1 // SPDX-License-Identifier: GPL-2.0 2 // CAN bus driver for Bosch M_CAN controller 3 // Copyright (C) 2014 Freescale Semiconductor, Inc. 4 // Dong Aisheng <b29396@freescale.com> 5 // Copyright (C) 2018-19 Texas Instruments Incorporated - http://www.ti.com/ 6 7 /* Bosch M_CAN user manual can be obtained from: 8 * https://github.com/linux-can/can-doc/tree/master/m_can 9 */ 10 11 #include <linux/bitfield.h> 12 #include <linux/interrupt.h> 13 #include <linux/io.h> 14 #include <linux/kernel.h> 15 #include <linux/module.h> 16 #include <linux/netdevice.h> 17 #include <linux/of.h> 18 #include <linux/of_device.h> 19 #include <linux/platform_device.h> 20 #include <linux/pm_runtime.h> 21 #include <linux/iopoll.h> 22 #include <linux/can/dev.h> 23 #include <linux/pinctrl/consumer.h> 24 #include <linux/phy/phy.h> 25 26 #include "m_can.h" 27 28 /* registers definition */ 29 enum m_can_reg { 30 M_CAN_CREL = 0x0, 31 M_CAN_ENDN = 0x4, 32 M_CAN_CUST = 0x8, 33 M_CAN_DBTP = 0xc, 34 M_CAN_TEST = 0x10, 35 M_CAN_RWD = 0x14, 36 M_CAN_CCCR = 0x18, 37 M_CAN_NBTP = 0x1c, 38 M_CAN_TSCC = 0x20, 39 M_CAN_TSCV = 0x24, 40 M_CAN_TOCC = 0x28, 41 M_CAN_TOCV = 0x2c, 42 M_CAN_ECR = 0x40, 43 M_CAN_PSR = 0x44, 44 /* TDCR Register only available for version >=3.1.x */ 45 M_CAN_TDCR = 0x48, 46 M_CAN_IR = 0x50, 47 M_CAN_IE = 0x54, 48 M_CAN_ILS = 0x58, 49 M_CAN_ILE = 0x5c, 50 M_CAN_GFC = 0x80, 51 M_CAN_SIDFC = 0x84, 52 M_CAN_XIDFC = 0x88, 53 M_CAN_XIDAM = 0x90, 54 M_CAN_HPMS = 0x94, 55 M_CAN_NDAT1 = 0x98, 56 M_CAN_NDAT2 = 0x9c, 57 M_CAN_RXF0C = 0xa0, 58 M_CAN_RXF0S = 0xa4, 59 M_CAN_RXF0A = 0xa8, 60 M_CAN_RXBC = 0xac, 61 M_CAN_RXF1C = 0xb0, 62 M_CAN_RXF1S = 0xb4, 63 M_CAN_RXF1A = 0xb8, 64 M_CAN_RXESC = 0xbc, 65 M_CAN_TXBC = 0xc0, 66 M_CAN_TXFQS = 0xc4, 67 M_CAN_TXESC = 0xc8, 68 M_CAN_TXBRP = 0xcc, 69 M_CAN_TXBAR = 0xd0, 70 M_CAN_TXBCR = 0xd4, 71 M_CAN_TXBTO = 0xd8, 72 M_CAN_TXBCF = 0xdc, 73 M_CAN_TXBTIE = 0xe0, 74 M_CAN_TXBCIE = 0xe4, 75 M_CAN_TXEFC = 0xf0, 76 M_CAN_TXEFS = 0xf4, 77 M_CAN_TXEFA = 0xf8, 78 }; 79 80 /* message ram configuration data length */ 81 #define MRAM_CFG_LEN 8 82 83 /* Core Release Register (CREL) */ 84 #define CREL_REL_MASK GENMASK(31, 28) 85 #define CREL_STEP_MASK GENMASK(27, 24) 86 #define CREL_SUBSTEP_MASK GENMASK(23, 20) 87 88 /* Data Bit Timing & Prescaler Register (DBTP) */ 89 #define DBTP_TDC BIT(23) 90 #define DBTP_DBRP_MASK GENMASK(20, 16) 91 #define DBTP_DTSEG1_MASK GENMASK(12, 8) 92 #define DBTP_DTSEG2_MASK GENMASK(7, 4) 93 #define DBTP_DSJW_MASK GENMASK(3, 0) 94 95 /* Transmitter Delay Compensation Register (TDCR) */ 96 #define TDCR_TDCO_MASK GENMASK(14, 8) 97 #define TDCR_TDCF_MASK GENMASK(6, 0) 98 99 /* Test Register (TEST) */ 100 #define TEST_LBCK BIT(4) 101 102 /* CC Control Register (CCCR) */ 103 #define CCCR_TXP BIT(14) 104 #define CCCR_TEST BIT(7) 105 #define CCCR_DAR BIT(6) 106 #define CCCR_MON BIT(5) 107 #define CCCR_CSR BIT(4) 108 #define CCCR_CSA BIT(3) 109 #define CCCR_ASM BIT(2) 110 #define CCCR_CCE BIT(1) 111 #define CCCR_INIT BIT(0) 112 /* for version 3.0.x */ 113 #define CCCR_CMR_MASK GENMASK(11, 10) 114 #define CCCR_CMR_CANFD 0x1 115 #define CCCR_CMR_CANFD_BRS 0x2 116 #define CCCR_CMR_CAN 0x3 117 #define CCCR_CME_MASK GENMASK(9, 8) 118 #define CCCR_CME_CAN 0 119 #define CCCR_CME_CANFD 0x1 120 #define CCCR_CME_CANFD_BRS 0x2 121 /* for version >=3.1.x */ 122 #define CCCR_EFBI BIT(13) 123 #define CCCR_PXHD BIT(12) 124 #define CCCR_BRSE BIT(9) 125 #define CCCR_FDOE BIT(8) 126 /* for version >=3.2.x */ 127 #define CCCR_NISO BIT(15) 128 /* for version >=3.3.x */ 129 #define CCCR_WMM BIT(11) 130 #define CCCR_UTSU BIT(10) 131 132 /* Nominal Bit Timing & Prescaler Register (NBTP) */ 133 #define NBTP_NSJW_MASK GENMASK(31, 25) 134 #define NBTP_NBRP_MASK GENMASK(24, 16) 135 #define NBTP_NTSEG1_MASK GENMASK(15, 8) 136 #define NBTP_NTSEG2_MASK GENMASK(6, 0) 137 138 /* Timestamp Counter Configuration Register (TSCC) */ 139 #define TSCC_TCP_MASK GENMASK(19, 16) 140 #define TSCC_TSS_MASK GENMASK(1, 0) 141 #define TSCC_TSS_DISABLE 0x0 142 #define TSCC_TSS_INTERNAL 0x1 143 #define TSCC_TSS_EXTERNAL 0x2 144 145 /* Timestamp Counter Value Register (TSCV) */ 146 #define TSCV_TSC_MASK GENMASK(15, 0) 147 148 /* Error Counter Register (ECR) */ 149 #define ECR_RP BIT(15) 150 #define ECR_REC_MASK GENMASK(14, 8) 151 #define ECR_TEC_MASK GENMASK(7, 0) 152 153 /* Protocol Status Register (PSR) */ 154 #define PSR_BO BIT(7) 155 #define PSR_EW BIT(6) 156 #define PSR_EP BIT(5) 157 #define PSR_LEC_MASK GENMASK(2, 0) 158 159 /* Interrupt Register (IR) */ 160 #define IR_ALL_INT 0xffffffff 161 162 /* Renamed bits for versions > 3.1.x */ 163 #define IR_ARA BIT(29) 164 #define IR_PED BIT(28) 165 #define IR_PEA BIT(27) 166 167 /* Bits for version 3.0.x */ 168 #define IR_STE BIT(31) 169 #define IR_FOE BIT(30) 170 #define IR_ACKE BIT(29) 171 #define IR_BE BIT(28) 172 #define IR_CRCE BIT(27) 173 #define IR_WDI BIT(26) 174 #define IR_BO BIT(25) 175 #define IR_EW BIT(24) 176 #define IR_EP BIT(23) 177 #define IR_ELO BIT(22) 178 #define IR_BEU BIT(21) 179 #define IR_BEC BIT(20) 180 #define IR_DRX BIT(19) 181 #define IR_TOO BIT(18) 182 #define IR_MRAF BIT(17) 183 #define IR_TSW BIT(16) 184 #define IR_TEFL BIT(15) 185 #define IR_TEFF BIT(14) 186 #define IR_TEFW BIT(13) 187 #define IR_TEFN BIT(12) 188 #define IR_TFE BIT(11) 189 #define IR_TCF BIT(10) 190 #define IR_TC BIT(9) 191 #define IR_HPM BIT(8) 192 #define IR_RF1L BIT(7) 193 #define IR_RF1F BIT(6) 194 #define IR_RF1W BIT(5) 195 #define IR_RF1N BIT(4) 196 #define IR_RF0L BIT(3) 197 #define IR_RF0F BIT(2) 198 #define IR_RF0W BIT(1) 199 #define IR_RF0N BIT(0) 200 #define IR_ERR_STATE (IR_BO | IR_EW | IR_EP) 201 202 /* Interrupts for version 3.0.x */ 203 #define IR_ERR_LEC_30X (IR_STE | IR_FOE | IR_ACKE | IR_BE | IR_CRCE) 204 #define IR_ERR_BUS_30X (IR_ERR_LEC_30X | IR_WDI | IR_BEU | IR_BEC | \ 205 IR_TOO | IR_MRAF | IR_TSW | IR_TEFL | IR_RF1L | \ 206 IR_RF0L) 207 #define IR_ERR_ALL_30X (IR_ERR_STATE | IR_ERR_BUS_30X) 208 209 /* Interrupts for version >= 3.1.x */ 210 #define IR_ERR_LEC_31X (IR_PED | IR_PEA) 211 #define IR_ERR_BUS_31X (IR_ERR_LEC_31X | IR_WDI | IR_BEU | IR_BEC | \ 212 IR_TOO | IR_MRAF | IR_TSW | IR_TEFL | IR_RF1L | \ 213 IR_RF0L) 214 #define IR_ERR_ALL_31X (IR_ERR_STATE | IR_ERR_BUS_31X) 215 216 /* Interrupt Line Select (ILS) */ 217 #define ILS_ALL_INT0 0x0 218 #define ILS_ALL_INT1 0xFFFFFFFF 219 220 /* Interrupt Line Enable (ILE) */ 221 #define ILE_EINT1 BIT(1) 222 #define ILE_EINT0 BIT(0) 223 224 /* Rx FIFO 0/1 Configuration (RXF0C/RXF1C) */ 225 #define RXFC_FWM_MASK GENMASK(30, 24) 226 #define RXFC_FS_MASK GENMASK(22, 16) 227 228 /* Rx FIFO 0/1 Status (RXF0S/RXF1S) */ 229 #define RXFS_RFL BIT(25) 230 #define RXFS_FF BIT(24) 231 #define RXFS_FPI_MASK GENMASK(21, 16) 232 #define RXFS_FGI_MASK GENMASK(13, 8) 233 #define RXFS_FFL_MASK GENMASK(6, 0) 234 235 /* Rx Buffer / FIFO Element Size Configuration (RXESC) */ 236 #define RXESC_RBDS_MASK GENMASK(10, 8) 237 #define RXESC_F1DS_MASK GENMASK(6, 4) 238 #define RXESC_F0DS_MASK GENMASK(2, 0) 239 #define RXESC_64B 0x7 240 241 /* Tx Buffer Configuration (TXBC) */ 242 #define TXBC_TFQS_MASK GENMASK(29, 24) 243 #define TXBC_NDTB_MASK GENMASK(21, 16) 244 245 /* Tx FIFO/Queue Status (TXFQS) */ 246 #define TXFQS_TFQF BIT(21) 247 #define TXFQS_TFQPI_MASK