /* Set the controller into appropriate mode */
  726. if (gpriv->info->ch_interface_mode) {
  727. /* Do not set CLOE and FDOE simultaneously */
  728. if (!gpriv->fdmode) {
  729. rcar_canfd_clear_bit_reg(&gpriv->fcbase[ch].cfdcfg,
  730. RCANFD_GEN4_FDCFG_FDOE);
  731. rcar_canfd_set_bit_reg(&gpriv->fcbase[ch].cfdcfg,
  732. RCANFD_GEN4_FDCFG_CLOE);
  733. } else if (gpriv->fd_only_mode) {
  734. rcar_canfd_clear_bit_reg(&gpriv->fcbase[ch].cfdcfg,
  735. RCANFD_GEN4_FDCFG_CLOE);
  736. rcar_canfd_set_bit_reg(&gpriv->fcbase[ch].cfdcfg,
  737. RCANFD_GEN4_FDCFG_FDOE);
  738. } else {
  739. rcar_canfd_clear_bit_reg(&gpriv->fcbase[ch].cfdcfg,
  740. RCANFD_GEN4_FDCFG_FDOE);
  741. rcar_canfd_clear_bit_reg(&gpriv->fcbase[ch].cfdcfg,
  742. RCANFD_GEN4_FDCFG_CLOE);
  743. }
  744. } else if (gpriv->fd_only_mode) {
  745. rcar_canfd_set_bit_reg(&gpriv->fcbase[ch].cfdcfg,
  746. RCANFD_GEN4_FDCFG_FDOE);
  747. }
  748. }
  749. return 0;
  750. }
  751. static void rcar_canfd_configure_controller(struct rcar_canfd_global *gpriv)
  752. {
  753. u32 cfg, ch;
  754. /* Global configuration settings */
  755. /* ECC Error flag Enable */
  756. cfg = RCANFD_GCFG_EEFE;
  757. if (gpriv->fdmode)
  758. /* Truncate payload to configured message size RFPLS */
  759. cfg |= RCANFD_GCFG_CMPOC;
  760. /* Set External Clock if selected */
  761. if (gpriv->extclk)
  762. cfg |= RCANFD_GCFG_DCS;
  763. rcar_canfd_set_bit(gpriv->base, RCANFD_GCFG, cfg);
  764. /* Channel configuration settings */
  765. for_each_set_bit(ch, &gpriv->channels_mask, gpriv->info->max_channels) {
  766. rcar_canfd_set_bit(gpriv->base, RCANFD_CCTR(ch),
  767. RCANFD_CCTR_ERRD);
  768. rcar_canfd_update_bit(gpriv->base, RCANFD_CCTR(ch),
  769. RCANFD_CCTR_BOM_MASK,
  770. RCANFD_CCTR_BOM_BENTRY);
  771. }
  772. }
  773. static void rcar_canfd_configure_afl_rules(struct rcar_canfd_global *gpriv,
  774. u32 ch, u32 rule_entry)
  775. {
  776. unsigned int offset, page, num_rules = RCANFD_CHANNEL_NUMRULES;
  777. u32 rule_entry_index = rule_entry % 16;
  778. u32 ridx = ch + RCANFD_RFFIFO_IDX;
  779. /* Enable write access to entry */
  780. page = RCANFD_GAFL_PAGENUM(rule_entry);
  781. rcar_canfd_set_bit(gpriv->base, RCANFD_GAFLECTR,
  782. (RCANFD_GAFLECTR_AFLPN(gpriv, page) |
  783. RCANFD_GAFLECTR_AFLDAE));
  784. /* Write number of rules for channel */
  785. rcar_canfd_set_rnc(gpriv, ch, num_rules);
  786. if (gpriv->info->shared_can_regs)
  787. offset = RCANFD_GEN4_GAFL_OFFSET;
  788. else if (gpriv->fdmode)
  789. offset = RCANFD_F_GAFL_OFFSET;
  790. else
  791. offset = RCANFD_C_GAFL_OFFSET;
  792. /* Accept all IDs */
  793. rcar_canfd_write(gpriv->base, RCANFD_GAFLID(offset, rule_entry_index), 0);
  794. /* IDE or RTR is not considered for matching */
  795. rcar_canfd_write(gpriv->base, RCANFD_GAFLM(offset, rule_entry_index), 0);
  796. /* Any data length accepted */
  797. rcar_canfd_write(gpriv->base, RCANFD_GAFLP0(offset, rule_entry_index), 0);
  798. /* Place the msg in corresponding Rx FIFO entry */
  799. rcar_canfd_set_bit(gpriv->base, RCANFD_GAFLP1(offset, rule_entry_index),
  800. RCANFD_GAFLP1_GAFLFDP(ridx));
  801. /* Disable write access to page */
  802. rcar_canfd_clear_bit(gpriv->base,
  803. RCANFD_GAFLECTR, RCANFD_GAFLECTR_AFLDAE);
  804. }
  805. static void rcar_canfd_configure_rx(struct rcar_canfd_global *gpriv, u32 ch)
  806. {
  807. /* Rx FIFO is used for reception */
  808. u32 cfg;
  809. u16 rfdc, rfpls;
  810. /* Select Rx FIFO based on channel */
  811. u32 ridx = ch + RCANFD_RFFIFO_IDX;
  812. rfdc = 2; /* b010 - 8 messages Rx FIFO depth */
  813. if (gpriv->fdmode)
  814. rfpls = 7; /* b111 - Max 64 bytes payload */
  815. else
  816. rfpls = 0; /* b000 - Max 8 bytes payload */
  817. cfg = (RCANFD_RFCC_RFIM | RCANFD_RFCC_RFDC(rfdc) |
  818. RCANFD_RFCC_RFPLS(rfpls) | RCANFD_RFCC_RFIE);
  819. rcar_canfd_write(gpriv->base, RCANFD_RFCC(gpriv, ridx), cfg);
  820. }
  821. static void rcar_canfd_configure_tx(struct rcar_canfd_global *gpriv, u32 ch)
  822. {
  823. /* Tx/Rx(Common) FIFO configured in Tx mode is
  824. * used for transmission
  825. *
  826. * Each channel has 3 Common FIFO dedicated to them.
  827. * Use the 1st (index 0) out of 3
  828. */
  829. u32 cfg;
  830. u16 cftml, cfm, cfdc, cfpls;
  831. cftml = 0; /* 0th buffer */
  832. cfm = 1; /* b01 - Transmit mode */
  833. cfdc = 2; /* b010 - 8 messages Tx FIFO depth */
  834. if (gpriv->fdmode)
  835. cfpls = 7; /* b111 - Max 64 bytes payload */
  836. else
  837. cfpls = 0; /* b000 - Max 8 bytes payload */
  838. cfg = (RCANFD_CFCC_CFTML(gpriv, cftml) | RCANFD_CFCC_CFM(gpriv, cfm) |
  839. RCANFD_CFCC_CFIM | RCANFD_CFCC_CFDC(gpriv, cfdc) |
  840. RCANFD_CFCC_CFPLS(cfpls) | RCANFD_CFCC_CFTXIE);
  841. rcar_canfd_write(gpriv->base, RCANFD_CFCC(gpriv, ch, RCANFD_CFFIFO_IDX), cfg);
  842. if (gpriv->fdmode)
  843. /* Clear FD mode specific control/status register */
  844. rcar_canfd_write(gpriv->base,
  845. RCANFD_F_CFFDCSTS(gpriv, ch, RCANFD_CFFIFO_IDX), 0);
  846. }
  847. static void rcar_canfd_enable_global_interrupts(struct rcar_canfd_global *gpriv)
  848. {
  849. u32 ctr;
  850. /* Clear any stray error interrupt flags */
  851. rcar_canfd_write(gpriv->base, RCANFD_GERFL, 0);
  852. /* Global interrupts setup */
  853. ctr = RCANFD_GCTR_MEIE;
  854. if (gpriv->fdmode)
  855. ctr |= RCANFD_GCTR_CFMPOFIE;
  856. rcar_canfd_set_bit(gpriv->base, RCANFD_GCTR, ctr);
  857. }
  858. static void rcar_canfd_disable_global_interrupts(struct rcar_canfd_global
  859. *gpriv)
  860. {
  861. /* Disable all interrupts */
  862. rcar_canfd_write(gpriv->base, RCANFD_GCTR, 0);
  863. /* Clear any stray error interrupt flags */
  864. rcar_canfd_write(gpriv->base, RCANFD_GERFL, 0);
  865. }
  866. static void rcar_canfd_enable_channel_interrupts(struct rcar_canfd_channel
  867. *priv)
  868. {
  869. u32 ctr, ch = priv->channel;
  870. /* Clear any stray error flags */
  871. rcar_canfd_write(priv->base, RCANFD_CERFL(ch), 0);
  872. /* Channel interrupts setup */
  873. ctr = (RCANFD_CCTR_TAIE |
  874. RCANFD_CCTR_ALIE | RCANFD_CCTR_BLIE |
  875. RCANFD_CCTR_OLIE | RCANFD_CCTR_BORIE |
  876. RCANFD_CCTR_BOEIE | RCANFD_CCTR_EPIE |
  877. RCANFD_CCTR_EWIE | RCANFD_CCTR_BEIE);
  878. rcar_canfd_set_bit(priv->base, RCANFD_CCTR(ch), ctr);
  879. }
  880. static void rcar_canfd_disable_channel_interrupts(struct rcar_canfd_channel
  881. *priv)
  882. {
  883. u32 ctr, ch = priv->channel;
