// SPDX-License-Identifier: GPL-2.0-only /* CAN bus driver for Microchip 251x/25625 CAN Controller with SPI Interface * * MCP2510 support and bug fixes by Christian Pellegrin * * * Copyright 2009 Christian Pellegrin EVOL S.r.l. * * Copyright 2007 Raymarine UK, Ltd. All Rights Reserved. * Written under contract by: * Chris Elston, Katalix Systems, Ltd. * * Based on Microchip MCP251x CAN controller driver written by * David Vrabel, Copyright 2006 Arcom Control Systems Ltd. * * Based on CAN bus driver for the CCAN controller written by * - Sascha Hauer, Marc Kleine-Budde, Pengutronix * - Simon Kallweit, intefo AG * Copyright 2007 */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* SPI interface instruction set */ #define INSTRUCTION_WRITE 0x02 #define INSTRUCTION_READ 0x03 #define INSTRUCTION_BIT_MODIFY 0x05 #define INSTRUCTION_LOAD_TXB(n) (0x40 + 2 * (n)) #define INSTRUCTION_READ_RXB(n) (((n) == 0) ? 0x90 : 0x94) #define INSTRUCTION_RESET 0xC0 #define RTS_TXB0 0x01 #define RTS_TXB1 0x02 #define RTS_TXB2 0x04 #define INSTRUCTION_RTS(n) (0x80 | ((n) & 0x07)) /* MPC251x registers */ #define BFPCTRL 0x0c # define BFPCTRL_B0BFM BIT(0) # define BFPCTRL_B1BFM BIT(1) # define BFPCTRL_BFM(n) (BFPCTRL_B0BFM << (n)) # define BFPCTRL_BFM_MASK GENMASK(1, 0) # define BFPCTRL_B0BFE BIT(2) # define BFPCTRL_B1BFE BIT(3) # define BFPCTRL_BFE(n) (BFPCTRL_B0BFE << (n)) # define BFPCTRL_BFE_MASK GENMASK(3, 2) # define BFPCTRL_B0BFS BIT(4) # define BFPCTRL_B1BFS BIT(5) # define BFPCTRL_BFS(n) (BFPCTRL_B0BFS << (n)) # define BFPCTRL_BFS_MASK GENMASK(5, 4) #define TXRTSCTRL 0x0d # define TXRTSCTRL_B0RTSM BIT(0) # define TXRTSCTRL_B1RTSM BIT(1) # define TXRTSCTRL_B2RTSM BIT(2) # define TXRTSCTRL_RTSM(n) (TXRTSCTRL_B0RTSM << (n)) # define TXRTSCTRL_RTSM_MASK GENMASK(2, 0) # define TXRTSCTRL_B0RTS BIT(3) # define TXRTSCTRL_B1RTS BIT(4) # define TXRTSCTRL_B2RTS BIT(5) # define TXRTSCTRL_RTS(n) (TXRTSCTRL_B0RTS << (n)) # define TXRTSCTRL_RTS_MASK GENMASK(5, 3) #define CANSTAT 0x0e #define CANCTRL 0x0f # define CANCTRL_REQOP_MASK 0xe0 # define CANCTRL_REQOP_CONF 0x80 # define CANCTRL_REQOP_LISTEN_ONLY 0x60 # define CANCTRL_REQOP_LOOPBACK 0x40 # define CANCTRL_REQOP_SLEEP 0x20 # define CANCTRL_REQOP_NORMAL 0x00 # define CANCTRL_OSM 0x08 # define CANCTRL_ABAT 0x10 #define TEC 0x1c #define REC 0x1d #define CNF1 0x2a # define CNF1_SJW_SHIFT 6 #define CNF2 0x29 # define CNF2_BTLMODE 0x80 # define CNF2_SAM 0x40 # define CNF2_PS1_SHIFT 3 #define CNF3 0x28 # define CNF3_SOF 0x08 # define CNF3_WAKFIL 0x04 # define CNF3_PHSEG2_MASK 0x07 #define CANINTE 0x2b # define CANINTE_MERRE 0x80 # define CANINTE_WAKIE 0x40 # define CANINTE_ERRIE 0x20 # define CANINTE_TX2IE 0x10 # define CANINTE_TX1IE 0x08 # define CANINTE_TX0IE 0x04 # define CANINTE_RX1IE 0x02 # define CANINTE_RX0IE 0x01 #define CANINTF 0x2c # define CANINTF_MERRF 0x80 # define CANINTF_WAKIF 0x40 # define CANINTF_ERRIF 0x20 # define CANINTF_TX2IF 0x10 # define CANINTF_TX1IF 0x08 # define CANINTF_TX0IF 0x04 # define CANINTF_RX1IF 0x02 # define CANINTF_RX0IF 0x01 # define CANINTF_RX (CANINTF_RX0IF | CANINTF_RX1IF) # define CANINTF_TX (CANINTF_TX2IF | CANINTF_TX1IF | CANINTF_TX0IF) # define CANINTF_ERR (CANINTF_ERRIF) #define EFLG 0x2d # define EFLG_EWARN 0x01 # define EFLG_RXWAR 0x02 # define EFLG_TXWAR 0x04 # define EFLG_RXEP 0x08 # define EFLG_TXEP 0x10 # define EFLG_TXBO 0x20 # define EFLG_RX0OVR 0x40 # define