GENMASK(20, 16) 248 #define TXFQS_TFGI_MASK GENMASK(12, 8) 249 #define TXFQS_TFFL_MASK GENMASK(5, 0) 250 251 /* Tx Buffer Element Size Configuration (TXESC) */ 252 #define TXESC_TBDS_MASK GENMASK(2, 0) 253 #define TXESC_TBDS_64B 0x7 254 255 /* Tx Event FIFO Configuration (TXEFC) */ 256 #define TXEFC_EFS_MASK GENMASK(21, 16) 257 258 /* Tx Event FIFO Status (TXEFS) */ 259 #define TXEFS_TEFL BIT(25) 260 #define TXEFS_EFF BIT(24) 261 #define TXEFS_EFGI_MASK GENMASK(12, 8) 262 #define TXEFS_EFFL_MASK GENMASK(5, 0) 263 264 /* Tx Event FIFO Acknowledge (TXEFA) */ 265 #define TXEFA_EFAI_MASK GENMASK(4, 0) 266 267 /* Message RAM Configuration (in bytes) */ 268 #define SIDF_ELEMENT_SIZE 4 269 #define XIDF_ELEMENT_SIZE 8 270 #define RXF0_ELEMENT_SIZE 72 271 #define RXF1_ELEMENT_SIZE 72 272 #define RXB_ELEMENT_SIZE 72 273 #define TXE_ELEMENT_SIZE 8 274 #define TXB_ELEMENT_SIZE 72 275 276 /* Message RAM Elements */ 277 #define M_CAN_FIFO_ID 0x0 278 #define M_CAN_FIFO_DLC 0x4 279 #define M_CAN_FIFO_DATA 0x8 280 281 /* Rx Buffer Element */ 282 /* R0 */ 283 #define RX_BUF_ESI BIT(31) 284 #define RX_BUF_XTD BIT(30) 285 #define RX_BUF_RTR BIT(29) 286 /* R1 */ 287 #define RX_BUF_ANMF BIT(31) 288 #define RX_BUF_FDF BIT(21) 289 #define RX_BUF_BRS BIT(20) 290 #define RX_BUF_RXTS_MASK GENMASK(15, 0) 291 292 /* Tx Buffer Element */ 293 /* T0 */ 294 #define TX_BUF_ESI BIT(31) 295 #define TX_BUF_XTD BIT(30) 296 #define TX_BUF_RTR BIT(29) 297 /* T1 */ 298 #define TX_BUF_EFC BIT(23) 299 #define TX_BUF_FDF BIT(21) 300 #define TX_BUF_BRS BIT(20) 301 #define TX_BUF_MM_MASK GENMASK(31, 24) 302 #define TX_BUF_DLC_MASK GENMASK(19, 16) 303 304 /* Tx event FIFO Element */ 305 /* E1 */ 306 #define TX_EVENT_MM_MASK GENMASK(31, 24) 307 #define TX_EVENT_TXTS_MASK GENMASK(15, 0) 308 309 /* The ID and DLC registers are adjacent in M_CAN FIFO memory, 310 * and we can save a (potentially slow) bus round trip by combining 311 * reads and writes to them. 312 */ 313 struct id_and_dlc { 314 u32 id; 315 u32 dlc; 316 }; 317 318 static inline u32 m_can_read(struct m_can_classdev *cdev, enum m_can_reg reg) 319 { 320 return cdev->ops->read_reg(cdev, reg); 321 } 322 323 static inline void m_can_write(struct m_can_classdev *cdev, enum m_can_reg reg, 324 u32 val) 325 { 326 cdev->ops->write_reg(cdev, reg, val); 327 } 328 329 static int 330 m_can_fifo_read(struct m_can_classdev *cdev, 331 u32 fgi, unsigned int offset, void *val, size_t val_count) 332 { 333 u32 addr_offset = cdev->mcfg[MRAM_RXF0].off + fgi * RXF0_ELEMENT_SIZE + 334 offset; 335 336 if (val_count == 0) 337 return 0; 338 339 return cdev->ops->read_fifo(cdev, addr_offset, val, val_count); 340 } 341 342 static int 343 m_can_fifo_write(struct m_can_classdev *cdev, 344 u32 fpi, unsigned int offset, const void *val, size_t val_count) 345 { 346 u32 addr_offset = cdev->mcfg[MRAM_TXB].off + fpi * TXB_ELEMENT_SIZE + 347 offset; 348 349 if (val_count == 0) 350 return 0; 351 352 return cdev->ops->write_fifo(cdev, addr_offset, val, val_count); 353 } 354 355 static inline int m_can_fifo_write_no_off(struct m_can_classdev *cdev, 356 u32 fpi, u32 val) 357 { 358 return cdev->ops->write_fifo(cdev, fpi, &val, 1); 359 } 360 361 static int 362 m_can_txe_fifo_read(struct m_can_classdev *cdev, u32 fgi, u32 offset, u32 *val) 363 { 364 u32 addr_offset = cdev->mcfg[MRAM_TXE].off + fgi * TXE_ELEMENT_SIZE + 365 offset; 366 367 return cdev->ops->read_fifo(cdev, addr_offset, val, 1); 368 } 369 370 static inline bool m_can_tx_fifo_full(struct m_can_classdev *cdev) 371 { 372 return !!(m_can_read(cdev, M_CAN_TXFQS) & TXFQS_TFQF); 373 } 374 375 static void m_can_config_endisable(struct m_can_classdev *cdev, bool enable) 376 { 377 u32 cccr = m_can_read(cdev, M_CAN_CCCR); 378 u32 timeout = 10; 379 u32 val = 0; 380 381 /* Clear the Clock stop request if it was set */ 382 if (cccr & CCCR_CSR) 383 cccr &= ~CCCR_CSR; 384 385 if (enable) { 386 /* enable m_can configuration */ 387 m_can_write(cdev, M_CAN_CCCR, cccr | CCCR_INIT); 388 udelay(5); 389 /* CCCR.CCE can only be set/reset while CCCR.INIT = '1' */ 390 m_can_write(cdev, M_CAN_CCCR, cccr | CCCR_INIT | CCCR_CCE); 391 } else { 392 m_can_write(cdev, M_CAN_CCCR, cccr & ~(CCCR_INIT | CCCR_CCE)); 393 } 394 395 /* there's a delay for module initialization */ 396 if (enable) 397 val = CCCR_INIT | CCCR_CCE; 398 399 while ((m_can_read(cdev, M_CAN_CCCR) & (CCCR_INIT | CCCR_CCE)) != val) { 400 if (timeout == 0) { 401 netdev_warn(cdev->net, "Failed to init module\n"); 402 return; 403 } 404 timeout--; 405 udelay(1); 406 } 407 } 408 409 static inline void m_can_enable_all_interrupts(struct m_can_classdev *cdev) 410 { 411 /* Only interrupt line 0 is used in this driver */ 412 m_can_write(cdev, M_CAN_ILE, ILE_EINT0); 413 } 414 415 static inline void m_can_disable_all_interrupts(struct m_can_classdev *cdev) 416 { 417 m_can_write(cdev, M_CAN_ILE, 0x0); 418 } 419 420 /* Retrieve internal timestamp counter from TSCV.TSC, and shift it to 32-bit 421 * width. 422 */ 423 static u32 m_can_get_timestamp(struct m_can_classdev *cdev) 424 { 425 u32 tscv; 426 u32 tsc; 427 428 tscv = m_can_read(cdev, M_CAN_TSCV); 429 tsc = FIELD_GET(TSCV_TSC_MASK, tscv); 430 431 return (tsc << 16); 432 } 433 434 static void m_can_clean(struct net_device *net) 435 { 436 struct m_can_classdev *cdev = netdev_priv(net); 437 438 if (cdev->tx_skb) { 439 int putidx = 0; 440 441 net->stats.tx_errors++; 442 if (cdev->version > 30) 443 putidx = FIELD_GET(TXFQS_TFQPI_MASK, 444 m_can_read(cdev, M_CAN_TXFQS)); 445 446 can_free_echo_skb(cdev->net, putidx, NULL); 447 cdev->tx_skb = NULL; 448 } 449 } 450 451 /* For peripherals, pass skb to rx-offload, which will push skb from 452 * napi. For non-peripherals, RX is done in napi already, so push 453 * directly. timestamp is used to ensure good skb ordering in 454 * rx-offload and is ignored for non-peripherals. 455 */ 456 static void m_can_receive_skb(struct m_can_classdev *cdev, 457 struct sk_buff *skb, 458 u32 timestamp) 459 { 460 if (cdev->is_peripheral) { 461 struct net_device_stats *stats = &cdev->net->stats; 462 int err; 463 464 err = can_rx_offload_queue_timestamp(&cdev->offload, skb, 465 timestamp); 466 if (err) 467 stats->rx_fifo_errors++; 468 } else { 469 netif_receive_skb(skb); 470 } 471 } 472 473 static int m_can_read_fifo(struct net_device *dev, u32 rxfs) 474 { 475 struct net_device_stats *stats = &dev->stats; 476 struct m_can_classdev *cdev = netdev_priv(dev); 477 struct canfd_frame *cf; 478 struct sk_buff *skb; 479 struct id_and_dlc fifo_header; 480 u32 fgi; 481 u32 timestamp = 0; 482 int err; 483 484 /* calculate the fifo get index for where to read data */ 485 fgi = FIELD_GET(RXFS_FGI_MASK, rxfs); 486 err = m_can_fifo_read(cdev, fgi, M_CAN_FIFO_ID, &fifo_header, 2); 487 if (err) 488 goto out_fail; 489 490 if (fifo_header.dlc & RX_BUF_FDF) 491 skb = alloc_canfd_skb(dev, &cf); 492 else 493 skb = alloc_can_skb(dev, (struct can_frame **)&cf); 494 if (!skb) { 495 stats->rx_dropped++; 496 return 0; 497 } 498 499 if (fifo_header.dlc & RX_BUF_FDF) 500 cf->len = can_fd_dlc2len((fifo_header.dlc >> 16) & 0x0F); 501 else 502 cf->len = can_cc_dlc2len((fifo_header.dlc >> 16) & 0x0F); 503 504 if (fifo_header.id & RX_BUF_XTD) 505 cf->can_id = (fifo_header.id & CAN_EFF_MASK) | CAN_EFF_FLAG; 506 else 507 cf->can_id = (fifo_header.id >> 18) & CAN_SFF_MASK; 508 509 if (fifo_header.id & RX_BUF_ESI) { 510 cf->flags |= CANFD_ESI; 511 netdev_dbg(dev, "ESI Error\n"); 512 } 513 514 if (!