  884. ctr = (RCANFD_CCTR_TAIE |
  885. RCANFD_CCTR_ALIE | RCANFD_CCTR_BLIE |
  886. RCANFD_CCTR_OLIE | RCANFD_CCTR_BORIE |
  887. RCANFD_CCTR_BOEIE | RCANFD_CCTR_EPIE |
  888. RCANFD_CCTR_EWIE | RCANFD_CCTR_BEIE);
  889. rcar_canfd_clear_bit(priv->base, RCANFD_CCTR(ch), ctr);
  890. /* Clear any stray error flags */
  891. rcar_canfd_write(priv->base, RCANFD_CERFL(ch), 0);
  892. }
  893. static void rcar_canfd_global_error(struct net_device *ndev)
  894. {
  895. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  896. struct rcar_canfd_global *gpriv = priv->gpriv;
  897. struct net_device_stats *stats = &ndev->stats;
  898. u32 ch = priv->channel;
  899. u32 gerfl, sts;
  900. u32 ridx = ch + RCANFD_RFFIFO_IDX;
  901. gerfl = rcar_canfd_read(priv->base, RCANFD_GERFL);
  902. if (gerfl & FIELD_PREP(RCANFD_GERFL_EEF, BIT(ch))) {
  903. netdev_dbg(ndev, "Ch%u: ECC Error flag\n", ch);
  904. stats->tx_dropped++;
  905. }
  906. if (gerfl & RCANFD_GERFL_MES) {
  907. sts = rcar_canfd_read(priv->base,
  908. RCANFD_CFSTS(gpriv, ch, RCANFD_CFFIFO_IDX));
  909. if (sts & RCANFD_CFSTS_CFMLT) {
  910. netdev_dbg(ndev, "Tx Message Lost flag\n");
  911. stats->tx_dropped++;
  912. rcar_canfd_write(priv->base,
  913. RCANFD_CFSTS(gpriv, ch, RCANFD_CFFIFO_IDX),
  914. sts & ~RCANFD_CFSTS_CFMLT);
  915. }
  916. sts = rcar_canfd_read(priv->base, RCANFD_RFSTS(gpriv, ridx));
  917. if (sts & RCANFD_RFSTS_RFMLT) {
  918. netdev_dbg(ndev, "Rx Message Lost flag\n");
  919. stats->rx_dropped++;
  920. rcar_canfd_write(priv->base, RCANFD_RFSTS(gpriv, ridx),
  921. sts & ~RCANFD_RFSTS_RFMLT);
  922. }
  923. }
  924. if (gpriv->fdmode && gerfl & RCANFD_GERFL_CMPOF) {
  925. /* Message Lost flag will be set for respective channel
  926. * when this condition happens with counters and flags
  927. * already updated.
  928. */
  929. netdev_dbg(ndev, "global payload overflow interrupt\n");
  930. }
  931. /* Clear all global error interrupts. Only affected channels bits
  932. * get cleared
  933. */
  934. rcar_canfd_write(priv->base, RCANFD_GERFL, 0);
  935. }
  936. static void rcar_canfd_error(struct net_device *ndev, u32 cerfl,
  937. u16 txerr, u16 rxerr)
  938. {
  939. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  940. struct net_device_stats *stats = &ndev->stats;
  941. struct can_frame *cf;
  942. struct sk_buff *skb;
  943. u32 ch = priv->channel;
  944. netdev_dbg(ndev, "ch erfl %x txerr %u rxerr %u\n", cerfl, txerr, rxerr);
  945. /* Propagate the error condition to the CAN stack */
  946. skb = alloc_can_err_skb(ndev, &cf);
  947. if (!skb) {
  948. stats->rx_dropped++;
  949. return;
  950. }
  951. /* Channel error interrupts */
  952. if (cerfl & RCANFD_CERFL_BEF) {
  953. netdev_dbg(ndev, "Bus error\n");
  954. cf->can_id |= CAN_ERR_BUSERROR | CAN_ERR_PROT;
  955. cf->data[2] = CAN_ERR_PROT_UNSPEC;
  956. priv->can.can_stats.bus_error++;
  957. }
  958. if (cerfl & RCANFD_CERFL_ADERR) {
  959. netdev_dbg(ndev, "ACK Delimiter Error\n");
  960. stats->tx_errors++;
  961. cf->data[3] |= CAN_ERR_PROT_LOC_ACK_DEL;
  962. }
  963. if (cerfl & RCANFD_CERFL_B0ERR) {
  964. netdev_dbg(ndev, "Bit Error (dominant)\n");
  965. stats->tx_errors++;
  966. cf->data[2] |= CAN_ERR_PROT_BIT0;
  967. }
  968. if (cerfl & RCANFD_CERFL_B1ERR) {
  969. netdev_dbg(ndev, "Bit Error (recessive)\n");
  970. stats->tx_errors++;
  971. cf->data[2] |= CAN_ERR_PROT_BIT1;
  972. }
  973. if (cerfl & RCANFD_CERFL_CERR) {
  974. netdev_dbg(ndev, "CRC Error\n");
  975. stats->rx_errors++;
  976. cf->data[3] |= CAN_ERR_PROT_LOC_CRC_SEQ;
  977. }
  978. if (cerfl & RCANFD_CERFL_AERR) {
  979. netdev_dbg(ndev, "ACK Error\n");
  980. stats->tx_errors++;
  981. cf->can_id |= CAN_ERR_ACK;
  982. cf->data[3] |= CAN_ERR_PROT_LOC_ACK;
  983. }
  984. if (cerfl & RCANFD_CERFL_FERR) {
  985. netdev_dbg(ndev, "Form Error\n");
  986. stats->rx_errors++;
  987. cf->data[2] |= CAN_ERR_PROT_FORM;
  988. }
  989. if (cerfl & RCANFD_CERFL_SERR) {
  990. netdev_dbg(ndev, "Stuff Error\n");
  991. stats->rx_errors++;
  992. cf->data[2] |= CAN_ERR_PROT_STUFF;
  993. }
  994. if (cerfl & RCANFD_CERFL_ALF) {
  995. netdev_dbg(ndev, "Arbitration lost Error\n");
  996. priv->can.can_stats.arbitration_lost++;
  997. cf->can_id |= CAN_ERR_LOSTARB;
  998. cf->data[0] |= CAN_ERR_LOSTARB_UNSPEC;
  999. }
  1000. if (cerfl & RCANFD_CERFL_BLF) {
  1001. netdev_dbg(ndev, "Bus Lock Error\n");
  1002. stats->rx_errors++;
  1003. cf->can_id |= CAN_ERR_BUSERROR;
  1004. }
  1005. if (cerfl & RCANFD_CERFL_EWF) {
  1006. netdev_dbg(ndev, "Error warning interrupt\n");
  1007. priv->can.state = CAN_STATE_ERROR_WARNING;
  1008. priv->can.can_stats.error_warning++;
  1009. cf->can_id |= CAN_ERR_CRTL | CAN_ERR_CNT;
  1010. cf->data[1] = txerr > rxerr ? CAN_ERR_CRTL_TX_WARNING :
  1011. CAN_ERR_CRTL_RX_WARNING;
  1012. cf->data[6] = txerr;
  1013. cf->data[7] = rxerr;
  1014. }
  1015. if (cerfl & RCANFD_CERFL_EPF) {
  1016. netdev_dbg(ndev, "Error passive interrupt\n");
  1017. priv->can.state = CAN_STATE_ERROR_PASSIVE;
  1018. priv->can.can_stats.error_passive++;
  1019. cf->can_id |= CAN_ERR_CRTL | CAN_ERR_CNT;
  1020. cf->data[1] = txerr > rxerr ? CAN_ERR_CRTL_TX_PASSIVE :
  1021. CAN_ERR_CRTL_RX_PASSIVE;
  1022. cf->data[6] = txerr;
  1023. cf->data[7] = rxerr;
  1024. }
  1025. if (cerfl & RCANFD_CERFL_BOEF) {
  1026. netdev_dbg(ndev, "Bus-off entry interrupt\n");
  1027. rcar_canfd_tx_failure_cleanup(ndev);
  1028. priv->can.state = CAN_STATE_BUS_OFF;
  1029. priv->can.can_stats.bus_off++;
  1030. can_bus_off(ndev);
  1031. cf->can_id |= CAN_ERR_BUSOFF;
  1032. }
  1033. if (cerfl & RCANFD_CERFL_OVLF) {
  1034. netdev_dbg(ndev,
  1035. "Overload Frame Transmission error interrupt\n");
  1036. stats->tx_errors++;
  1037. cf->can_id |= CAN_ERR_PROT;
  1038. cf->data[2] |= CAN_ERR_PROT_OVERLOAD;
  1039. }
  1040. /* Clear channel error interrupts that are handled */
  1041. rcar_canfd_write(priv->base, RCANFD_CERFL(ch),
  1042. RCANFD_CERFL_ERR(~cerfl));
  1043. netif_rx(skb);
  1044. }
  1045. static void rcar_canfd_tx_done(struct net_device *ndev)
  1046. {
  1047. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  1048. struct rcar_canfd_global *gpriv = priv->gpriv;
  1049. struct net_device_stats *stats = &ndev->stats;
  1050. u32 sts;
  1051. unsigned long flags;
  1052. u32 ch = priv->channel;
  1053. do {
  1054. u8 unsent, sent;
  1055. sent = priv->tx_tail % RCANFD_FIFO_DEPTH;