EFLG_RX1OVR 0x80 #define TXBCTRL(n) (((n) * 0x10) + 0x30 + TXBCTRL_OFF) # define TXBCTRL_ABTF 0x40 # define TXBCTRL_MLOA 0x20 # define TXBCTRL_TXERR 0x10 # define TXBCTRL_TXREQ 0x08 #define TXBSIDH(n) (((n) * 0x10) + 0x30 + TXBSIDH_OFF) # define SIDH_SHIFT 3 #define TXBSIDL(n) (((n) * 0x10) + 0x30 + TXBSIDL_OFF) # define SIDL_SID_MASK 7 # define SIDL_SID_SHIFT 5 # define SIDL_EXIDE_SHIFT 3 # define SIDL_EID_SHIFT 16 # define SIDL_EID_MASK 3 #define TXBEID8(n) (((n) * 0x10) + 0x30 + TXBEID8_OFF) #define TXBEID0(n) (((n) * 0x10) + 0x30 + TXBEID0_OFF) #define TXBDLC(n) (((n) * 0x10) + 0x30 + TXBDLC_OFF) # define DLC_RTR_SHIFT 6 #define TXBCTRL_OFF 0 #define TXBSIDH_OFF 1 #define TXBSIDL_OFF 2 #define TXBEID8_OFF 3 #define TXBEID0_OFF 4 #define TXBDLC_OFF 5 #define TXBDAT_OFF 6 #define RXBCTRL(n) (((n) * 0x10) + 0x60 + RXBCTRL_OFF) # define RXBCTRL_BUKT 0x04 # define RXBCTRL_RXM0 0x20 # define RXBCTRL_RXM1 0x40 #define RXBSIDH(n) (((n) * 0x10) + 0x60 + RXBSIDH_OFF) # define RXBSIDH_SHIFT 3 #define RXBSIDL(n) (((n) * 0x10) + 0x60 + RXBSIDL_OFF) # define RXBSIDL_IDE 0x08 # define RXBSIDL_SRR 0x10 # define RXBSIDL_EID 3 # define RXBSIDL_SHIFT 5 #define RXBEID8(n) (((n) * 0x10) + 0x60 + RXBEID8_OFF) #define RXBEID0(n) (((n) * 0x10) + 0x60 + RXBEID0_OFF) #define RXBDLC(n) (((n) * 0x10) + 0x60 + RXBDLC_OFF) # define RXBDLC_LEN_MASK 0x0f # define RXBDLC_RTR 0x40 #define RXBCTRL_OFF 0 #define RXBSIDH_OFF 1 #define RXBSIDL_OFF 2 #define RXBEID8_OFF 3 #define RXBEID0_OFF 4 #define RXBDLC_OFF 5 #define RXBDAT_OFF 6 #define RXFSID(n) ((n < 3) ? 0 : 4) #define RXFSIDH(n) ((n) * 4 + RXFSID(n)) #define RXFSIDL(n) ((n) * 4 + 1 + RXFSID(n)) #define RXFEID8(n) ((n) * 4 + 2 + RXFSID(n)) #define RXFEID0(n) ((n) * 4 + 3 + RXFSID(n)) #define RXMSIDH(n) ((n) * 4 + 0x20) #define RXMSIDL(n) ((n) * 4 + 0x21) #define RXMEID8(n) ((n) * 4 + 0x22) #define RXMEID0(n) ((n) * 4 + 0x23) #define GET_BYTE(val, byte) \ (((val) >> ((byte) * 8)) & 0xff) #define SET_BYTE(val, byte) \ (((val) & 0xff) << ((byte) * 8)) /* Buffer size required for the largest SPI transfer (i.e., reading a * frame) */ #define CAN_FRAME_MAX_DATA_LEN 8 #define SPI_TRANSFER_BUF_LEN (6 + CAN_FRAME_MAX_DATA_LEN) #define CAN_FRAME_MAX_BITS 128 #define TX_ECHO_SKB_MAX 1 #define MCP251X_OST_DELAY_MS (5) #define DEVICE_NAME "mcp251x" static const struct can_bittiming_const mcp251x_bittiming_const = { .name = DEVICE_NAME, .tseg1_min = 3, .tseg1_max = 16, .tseg2_min = 2, .tseg2_max = 8, .sjw_max = 4, .brp_min = 1, .brp_max = 64, .brp_inc = 1, }; enum mcp251x_model { CAN_MCP251X_MCP2510 = 0x2510, CAN_MCP251X_MCP2515 = 0x2515, CAN_MCP251X_MCP25625 = 0x25625, }; struct mcp251x_priv { struct can_priv can; struct net_device *net; struct spi_device *spi; enum mcp251x_model model; struct mutex mcp_lock; /* SPI device lock */ u8 *spi_tx_buf; u8 *spi_rx_buf; struct sk_buff *tx_skb; struct workqueue_struct *wq; struct work_struct tx_work; struct work_struct restart_work; int force_quit; int after_suspend; #define AFTER_SUSPEND_UP 1 #define AFTER_SUSPEND_DOWN 2 #define AFTER_SUSPEND_POWER 4 #define AFTER_SUSPEND_RESTART 8 int restart_tx; bool tx_busy; struct regulator *power; struct regulator *transceiver; struct clk *clk; #ifdef CONFIG_GPIOLIB struct gpio_chip gpio; u8 reg_bfpctrl; #endif }; #define MCP251X_IS(_model) \ static inline int mcp251x_is_##_model(struct spi_device *spi) \ { \ struct mcp251x_priv *priv = spi_get_drvdata(spi); \ return priv->model == CAN_MCP251X_MCP##_model; \ } MCP251X_IS(2510); static void mcp251x_clean(struct net_device *net) { struct mcp251x_priv *priv = netdev_priv(net); if (priv->tx_skb || priv->tx_busy) net->stats.tx_errors++; dev_kfree_skb(priv->tx_skb); if (priv->tx_busy) can_free_echo_skb(priv->net, 0, NULL); priv->tx_skb = NULL; priv->tx_busy = false; } /* Note about handling of error return of mcp251x_spi_trans: accessing * registers via SPI is not really different conceptually than using * normal I/O assembler instructions, although it's much more * complicated from a practical POV. So it's not advisable to always * check the return value of this function. Imagine that every * read{b,l}, write{b,l} and friends would be bracketed in "if ( < 0) * error();", it would be a great mess (well there are some situation * when exception handling C++ like could be useful after all). So we * just check that transfers are OK at the beginning of our * conversation with the chip and to avoid doing really nasty things * (like injecting bogus packets in the network stack). */ static int mcp251x_spi_trans(struct spi_device *spi, int len) { struct mcp251x_priv *priv = spi_get_drvdata(spi); struct spi_transfer t = { .tx_buf = priv->spi_tx_buf, .rx_buf = priv->spi_rx_buf, .len = len, .cs_change = 0, }; struct spi_message m; int ret; spi_message_init(&m); spi_message_add_tail(&t, &m); ret = spi_sync(spi, &m); if (ret) dev_err(&spi->dev, "spi transfer failed: ret = %d\n", ret); return ret; } static int mcp251x_spi_write(struct spi_device *spi, int len) { struct mcp251x_priv *priv = spi_get_drvdata(spi); int ret; ret = spi_write(spi, priv->spi_tx_buf, len); if (ret) dev_err(&spi->dev, "spi write failed: ret = %d\n", ret); return ret; } static u8 mcp251x_read_reg(struct spi_device *spi, u8 reg) { struct mcp251x_priv *priv = spi_get_drvdata(spi); u8 val = 0; priv->spi_tx_buf[0] = INSTRUCTION_READ; priv->spi_tx_buf[1] = reg; if (spi->controller->flags & SPI_CONTROLLER_HALF_DUPLEX) { spi_write_then_read(spi, priv->spi_tx_buf, 2, &val, 1); } else { mcp251x_spi_trans(spi, 3); val = priv->spi_rx_buf[2]; } return val; } static void mcp251x_read_2regs(struct spi_device *spi, u8 reg, u8 *v1, u8 *v2) { struct mcp251x_priv *priv = spi_get_drvdata(spi); priv->spi_tx_buf[0] = INSTRUCTION_READ; priv->spi_tx_buf[1] = reg; if (spi->controller->flags & SPI_CONTROLLER_HALF_DUPLEX) { u8 val[2] = { 0 }; spi_write_then_read(spi, priv->spi_tx_buf, 2, val, 2); *v1 = val[0]; *v2 = val[1]; } else { mcp251x_spi_trans(spi, 4); *v1 = priv->spi_rx_buf[2]; *v2 = priv->spi_rx_buf[3]; } } static void mcp251x_write_reg(struct spi_device *spi, u8 reg, u8 val) { struct mcp251x_priv *priv = spi_get_drvdata(spi); priv->spi_tx_buf[0] = INSTRUCTION_WRITE; priv->spi_tx_buf[1] = reg; priv->spi_tx_buf[2] = val; mcp251x_spi_write(spi, 3); } static void mcp251x_write_2regs(struct spi_device *spi, u8 reg, u8 v1, u8 v2) { struct mcp251x_priv *priv = spi_get_drvdata(spi); priv->spi_tx_buf[0] = INSTRUCTION_WRITE; priv->spi_tx_buf[1] = reg; priv->spi_tx_buf[2] = v1; priv->spi_tx_buf[3] = v2; mcp251x_spi_write(spi, 4); } static void mcp251x_write_bits(struct spi_device *spi, u8 reg, u8 mask, u8 val) { struct mcp251x_priv *priv = spi_get_drvdata(spi); priv->spi_tx_buf[0] = INSTRUCTION_BIT_MODIFY; priv->spi_tx_buf[1] = reg; priv->spi_tx_buf[2] = mask; priv->spi_tx_buf[3] = val; mcp251x_spi_write(spi, 