(fifo_header.dlc & RX_BUF_FDF) && (fifo_header.id & RX_BUF_RTR)) { 515 cf->can_id |= CAN_RTR_FLAG; 516 } else { 517 if (fifo_header.dlc & RX_BUF_BRS) 518 cf->flags |= CANFD_BRS; 519 520 err = m_can_fifo_read(cdev, fgi, M_CAN_FIFO_DATA, 521 cf->data, DIV_ROUND_UP(cf->len, 4)); 522 if (err) 523 goto out_free_skb; 524 525 stats->rx_bytes += cf->len; 526 } 527 stats->rx_packets++; 528 529 /* acknowledge rx fifo 0 */ 530 m_can_write(cdev, M_CAN_RXF0A, fgi); 531 532 timestamp = FIELD_GET(RX_BUF_RXTS_MASK, fifo_header.dlc); 533 534 m_can_receive_skb(cdev, skb, timestamp); 535 536 return 0; 537 538 out_free_skb: 539 kfree_skb(skb); 540 out_fail: 541 netdev_err(dev, "FIFO read returned %d\n", err); 542 return err; 543 } 544 545 static int m_can_do_rx_poll(struct net_device *dev, int quota) 546 { 547 struct m_can_classdev *cdev = netdev_priv(dev); 548 u32 pkts = 0; 549 u32 rxfs; 550 int err; 551 552 rxfs = m_can_read(cdev, M_CAN_RXF0S); 553 if (!(rxfs & RXFS_FFL_MASK)) { 554 netdev_dbg(dev, "no messages in fifo0\n"); 555 return 0; 556 } 557 558 while ((rxfs & RXFS_FFL_MASK) && (quota > 0)) { 559 err = m_can_read_fifo(dev, rxfs); 560 if (err) 561 return err; 562 563 quota--; 564 pkts++; 565 rxfs = m_can_read(cdev, M_CAN_RXF0S); 566 } 567 568 return pkts; 569 } 570 571 static int m_can_handle_lost_msg(struct net_device *dev) 572 { 573 struct m_can_classdev *cdev = netdev_priv(dev); 574 struct net_device_stats *stats = &dev->stats; 575 struct sk_buff *skb; 576 struct can_frame *frame; 577 u32 timestamp = 0; 578 579 netdev_err(dev, "msg lost in rxf0\n"); 580 581 stats->rx_errors++; 582 stats->rx_over_errors++; 583 584 skb = alloc_can_err_skb(dev, &frame); 585 if (unlikely(!skb)) 586 return 0; 587 588 frame->can_id |= CAN_ERR_CRTL; 589 frame->data[1] = CAN_ERR_CRTL_RX_OVERFLOW; 590 591 if (cdev->is_peripheral) 592 timestamp = m_can_get_timestamp(cdev); 593 594 m_can_receive_skb(cdev, skb, timestamp); 595 596 return 1; 597 } 598 599 static int m_can_handle_lec_err(struct net_device *dev, 600 enum m_can_lec_type lec_type) 601 { 602 struct m_can_classdev *cdev = netdev_priv(dev); 603 struct net_device_stats *stats = &dev->stats; 604 struct can_frame *cf; 605 struct sk_buff *skb; 606 u32 timestamp = 0; 607 608 cdev->can.can_stats.bus_error++; 609 stats->rx_errors++; 610 611 /* propagate the error condition to the CAN stack */ 612 skb = alloc_can_err_skb(dev, &cf); 613 if (unlikely(!skb)) 614 return 0; 615 616 /* check for 'last error code' which tells us the 617 * type of the last error to occur on the CAN bus 618 */ 619 cf->can_id |= CAN_ERR_PROT | CAN_ERR_BUSERROR; 620 621 switch (lec_type) { 622 case LEC_STUFF_ERROR: 623 netdev_dbg(dev, "stuff error\n"); 624 cf->data[2] |= CAN_ERR_PROT_STUFF; 625 break; 626 case LEC_FORM_ERROR: 627 netdev_dbg(dev, "form error\n"); 628 cf->data[2] |= CAN_ERR_PROT_FORM; 629 break; 630 case LEC_ACK_ERROR: 631 netdev_dbg(dev, "ack error\n"); 632 cf->data[3] = CAN_ERR_PROT_LOC_ACK; 633 break; 634 case LEC_BIT1_ERROR: 635 netdev_dbg(dev, "bit1 error\n"); 636 cf->data[2] |= CAN_ERR_PROT_BIT1; 637 break; 638 case LEC_BIT0_ERROR: 639 netdev_dbg(dev, "bit0 error\n"); 640 cf->data[2] |= CAN_ERR_PROT_BIT0; 641 break; 642 case LEC_CRC_ERROR: 643 netdev_dbg(dev, "CRC error\n"); 644 cf->data[3] = CAN_ERR_PROT_LOC_CRC_SEQ; 645 break; 646 default: 647 break; 648 } 649 650 if (cdev->is_peripheral) 651 timestamp = m_can_get_timestamp(cdev); 652 653 m_can_receive_skb(cdev, skb, timestamp); 654 655 return 1; 656 } 657 658 static int __m_can_get_berr_counter(const struct net_device *dev, 659 struct can_berr_counter *bec) 660 { 661 struct m_can_classdev *cdev = netdev_priv(dev); 662 unsigned int ecr; 663 664 ecr = m_can_read(cdev, M_CAN_ECR); 665 bec->rxerr = FIELD_GET(ECR_REC_MASK, ecr); 666 bec->txerr = FIELD_GET(ECR_TEC_MASK, ecr); 667 668 return 0; 669 } 670 671 static int m_can_clk_start(struct m_can_classdev *cdev) 672 { 673 if (cdev->pm_clock_support == 0) 674 return 0; 675 676 return pm_runtime_resume_and_get(cdev->dev); 677 } 678 679 static void m_can_clk_stop(struct m_can_classdev *cdev) 680 { 681 if (cdev->pm_clock_support) 682 pm_runtime_put_sync(cdev->dev); 683 } 684 685 static int m_can_get_berr_counter(const struct net_device *dev, 686 struct can_berr_counter *bec) 687 { 688 struct m_can_classdev *cdev = netdev_priv(dev); 689 int err; 690 691 err = m_can_clk_start(cdev); 692 if (err) 693 return err; 694 695 __m_can_get_berr_counter(dev, bec); 696 697 m_can_clk_stop(cdev); 698 699 return 0; 700 } 701 702 static int m_can_handle_state_change(struct net_device *dev, 703 enum can_state new_state) 704 { 705 struct m_can_classdev *cdev = netdev_priv(dev); 706 struct can_frame *cf; 707 struct sk_buff *skb; 708 struct can_berr_counter bec; 709 unsigned int ecr; 710 u32 timestamp = 0; 711 712 switch (new_state) { 713 case CAN_STATE_ERROR_WARNING: 714 /* error warning state */ 715 cdev->can.can_stats.error_warning++; 716 cdev->can.state = CAN_STATE_ERROR_WARNING; 717 break; 718 case CAN_STATE_ERROR_PASSIVE: 719 /* error passive state */ 720 cdev->can.can_stats.error_passive++; 721 cdev->can.state = CAN_STATE_ERROR_PASSIVE; 722 break; 723 case CAN_STATE_BUS_OFF: 724 /* bus-off state */ 725 cdev->can.state = CAN_STATE_BUS_OFF; 726 m_can_disable_all_interrupts(cdev); 727 cdev->can.can_stats.bus_off++; 728 can_bus_off(dev); 729 break; 730 default: 731 break; 732 } 733 734 /* propagate the error condition to the CAN stack */ 735 skb = alloc_can_err_skb(dev, &cf); 736 if (unlikely(!skb)) 737 return 0; 738 739 __m_can_get_berr_counter(dev, &bec); 740 741 switch (new_state) { 742 case CAN_STATE_ERROR_WARNING: 743 /* error warning state */ 744 cf->can_id |= CAN_ERR_CRTL; 745 cf->data[1] = (bec.txerr > bec.rxerr) ? 746 CAN_ERR_CRTL_TX_WARNING : 747 CAN_ERR_CRTL_RX_WARNING; 748 cf->data[6] = bec.txerr; 749 cf->data[7] = bec.rxerr; 750 break; 751 case CAN_STATE_ERROR_PASSIVE: 752 /* error passive state */ 753 cf->can_id |= CAN_ERR_CRTL; 754 ecr = m_can_read(cdev, M_CAN_ECR); 755 if (ecr & ECR_RP) 756 cf->data[1] |= CAN_ERR_CRTL_RX_PASSIVE; 757 if (bec.txerr > 127) 758 cf->data[1] |= CAN_ERR_CRTL_TX_PASSIVE; 759 cf->data[6] = bec.txerr; 760 cf->data[7] = bec.rxerr; 761 break; 762 case CAN_STATE_BUS_OFF: 763 /* bus-off state */ 764 cf->can_id |= CAN_ERR_BUSOFF; 765 break; 766 default: 767 break; 768 } 769 770 if (cdev->is_peripheral) 771 timestamp = m_can_get_timestamp(cdev); 772 773 m_can_receive_skb(cdev, skb, timestamp); 774 775 return 1; 776 } 777 778 static int m_can_handle_state_errors(struct net_device *dev, u32 psr) 779 { 780 struct m_can_classdev *cdev = netdev_priv(dev); 781 int work_done = 0; 782 783 if (psr & PSR_EW && cdev->can.state != CAN_STATE_ERROR_WARNING) { 784 netdev_dbg(dev, "entered error warning state\n"); 785 work_done += m_can_handle_state_change(dev, 786 CAN_STATE_ERROR_WARNING); 787 } 788 789 if (psr & PSR_EP && cdev->can.state != CAN_STATE_ERROR_PASSIVE) { 790 netdev_dbg(dev, "entered error passive state\n"); 791 work_done += m_can_handle_state_change(dev, 792 CAN_STATE_ERROR_PASSIVE); 793 } 794 795 if (psr & PSR_BO && cdev->can.state != CAN_STATE_BUS_OFF) { 