  1056. stats->tx_packets++;
  1057. stats->tx_bytes += can_get_echo_skb(ndev, sent, NULL);
  1058. spin_lock_irqsave(&priv->tx_lock, flags);
  1059. priv->tx_tail++;
  1060. sts = rcar_canfd_read(priv->base,
  1061. RCANFD_CFSTS(gpriv, ch, RCANFD_CFFIFO_IDX));
  1062. unsent = RCANFD_CFSTS_CFMC(sts);
  1063. /* Wake producer only when there is room */
  1064. if (unsent != RCANFD_FIFO_DEPTH)
  1065. netif_wake_queue(ndev);
  1066. if (priv->tx_head - priv->tx_tail <= unsent) {
  1067. spin_unlock_irqrestore(&priv->tx_lock, flags);
  1068. break;
  1069. }
  1070. spin_unlock_irqrestore(&priv->tx_lock, flags);
  1071. } while (1);
  1072. /* Clear interrupt */
  1073. rcar_canfd_write(priv->base, RCANFD_CFSTS(gpriv, ch, RCANFD_CFFIFO_IDX),
  1074. sts & ~RCANFD_CFSTS_CFTXIF);
  1075. }
  1076. static void rcar_canfd_handle_global_err(struct rcar_canfd_global *gpriv, u32 ch)
  1077. {
  1078. struct rcar_canfd_channel *priv = gpriv->ch[ch];
  1079. struct net_device *ndev = priv->ndev;
  1080. u32 gerfl;
  1081. /* Handle global error interrupts */
  1082. gerfl = rcar_canfd_read(priv->base, RCANFD_GERFL);
  1083. if (unlikely(RCANFD_GERFL_ERR(gpriv, gerfl)))
  1084. rcar_canfd_global_error(ndev);
  1085. }
  1086. static irqreturn_t rcar_canfd_global_err_interrupt(int irq, void *dev_id)
  1087. {
  1088. struct rcar_canfd_global *gpriv = dev_id;
  1089. u32 ch;
  1090. for_each_set_bit(ch, &gpriv->channels_mask, gpriv->info->max_channels)
  1091. rcar_canfd_handle_global_err(gpriv, ch);
  1092. return IRQ_HANDLED;
  1093. }
  1094. static void rcar_canfd_handle_global_receive(struct rcar_canfd_global *gpriv, u32 ch)
  1095. {
  1096. struct rcar_canfd_channel *priv = gpriv->ch[ch];
  1097. u32 ridx = ch + RCANFD_RFFIFO_IDX;
  1098. u32 sts, cc;
  1099. /* Handle Rx interrupts */
  1100. sts = rcar_canfd_read(priv->base, RCANFD_RFSTS(gpriv, ridx));
  1101. cc = rcar_canfd_read(priv->base, RCANFD_RFCC(gpriv, ridx));
  1102. if (likely(sts & RCANFD_RFSTS_RFIF &&
  1103. cc & RCANFD_RFCC_RFIE)) {
  1104. if (napi_schedule_prep(&priv->napi)) {
  1105. /* Disable Rx FIFO interrupts */
  1106. rcar_canfd_clear_bit(priv->base,
  1107. RCANFD_RFCC(gpriv, ridx),
  1108. RCANFD_RFCC_RFIE);
  1109. __napi_schedule(&priv->napi);
  1110. }
  1111. }
  1112. }
  1113. static irqreturn_t rcar_canfd_global_receive_fifo_interrupt(int irq, void *dev_id)
  1114. {
  1115. struct rcar_canfd_global *gpriv = dev_id;
  1116. u32 ch;
  1117. for_each_set_bit(ch, &gpriv->channels_mask, gpriv->info->max_channels)
  1118. rcar_canfd_handle_global_receive(gpriv, ch);
  1119. return IRQ_HANDLED;
  1120. }
  1121. static irqreturn_t rcar_canfd_global_interrupt(int irq, void *dev_id)
  1122. {
  1123. struct rcar_canfd_global *gpriv = dev_id;
  1124. u32 ch;
  1125. /* Global error interrupts still indicate a condition specific
  1126. * to a channel. RxFIFO interrupt is a global interrupt.
  1127. */
  1128. for_each_set_bit(ch, &gpriv->channels_mask, gpriv->info->max_channels) {
  1129. rcar_canfd_handle_global_err(gpriv, ch);
  1130. rcar_canfd_handle_global_receive(gpriv, ch);
  1131. }
  1132. return IRQ_HANDLED;
  1133. }
  1134. static void rcar_canfd_state_change(struct net_device *ndev,
  1135. u16 txerr, u16 rxerr)
  1136. {
  1137. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  1138. struct net_device_stats *stats = &ndev->stats;
  1139. enum can_state rx_state, tx_state, state = priv->can.state;
  1140. struct can_frame *cf;
  1141. struct sk_buff *skb;
  1142. /* Handle transition from error to normal states */
  1143. if (txerr < 96 && rxerr < 96)
  1144. state = CAN_STATE_ERROR_ACTIVE;
  1145. else if (txerr < 128 && rxerr < 128)
  1146. state = CAN_STATE_ERROR_WARNING;
  1147. if (state != priv->can.state) {
  1148. netdev_dbg(ndev, "state: new %d, old %d: txerr %u, rxerr %u\n",
  1149. state, priv->can.state, txerr, rxerr);
  1150. skb = alloc_can_err_skb(ndev, &cf);
  1151. if (!skb) {
  1152. stats->rx_dropped++;
  1153. return;
  1154. }
  1155. tx_state = txerr >= rxerr ? state : 0;
  1156. rx_state = txerr <= rxerr ? state : 0;
  1157. can_change_state(ndev, cf, tx_state, rx_state);
  1158. netif_rx(skb);
  1159. }
  1160. }
  1161. static void rcar_canfd_handle_channel_tx(struct rcar_canfd_global *gpriv, u32 ch)
  1162. {
  1163. struct rcar_canfd_channel *priv = gpriv->ch[ch];
  1164. struct net_device *ndev = priv->ndev;
  1165. u32 sts;
  1166. /* Handle Tx interrupts */
  1167. sts = rcar_canfd_read(priv->base,
  1168. RCANFD_CFSTS(gpriv, ch, RCANFD_CFFIFO_IDX));
  1169. if (likely(sts & RCANFD_CFSTS_CFTXIF))
  1170. rcar_canfd_tx_done(ndev);
  1171. }
  1172. static irqreturn_t rcar_canfd_channel_tx_interrupt(int irq, void *dev_id)
  1173. {
  1174. struct rcar_canfd_channel *priv = dev_id;
  1175. rcar_canfd_handle_channel_tx(priv->gpriv, priv->channel);
  1176. return IRQ_HANDLED;
  1177. }
  1178. static void rcar_canfd_handle_channel_err(struct rcar_canfd_global *gpriv, u32 ch)
  1179. {
  1180. struct rcar_canfd_channel *priv = gpriv->ch[ch];
  1181. struct net_device *ndev = priv->ndev;
  1182. u16 txerr, rxerr;
  1183. u32 sts, cerfl;
  1184. /* Handle channel error interrupts */
  1185. cerfl = rcar_canfd_read(priv->base, RCANFD_CERFL(ch));
  1186. sts = rcar_canfd_read(priv->base, RCANFD_CSTS(ch));
  1187. txerr = RCANFD_CSTS_TECCNT(sts);
  1188. rxerr = RCANFD_CSTS_RECCNT(sts);
  1189. if (unlikely(RCANFD_CERFL_ERR(cerfl)))
  1190. rcar_canfd_error(ndev, cerfl, txerr, rxerr);
  1191. /* Handle state change to lower states */
  1192. if (unlikely(priv->can.state != CAN_STATE_ERROR_ACTIVE &&
  1193. priv->can.state != CAN_STATE_BUS_OFF))
  1194. rcar_canfd_state_change(ndev, txerr, rxerr);
  1195. }
  1196. static irqreturn_t rcar_canfd_channel_err_interrupt(int irq, void *dev_id)
  1197. {
  1198. struct rcar_canfd_channel *priv = dev_id;
  1199. rcar_canfd_handle_channel_err(priv->gpriv, priv->channel);
  1200. return IRQ_HANDLED;
  1201. }
  1202. static irqreturn_t rcar_canfd_channel_interrupt(int irq, void *dev_id)
  1203. {
  1204. struct rcar_canfd_global *gpriv = dev_id;
  1205. u32 ch;
  1206. /* Common FIFO is a per channel resource */
  1207. for_each_set_bit(ch, &gpriv->channels_mask, gpriv->info->max_channels) {
  1208. rcar_canfd_handle_channel_err(gpriv, ch);
  1209. rcar_canfd_handle_channel_tx(gpriv, ch);
  1210. }
  1211. return IRQ_HANDLED;
  1212. }