4); } static u8 mcp251x_read_stat(struct spi_device *spi) { return mcp251x_read_reg(spi, CANSTAT) & CANCTRL_REQOP_MASK; } #define mcp251x_read_stat_poll_timeout(addr, val, cond, delay_us, timeout_us) \ readx_poll_timeout(mcp251x_read_stat, addr, val, cond, \ delay_us, timeout_us) #ifdef CONFIG_GPIOLIB enum { MCP251X_GPIO_TX0RTS = 0, /* inputs */ MCP251X_GPIO_TX1RTS, MCP251X_GPIO_TX2RTS, MCP251X_GPIO_RX0BF, /* outputs */ MCP251X_GPIO_RX1BF, }; #define MCP251X_GPIO_INPUT_MASK \ GENMASK(MCP251X_GPIO_TX2RTS, MCP251X_GPIO_TX0RTS) #define MCP251X_GPIO_OUTPUT_MASK \ GENMASK(MCP251X_GPIO_RX1BF, MCP251X_GPIO_RX0BF) static const char * const mcp251x_gpio_names[] = { [MCP251X_GPIO_TX0RTS] = "TX0RTS", /* inputs */ [MCP251X_GPIO_TX1RTS] = "TX1RTS", [MCP251X_GPIO_TX2RTS] = "TX2RTS", [MCP251X_GPIO_RX0BF] = "RX0BF", /* outputs */ [MCP251X_GPIO_RX1BF] = "RX1BF", }; static inline bool mcp251x_gpio_is_input(unsigned int offset) { return offset <= MCP251X_GPIO_TX2RTS; } static int mcp251x_gpio_request(struct gpio_chip *chip, unsigned int offset) { struct mcp251x_priv *priv = gpiochip_get_data(chip); u8 val; /* nothing to be done for inputs */ if (mcp251x_gpio_is_input(offset)) return 0; val = BFPCTRL_BFE(offset - MCP251X_GPIO_RX0BF); mutex_lock(&priv->mcp_lock); mcp251x_write_bits(priv->spi, BFPCTRL, val, val); mutex_unlock(&priv->mcp_lock); priv->reg_bfpctrl |= val; return 0; } static void mcp251x_gpio_free(struct gpio_chip *chip, unsigned int offset) { struct mcp251x_priv *priv = gpiochip_get_data(chip); u8 val; /* nothing to be done for inputs */ if (mcp251x_gpio_is_input(offset)) return; val = BFPCTRL_BFE(offset - MCP251X_GPIO_RX0BF); mutex_lock(&priv->mcp_lock); mcp251x_write_bits(priv->spi, BFPCTRL, val, 0); mutex_unlock(&priv->mcp_lock); priv->reg_bfpctrl &= ~val; } static int mcp251x_gpio_get_direction(struct gpio_chip *chip, unsigned int offset) { if (mcp251x_gpio_is_input(offset)) return GPIOF_DIR_IN; return GPIOF_DIR_OUT; } static int mcp251x_gpio_get(struct gpio_chip *chip, unsigned int offset) { struct mcp251x_priv *priv = gpiochip_get_data(chip); u8 reg, mask, val; if (mcp251x_gpio_is_input(offset)) { reg = TXRTSCTRL; mask = TXRTSCTRL_RTS(offset); } else { reg = BFPCTRL; mask = BFPCTRL_BFS(offset - MCP251X_GPIO_RX0BF); } mutex_lock(&priv->mcp_lock); val = mcp251x_read_reg(priv->spi, reg); mutex_unlock(&priv->mcp_lock); return !!(val & mask); } static int mcp251x_gpio_get_multiple(struct gpio_chip *chip, unsigned long *maskp, unsigned long *bitsp) { struct mcp251x_priv *priv = gpiochip_get_data(chip); unsigned long bits = 0; u8 val; mutex_lock(&priv->mcp_lock); if (maskp[0] & MCP251X_GPIO_INPUT_MASK) { val = mcp251x_read_reg(priv->spi, TXRTSCTRL); val = FIELD_GET(TXRTSCTRL_RTS_MASK, val); bits |= FIELD_PREP(MCP251X_GPIO_INPUT_MASK, val); } if (maskp[0] & MCP251X_GPIO_OUTPUT_MASK) { val = mcp251x_read_reg(priv->spi, BFPCTRL); val = FIELD_GET(BFPCTRL_BFS_MASK, val); bits |= FIELD_PREP(MCP251X_GPIO_OUTPUT_MASK, val); } mutex_unlock(&priv->mcp_lock); bitsp[0] = bits; return 0; } static void mcp251x_gpio_set(struct gpio_chip *chip, unsigned int offset, int value) { struct mcp251x_priv *priv = gpiochip_get_data(chip); u8 mask, val; mask = BFPCTRL_BFS(offset - MCP251X_GPIO_RX0BF); val = value ? mask : 0; mutex_lock(&priv->mcp_lock); mcp251x_write_bits(priv->spi, BFPCTRL, mask, val); mutex_unlock(&priv->mcp_lock); priv->reg_bfpctrl &= ~mask; priv->reg_bfpctrl |= val; } static void mcp251x_gpio_set_multiple(struct gpio_chip *chip, unsigned long *maskp, unsigned long *bitsp) { struct mcp251x_priv *priv = gpiochip_get_data(chip); u8 mask, val; mask = FIELD_GET(MCP251X_GPIO_OUTPUT_MASK, maskp[0]); mask = FIELD_PREP(BFPCTRL_BFS_MASK, mask); val = FIELD_GET(MCP251X_GPIO_OUTPUT_MASK, bitsp[0]); val = FIELD_PREP(BFPCTRL_BFS_MASK, val); if (!mask) return; mutex_lock(&priv->mcp_lock); mcp251x_write_bits(priv->spi, BFPCTRL, mask, val); mutex_unlock(&priv->mcp_lock); priv->reg_bfpctrl &= ~mask; priv->reg_bfpctrl |= val; } static void mcp251x_gpio_restore(struct spi_device *spi) { struct mcp251x_priv *priv = spi_get_drvdata(spi); mcp251x_write_reg(spi, BFPCTRL, priv->reg_bfpctrl); } static int mcp251x_gpio_setup(struct mcp251x_priv *priv) { struct gpio_chip *gpio = &priv->gpio; if (!device_property_present(&priv->spi->dev, "gpio-controller")) return 0; /* gpiochip handles TX[0..2]RTS and RX[0..1]BF */ gpio->label = priv->spi->modalias; gpio->parent = &priv->spi->dev; gpio->owner = THIS_MODULE; gpio->request = mcp251x_gpio_request; gpio->free = mcp251x_gpio_free; gpio->get_direction = mcp251x_gpio_get_direction; gpio->get = mcp251x_gpio_get; gpio->get_multiple = mcp251x_gpio_get_multiple; gpio->set = mcp251x_gpio_set; gpio->set_multiple = mcp251x_gpio_set_multiple; gpio->base = -1; gpio->ngpio = ARRAY_SIZE(mcp251x_gpio_names); gpio->names = mcp251x_gpio_names; gpio->can_sleep = true; return devm_gpiochip_add_data(&priv->spi->dev, gpio, priv); } #else static inline void mcp251x_gpio_restore(struct spi_device *spi) { } static inline int mcp251x_gpio_setup(struct mcp251x_priv *priv) { return 0; } #endif static void mcp251x_hw_tx_frame(struct spi_device *spi, u8 *buf, int len, int tx_buf_idx) { struct mcp251x_priv *priv = spi_get_drvdata(spi); if (mcp251x_is_2510(spi)) { int i; for (i = 1; i < TXBDAT_OFF + len; i++) mcp251x_write_reg(spi, TXBCTRL(tx_buf_idx) + i, buf[i]); } else { memcpy(priv->spi_tx_buf, buf, TXBDAT_OFF + len); mcp251x_spi_write(spi, TXBDAT_OFF + len); } } static void mcp251x_hw_tx(struct spi_device *spi, struct can_frame *frame, int tx_buf_idx) { struct mcp251x_priv *priv = spi_get_drvdata(spi); u32 sid, eid, exide, rtr; u8 buf[SPI_TRANSFER_BUF_LEN]; exide = (frame->can_id & CAN_EFF_FLAG) ? 1 : 0; /* Extended ID Enable */ if (exide) sid = (frame->can_id & CAN_EFF_MASK) >> 18; else sid = frame->can_id & CAN_SFF_MASK; /* Standard ID */ eid = frame->can_id & CAN_EFF_MASK; /* Extended ID */ rtr = (frame->can_id & CAN_RTR_FLAG) ? 1 : 0; /* Remote transmission */ buf[TXBCTRL_OFF] = INSTRUCTION_LOAD_TXB(tx_buf_idx); buf[TXBSIDH_OFF] = sid >> SIDH_SHIFT; buf[TXBSIDL_OFF] = ((sid & SIDL_SID_MASK) << SIDL_SID_SHIFT) | (exide << SIDL_EXIDE_SHIFT) | ((eid >> SIDL_EID_SHIFT) & SIDL_EID_MASK); buf[TXBEID8_OFF] = GET_BYTE(eid, 1); buf[TXBEID0_OFF] = GET_BYTE(eid, 0); buf[TXBDLC_OFF] = (rtr << DLC_RTR_SHIFT) | frame->len; memcpy(buf + TXBDAT_OFF, frame->data, frame->len); mcp251x_hw_tx_frame(spi, buf, frame->len, tx_buf_idx); /* use INSTRUCTION_RTS, to avoid "repeated frame problem" */ priv->spi_tx_buf[0] = INSTRUCTION_RTS(1 << tx_buf_idx); mcp251x_spi_write(priv->spi, 1); } static void mcp251x_hw_rx_frame(struct spi_device *spi, u8 *buf, int buf_idx) { struct mcp251x_priv *priv = spi_get_drvdata(spi); if (mcp251x_is_2510(spi)) { int i, len; for (i = 1; i < RXBDAT_OFF; i++) buf[i] = mcp251x_read_reg(spi, RXBCTRL(buf_idx) + i); len = can_cc_dlc2len(buf[RXBDLC_OFF] & RXBDLC_LEN_MASK); for (; i < (RXBDAT_OFF + len); i++) buf[i] = mcp251x_read_reg(spi, RXBCTRL(buf_idx) + i); } else { priv->spi_tx_buf[RXBCTRL_OFF] = INSTRUCTION_READ_RXB(buf_idx); if (spi->controller->flags & SPI_CONTROLLER_HALF_DUPLEX) { spi_write_then_read(spi, priv->spi_tx_buf, 1, priv->spi_rx_buf, SPI_TRANSFER_BUF_LEN); memcpy(buf + 1, priv->spi_rx_buf, SPI_TRANSFER_BUF_LEN - 1); } else { mcp251x_spi_trans(spi, SPI_TRANSFER_BUF_LEN); memcpy(buf, priv->spi_rx_buf, SPI_TRANSFER_BUF_LEN); } } } static void mcp251x_hw_rx(struct spi_device *spi, int buf_idx) { struct mcp251x_priv *priv = spi_get_drvdata(spi); struct sk_buff *skb; struct can_frame *frame; u8 buf[SPI_TRANSFER_BUF_LEN]; skb = alloc_can_skb(priv->net, &frame); if (!skb) { dev_err(&spi->dev, "cannot allocate RX skb\n"); priv->net->stats.rx_dropped++; return; } mcp251x_hw_rx_frame(spi, buf, buf_idx); if (buf[RXBSIDL_OFF] & RXBSIDL_IDE) { /* Extended ID format */ frame->can_id = CAN_EFF_FLAG; frame->can_id |= /* Extended ID part */ SET_BYTE(buf[RXBSIDL_OFF] & RXBSIDL_EID, 2) | SET_BYTE(buf[RXBEID8_OFF], 1) | SET_BYTE(buf[RXBEID0_OFF], 0) | /* Standard ID part */ (((buf[RXBSIDH_OFF] << RXBSIDH_SHIFT) | (buf[RXBSIDL_OFF] >> RXBSIDL_SHIFT)) << 18); /* Remote transmission request */ if (buf[RXBDLC_OFF] & RXBDLC_RTR) frame->can_id |= CAN_RTR_FLAG; } else { /* Standard ID format */ frame->can_id = (buf[RXBSIDH_OFF] << RXBSIDH_SHIFT) | (buf[RXBSIDL_OFF] >> RXBSIDL_SHIFT); if (buf[RXBSIDL_OFF] & RXBSIDL_SRR) frame->can_id |= CAN_RTR_FLAG; } /* Data length */ frame->len = can_cc_dlc2len(buf[RXBDLC_OFF] & RXBDLC_LEN_MASK); if (!(frame->can_id & CAN_RTR_FLAG)) { memcpy(frame->data, buf + RXBDAT_OFF, frame->len); priv->net->stats.rx_bytes += frame->len; } priv->net->stats.rx_packets++; netif_rx(skb); } static void mcp251x_hw_sleep(struct spi_device *spi) { mcp251x_write_reg(spi, CANCTRL, CANCTRL_REQOP_SLEEP); } /* May only be called when device is sleeping! */ static int mcp251x_hw_wake(struct spi_device *spi) { u8 value; int ret; /* Force wakeup interrupt to wake device, but don't execute IST */ disable_irq(spi->irq); mcp251x_write_2regs(spi, CANINTE, CANINTE_WAKIE, CANINTF_WAKIF); /* Wait for oscillator startup timer after wake up */ mdelay(MCP251X_OST_DELAY_MS); /* Put device into config mode */ mcp251x_write_reg(spi, CANCTRL, CANCTRL_REQOP_CONF); /* Wait for the device to enter config mode */ ret = mcp251x_read_stat_poll_timeout(spi, value, value == CANCTRL_REQOP_CONF, MCP251X_OST_DELAY_MS * 1000, USEC_PER_SEC); if (ret) { dev_err(&spi->dev, "MCP251x didn't enter in config mode\n"); return ret; } /* Disable and clear pending interrupts */ mcp251x_write_2regs(spi, CANINTE, 0x00, 0x00); enable_irq(spi->irq); return 0; } static netdev_tx_t mcp251x_hard_start_xmit(struct sk_buff *skb, struct net_device *net) { struct mcp251x_priv *priv = netdev_priv(net); struct spi_device *spi = priv->spi; if (priv->tx_skb || priv->tx_busy) { dev_warn(&spi->dev, "hard_xmit called while tx busy\n"); return NETDEV_TX_BUSY; } if (can_dropped_invalid_skb(net, skb)) return NETDEV_TX_OK; netif_stop_queue(net); priv->tx_skb = skb; queue_work(priv->wq, &priv->tx_work); return NETDEV_TX_OK; } static int mcp251x_do_set_mode(struct net_device *net, enum can_mode mode) { struct mcp251x_priv *priv = netdev_priv(net); switch (mode) { case