796 netdev_dbg(dev, "entered error bus off state\n"); 797 work_done += m_can_handle_state_change(dev, 798 CAN_STATE_BUS_OFF); 799 } 800 801 return work_done; 802 } 803 804 static void m_can_handle_other_err(struct net_device *dev, u32 irqstatus) 805 { 806 if (irqstatus & IR_WDI) 807 netdev_err(dev, "Message RAM Watchdog event due to missing READY\n"); 808 if (irqstatus & IR_BEU) 809 netdev_err(dev, "Bit Error Uncorrected\n"); 810 if (irqstatus & IR_BEC) 811 netdev_err(dev, "Bit Error Corrected\n"); 812 if (irqstatus & IR_TOO) 813 netdev_err(dev, "Timeout reached\n"); 814 if (irqstatus & IR_MRAF) 815 netdev_err(dev, "Message RAM access failure occurred\n"); 816 } 817 818 static inline bool is_lec_err(u32 psr) 819 { 820 psr &= LEC_UNUSED; 821 822 return psr && (psr != LEC_UNUSED); 823 } 824 825 static inline bool m_can_is_protocol_err(u32 irqstatus) 826 { 827 return irqstatus & IR_ERR_LEC_31X; 828 } 829 830 static int m_can_handle_protocol_error(struct net_device *dev, u32 irqstatus) 831 { 832 struct net_device_stats *stats = &dev->stats; 833 struct m_can_classdev *cdev = netdev_priv(dev); 834 struct can_frame *cf; 835 struct sk_buff *skb; 836 u32 timestamp = 0; 837 838 /* propagate the error condition to the CAN stack */ 839 skb = alloc_can_err_skb(dev, &cf); 840 841 /* update tx error stats since there is protocol error */ 842 stats->tx_errors++; 843 844 /* update arbitration lost status */ 845 if (cdev->version >= 31 && (irqstatus & IR_PEA)) { 846 netdev_dbg(dev, "Protocol error in Arbitration fail\n"); 847 cdev->can.can_stats.arbitration_lost++; 848 if (skb) { 849 cf->can_id |= CAN_ERR_LOSTARB; 850 cf->data[0] |= CAN_ERR_LOSTARB_UNSPEC; 851 } 852 } 853 854 if (unlikely(!skb)) { 855 netdev_dbg(dev, "allocation of skb failed\n"); 856 return 0; 857 } 858 859 if (cdev->is_peripheral) 860 timestamp = m_can_get_timestamp(cdev); 861 862 m_can_receive_skb(cdev, skb, timestamp); 863 864 return 1; 865 } 866 867 static int m_can_handle_bus_errors(struct net_device *dev, u32 irqstatus, 868 u32 psr) 869 { 870 struct m_can_classdev *cdev = netdev_priv(dev); 871 int work_done = 0; 872 873 if (irqstatus & IR_RF0L) 874 work_done += m_can_handle_lost_msg(dev); 875 876 /* handle lec errors on the bus */ 877 if ((cdev->can.ctrlmode & CAN_CTRLMODE_BERR_REPORTING) && 878 is_lec_err(psr)) 879 work_done += m_can_handle_lec_err(dev, psr & LEC_UNUSED); 880 881 /* handle protocol errors in arbitration phase */ 882 if ((cdev->can.ctrlmode & CAN_CTRLMODE_BERR_REPORTING) && 883 m_can_is_protocol_err(irqstatus)) 884 work_done += m_can_handle_protocol_error(dev, irqstatus); 885 886 /* other unproccessed error interrupts */ 887 m_can_handle_other_err(dev, irqstatus); 888 889 return work_done; 890 } 891 892 static int m_can_rx_handler(struct net_device *dev, int quota) 893 { 894 struct m_can_classdev *cdev = netdev_priv(dev); 895 int rx_work_or_err; 896 int work_done = 0; 897 u32 irqstatus, psr; 898 899 irqstatus = cdev->irqstatus | m_can_read(cdev, M_CAN_IR); 900 if (!irqstatus) 901 goto end; 902 903 /* Errata workaround for issue "Needless activation of MRAF irq" 904 * During frame reception while the MCAN is in Error Passive state 905 * and the Receive Error Counter has the value MCAN_ECR.REC = 127, 906 * it may happen that MCAN_IR.MRAF is set although there was no 907 * Message RAM access failure. 908 * If MCAN_IR.MRAF is enabled, an interrupt to the Host CPU is generated 909 * The Message RAM Access Failure interrupt routine needs to check 910 * whether MCAN_ECR.RP = ’1’ and MCAN_ECR.REC = 127. 911 * In this case, reset MCAN_IR.MRAF. No further action is required. 912 */ 913 if (cdev->version <= 31 && irqstatus & IR_MRAF && 914 m_can_read(cdev, M_CAN_ECR) & ECR_RP) { 915 struct can_berr_counter bec; 916 917 __m_can_get_berr_counter(dev, &bec); 918 if (bec.rxerr == 127) { 919 m_can_write(cdev, M_CAN_IR, IR_MRAF); 920 irqstatus &= ~IR_MRAF; 921 } 922 } 923 924 psr = m_can_read(cdev, M_CAN_PSR); 925 926 if (irqstatus & IR_ERR_STATE) 927 work_done += m_can_handle_state_errors(dev, psr); 928 929 if (irqstatus & IR_ERR_BUS_30X) 930 work_done += m_can_handle_bus_errors(dev, irqstatus, psr); 931 932 if (irqstatus & IR_RF0N) { 933 rx_work_or_err = m_can_do_rx_poll(dev, (quota - work_done)); 934 if (rx_work_or_err < 0) 935 return rx_work_or_err; 936 937 work_done += rx_work_or_err; 938 } 939 end: 940 return work_done; 941 } 942 943 static int m_can_rx_peripheral(struct net_device *dev) 944 { 945 struct m_can_classdev *cdev = netdev_priv(dev); 946 int work_done; 947 948 work_done = m_can_rx_handler(dev, NAPI_POLL_WEIGHT); 949 950 /* Don't re-enable interrupts if the driver had a fatal error 951 * (e.g., FIFO read failure). 952 */ 953 if (work_done >= 0) 954 m_can_enable_all_interrupts(cdev); 955 956 return work_done; 957 } 958 959 static int m_can_poll(struct napi_struct *napi, int quota) 960 { 961 struct net_device *dev = napi->dev; 962 struct m_can_classdev *cdev = netdev_priv(dev); 963 int work_done; 964 965 work_done = m_can_rx_handler(dev, quota); 966 967 /* Don't re-enable interrupts if the driver had a fatal error 968 * (e.g., FIFO read failure). 969 */ 970 if (work_done >= 0 && work_done < quota) { 971 napi_complete_done(napi, work_done); 972 m_can_enable_all_interrupts(cdev); 973 } 974 975 return work_done; 976 } 977 978 /* Echo tx skb and update net stats. Peripherals use rx-offload for 979 * echo. timestamp is used for peripherals to ensure correct ordering 980 * by rx-offload, and is ignored for non-peripherals. 981 */ 982 static void m_can_tx_update_stats(struct m_can_classdev *cdev, 983 unsigned int msg_mark, 984 u32 timestamp) 985 { 986 struct net_device *dev = cdev->net; 987 struct net_device_stats *stats = &dev->stats; 988 989 if (cdev->is_peripheral) 990 stats->tx_bytes += 991 can_rx_offload_get_echo_skb(&cdev->offload, 992 msg_mark, 993 timestamp, 994 NULL); 995 else 996 stats->tx_bytes += can_get_echo_skb(dev, msg_mark, NULL); 997 998 stats->tx_packets++; 999 } 1000 1001 static int m_can_echo_tx_event(struct net_device *dev) 1002 { 1003 u32 txe_count = 0; 1004 u32 m_can_txefs; 1005 u32 fgi = 0; 1006 int i = 0; 1007 unsigned int msg_mark; 1008 1009 struct m_can_classdev *cdev = netdev_priv(dev); 1010 1011 /* read tx event fifo status */ 1012 m_can_txefs = m_can_read(cdev, M_CAN_TXEFS); 1013 1014 /* Get Tx Event fifo element count */ 1015 txe_count = FIELD_GET(TXEFS_EFFL_MASK, m_can_txefs); 1016 1017 /* Get and process all sent elements */ 1018 for (i = 0; i < txe_count; i++) { 1019 u32 txe, timestamp = 0; 1020 int err; 1021 1022 /* retrieve get index */ 1023 fgi = FIELD_GET(TXEFS_EFGI_MASK, m_can_read(cdev, M_CAN_TXEFS)); 1024 1025 /* get message marker, timestamp */ 1026 err = m_can_txe_fifo_read(cdev, fgi, 4, &txe); 1027 if (err) { 1028 netdev_err(dev, "TXE FIFO read returned %d\n", err); 1029 return err; 1030 } 1031 1032 msg_mark = FIELD_GET(TX_EVENT_MM_MASK, txe); 1033 timestamp = FIELD_GET(TX_EVENT_TXTS_MASK, txe); 1034 1035 /* ack txe element */ 1036 m_can_write(cdev, M_CAN_TXEFA, FIELD_PREP(TXEFA_EFAI_MASK, 1037 fgi)); 1038 1039 /* update stats */ 1040 m_can_tx_update_stats(cdev, msg_mark, timestamp); 1041 } 1042 1043 return 0; 1044 } 1045 1046 static irqreturn_t m_can_isr(int irq, void *dev_id) 1047 { 1048 struct net_device *dev = (struct net_device *)dev_id; 1049 struct m_can_classdev *cdev = netdev_priv(dev); 1050 u32 ir; 1051 1052 if (pm_runtime_suspended(cdev->dev)) 1053 return IRQ_NONE; 1054 ir = m_can_read(cdev, M_CAN_IR); 1055 if (!ir) 1056 return IRQ_NONE; 1057 1058 /* ACK all irqs */ 1059 if (ir & IR_ALL_INT) 1060 m_can_write(cdev, M_CAN_IR, ir); 1061 1062 if (cdev->ops->clear_interrupts) 1063 cdev->ops->clear_interrupts(cdev); 1064 1065 /* schedule NAPI in case of 1066 * - rx IRQ 1067 * - state change IRQ 1068 * - bus error IRQ and bus error reporting 1069 */ 1070 if ((ir & IR_RF0N) || (ir & IR_ERR_ALL_30X)) { 1071 cdev->irqstatus = ir; 1072 m_can_disable_all_interrupts(cdev); 1073 if (!cdev->is_peripheral) 1074 napi_schedule(&cdev->napi); 1075 else if (m_can_rx_peripheral(dev) < 0) 1076 goto out_fail; 1077 } 1078 1079 if (cdev->version == 30) { 1080 if (ir & IR_TC) { 1081 /* Transmission Complete Interrupt*/ 1082 u32 timestamp = 0; 1083 1084 if (cdev->is_peripheral) 1085 timestamp = m_can_get_timestamp(cdev); 1086 m_can_tx_update_stats(cdev, 0, timestamp); 1087 netif_wake_queue(dev); 1088 } 1089 } else { 1090 if (ir & IR_TEFN) { 1091 /* New TX FIFO Element arrived */ 1092 if (m_can_echo_tx_event(dev) != 0) 1093 goto out_fail; 1094 1095 if (netif_queue_stopped(dev) && 1096 !m_can_tx_fifo_full(cdev)) 1097 netif_wake_queue(dev); 1098 } 1099 } 1100 1101 if (cdev->is_peripheral) 1102 can_rx_offload_threaded_irq_finish(&cdev->offload); 1103 1104 return IRQ_HANDLED; 1105 1106 out_fail: 1107 m_can_disable_all_interrupts(cdev); 1108 return IRQ_HANDLED; 1109 } 1110 1111 static const struct can_bittiming_const m_can_bittiming_const_30X = { 1112 .name = KBUILD_MODNAME, 1113 .tseg1_min = 2, /* Time segment 1 = prop_seg + phase_seg1 */ 1114 .tseg1_max = 64, 1115 .tseg2_min = 1, /* Time segment 2 = phase_seg2 */ 1116 .tseg2_max = 16, 1117 .sjw_max = 16, 1118 .brp_min = 1, 1119 .brp_max = 1024, 1120 .brp_inc = 1, 1121 }; 1122 1123 static const struct can_bittiming_const m_can_data_bittiming_const_30X = { 1124 .name = KBUILD_MODNAME, 1125 .tseg1_min = 2, /* Time segment 1 = prop_seg + phase_seg1 */ 1126 .tseg1_max = 16, 1127 .tseg2_min = 1, /* Time segment 2 = phase_seg2 */ 1128 .tseg2_max = 8, 1129 .sjw_max = 4, 1130 .brp_min = 1, 1131 .brp_max = 32, 1132 .brp_inc = 1, 1133 }; 1134 1135 static const struct can_bittiming_const m_can_bittiming_const_31X = { 1136 .name = KBUILD_MODNAME, 1137 .tseg1_min = 2, /* Time segment 1 = prop_seg + phase_seg1 */ 1138 .tseg1_max = 256, 1139 .tseg2_min = 2, /* Time segment 2 = phase_seg2 */ 1140 .tseg2_max = 128, 1141 .sjw_max = 128, 1142 .brp_min = 1, 1143 .brp_max = 512, 1144 .brp_inc = 1, 1145 }; 1146 1147 static const struct can_bittiming_const m_can_data_bittiming_const_31X = { 1148 .name = KBUILD_MODNAME, 1149 .tseg1_min = 1, /* Time segment 1 = prop_seg + phase_seg1 */ 1150 .tseg1_max = 32, 1151 .tseg2_min = 1, /* Time segment 2 = phase_seg2 */ 1152 .tseg2_max = 16, 1153 .sjw_max = 16, 1154 .brp_min = 1, 1155 .brp_max = 32, 1156 .brp_inc = 1, 1157 }; 1158 1159 static int m_can_set_bittiming(struct net_device *dev) 1160 { 1161 struct m_can_classdev *cdev = netdev_priv(dev); 1162 const struct can_bittiming *bt = &cdev->can.bittiming; 1163 const struct can_bittiming *dbt = &cdev->can.data_bittiming; 1164 u16 brp, sjw, tseg1, tseg2; 1165 u32 reg_btp; 1166 1167 brp = bt->brp - 1; 1168 sjw = bt->sjw - 1; 1169 tseg1 = bt->prop_seg + bt->phase_seg1 - 1; 1170 tseg2 = bt->phase_seg2 - 1; 1171 reg_btp = FIELD_PREP(NBTP_NBRP_MASK, brp) | 1172 FIELD_PREP(NBTP_NSJW_MASK, sjw) | 1173 FIELD_PREP(NBTP_NTSEG1_MASK, tseg1) | 1174 FIELD_PREP(NBTP_NTSEG2_MASK, tseg2); 1175 m_can_write(cdev, M_CAN_NBTP, reg_btp); 1176 1177 if (cdev->can.ctrlmode & CAN_CTRLMODE_FD) { 1178 reg_btp = 0; 1179 brp = dbt->brp - 1; 1180 sjw = dbt->sjw - 1; 1181 tseg1 = dbt->prop_seg + dbt->phase_seg1 - 1; 1182 tseg2 = dbt->phase_seg2 - 1; 1183 1184 /* TDC is only needed for bitrates beyond 2.5 MBit/s. 1185 * This is mentioned in the "Bit Time Requirements for CAN FD" 1186 * paper presented at the International CAN Conference 2013 1187 */ 1188 if (dbt->bitrate > 2500000) { 1189 u32 tdco, ssp; 1190 1191 /* Use the same value of secondary sampling point 1192 * as the data sampling point 1193 */ 1194 ssp = dbt->sample_point; 1195 1196 /* Equation based on Bosch's M_CAN User Manual's 1197 * Transmitter Delay Compensation Section 1198 */ 1199 tdco = (cdev->can.clock.freq / 1000) * 1200 ssp / dbt->bitrate; 1201 1202 /* Max valid TDCO value is 127 */ 1203 if (tdco > 127) { 1204 netdev_warn(dev, "TDCO value of %u is beyond maximum. Using maximum possible value\n", 1205 tdco); 1206 tdco = 127; 1207 } 1208 1209 reg_btp |= DBTP_TDC; 1210 m_can_write(cdev, M_CAN_TDCR, 1211 FIELD_PREP(TDCR_TDCO_MASK, tdco)); 1212 } 1213 1214 reg_btp |= FIELD_PREP(DBTP_DBRP_MASK, brp) | 1215 FIELD_PREP(DBTP_DSJW_MASK, sjw) | 1216 FIELD_PREP(DBTP_DTSEG1_MASK, tseg1) | 1217 FIELD_PREP(DBTP_DTSEG2_MASK, tseg2); 1218 1219 m_can_write(cdev, M_CAN_DBTP, reg_btp); 1220 } 1221 1222 return 0; 1223 } 1224 1225 /* Configure M_CAN chip: 1226 * - set rx buffer/fifo element size 1227 * - configure rx fifo 1228 * - accept non-matching frame into fifo 0 1229 * - configure tx buffer 1230 * - >= v3.1.x: TX FIFO is used 1231 * - configure mode 1232 * - setup bittiming 1233 * - configure timestamp generation 1234 */ 1235 static void m_can_chip_config(struct net_device *dev) 1236 { 1237 struct m_can_classdev *cdev = netdev_priv(dev); 1238 u32 cccr, test; 1239 1240 m_can_config_endisable(cdev, true); 1241 1242 /* RX Buffer/FIFO Element Size 64 bytes data field */ 1243 m_can_write(cdev, M_CAN_RXESC, 1244 FIELD_PREP(RXESC_RBDS_MASK, RXESC_64B) | 1245 FIELD_PREP(RXESC_F1DS_MASK, RXESC_64B) | 1246 FIELD_PREP(RXESC_F0DS_MASK, RXESC_64B)); 1247 1248 /* Accept Non-matching Frames Into FIFO 0 */ 1249 m_can_write(cdev, M_CAN_GFC, 0x0); 1250 1251 if (cdev->version == 30) { 1252 /* only support one Tx Buffer currently */ 1253 m_can_write(cdev, M_CAN_TXBC, FIELD_PREP(TXBC_NDTB_MASK, 1) | 1254 cdev->mcfg[MRAM_TXB].off); 1255 } else { 1256 /* TX FIFO is used for newer IP Core versions */ 1257 m_can_write(cdev, M_CAN_TXBC, 1258 FIELD_PREP(TXBC_TFQS_MASK, 1259 cdev->mcfg[MRAM_TXB].num) | 1260 cdev->mcfg[MRAM_TXB].off); 1261 } 1262 1263 /* support 64 bytes payload */ 1264 m_can_write(cdev, M_CAN_TXESC, 1265 FIELD_PREP(TXESC_TBDS_MASK, TXESC_TBDS_64B)); 1266 1267 /* TX Event FIFO */ 1268 if (cdev->version == 30) { 1269 m_can_write(cdev, M_CAN_TXEFC, 1270 FIELD_PREP(TXEFC_EFS_MASK, 1) | 1271 cdev->mcfg[MRAM_TXE].off); 1272 } else { 1273 /* Full TX Event FIFO is used */ 1274 m_can_write(cdev, M_CAN_TXEFC, 1275 FIELD_PREP(TXEFC_EFS_MASK, 1276 cdev->mcfg[MRAM_TXE].num) | 1277 cdev->mcfg[MRAM_TXE].off); 1278 } 1279 1280 /* rx fifo configuration, blocking mode, fifo size 1 */ 1281 m_can_write(cdev, M_CAN_RXF0C, 1282 FIELD_PREP(RXFC_FS_MASK, cdev->mcfg[MRAM_RXF0].num) | 1283 cdev->mcfg[MRAM_RXF0].off); 1284 1285 m_can_write(cdev, M_CAN_RXF1C, 1286 FIELD_PREP(RXFC_FS_MASK, cdev->mcfg[MRAM_RXF1].num) | 1287 cdev->mcfg[MRAM_RXF1].off); 1288 1289 cccr = m_can_read(cdev, M_CAN_CCCR); 1290 test = m_can_read(cdev, M_CAN_TEST); 1291 test &= ~TEST_LBCK; 1292 if (cdev->version == 30) { 1293 /* Version 3.0.x */ 1294 1295 cccr &= ~(CCCR_TEST | CCCR_MON | CCCR_DAR | 1296 FIELD_PREP(CCCR_CMR_MASK, FIELD_MAX(CCCR_CMR_MASK)) | 1297 FIELD_PREP(CCCR_CME_MASK, FIELD_MAX(CCCR_CME_MASK))); 1298 1299 if (cdev->can.ctrlmode & CAN_CTRLMODE_FD) 1300 cccr |= FIELD_PREP(CCCR_CME_MASK, CCCR_CME_CANFD_BRS); 1301 1302 } else { 1303 /* Version 3.1.x or 3.2.x */ 1304 cccr &= ~(CCCR_TEST | CCCR_MON | CCCR_BRSE | CCCR_FDOE | 1305 CCCR_NISO | CCCR_DAR); 1306 1307 /* Only 3.2.x has NISO Bit implemented */ 1308 if (cdev->can.ctrlmode & CAN_CTRLMODE_FD_NON_ISO) 1309 cccr |= CCCR_NISO; 1310 1311 if (cdev->can.ctrlmode & CAN_CTRLMODE_FD) 1312 cccr |= (CCCR_BRSE | CCCR_FDOE); 1313 } 1314 1315 /* Loopback Mode */ 1316 if (cdev->can.ctrlmode & CAN_CTRLMODE_LOOPBACK) { 1317 cccr |= CCCR_TEST | CCCR_MON; 1318 test |= TEST_LBCK; 1319 } 1320 1321 /* Enable Monitoring (all versions) */ 1322 if (cdev->can.ctrlmode & CAN_CTRLMODE_LISTENONLY) 1323 cccr |= CCCR_MON; 1324 1325 /* Disable Auto Retransmission (all versions) */ 1326 if (cdev->can.ctrlmode & CAN_CTRLMODE_ONE_SHOT) 1327 cccr |= CCCR_DAR; 1328 1329 /* Write config */ 1330 m_can_write(cdev, M_CAN_CCCR, cccr); 1331 m_can_write(cdev, M_CAN_TEST, test); 1332 1333 /* Enable interrupts */ 1334 m_can_write(cdev, M_CAN_IR, IR_ALL_INT); 1335 if (!(cdev->can.ctrlmode & CAN_CTRLMODE_BERR_REPORTING)) 1336 if (cdev->version == 30) 1337 m_can_write(cdev, M_CAN_IE, IR_ALL_INT & 1338 ~(IR_ERR_LEC_30X)); 1339 else 1340 m_can_write(cdev, M_CAN_IE, IR_ALL_INT & 1341 ~(IR_ERR_LEC_31X)); 1342 else 1343 m_can_write(cdev, M_CAN_IE, IR_ALL_INT); 1344 1345 /* route all interrupts to INT0 */ 1346 m_can_write(cdev, M_CAN_ILS, ILS_ALL_INT0); 1347 1348 /* set bittiming params */ 1349 m_can_set_bittiming(dev); 1350 1351 /* enable internal timestamp generation, with a prescaler of 16. The 1352 * prescaler is applied to the nominal bit timing 1353 */ 1354 m_can_write(cdev, M_CAN_TSCC, FIELD_PREP(TSCC_TCP_MASK, 0xf)); 1355 1356 m_can_config_endisable(cdev, false); 1357 1358 if (cdev->ops->init) 1359 cdev->ops->init(cdev); 1360 } 1361 1362 static void m_can_start(struct net_device *dev) 1363 { 1364 struct m_can_classdev *cdev = netdev_priv(dev); 1365 1366 /* basic m_can configuration */ 1367 m_can_chip_config(dev); 1368 1369 cdev->can.state = CAN_STATE_ERROR_ACTIVE; 1370 1371 m_can_enable_all_interrupts(cdev); 1372 } 1373 1374 static int m_can_set_mode(struct net_device *dev, enum can_mode mode) 1375 { 1376 switch (mode) { 1377 case CAN_MODE_START: 1378 m_can_clean(dev); 1379 m_can_start(dev); 1380 netif_wake_queue(dev); 1381 break; 1382 default: 1383 return -EOPNOTSUPP; 1384 } 1385 1386 return 0; 1387 } 1388 1389 /* Checks core release number of M_CAN 1390 * returns 0 if an unsupported device is detected 1391 * else it returns the release and step coded as: 1392 * return value = 10 * <release> + 1 * <step> 1393 */ 1394 static int m_can_check_core_release(struct m_can_classdev *cdev) 1395 { 1396 u32 crel_reg; 1397 u8 rel; 1398 u8 step; 1399 int res; 1400 1401 /* Read Core Release Version and split into version number 1402 * Example: Version 3.2.1 => rel = 3; step = 2; substep = 1; 1403 */ 1404 crel_reg = m_can_read(cdev, M_CAN_CREL); 1405 rel = (u8)FIELD_GET(CREL_REL_MASK, crel_reg); 1406 step = (u8)FIELD_GET(CREL_STEP_MASK, crel_reg); 1407 1408 if (rel == 3) { 1409 /* M_CAN v3.x.y: create return value */ 1410 res = 30 + step; 1411 } else { 1412 /* Unsupported M_CAN version */ 1413 res = 0; 1414 } 1415 1416 return res; 1417 } 1418 1419 /* Selectable Non ISO support only in version 3.2.x 1420 * This function checks if the bit is writable. 1421 */ 1422 static bool m_can_niso_supported(struct m_can_classdev *cdev) 1423 { 1424 u32 cccr_reg, cccr_poll = 0; 1425 int niso_timeout = -ETIMEDOUT; 1426 int i; 1427 1428 m_can_config_endisable(cdev, true); 1429 cccr_reg = m_can_read(cdev, M_CAN_CCCR); 1430 cccr_reg |= CCCR_NISO; 1431 m_can_write(cdev, M_CAN_CCCR, cccr_reg); 1432 1433 for (i = 0; i <= 10; i++) { 1434 cccr_poll = m_can_read(cdev, M_CAN_CCCR); 1435 if (cccr_poll == cccr_reg) { 1436 niso_timeout = 0; 1437 break; 1438 } 1439 1440 usleep_range(1, 5); 1441 } 1442 1443 /* Clear NISO */ 1444 cccr_reg &= ~(CCCR_NISO); 1445 m_can_write(cdev, M_CAN_CCCR, cccr_reg); 1446 1447 m_can_config_endisable(cdev, false); 1448 1449 /* return false if time out (-ETIMEDOUT), else return true */ 1450 return !niso_timeout; 1451 } 1452 1453 static int m_can_dev_setup(struct m_can_classdev *cdev) 1454 { 1455 struct net_device *dev = cdev->net; 1456 int m_can_version, err; 1457 1458 m_can_version = m_can_check_core_release(cdev); 1459 /* return if unsupported version */ 1460 if (!m_can_version) { 1461 dev_err(cdev->dev, "Unsupported version number: %2d", 1462 m_can_version); 1463 return -EINVAL; 1464 } 1465 1466 if (!cdev->is_peripheral) 1467 netif_napi_add(dev, &cdev->napi, 1468 m_can_poll, NAPI_POLL_WEIGHT); 1469 1470 /* Shared properties of all M_CAN versions */ 1471 cdev->version = m_can_version; 1472 cdev->can.do_set_mode = m_can_set_mode; 1473 cdev->can.do_get_berr_counter = m_can_get_berr_counter; 1474 1475 /* Set M_CAN supported operations */ 1476 cdev->can.ctrlmode_supported = CAN_CTRLMODE_LOOPBACK | 1477 CAN_CTRLMODE_LISTENONLY | 1478 CAN_CTRLMODE_BERR_REPORTING | 1479 CAN_CTRLMODE_FD | 1480 CAN_CTRLMODE_ONE_SHOT; 1481 1482 /* Set properties depending on M_CAN version */ 1483 switch (cdev->version) { 1484 case 30: 1485 /* CAN_CTRLMODE_FD_NON_ISO is fixed with M_CAN IP v3.0.x */ 1486 err = can_set_static_ctrlmode(dev, CAN_CTRLMODE_FD_NON_ISO); 1487 if (err) 1488 return err; 1489 cdev->can.bittiming_const = &m_can_bittiming_const_30X; 1490 cdev->can.data_bittiming_const = &m_can_data_bittiming_const_30X; 1491 break; 1492 case 31: 1493 /* CAN_CTRLMODE_FD_NON_ISO is fixed with M_CAN IP v3.1.x */ 1494 err = can_set_static_ctrlmode(dev, CAN_CTRLMODE_FD_NON_ISO); 1495 if (err) 1496 return err; 1497 cdev->can.bittiming_const = &m_can_bittiming_const_31X; 1498 cdev->can.data_bittiming_const = &m_can_data_bittiming_const_31X; 1499 break; 1500 case 32: 1501 case 33: 1502 /* Support both MCAN version v3.2.x and v3.3.0 */ 1503 cdev->can.bittiming_const = &m_can_bittiming_const_31X; 1504 cdev->can.data_bittiming_const = &m_can_data_bittiming_const_31X; 1505 1506 cdev->can.ctrlmode_supported |= 1507 (m_can_niso_supported(cdev) ? 1508 CAN_CTRLMODE_FD_NON_ISO : 0); 1509 break; 1510 default: 1511 dev_err(cdev->dev, "Unsupported version number: %2d", 1512 cdev->version); 1513 return -EINVAL; 1514 } 1515 1516 if (cdev->ops->init) 1517 cdev->ops->init(cdev); 1518 1519 return 0; 1520 } 1521 1522 static void m_can_stop(struct net_device *dev) 1523 { 1524 struct m_can_classdev *cdev = netdev_priv(dev); 1525 1526 /* disable all interrupts */ 1527 m_can_disable_all_interrupts(cdev); 1528 1529 /* Set init mode to disengage from the network */ 1530 m_can_config_endisable(cdev, true); 1531 1532 /* set the state as STOPPED */ 1533 cdev->can.state = CAN_STATE_STOPPED; 1534 } 1535 1536 static int m_can_close(struct net_device *dev) 1537 { 1538 struct m_can_classdev *cdev = netdev_priv(dev); 1539 1540 netif_stop_queue(dev); 1541 1542 if (!cdev->is_peripheral) 1543 napi_disable(&cdev->napi); 1544 1545 m_can_stop(dev); 1546 m_can_clk_stop(cdev); 1547 free_irq(dev->irq, dev); 1548 1549 if (cdev->is_peripheral) { 1550 cdev->tx_skb = NULL; 1551 destroy_workqueue(cdev->tx_wq); 1552 cdev->tx_wq = NULL; 1553 } 1554 1555 if (cdev->is_peripheral) 1556 can_rx_offload_disable(&cdev->offload); 1557 1558 close_candev(dev); 1559 1560 phy_power_off(cdev->transceiver); 1561 1562 return 0; 1563 } 1564 1565 static int m_can_next_echo_skb_occupied(struct net_device *dev, int putidx) 1566 { 1567 struct m_can_classdev *cdev = netdev_priv(dev); 1568 /*get wrap around for loopback skb index */ 1569 unsigned int wrap = cdev->can.echo_skb_max; 1570 int next_idx; 1571 1572 /* calculate next index */ 1573 next_idx = (++putidx >= wrap ? 