  1213. static inline u32 rcar_canfd_compute_nominal_bit_rate_cfg(struct rcar_canfd_channel *priv,
  1214. u16 tseg1, u16 tseg2, u16 sjw, u16 brp)
  1215. {
  1216. struct rcar_canfd_global *gpriv = priv->gpriv;
  1217. const struct rcar_canfd_hw_info *info = gpriv->info;
  1218. u32 ntseg1, ntseg2, nsjw, nbrp;
  1219. if ((priv->can.ctrlmode & CAN_CTRLMODE_FD) || gpriv->info->shared_can_regs) {
  1220. ntseg1 = (tseg1 & (info->nom_bittiming->tseg1_max - 1)) << info->sh->ntseg1;
  1221. ntseg2 = (tseg2 & (info->nom_bittiming->tseg2_max - 1)) << info->sh->ntseg2;
  1222. nsjw = (sjw & (info->nom_bittiming->sjw_max - 1)) << info->sh->nsjw;
  1223. nbrp = FIELD_PREP(RCANFD_NCFG_NBRP, brp);
  1224. } else {
  1225. ntseg1 = FIELD_PREP(RCANFD_CFG_TSEG1, tseg1);
  1226. ntseg2 = FIELD_PREP(RCANFD_CFG_TSEG2, tseg2);
  1227. nsjw = FIELD_PREP(RCANFD_CFG_SJW, sjw);
  1228. nbrp = FIELD_PREP(RCANFD_CFG_BRP, brp);
  1229. }
  1230. return (ntseg1 | ntseg2 | nsjw | nbrp);
  1231. }
  1232. static inline u32 rcar_canfd_compute_data_bit_rate_cfg(const struct rcar_canfd_hw_info *info,
  1233. u16 tseg1, u16 tseg2, u16 sjw, u16 brp)
  1234. {
  1235. u32 dtseg1, dtseg2, dsjw, dbrp;
  1236. dtseg1 = (tseg1 & (info->data_bittiming->tseg1_max - 1)) << info->sh->dtseg1;
  1237. dtseg2 = (tseg2 & (info->data_bittiming->tseg2_max - 1)) << info->sh->dtseg2;
  1238. dsjw = (sjw & (info->data_bittiming->sjw_max - 1)) << 24;
  1239. dbrp = FIELD_PREP(RCANFD_DCFG_DBRP, brp);
  1240. return (dtseg1 | dtseg2 | dsjw | dbrp);
  1241. }
  1242. static void rcar_canfd_set_bittiming(struct net_device *ndev)
  1243. {
  1244. u32 mask = RCANFD_FDCFG_TDCO | RCANFD_FDCFG_TDCE | RCANFD_FDCFG_TDCOC;
  1245. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  1246. struct rcar_canfd_global *gpriv = priv->gpriv;
  1247. const struct can_bittiming *bt = &priv->can.bittiming;
  1248. const struct can_bittiming *dbt = &priv->can.fd.data_bittiming;
  1249. const struct can_tdc_const *tdc_const = priv->can.fd.tdc_const;
  1250. const struct can_tdc *tdc = &priv->can.fd.tdc;
  1251. u32 cfg, tdcmode = 0, tdco = 0;
  1252. u16 brp, sjw, tseg1, tseg2;
  1253. u32 ch = priv->channel;
  1254. /* Nominal bit timing settings */
  1255. brp = bt->brp - 1;
  1256. sjw = bt->sjw - 1;
  1257. tseg1 = bt->prop_seg + bt->phase_seg1 - 1;
  1258. tseg2 = bt->phase_seg2 - 1;
  1259. cfg = rcar_canfd_compute_nominal_bit_rate_cfg(priv, tseg1, tseg2, sjw, brp);
  1260. rcar_canfd_write(priv->base, RCANFD_CCFG(ch), cfg);
  1261. if (!(priv->can.ctrlmode & CAN_CTRLMODE_FD))
  1262. return;
  1263. /* Data bit timing settings */
  1264. brp = dbt->brp - 1;
  1265. sjw = dbt->sjw - 1;
  1266. tseg1 = dbt->prop_seg + dbt->phase_seg1 - 1;
  1267. tseg2 = dbt->phase_seg2 - 1;
  1268. cfg = rcar_canfd_compute_data_bit_rate_cfg(gpriv->info, tseg1, tseg2, sjw, brp);
  1269. writel(cfg, &gpriv->fcbase[ch].dcfg);
  1270. /* Transceiver Delay Compensation */
  1271. if (priv->can.ctrlmode & CAN_CTRLMODE_TDC_AUTO) {
  1272. /* TDC enabled, measured + offset */
  1273. tdcmode = RCANFD_FDCFG_TDCE;
  1274. tdco = tdc->tdco - 1;
  1275. } else if (priv->can.ctrlmode & CAN_CTRLMODE_TDC_MANUAL) {
  1276. /* TDC enabled, offset only */
  1277. tdcmode = RCANFD_FDCFG_TDCE | RCANFD_FDCFG_TDCOC;
  1278. tdco = min(tdc->tdcv + tdc->tdco, tdc_const->tdco_max) - 1;
  1279. }
  1280. rcar_canfd_update_bit_reg(&gpriv->fcbase[ch].cfdcfg, mask,
  1281. tdcmode | FIELD_PREP(RCANFD_FDCFG_TDCO, tdco));
  1282. }
  1283. static int rcar_canfd_start(struct net_device *ndev)
  1284. {
  1285. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  1286. struct rcar_canfd_global *gpriv = priv->gpriv;
  1287. int err = -EOPNOTSUPP;
  1288. u32 sts, ch = priv->channel;
  1289. u32 ridx = ch + RCANFD_RFFIFO_IDX;
  1290. rcar_canfd_set_bittiming(ndev);
  1291. rcar_canfd_enable_channel_interrupts(priv);
  1292. /* Set channel to Operational mode */
  1293. rcar_canfd_update_bit(priv->base, RCANFD_CCTR(ch),
  1294. RCANFD_CCTR_CHMDC_MASK, RCANFD_CCTR_CHDMC_COPM);
  1295. /* Verify channel mode change */
  1296. err = readl_poll_timeout((priv->base + RCANFD_CSTS(ch)), sts,
  1297. (sts & RCANFD_CSTS_COMSTS), 2, 500000);
  1298. if (err) {
  1299. netdev_err(ndev, "channel %u communication state failed\n", ch);
  1300. goto fail_mode_change;
  1301. }
  1302. /* Enable Common & Rx FIFO */
  1303. rcar_canfd_set_bit(priv->base, RCANFD_CFCC(gpriv, ch, RCANFD_CFFIFO_IDX),
  1304. RCANFD_CFCC_CFE);
  1305. rcar_canfd_set_bit(priv->base, RCANFD_RFCC(gpriv, ridx), RCANFD_RFCC_RFE);
  1306. priv->can.state = CAN_STATE_ERROR_ACTIVE;
  1307. return 0;
  1308. fail_mode_change:
  1309. rcar_canfd_disable_channel_interrupts(priv);
  1310. return err;
  1311. }
  1312. static int rcar_canfd_open(struct net_device *ndev)
  1313. {
  1314. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  1315. struct rcar_canfd_global *gpriv = priv->gpriv;
  1316. int err;
  1317. err = phy_power_on(priv->transceiver);
  1318. if (err) {
  1319. netdev_err(ndev, "failed to power on PHY: %pe\n", ERR_PTR(err));
  1320. return err;
  1321. }
  1322. /* Peripheral clock is already enabled in probe */
  1323. err = clk_prepare_enable(gpriv->can_clk);
  1324. if (err) {
  1325. netdev_err(ndev, "failed to enable CAN clock: %pe\n", ERR_PTR(err));
  1326. goto out_phy;
  1327. }
  1328. err = open_candev(ndev);
  1329. if (err) {
  1330. netdev_err(ndev, "open_candev() failed: %pe\n", ERR_PTR(err));
  1331. goto out_can_clock;
  1332. }
  1333. napi_enable(&priv->napi);
  1334. err = rcar_canfd_start(ndev);
  1335. if (err)
  1336. goto out_close;
  1337. netif_start_queue(ndev);
  1338. return 0;
  1339. out_close:
  1340. napi_disable(&priv->napi);
  1341. close_candev(ndev);
  1342. out_can_clock:
  1343. clk_disable_unprepare(gpriv->can_clk);
  1344. out_phy:
  1345. phy_power_off(priv->transceiver);
  1346. return err;
  1347. }
  1348. static void rcar_canfd_stop(struct net_device *ndev)
  1349. {
  1350. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  1351. struct rcar_canfd_global *gpriv = priv->gpriv;
  1352. int err;
  1353. u32 sts, ch = priv->channel;
  1354. u32 ridx = ch + RCANFD_RFFIFO_IDX;
  1355. /* Transition to channel reset mode */
  1356. rcar_canfd_update_bit(priv->base, RCANFD_CCTR(ch),
  1357. RCANFD_CCTR_CHMDC_MASK, RCANFD_CCTR_CHDMC_CRESET);
  1358. /* Check Channel reset mode */
  1359. err = readl_poll_timeout((priv->base + RCANFD_CSTS(ch)), sts,