CAN_MODE_START: mcp251x_clean(net); /* We have to delay work since SPI I/O may sleep */ priv->can.state = CAN_STATE_ERROR_ACTIVE; priv->restart_tx = 1; if (priv->can.restart_ms == 0) priv->after_suspend = AFTER_SUSPEND_RESTART; queue_work(priv->wq, &priv->restart_work); break; default: return -EOPNOTSUPP; } return 0; } static int mcp251x_set_normal_mode(struct spi_device *spi) { struct mcp251x_priv *priv = spi_get_drvdata(spi); u8 value; int ret; /* Enable interrupts */ mcp251x_write_reg(spi, CANINTE, CANINTE_ERRIE | CANINTE_TX2IE | CANINTE_TX1IE | CANINTE_TX0IE | CANINTE_RX1IE | CANINTE_RX0IE); if (priv->can.ctrlmode & CAN_CTRLMODE_LOOPBACK) { /* Put device into loopback mode */ mcp251x_write_reg(spi, CANCTRL, CANCTRL_REQOP_LOOPBACK); } else if (priv->can.ctrlmode & CAN_CTRLMODE_LISTENONLY) { /* Put device into listen-only mode */ mcp251x_write_reg(spi, CANCTRL, CANCTRL_REQOP_LISTEN_ONLY); } else { /* Put device into normal mode */ mcp251x_write_reg(spi, CANCTRL, CANCTRL_REQOP_NORMAL); /* Wait for the device to enter normal mode */ ret = mcp251x_read_stat_poll_timeout(spi, value, value == 0, MCP251X_OST_DELAY_MS * 1000, USEC_PER_SEC); if (ret) { dev_err(&spi->dev, "MCP251x didn't enter in normal mode\n"); return ret; } } priv->can.state = CAN_STATE_ERROR_ACTIVE; return 0; } static int mcp251x_do_set_bittiming(struct net_device *net) { struct mcp251x_priv *priv = netdev_priv(net); struct can_bittiming *bt = &priv->can.bittiming; struct spi_device *spi = priv->spi; mcp251x_write_reg(spi, CNF1, ((bt->sjw - 1) << CNF1_SJW_SHIFT) | (bt->brp - 1)); mcp251x_write_reg(spi, CNF2, CNF2_BTLMODE | (priv->can.ctrlmode & CAN_CTRLMODE_3_SAMPLES ? CNF2_SAM : 0) | ((bt->phase_seg1 - 1) << CNF2_PS1_SHIFT) | (bt->prop_seg - 1)); mcp251x_write_bits(spi, CNF3, CNF3_PHSEG2_MASK, (bt->phase_seg2 - 1)); dev_dbg(&spi->dev, "CNF: 0x%02x 0x%02x 0x%02x\n", mcp251x_read_reg(spi, CNF1), mcp251x_read_reg(spi, CNF2), mcp251x_read_reg(spi, CNF3)); return 0; } static int mcp251x_setup(struct net_device *net, struct spi_device *spi) { mcp251x_do_set_bittiming(net); mcp251x_write_reg(spi, RXBCTRL(0), RXBCTRL_BUKT | RXBCTRL_RXM0 | RXBCTRL_RXM1); mcp251x_write_reg(spi, RXBCTRL(1), RXBCTRL_RXM0 | RXBCTRL_RXM1); return 0; } static int mcp251x_hw_reset(struct spi_device *spi) { struct mcp251x_priv *priv = spi_get_drvdata(spi); u8 value; int ret; /* Wait for oscillator startup timer after power up */ mdelay(MCP251X_OST_DELAY_MS); priv->spi_tx_buf[0] = INSTRUCTION_RESET; ret = mcp251x_spi_write(spi, 1); if (ret) return ret; /* Wait for oscillator startup timer after reset */ mdelay(MCP251X_OST_DELAY_MS); /* Wait for reset to finish */ ret = mcp251x_read_stat_poll_timeout(spi, value, value == CANCTRL_REQOP_CONF, MCP251X_OST_DELAY_MS * 1000, USEC_PER_SEC); if (ret) dev_err(&spi->dev, "MCP251x didn't enter in conf mode after reset\n"); return ret; } static int mcp251x_hw_probe(struct spi_device *spi) { u8 ctrl; int ret; ret = mcp251x_hw_reset(spi); if (ret) return ret; ctrl = mcp251x_read_reg(spi, CANCTRL); dev_dbg(&spi->dev, "CANCTRL 0x%02x\n", ctrl); /* Check for power up default value */ if ((ctrl & 0x17) != 0x07) return -ENODEV; return 0; } static int mcp251x_power_enable(struct regulator *reg, int enable) { if (IS_ERR_OR_NULL(reg)) return 0; if (enable) return regulator_enable(reg); else return regulator_disable(reg); } static int mcp251x_stop(struct net_device *net) { struct