0 : putidx); 1574 1575 /* check if occupied */ 1576 return !!cdev->can.echo_skb[next_idx]; 1577 } 1578 1579 static netdev_tx_t m_can_tx_handler(struct m_can_classdev *cdev) 1580 { 1581 struct canfd_frame *cf = (struct canfd_frame *)cdev->tx_skb->data; 1582 struct net_device *dev = cdev->net; 1583 struct sk_buff *skb = cdev->tx_skb; 1584 struct id_and_dlc fifo_header; 1585 u32 cccr, fdflags; 1586 int err; 1587 int putidx; 1588 1589 cdev->tx_skb = NULL; 1590 1591 /* Generate ID field for TX buffer Element */ 1592 /* Common to all supported M_CAN versions */ 1593 if (cf->can_id & CAN_EFF_FLAG) { 1594 fifo_header.id = cf->can_id & CAN_EFF_MASK; 1595 fifo_header.id |= TX_BUF_XTD; 1596 } else { 1597 fifo_header.id = ((cf->can_id & CAN_SFF_MASK) << 18); 1598 } 1599 1600 if (cf->can_id & CAN_RTR_FLAG) 1601 fifo_header.id |= TX_BUF_RTR; 1602 1603 if (cdev->version == 30) { 1604 netif_stop_queue(dev); 1605 1606 fifo_header.dlc = can_fd_len2dlc(cf->len) << 16; 1607 1608 /* Write the frame ID, DLC, and payload to the FIFO element. */ 1609 err = m_can_fifo_write(cdev, 0, M_CAN_FIFO_ID, &fifo_header, 2); 1610 if (err) 1611 goto out_fail; 1612 1613 err = m_can_fifo_write(cdev, 0, M_CAN_FIFO_DATA, 1614 cf->data, DIV_ROUND_UP(cf->len, 4)); 1615 if (err) 1616 goto out_fail; 1617 1618 if (cdev->can.ctrlmode & CAN_CTRLMODE_FD) { 1619 cccr = m_can_read(cdev, M_CAN_CCCR); 1620 cccr &= ~CCCR_CMR_MASK; 1621 if (can_is_canfd_skb(skb)) { 1622 if (cf->flags & CANFD_BRS) 1623 cccr |= FIELD_PREP(CCCR_CMR_MASK, 1624 CCCR_CMR_CANFD_BRS); 1625 else 1626 cccr |= FIELD_PREP(CCCR_CMR_MASK, 1627 CCCR_CMR_CANFD); 1628 } else { 1629 cccr |= FIELD_PREP(CCCR_CMR_MASK, CCCR_CMR_CAN); 1630 } 1631 m_can_write(cdev, M_CAN_CCCR, cccr); 1632 } 1633 m_can_write(cdev, M_CAN_TXBTIE, 0x1); 1634 1635 can_put_echo_skb(skb, dev, 0, 0); 1636 1637 m_can_write(cdev, M_CAN_TXBAR, 0x1); 1638 /* End of xmit function for version 3.0.x */ 1639 } else { 1640 /* Transmit routine for version >= v3.1.x */ 1641 1642 /* Check if FIFO full */ 1643 if (m_can_tx_fifo_full(cdev)) { 1644 /* This shouldn't happen */ 1645 netif_stop_queue(dev); 1646 netdev_warn(dev, 1647 "TX queue active although FIFO is full."); 1648 1649 if (cdev->is_peripheral) { 1650 kfree_skb(skb); 1651 dev->stats.tx_dropped++; 1652 return NETDEV_TX_OK; 1653 } else { 1654 return NETDEV_TX_BUSY; 1655 } 1656 } 1657 1658 /* get put index for frame */ 1659 putidx = FIELD_GET(TXFQS_TFQPI_MASK, 1660 m_can_read(cdev, M_CAN_TXFQS)); 1661 1662 /* Construct DLC Field, with CAN-FD configuration. 1663 * Use the put index of the fifo as the message marker, 1664 * used in the TX interrupt for sending the correct echo frame. 1665 */ 1666 1667 /* get CAN FD configuration of frame */ 1668 fdflags = 0; 1669 if (can_is_canfd_skb(skb)) { 1670 fdflags |= TX_BUF_FDF; 1671 if (cf->flags & CANFD_BRS) 1672 fdflags |= TX_BUF_BRS; 1673 } 1674 1675 fifo_header.dlc = FIELD_PREP(TX_BUF_MM_MASK, putidx) | 1676 FIELD_PREP(TX_BUF_DLC_MASK, can_fd_len2dlc(cf->len)) | 1677 fdflags | TX_BUF_EFC; 1678 err = m_can_fifo_write(cdev, putidx, M_CAN_FIFO_ID, &fifo_header, 2); 1679 if (err) 1680 goto out_fail; 1681 1682 err = m_can_fifo_write(cdev, putidx, M_CAN_FIFO_DATA, 1683 cf->data, DIV_ROUND_UP(cf->len, 4)); 1684 if (err) 1685 goto out_fail; 1686 1687 /* Push loopback echo. 1688 * Will be looped back on TX interrupt based on message marker 1689 */ 1690 can_put_echo_skb(skb, dev, putidx, 0); 1691 1692 /* Enable TX FIFO element to start transfer */ 1693 m_can_write(cdev, M_CAN_TXBAR, (1 << putidx)); 1694 1695 /* stop network queue if fifo full */ 1696 if (m_can_tx_fifo_full(cdev) || 1697 m_can_next_echo_skb_occupied(dev, putidx)) 1698 netif_stop_queue(dev); 1699 } 1700 1701 return NETDEV_TX_OK; 1702 1703 out_fail: 1704 netdev_err(dev, "FIFO write returned %d\n", err); 1705 m_can_disable_all_interrupts(cdev); 1706 return NETDEV_TX_BUSY; 1707 } 1708 1709 static void m_can_tx_work_queue(struct work_struct *ws) 1710 { 1711 struct m_can_classdev *cdev = container_of(ws, struct m_can_classdev, 1712 tx_work); 1713 1714 m_can_tx_handler(cdev); 1715 } 1716 1717 static netdev_tx_t m_can_start_xmit(struct sk_buff *skb, 1718 struct net_device *dev) 1719 { 1720 struct m_can_classdev *cdev = netdev_priv(dev); 1721 1722 if (can_dropped_invalid_skb(dev, skb)) 1723 return NETDEV_TX_OK; 1724 1725 if (cdev->is_peripheral) { 1726 if (cdev->tx_skb) { 1727 netdev_err(dev, "hard_xmit called while tx busy\n"); 1728 return NETDEV_TX_BUSY; 1729 } 1730 1731 if (cdev->can.state == CAN_STATE_BUS_OFF) { 1732 m_can_clean(dev); 1733 } else { 1734 /* Need to stop the queue to avoid numerous requests 1735 * from being sent. Suggested improvement is to create 1736 * a queueing mechanism that will queue the skbs and 1737 * process them in order. 1738 */ 1739 cdev->tx_skb = skb; 1740 netif_stop_queue(cdev->net); 1741 queue_work(cdev->tx_wq, &cdev->tx_work); 1742 } 1743 } else { 1744 cdev->tx_skb = skb; 1745 return m_can_tx_handler(cdev); 1746 } 1747 1748 return NETDEV_TX_OK; 1749 } 1750 1751 static int m_can_open(struct net_device *dev) 1752 { 1753 struct m_can_classdev *cdev = netdev_priv(dev); 1754 int err; 1755 1756 err = phy_power_on(cdev->transceiver); 1757 if (err) 1758 return err; 1759 1760 err = m_can_clk_start(cdev); 1761 if (err) 1762 goto out_phy_power_off; 1763 1764 /* open the can device */ 1765 err = open_candev(dev); 1766 if (err) { 1767 netdev_err(dev, "failed to open can device\n"); 1768 goto exit_disable_clks; 1769 } 1770 1771 if (cdev->is_peripheral) 1772 can_rx_offload_enable(&cdev->offload); 1773 1774 /* register interrupt handler */ 1775 if (cdev->is_peripheral) { 1776 cdev->tx_skb = NULL; 1777 cdev->tx_wq = alloc_workqueue("mcan_wq", 1778 WQ_FREEZABLE | WQ_MEM_RECLAIM, 0); 1779 if (!cdev->tx_wq) { 1780 err = -ENOMEM; 1781 goto out_wq_fail; 1782 } 1783 1784 INIT_WORK(&cdev->tx_work, m_can_tx_work_queue); 1785 1786 err = request_threaded_irq(dev->irq, NULL, m_can_isr, 1787 IRQF_ONESHOT, 1788 dev->name, dev); 1789 } else { 1790 err = request_irq(dev->irq, m_can_isr, IRQF_SHARED, dev->name, 1791 dev); 1792 } 1793 1794 if (err < 0) { 1795 netdev_err(dev, "failed to request interrupt\n"); 1796 goto exit_irq_fail; 1797 } 1798 1799 /* start the m_can controller */ 1800 m_can_start(dev); 1801 1802 if (!cdev->is_peripheral) 1803 napi_enable(&cdev->napi); 1804 1805 netif_start_queue(dev); 1806 1807 return 0; 1808 1809 exit_irq_fail: 1810 if (cdev->is_peripheral) 1811 destroy_workqueue(cdev->tx_wq); 1812 out_wq_fail: 1813 if (cdev->is_peripheral) 1814 can_rx_offload_disable(&cdev->offload); 1815 close_candev(dev); 1816 exit_disable_clks: 1817 m_can_clk_stop(cdev); 1818 out_phy_power_off: 1819 