  1360. (sts & RCANFD_CSTS_CRSTSTS), 2, 500000);
  1361. if (err)
  1362. netdev_err(ndev, "channel %u reset failed\n", ch);
  1363. rcar_canfd_disable_channel_interrupts(priv);
  1364. /* Disable Common & Rx FIFO */
  1365. rcar_canfd_clear_bit(priv->base, RCANFD_CFCC(gpriv, ch, RCANFD_CFFIFO_IDX),
  1366. RCANFD_CFCC_CFE);
  1367. rcar_canfd_clear_bit(priv->base, RCANFD_RFCC(gpriv, ridx), RCANFD_RFCC_RFE);
  1368. /* Set the state as STOPPED */
  1369. priv->can.state = CAN_STATE_STOPPED;
  1370. }
  1371. static int rcar_canfd_close(struct net_device *ndev)
  1372. {
  1373. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  1374. struct rcar_canfd_global *gpriv = priv->gpriv;
  1375. netif_stop_queue(ndev);
  1376. rcar_canfd_stop(ndev);
  1377. napi_disable(&priv->napi);
  1378. close_candev(ndev);
  1379. clk_disable_unprepare(gpriv->can_clk);
  1380. phy_power_off(priv->transceiver);
  1381. return 0;
  1382. }
  1383. static netdev_tx_t rcar_canfd_start_xmit(struct sk_buff *skb,
  1384. struct net_device *ndev)
  1385. {
  1386. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  1387. struct rcar_canfd_global *gpriv = priv->gpriv;
  1388. struct canfd_frame *cf = (struct canfd_frame *)skb->data;
  1389. u32 sts = 0, id, dlc;
  1390. unsigned long flags;
  1391. u32 ch = priv->channel;
  1392. if (can_dev_dropped_skb(ndev, skb))
  1393. return NETDEV_TX_OK;
  1394. if (cf->can_id & CAN_EFF_FLAG) {
  1395. id = cf->can_id & CAN_EFF_MASK;
  1396. id |= RCANFD_CFID_CFIDE;
  1397. } else {
  1398. id = cf->can_id & CAN_SFF_MASK;
  1399. }
  1400. if (cf->can_id & CAN_RTR_FLAG)
  1401. id |= RCANFD_CFID_CFRTR;
  1402. dlc = RCANFD_CFPTR_CFDLC(can_fd_len2dlc(cf->len));
  1403. if ((priv->can.ctrlmode & CAN_CTRLMODE_FD) || gpriv->info->shared_can_regs) {
  1404. rcar_canfd_write(priv->base,
  1405. RCANFD_F_CFID(gpriv, ch, RCANFD_CFFIFO_IDX), id);
  1406. rcar_canfd_write(priv->base,
  1407. RCANFD_F_CFPTR(gpriv, ch, RCANFD_CFFIFO_IDX), dlc);
  1408. if (can_is_canfd_skb(skb)) {
  1409. /* CAN FD frame format */
  1410. sts |= RCANFD_CFFDCSTS_CFFDF;
  1411. if (cf->flags & CANFD_BRS)
  1412. sts |= RCANFD_CFFDCSTS_CFBRS;
  1413. if (priv->can.state == CAN_STATE_ERROR_PASSIVE)
  1414. sts |= RCANFD_CFFDCSTS_CFESI;
  1415. }
  1416. rcar_canfd_write(priv->base,
  1417. RCANFD_F_CFFDCSTS(gpriv, ch, RCANFD_CFFIFO_IDX), sts);
  1418. rcar_canfd_put_data(priv, cf,
  1419. RCANFD_F_CFDF(gpriv, ch, RCANFD_CFFIFO_IDX, 0));
  1420. } else {
  1421. rcar_canfd_write(priv->base,
  1422. RCANFD_C_CFID(ch, RCANFD_CFFIFO_IDX), id);
  1423. rcar_canfd_write(priv->base,
  1424. RCANFD_C_CFPTR(ch, RCANFD_CFFIFO_IDX), dlc);
  1425. rcar_canfd_put_data(priv, cf,
  1426. RCANFD_C_CFDF(ch, RCANFD_CFFIFO_IDX, 0));
  1427. }
  1428. can_put_echo_skb(skb, ndev, priv->tx_head % RCANFD_FIFO_DEPTH, 0);
  1429. spin_lock_irqsave(&priv->tx_lock, flags);
  1430. priv->tx_head++;
  1431. /* Stop the queue if we've filled all FIFO entries */
  1432. if (priv->tx_head - priv->tx_tail >= RCANFD_FIFO_DEPTH)
  1433. netif_stop_queue(ndev);
  1434. /* Start Tx: Write 0xff to CFPC to increment the CPU-side
  1435. * pointer for the Common FIFO
  1436. */
  1437. rcar_canfd_write(priv->base,
  1438. RCANFD_CFPCTR(gpriv, ch, RCANFD_CFFIFO_IDX), 0xff);
  1439. spin_unlock_irqrestore(&priv->tx_lock, flags);
  1440. return NETDEV_TX_OK;
  1441. }
  1442. static void rcar_canfd_rx_pkt(struct rcar_canfd_channel *priv)
  1443. {
  1444. struct net_device *ndev = priv->ndev;
  1445. struct net_device_stats *stats = &ndev->stats;
  1446. struct rcar_canfd_global *gpriv = priv->gpriv;
  1447. struct canfd_frame *cf;
  1448. struct sk_buff *skb;
  1449. u32 sts = 0, id, dlc;
  1450. u32 ch = priv->channel;
  1451. u32 ridx = ch + RCANFD_RFFIFO_IDX;
  1452. if ((priv->can.ctrlmode & CAN_CTRLMODE_FD) || gpriv->info->shared_can_regs) {
  1453. id = rcar_canfd_read(priv->base, RCANFD_F_RFID(gpriv, ridx));
  1454. dlc = rcar_canfd_read(priv->base, RCANFD_F_RFPTR(gpriv, ridx));
  1455. sts = rcar_canfd_read(priv->base, RCANFD_F_RFFDSTS(gpriv, ridx));
  1456. if ((priv->can.ctrlmode & CAN_CTRLMODE_FD) &&
  1457. sts & RCANFD_RFFDSTS_RFFDF)
  1458. skb = alloc_canfd_skb(ndev, &cf);
  1459. else
  1460. skb = alloc_can_skb(ndev, (struct can_frame **)&cf);
  1461. } else {
  1462. id = rcar_canfd_read(priv->base, RCANFD_C_RFID(ridx));
  1463. dlc = rcar_canfd_read(priv->base, RCANFD_C_RFPTR(ridx));
  1464. skb = alloc_can_skb(ndev, (struct can_frame **)&cf);
  1465. }
  1466. if (!skb) {
  1467. stats->rx_dropped++;
  1468. return;
  1469. }
  1470. if (id & RCANFD_RFID_RFIDE)
  1471. cf->can_id = (id & CAN_EFF_MASK) | CAN_EFF_FLAG;
  1472. else
  1473. cf->can_id = id & CAN_SFF_MASK;
  1474. if (priv->can.ctrlmode & CAN_CTRLMODE_FD) {
  1475. if (sts & RCANFD_RFFDSTS_RFFDF)
  1476. cf->len = can_fd_dlc2len(RCANFD_RFPTR_RFDLC(dlc));
  1477. else
  1478. cf->len = can_cc_dlc2len(RCANFD_RFPTR_RFDLC(dlc));
  1479. if (sts & RCANFD_RFFDSTS_RFESI) {
  1480. cf->flags |= CANFD_ESI;
  1481. netdev_dbg(ndev, "ESI Error\n");
  1482. }
  1483. if (!(sts & RCANFD_RFFDSTS_RFFDF) && (id & RCANFD_RFID_RFRTR)) {
  1484. cf->can_id |= CAN_RTR_FLAG;
  1485. } else {
  1486. if (sts & RCANFD_RFFDSTS_RFBRS)
  1487. cf->flags |= CANFD_BRS;
  1488. rcar_canfd_get_data(priv, cf, RCANFD_F_RFDF(gpriv, ridx, 0));
  1489. }
  1490. } else {
  1491. cf->len = can_cc_dlc2len(RCANFD_RFPTR_RFDLC(dlc));
  1492. if (id & RCANFD_RFID_RFRTR)
  1493. cf->can_id |= CAN_RTR_FLAG;
  1494. else if (gpriv->info->shared_can_regs)
  1495. rcar_canfd_get_data(priv, cf, RCANFD_F_RFDF(gpriv, ridx, 0));
  1496. else
  1497. rcar_canfd_get_data(priv, cf, RCANFD_C_RFDF(ridx, 0));
  1498. }
  1499. /* Write 0xff to RFPC to increment the CPU-side
  1500. * pointer of the Rx FIFO
  1501. */
  1502. rcar_canfd_write(priv->base, RCANFD_RFPCTR(gpriv, ridx), 0xff);
  1503. if (!(cf->can_id & CAN_RTR_FLAG))
  1504. stats->rx_bytes += cf->len;
  1505. stats->rx_packets++;
  1506. netif_receive_skb(skb);
  1507. }
  1508. static int rcar_canfd_rx_poll(struct napi_struct *napi, int quota)
  1509. {
  1510. struct rcar_canfd_channel *priv =
  1511. container_of(napi, struct rcar_canfd_channel, napi);
  1512. struct rcar_canfd_global *gpriv = priv->gpriv;
  1513. int num_pkts;
  1514. u32 sts;
  1515. u32 ch = priv->channel;
  1516. u32 ridx = ch + RCANFD_RFFIFO_IDX;
  1517. for (num_pkts = 0; num_pkts < quota; num_pkts++) {
  1518. sts = rcar_canfd_read(priv->base, RCANFD_RFSTS(gpriv, ridx));
  1519. /* Check FIFO empty condition */
  1520. if (sts & RCANFD_RFSTS_RFEMP)
  1521. break;
  1522. rcar_canfd_rx_pkt(priv);
  1523. /* Clear interrupt bit */
  1524. if (sts & RCANFD_RFSTS_RFIF)
  1525. rcar_canfd_write(priv->base, RCANFD_RFSTS(gpriv, ridx),
  1526. sts & ~RCANFD_RFSTS_RFIF);
  1527. }
  1528. /* All packets processed */
  1529. if (num_pkts < quota) {
  1530. if (napi_complete_done(napi, num_pkts)) {
  1531. /* Enable Rx FIFO interrupts */
  1532. rcar_canfd_set_bit(priv->base, RCANFD_RFCC(gpriv, ridx),
  1533. RCANFD_RFCC_RFIE);
  1534. }
  1535. }
  1536. return num_pkts;
  1537. }
  1538. static unsigned int rcar_canfd_get_tdcr(struct rcar_canfd_global *gpriv,
  1539. unsigned int ch)
  1540. {
  1541. u32 sts = readl(&gpriv->fcbase[ch].cfdsts);
  1542. u32 tdcr = FIELD_GET(RCANFD_FDSTS_TDCR, sts);
  1543. return tdcr & (gpriv->info->tdc_const->tdcv_max - 1);
  1544. }
  1545. static int rcar_canfd_get_auto_tdcv(const struct net_device *ndev, u32 *tdcv)
  1546. {
  1547. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  1548. u32 tdco = priv->can.fd.tdc.tdco;
  1549. u32 tdcr;
  1550. /* Transceiver Delay Compensation Result */
  1551. tdcr = rcar_canfd_get_tdcr(priv->gpriv, priv->channel) + 1;
  1552. *tdcv = tdcr < tdco ? 0 : tdcr - tdco;
  1553. return 0;
  1554. }
  1555. static int rcar_canfd_do_set_mode(struct net_device *ndev, enum can_mode mode)
  1556. {
  1557. int err;
  1558. switch (mode) {
  1559. case CAN_MODE_START:
  1560. err = rcar_canfd_start(ndev);
  1561. if (err)
  1562. return err;
  1563. netif_wake_queue(ndev);
  1564. return 0;
  1565. default:
  1566. return -EOPNOTSUPP;
  1567. }
  1568. }
  1569. static int rcar_canfd_get_berr_counter(const struct net_device *ndev,
  1570. struct can_berr_counter *bec)
  1571. {
  1572. struct rcar_canfd_channel *priv = netdev_priv(ndev);
  1573. u32 val, ch = priv->channel;
  1574. /* Peripheral clock is already enabled in probe */
  1575. val = rcar_canfd_read(priv->base, RCANFD_CSTS(ch));
  1576. bec->txerr = RCANFD_CSTS_TECCNT(val);
  1577. bec->rxerr = RCANFD_CSTS_RECCNT(val);
  1578. return 0;
  1579. }
  1580. static const struct net_device_ops rcar_canfd_netdev_ops = {
  1581. .ndo_open = rcar_canfd_open,
  1582. .ndo_stop = rcar_canfd_close,
  1583. .ndo_start_xmit = rcar_canfd_start_xmit,
  1584. };
  1585. static const struct ethtool_ops rcar_canfd_ethtool_ops = {
  1586. .get_ts_info = ethtool_op_get_ts_info,
  1587. };
  1588. static int rcar_canfd_channel_probe(struct rcar_canfd_global *gpriv, u32 ch,
  1589. u32 fcan_freq, struct phy *transceiver)
  1590. {
  1591. const struct rcar_canfd_hw_info *info = gpriv->info;
  1592. struct platform_device *pdev = gpriv->pdev;
  1593. struct device *dev = &pdev->dev;
  1594. struct rcar_canfd_channel *priv;
  1595. struct net_device *ndev;
  1596. int err = -ENODEV;
  1597. ndev = alloc_candev(sizeof(*priv), RCANFD_FIFO_DEPTH);
  1598. if (!ndev)
  1599. return -ENOMEM;
  1600. priv = netdev_priv(ndev);
  1601. ndev->netdev_ops = &rcar_canfd_netdev_ops;
  1602. ndev->ethtool_ops = &rcar_canfd_ethtool_ops;
  1603. ndev->flags |= IFF_ECHO;
  1604. priv->ndev = ndev;
  1605. priv->base = gpriv->base;
  1606. priv->transceiver = transceiver;
  1607. priv->channel = ch;
  1608. priv->gpriv = gpriv;
  1609. if (transceiver)
  1610. priv->can.bitrate_max = transceiver->attrs.max_link_rate;
  1611. priv->can.clock.freq = fcan_freq;
  1612. dev_info(dev, "can_clk rate is %u\n", priv->can.clock.freq);
  1613. if (info->multi_channel_irqs) {
  1614. char *irq_name;
  1615. char name[10];
  1616. int err_irq;
  1617. int tx_irq;
  1618. scnprintf(name, sizeof(name), "ch%u_err", ch);
  1619. err_irq = platform_get_irq_byname(pdev, name);
  1620. if (err_irq < 0) {
  1621. err = err_irq;
  1622. goto fail;
  1623. }
  1624. scnprintf(name, sizeof(name), "ch%u_trx", ch);
  1625. tx_irq = platform_get_irq_byname(pdev, name);
  1626. if (tx_irq < 0) {
  1627. err = tx_irq;
  1628. goto fail;
  1629. }
  1630. irq_name = devm_kasprintf(dev, GFP_KERNEL, "canfd.ch%d_err",
  1631. ch);
  1632. if (!irq_name) {
  1633. err = -ENOMEM;
  1634. goto fail;
  1635. }
  1636. err = devm_request_irq(dev, err_irq,
  1637. rcar_canfd_channel_err_interrupt, 0,
  1638. irq_name, priv);
  1639. if (err) {
  1640. dev_err(dev, "devm_request_irq CH Err %d failed: %pe\n",
  1641. err_irq, ERR_PTR(err));
  1642. goto fail;
  1643. }
  1644. irq_name = devm_kasprintf(dev, GFP_KERNEL, "canfd.ch%d_trx",
  1645. ch);
  1646. if (!irq_name) {
  1647. err = -ENOMEM;
  1648. goto fail;
  1649. }
  1650. err = devm_request_irq(dev, tx_irq,
  1651. rcar_canfd_channel_tx_interrupt, 0,
  1652. irq_name, priv);
  1653. if (err) {
  1654. dev_err(dev, "devm_request_irq Tx %d failed: %pe\n",
  1655. tx_irq, ERR_PTR(err));
  1656. goto fail;
  1657. }
  1658. }
  1659. if (gpriv->fdmode) {
  1660. priv->can.bittiming_const = gpriv->info->nom_bittiming;
  1661. priv->can.fd.data_bittiming_const = gpriv->info->data_bittiming;
  1662. priv->can.fd.tdc_const = gpriv->info->tdc_const;
  1663. /* Controller starts in CAN FD only mode */
  1664. err = can_set_static_ctrlmode(ndev, CAN_CTRLMODE_FD);
  1665. if (err)
  1666. goto fail;
  1667. priv->can.ctrlmode_supported = CAN_CTRLMODE_BERR_REPORTING |
  1668. CAN_CTRLMODE_TDC_AUTO |
  1669. CAN_CTRLMODE_TDC_MANUAL;
  1670. priv->can.fd.do_get_auto_tdcv = rcar_canfd_get_auto_tdcv;
  1671. } else {
  1672. /* Controller starts in Classical CAN only mode */
  1673. if (gpriv->info->shared_can_regs)
  1674. priv->can.bittiming_const = gpriv->info->nom_bittiming;
  1675. else
  1676. priv->can.bittiming_const = &rcar_canfd_bittiming_const;
  1677. priv->can.ctrlmode_supported = CAN_CTRLMODE_BERR_REPORTING;
  1678. }
  1679. priv->can.do_set_mode = rcar_canfd_do_set_mode;
  1680. priv->can.do_get_berr_counter = rcar_canfd_get_berr_counter;
  1681. SET_NETDEV_DEV(ndev, dev);
  1682. netif_napi_add_weight(ndev, &priv->napi, rcar_canfd_rx_poll,
  1683. RCANFD_NAPI_WEIGHT);
  1684. spin_lock_init(&priv->tx_lock);
  1685. gpriv->ch[priv->channel] = priv;
  1686. err = register_candev(ndev);
  1687. if (err) {
  1688. dev_err(dev, "register_candev() failed: %pe\n", ERR_PTR(err));
  1689. goto fail_candev;
  1690. }
  1691. dev_info(dev, "device registered (channel %u)\n", priv->channel);
  1692. return 0;
  1693. fail_candev:
  1694. netif_napi_del(&priv->napi);
  1695. fail:
  1696. free_candev(ndev);
  1697. return err;
  1698. }
  1699. static void rcar_canfd_channel_remove(struct rcar_canfd_global *gpriv, u32 ch)
  1700. {
  1701. struct rcar_canfd_channel *priv = gpriv->ch[ch];
  1702. if (priv) {
  1703. unregister_candev(priv->ndev);
  1704. netif_napi_del(&priv->napi);
  1705. free_candev(priv->ndev);
  1706. }
  1707. }
  1708. static int rcar_canfd_global_init(struct rcar_canfd_global *gpriv)
  1709. {
  1710. struct device *dev = &gpriv->pdev->dev;
  1711. u32 rule_entry = 0;
  1712. u32 ch, sts;
  1713. int err;
  1714. err = reset_control_reset(gpriv->rstc1);
  1715. if (err)
  1716. return err;
  1717. err = reset_control_reset(gpriv->rstc2);
  1718. if (err)
  1719. goto fail_reset1;
  1720. /* Enable peripheral clock for register access */
  1721. err = clk_prepare_enable(gpriv->clkp);
  1722. if (err) {
  1723. dev_err(dev, "failed to enable peripheral clock: %pe\n",
  1724. ERR_PTR(err));
  1725. goto fail_reset2;
  1726. }
  1727. /* Enable RAM clock */
  1728. err = clk_prepare_enable(gpriv->clk_ram);
  1729. if (err) {
  1730. dev_err(dev,
  1731. "failed to enable RAM clock, error %d\n", err);
  1732. goto fail_clk;
  1733. }
  1734. err = rcar_canfd_reset_controller(gpriv);
  1735. if (err) {
  1736. dev_err(dev, "reset controller failed: %pe\n", ERR_PTR(err));
  1737. goto fail_ram_clk;
  1738. }
  1739. /* Controller in Global reset & Channel reset mode */
  1740. rcar_canfd_configure_controller(gpriv);
  1741. /* Configure per channel attributes */
  1742. for_each_set_bit(ch, &gpriv->channels_mask, gpriv->info->max_channels) {
  1743. /* Configure Channel's Rx fifo */
  1744. rcar_canfd_configure_rx(gpriv, ch);
  1745. /* Configure Channel's Tx (Common) fifo */
  1746. rcar_canfd_configure_tx(gpriv, ch);
  1747. /* Configure receive rules */
  1748. rcar_canfd_configure_afl_rules(gpriv, ch, rule_entry);
  1749. rule_entry += RCANFD_CHANNEL_NUMRULES;
  1750. }
  1751. /* Configure common interrupts */
  1752. rcar_canfd_enable_global_interrupts(gpriv);
  1753. /* Start Global operation mode */
  1754. rcar_canfd_update_bit(gpriv->base, RCANFD_GCTR, RCANFD_GCTR_GMDC_MASK,
  1755. RCANFD_GCTR_GMDC_GOPM);
  1756. /* Verify mode change */
  1757. err = readl_poll_timeout((gpriv->base + RCANFD_GSTS), sts,
  1758. !(sts & RCANFD_GSTS_GNOPM), 2, 500000);
  1759. if (err) {
  1760. dev_err(dev, "global operational mode failed\n");
  1761. goto fail_mode;
  1762. }
  1763. return 0;
  1764. fail_mode:
  1765. rcar_canfd_disable_global_interrupts(gpriv);
  1766. fail_ram_clk:
  1767. clk_disable_unprepare(gpriv->clk_ram);
  1768. fail_clk:
  1769. clk_disable_unprepare(gpriv->clkp);
  1770. fail_reset2:
  1771. reset_control_assert(gpriv->rstc2);
  1772. fail_reset1:
  1773. reset_control_assert(gpriv->rstc1);
  1774. return err;
  1775. }
  1776. static void rcar_canfd_global_deinit(struct rcar_canfd_global *gpriv, bool full)
  1777. {
  1778. rcar_canfd_disable_global_interrupts(gpriv);
  1779. if (full) {
  1780. rcar_canfd_reset_controller(gpriv);
  1781. /* Enter global sleep mode */
  1782. rcar_canfd_set_bit(gpriv->base, RCANFD_GCTR, RCANFD_GCTR_GSLPR);
  1783. }
  1784. clk_disable_unprepare(gpriv->clk_ram);
  1785. clk_disable_unprepare(gpriv->clkp);
  1786. reset_control_assert(gpriv->rstc2);
  1787. reset_control_assert(gpriv->rstc1);
  1788. }
  1789. static int rcar_canfd_probe(struct platform_device *pdev)
  1790. {
  1791. struct phy *transceivers[RCANFD_NUM_CHANNELS] = { NULL, };
  1792. const struct rcar_canfd_hw_info *info;
  1793. struct device *dev = &pdev->dev;
  1794. void __iomem *addr;
  1795. struct rcar_canfd_global *gpriv;
  1796. struct device_node *of_child;
  1797. unsigned long channels_mask = 0;
  1798. int err, ch_irq, g_irq;
  1799. int g_err_irq, g_recc_irq;
  1800. bool fdmode = true; /* CAN FD only mode - default */
  1801. char name[9] = "channelX";
  1802. u32 ch, fcan_freq;
  1803. int i;
  1804. info = of_device_get_match_data(dev);
  1805. if (of_property_read_bool(dev->of_node, "renesas,no-can-fd"))
  1806. fdmode = false; /* Classical CAN only mode */
  1807. for (i = 0; i < info->max_channels; ++i) {
  1808. name[7] = '0' + i;
  1809. of_child = of_get_available_child_by_name(dev->of_node, name);
  1810. if (of_child) {
  1811. channels_mask |= BIT(i);
  1812. transceivers[i] = devm_of_phy_optional_get(dev,
  1813. of_child, NULL);
  1814. of_node_put(of_child);
  1815. }
  1816. if (IS_ERR(transceivers[i]))
  1817. return PTR_ERR(transceivers[i]);
  1818. }
  1819. if (info->shared_global_irqs) {
  1820. ch_irq = platform_get_irq_byname_optional(pdev, "ch_int");
  1821. if (ch_irq < 0) {
  1822. /* For backward compatibility get irq by index */
  1823. ch_irq = platform_get_irq(pdev, 0);
  1824. if (ch_irq < 0)
  1825. return ch_irq;
  1826. }
  1827. g_irq = platform_get_irq_byname_optional(pdev, "g_int");
  1828. if (g_irq < 0) {
  1829. /* For backward compatibility get irq by index */
  1830. g_irq = platform_get_irq(pdev, 1);
  1831. if (g_irq < 0)
  1832. return g_irq;
  1833. }
  1834. } else {
  1835. g_err_irq = platform_get_irq_byname(pdev, "g_err");
  1836. if (g_err_irq < 0)
  1837. return g_err_irq;
  1838. g_recc_irq = platform_get_irq_byname(pdev, "g_recc");
  1839. if (g_recc_irq < 0)
  1840. return g_recc_irq;
  1841. }
  1842. /* Global controller context */
  1843. gpriv = devm_kzalloc(dev, sizeof(*gpriv), GFP_KERNEL);
  1844. if (!gpriv)
  1845. return -ENOMEM;
  1846. gpriv->pdev = pdev;
  1847. gpriv->channels_mask = channels_mask;
  1848. gpriv->fdmode = fdmode;
  1849. gpriv->info = info;
  1850. if (of_property_read_bool(dev->of_node, "renesas,fd-only"))
  1851. gpriv->fd_only_mode = true; /* FD-Only mode for CAN-FD */
  1852. gpriv->rstc1 = devm_reset_control_get_optional_exclusive(dev, "rstp_n");
  1853. if (IS_ERR(gpriv->rstc1))
  1854. return dev_err_probe(dev, PTR_ERR(gpriv->rstc1),
  1855. "failed to get rstp_n\n");
  1856. gpriv->rstc2 = devm_reset_control_get_optional_exclusive(dev, "rstc_n");
  1857. if (IS_ERR(gpriv->rstc2))
  1858. return dev_err_probe(dev, PTR_ERR(gpriv->rstc2),
  1859. "failed to get rstc_n\n");
  1860. /* Peripheral clock */
  1861. gpriv->clkp = devm_clk_get(dev, "fck");
  1862. if (IS_ERR(gpriv->clkp))
  1863. return dev_err_probe(dev, PTR_ERR(gpriv->clkp),
  1864. "cannot get peripheral clock\n");
  1865. /* fCAN clock: Pick External clock. If not available fallback to