phy_power_off(cdev->transceiver); 1820 return err; 1821 } 1822 1823 static const struct net_device_ops m_can_netdev_ops = { 1824 .ndo_open = m_can_open, 1825 .ndo_stop = m_can_close, 1826 .ndo_start_xmit = m_can_start_xmit, 1827 .ndo_change_mtu = can_change_mtu, 1828 }; 1829 1830 static int register_m_can_dev(struct net_device *dev) 1831 { 1832 dev->flags |= IFF_ECHO; /* we support local echo */ 1833 dev->netdev_ops = &m_can_netdev_ops; 1834 1835 return register_candev(dev); 1836 } 1837 1838 static void m_can_of_parse_mram(struct m_can_classdev *cdev, 1839 const u32 *mram_config_vals) 1840 { 1841 cdev->mcfg[MRAM_SIDF].off = mram_config_vals[0]; 1842 cdev->mcfg[MRAM_SIDF].num = mram_config_vals[1]; 1843 cdev->mcfg[MRAM_XIDF].off = cdev->mcfg[MRAM_SIDF].off + 1844 cdev->mcfg[MRAM_SIDF].num * SIDF_ELEMENT_SIZE; 1845 cdev->mcfg[MRAM_XIDF].num = mram_config_vals[2]; 1846 cdev->mcfg[MRAM_RXF0].off = cdev->mcfg[MRAM_XIDF].off + 1847 cdev->mcfg[MRAM_XIDF].num * XIDF_ELEMENT_SIZE; 1848 cdev->mcfg[MRAM_RXF0].num = mram_config_vals[3] & 1849 FIELD_MAX(RXFC_FS_MASK); 1850 cdev->mcfg[MRAM_RXF1].off = cdev->mcfg[MRAM_RXF0].off + 1851 cdev->mcfg[MRAM_RXF0].num * RXF0_ELEMENT_SIZE; 1852 cdev->mcfg[MRAM_RXF1].num = mram_config_vals[4] & 1853 FIELD_MAX(RXFC_FS_MASK); 1854 cdev->mcfg[MRAM_RXB].off = cdev->mcfg[MRAM_RXF1].off + 1855 cdev->mcfg[MRAM_RXF1].num * RXF1_ELEMENT_SIZE; 1856 cdev->mcfg[MRAM_RXB].num = mram_config_vals[5]; 1857 cdev->mcfg[MRAM_TXE].off = cdev->mcfg[MRAM_RXB].off + 1858 cdev->mcfg[MRAM_RXB].num * RXB_ELEMENT_SIZE; 1859 cdev->mcfg[MRAM_TXE].num = mram_config_vals[6]; 1860 cdev->mcfg[MRAM_TXB].off = cdev->mcfg[MRAM_TXE].off + 1861 cdev->mcfg[MRAM_TXE].num * TXE_ELEMENT_SIZE; 1862 cdev->mcfg[MRAM_TXB].num = mram_config_vals[7] & 1863 FIELD_MAX(TXBC_NDTB_MASK); 1864 1865 dev_dbg(cdev->dev, 1866 "sidf 0x%x %d xidf 0x%x %d rxf0 0x%x %d rxf1 0x%x %d rxb 0x%x %d txe 0x%x %d txb 0x%x %d\n", 1867 cdev->mcfg[MRAM_SIDF].off, cdev->mcfg[MRAM_SIDF].num, 1868 cdev->mcfg[MRAM_XIDF].off, cdev->mcfg[MRAM_XIDF].num, 1869 cdev->mcfg[MRAM_RXF0].off, cdev->mcfg[MRAM_RXF0].num, 1870 cdev->mcfg[MRAM_RXF1].off, cdev->mcfg[MRAM_RXF1].num, 1871 cdev->mcfg[MRAM_RXB].off, cdev->mcfg[MRAM_RXB].num, 1872 cdev->mcfg[MRAM_TXE].off, cdev->mcfg[MRAM_TXE].num, 1873 cdev->mcfg[MRAM_TXB].off, cdev->mcfg[MRAM_TXB].num); 1874 } 1875 1876 int m_can_init_ram(struct m_can_classdev *cdev) 1877 { 1878 int end, i, start; 1879 int err = 0; 1880 1881 /* initialize the entire Message RAM in use to avoid possible 1882 * ECC/parity checksum errors when reading an uninitialized buffer 1883 */ 1884 start = cdev->mcfg[MRAM_SIDF].off; 1885 end = cdev->mcfg[MRAM_TXB].off + 1886 cdev->mcfg[MRAM_TXB].num * TXB_ELEMENT_SIZE; 1887 1888 for (i = start; i < end; i += 4) { 1889 err = m_can_fifo_write_no_off(cdev, i, 0x0); 1890 if (err) 1891 break; 1892 } 1893 1894 return err; 1895 } 1896 EXPORT_SYMBOL_GPL(m_can_init_ram); 1897 1898 int m_can_class_get_clocks(struct m_can_classdev *cdev) 1899 { 1900 int ret = 0; 1901 1902 cdev->hclk = devm_clk_get(cdev->dev, "hclk"); 1903 cdev->cclk = devm_clk_get(cdev->dev, "cclk"); 1904 1905 if (IS_ERR(cdev->cclk)) { 1906 dev_err(cdev->dev, "no clock found\n"); 1907 ret = -ENODEV; 1908 } 1909 1910 return ret; 1911 } 1912 EXPORT_SYMBOL_GPL(m_can_class_get_clocks); 1913 1914 struct m_can_classdev *m_can_class_allocate_dev(struct device *dev, 1915 int sizeof_priv) 1916 { 1917 struct m_can_classdev *class_dev = NULL; 1918 u32 mram_config_vals[MRAM_CFG_LEN]; 1919 struct net_device *net_dev; 1920 u32 tx_fifo_size; 1921 int ret; 1922 1923 ret = fwnode_property_read_u32_array(dev_fwnode(dev), 1924 "bosch,mram-cfg", 1925 mram_config_vals, 1926 sizeof(mram_config_vals) / 4); 1927 if (ret) { 1928 dev_err(dev, "Could not get Message RAM configuration."); 1929 goto out; 1930 } 1931 1932 /* Get TX FIFO size 1933 * Defines the total amount of echo buffers for loopback 1934 */ 1935 tx_fifo_size = mram_config_vals[7]; 1936 1937 /* allocate the m_can device */ 1938 net_dev = alloc_candev(sizeof_priv, tx_fifo_size); 1939 if (!net_dev) { 1940 dev_err(dev, "Failed to allocate CAN device"); 1941 goto out; 1942 } 1943 1944 class_dev = netdev_priv(net_dev); 1945 class_dev->net = net_dev; 1946 class_dev->dev = dev; 1947 SET_NETDEV_DEV(net_dev, dev); 1948 1949 m_can_of_parse_mram(class_dev, mram_config_vals); 1950 out: 1951 return class_dev; 1952 } 1953 EXPORT_SYMBOL_GPL(m_can_class_allocate_dev); 1954 1955 void m_can_class_free_dev(struct net_device *net) 1956 { 1957 free_candev(net); 1958 } 1959 EXPORT_SYMBOL_GPL(m_can_class_free_dev); 1960 1961 int m_can_class_register(struct m_can_classdev *cdev) 1962 { 1963 int ret; 1964 1965 if (cdev->pm_clock_support) { 1966 ret = m_can_clk_start(cdev); 1967 if (ret) 1968 return ret; 1969 } 1970 1971 if (cdev->is_peripheral) { 1972 ret = can_rx_offload_add_manual(cdev->net, &cdev->offload, 1973 NAPI_POLL_WEIGHT); 1974 if (ret) 1975 goto clk_disable; 1976 } 1977 1978 ret = m_can_dev_setup(cdev); 1979 if (ret) 1980 goto rx_offload_del; 1981 1982 ret = register_m_can_dev(cdev->net); 1983 if (ret) { 1984 dev_err(cdev->dev, "registering %s failed (err=%d)\n", 1985 cdev->net->name, ret); 1986 goto rx_offload_del; 1987 } 1988 1989 of_can_transceiver(cdev->net); 1990 1991 dev_info(cdev->dev, "%s device registered (irq=%d, version=%d)\n", 1992 KBUILD_MODNAME, cdev->net->irq, cdev->version); 1993 1994 /* Probe finished 1995 * Stop clocks. They will be reactivated once the M_CAN device is opened 1996 */ 1997 m_can_clk_stop(cdev); 1998 1999 return 0; 2000 2001 rx_offload_del: 2002 if (cdev->is_peripheral) 2003 can_rx_offload_del(&cdev->offload); 2004 clk_disable: 2005 m_can_clk_stop(cdev); 2006 2007 return ret; 2008 } 2009 EXPORT_SYMBOL_GPL(m_can_class_register); 2010 2011 void m_can_class_unregister(struct m_can_classdev *cdev) 2012 { 2013 if (cdev->is_peripheral) 2014 can_rx_offload_del(&cdev->offload); 2015 unregister_candev(cdev->net); 2016 } 2017 EXPORT_SYMBOL_GPL(m_can_class_unregister); 2018 2019 int m_can_class_suspend(struct device *dev) 2020 { 2021 struct m_can_classdev *cdev = dev_get_drvdata(dev); 2022 struct net_device *ndev = cdev->net; 2023 2024 if (netif_running(ndev)) { 2025 netif_stop_queue(ndev); 2026 netif_device_detach(ndev); 2027 m_can_stop(ndev); 2028 m_can_clk_stop(cdev); 2029 } 2030 2031 pinctrl_pm_select_sleep_state(dev); 2032 2033 cdev->can.state = CAN_STATE_SLEEPING; 2034 2035 return 0; 2036 } 2037 EXPORT_SYMBOL_GPL(m_can_class_suspend); 2038 2039 int m_can_class_resume(struct device *dev) 2040 { 2041 struct m_can_classdev *cdev = dev_get_drvdata(dev); 2042 struct net_device *ndev = cdev->net; 2043 2044 pinctrl_pm_select_default_state(dev); 2045 2046 cdev->can.state = CAN_STATE_ERROR_ACTIVE; 2047 2048 if (netif_running(ndev)) { 2049 int ret; 2050 2051 ret = m_can_clk_start(cdev); 2052 if (ret) 2053 return ret; 2054 2055 m_can_init_ram(cdev); 2056 m_can_start(ndev); 2057 netif_device_attach(ndev); 2058 netif_start_queue(ndev); 2059 } 2060 2061 return 0; 2062 } 2063 EXPORT_SYMBOL_GPL(m_can_class_resume); 2064 2065 MODULE_AUTHOR("Dong Aisheng <b29396@freescale.com>"); 2066 MODULE_AUTHOR("Dan Murphy <dmurphy@ti.com>"); 2067 MODULE_LICENSE("GPL v2"); 2068 MODULE_DESCRIPTION("CAN bus driver for Bosch M_CAN controller"); 2069