  1866. * CANFD clock
  1867. */
  1868. gpriv->can_clk = devm_clk_get(dev, "can_clk");
  1869. if (IS_ERR(gpriv->can_clk) || (clk_get_rate(gpriv->can_clk) == 0)) {
  1870. gpriv->can_clk = devm_clk_get(dev, "canfd");
  1871. if (IS_ERR(gpriv->can_clk))
  1872. return dev_err_probe(dev, PTR_ERR(gpriv->can_clk),
  1873. "cannot get canfd clock\n");
  1874. /* CANFD clock may be further divided within the IP */
  1875. fcan_freq = clk_get_rate(gpriv->can_clk) / info->postdiv;
  1876. } else {
  1877. fcan_freq = clk_get_rate(gpriv->can_clk);
  1878. gpriv->extclk = gpriv->info->external_clk;
  1879. }
  1880. gpriv->clk_ram = devm_clk_get_optional(dev, "ram_clk");
  1881. if (IS_ERR(gpriv->clk_ram))
  1882. return dev_err_probe(dev, PTR_ERR(gpriv->clk_ram),
  1883. "cannot get ram clock\n");
  1884. addr = devm_platform_ioremap_resource(pdev, 0);
  1885. if (IS_ERR(addr)) {
  1886. err = PTR_ERR(addr);
  1887. goto fail_dev;
  1888. }
  1889. gpriv->base = addr;
  1890. gpriv->fcbase = addr + gpriv->info->regs->coffset;
  1891. /* Request IRQ that's common for both channels */
  1892. if (info->shared_global_irqs) {
  1893. err = devm_request_irq(dev, ch_irq,
  1894. rcar_canfd_channel_interrupt, 0,
  1895. "canfd.ch_int", gpriv);
  1896. if (err) {
  1897. dev_err(dev, "devm_request_irq %d failed: %pe\n",
  1898. ch_irq, ERR_PTR(err));
  1899. goto fail_dev;
  1900. }
  1901. err = devm_request_irq(dev, g_irq, rcar_canfd_global_interrupt,
  1902. 0, "canfd.g_int", gpriv);
  1903. if (err) {
  1904. dev_err(dev, "devm_request_irq %d failed: %pe\n",
  1905. g_irq, ERR_PTR(err));
  1906. goto fail_dev;
  1907. }
  1908. } else {
  1909. err = devm_request_irq(dev, g_recc_irq,
  1910. rcar_canfd_global_receive_fifo_interrupt, 0,
  1911. "canfd.g_recc", gpriv);
  1912. if (err) {
  1913. dev_err(dev, "devm_request_irq %d failed: %pe\n",
  1914. g_recc_irq, ERR_PTR(err));
  1915. goto fail_dev;
  1916. }
  1917. err = devm_request_irq(dev, g_err_irq,
  1918. rcar_canfd_global_err_interrupt, 0,
  1919. "canfd.g_err", gpriv);
  1920. if (err) {
  1921. dev_err(dev, "devm_request_irq %d failed: %pe\n",
  1922. g_err_irq, ERR_PTR(err));
  1923. goto fail_dev;
  1924. }
  1925. }
  1926. err = rcar_canfd_global_init(gpriv);
  1927. if (err)
  1928. goto fail_mode;
  1929. for_each_set_bit(ch, &gpriv->channels_mask, info->max_channels) {
  1930. err = rcar_canfd_channel_probe(gpriv, ch, fcan_freq,
  1931. transceivers[ch]);
  1932. if (err)
  1933. goto fail_channel;
  1934. }
  1935. platform_set_drvdata(pdev, gpriv);
  1936. dev_info(dev, "global operational state (%s clk, %s mode)\n",
  1937. gpriv->extclk ? "ext" : "canfd",
  1938. gpriv->fdmode ? (gpriv->fd_only_mode ? "fd-only" : "fd") : "classical");
  1939. return 0;
  1940. fail_channel:
  1941. for_each_set_bit(ch, &gpriv->channels_mask, info->max_channels)
  1942. rcar_canfd_channel_remove(gpriv, ch);
  1943. fail_mode:
  1944. rcar_canfd_global_deinit(gpriv, false);
  1945. fail_dev:
  1946. return err;
  1947. }
  1948. static void rcar_canfd_remove(struct platform_device *pdev)
  1949. {
  1950. struct rcar_canfd_global *gpriv = platform_get_drvdata(pdev);
  1951. u32 ch;
  1952. for_each_set_bit(ch, &gpriv->channels_mask, gpriv->info->max_channels) {
  1953. rcar_canfd_disable_channel_interrupts(gpriv->ch[ch]);
  1954. rcar_canfd_channel_remove(gpriv, ch);
  1955. }
  1956. rcar_canfd_global_deinit(gpriv, true);
  1957. }
  1958. static int rcar_canfd_suspend(struct device *dev)
  1959. {
  1960. struct rcar_canfd_global *gpriv = dev_get_drvdata(dev);
  1961. int err;
  1962. u32 ch;
  1963. for_each_set_bit(ch, &gpriv->channels_mask, gpriv->info->max_channels) {
  1964. struct rcar_canfd_channel *priv = gpriv->ch[ch];
  1965. struct net_device *ndev = priv->ndev;
  1966. if (!netif_running(ndev))
  1967. continue;
  1968. netif_device_detach(ndev);
  1969. err = rcar_canfd_close(ndev);
  1970. if (err) {
  1971. netdev_err(ndev, "rcar_canfd_close() failed %pe\n",
  1972. ERR_PTR(err));
  1973. return err;
  1974. }
  1975. priv->can.state = CAN_STATE_SLEEPING;
  1976. }
  1977. /* TODO Skip if wake-up (which is not yet supported) is enabled */
  1978. rcar_canfd_global_deinit(gpriv, false);
  1979. return 0;
  1980. }
  1981. static int rcar_canfd_resume(struct device *dev)
  1982. {
  1983. struct rcar_canfd_global *gpriv = dev_get_drvdata(dev);
  1984. int err;
  1985. u32 ch;
  1986. err = rcar_canfd_global_init(gpriv);
  1987. if (err) {
  1988. dev_err(dev, "rcar_canfd_global_init() failed %pe\n", ERR_PTR(err));
  1989. return err;
  1990. }
  1991. for_each_set_bit(ch, &gpriv->channels_mask, gpriv->info->max_channels) {
  1992. struct rcar_canfd_channel *priv = gpriv->ch[ch];
  1993. struct net_device *ndev = priv->ndev;
  1994. if (!netif_running(ndev))
  1995. continue;
  1996. err = rcar_canfd_open(ndev);
  1997. if (err) {
  1998. netdev_err(ndev, "rcar_canfd_open() failed %pe\n",
  1999. ERR_PTR(err));
  2000. return err;
  2001. }
  2002. netif_device_attach(ndev);
  2003. }
  2004. return 0;
  2005. }
  2006. static DEFINE_SIMPLE_DEV_PM_OPS(rcar_canfd_pm_ops, rcar_canfd_suspend,
  2007. rcar_canfd_resume);
  2008. static const __maybe_unused struct of_device_id rcar_canfd_of_table[] = {
  2009. { .compatible = "renesas,r8a779a0-canfd", .data = &rcar_gen4_hw_info },
  2010. { .compatible = "renesas,r9a09g047-canfd", .data = &r9a09g047_hw_info },
  2011. { .compatible = "renesas,r9a09g077-canfd", .data = &r9a09g077_hw_info },
  2012. { .compatible = "renesas,rcar-gen3-canfd", .data = &rcar_gen3_hw_info },
  2013. { .compatible = "renesas,rcar-gen4-canfd", .data = &rcar_gen4_hw_info },
  2014. { .compatible = "renesas,rzg2l-canfd", .data = &rzg2l_hw_info },
  2015. { }
  2016. };
  2017. MODULE_DEVICE_TABLE(of, rcar_canfd_of_table);
  2018. static struct platform_driver rcar_canfd_driver = {
  2019. .driver = {
  2020. .name = RCANFD_DRV_NAME,
  2021. .of_match_table = of_match_ptr(rcar_canfd_of_table),
  2022. .pm = pm_sleep_ptr(&rcar_canfd_pm_ops),
  2023. },
  2024. .probe = rcar_canfd_probe,
  2025. .remove = rcar_canfd_remove,
  2026. };
  2027. module_platform_driver(rcar_canfd_driver);
  2028. MODULE_AUTHOR("Ramesh Shanmugasundaram <ramesh.shanmugasundaram@bp.renesas.com>");
  2029. MODULE_LICENSE("GPL");
  2030. MODULE_DESCRIPTION("CAN FD driver for Renesas R-Car SoC");
  2031. MODULE_ALIAS("platform:" RCANFD_DRV_NAME);