mcp251x_priv *priv = netdev_priv(net); struct spi_device *spi = priv->spi; close_candev(net); priv->force_quit = 1; free_irq(spi->irq, priv); mutex_lock(&priv->mcp_lock); /* Disable and clear pending interrupts */ mcp251x_write_2regs(spi, CANINTE, 0x00, 0x00); mcp251x_write_reg(spi, TXBCTRL(0), 0); mcp251x_clean(net); mcp251x_hw_sleep(spi); mcp251x_power_enable(priv->transceiver, 0); priv->can.state = CAN_STATE_STOPPED; mutex_unlock(&priv->mcp_lock); return 0; } static void mcp251x_error_skb(struct net_device *net, int can_id, int data1) { struct sk_buff *skb; struct can_frame *frame; skb = alloc_can_err_skb(net, &frame); if (skb) { frame->can_id |= can_id; frame->data[1] = data1; netif_rx(skb); } else { netdev_err(net, "cannot allocate error skb\n"); } } static void mcp251x_tx_work_handler(struct work_struct *ws) { struct mcp251x_priv *priv = container_of(ws, struct mcp251x_priv, tx_work); struct spi_device *spi = priv->spi; struct net_device *net = priv->net; struct can_frame *frame; mutex_lock(&priv->mcp_lock); if (priv->tx_skb) { if (priv->can.state == CAN_STATE_BUS_OFF) { mcp251x_clean(net); } else { frame = (struct can_frame *)priv->tx_skb->data; if (frame->len > CAN_FRAME_MAX_DATA_LEN) frame->len = CAN_FRAME_MAX_DATA_LEN; mcp251x_hw_tx(spi, frame, 0); priv->tx_busy = true; can_put_echo_skb(priv->tx_skb, net, 0, 0); priv->tx_skb = NULL; } } mutex_unlock(&priv->mcp_lock); } static void mcp251x_restart_work_handler(struct work_struct *ws) { struct mcp251x_priv *priv = container_of(ws, struct mcp251x_priv, restart_work); struct spi_device *spi = priv->spi; struct net_device *net = priv->net; mutex_lock(&priv->mcp_lock); if (priv->after_suspend) { if (priv->after_suspend & AFTER_SUSPEND_POWER) { mcp251x_hw_reset(spi); mcp251x_setup(net, spi); mcp251x_gpio_restore(spi); } else { mcp251x_hw_wake(spi); } priv->force_quit = 0; if (priv->after_suspend & AFTER_SUSPEND_RESTART) { mcp251x_set_normal_mode(spi); } else if (priv->after_suspend & AFTER_SUSPEND_UP) { netif_device_attach(net); mcp251x_clean(net); mcp251x_set_normal_mode(spi); netif_wake_queue(net); } else { mcp251x_hw_sleep(spi); } priv->after_suspend = 0; } if (priv->restart_tx) { priv->restart_tx = 0; mcp251x_write_reg(spi, TXBCTRL(0), 0); mcp251x_clean(net); netif_wake_queue(net); mcp251x_error_skb(net, CAN_ERR_RESTARTED, 0); } mutex_unlock(&priv->mcp_lock); } static irqreturn_t mcp251x_can_ist(int irq, void *dev_id) { struct mcp251x_priv *priv = dev_id; struct spi_device *spi = priv->spi; struct net_device *net = priv->net; mutex_lock(&priv->mcp_lock); while (!priv->force_quit) { enum can_state new_state; u8 intf, eflag; u8 clear_intf = 0; int can_id = 0, data1 = 0; mcp251x_read_2regs(spi, CANINTF, &intf, &eflag); /* receive buffer 0 */ if (intf & CANINTF_RX0IF) { mcp251x_hw_rx(spi, 0); /* Free one buffer ASAP * (The MCP2515/25625 does this automatically.) */ if (mcp251x_is_2510(spi)) mcp251x_write_bits(spi, CANINTF, CANINTF_RX0IF, 0x00); /* check if buffer 1 is already known to be full, no need to re-read */ if (!(intf & CANINTF_RX1IF)) { u8 intf1, eflag1; /* intf needs to be read again to avoid a race condition */ mcp251x_read_2regs(spi, CANINTF, &intf1, &eflag1); /* combine flags from both operations for error handling */ intf |= intf1; eflag |= eflag1; } } /* receive buffer 1 */ if (intf & CANINTF_RX1IF) { mcp251x_hw_rx(spi, 1); /* The MCP2515/25625 does this automatically. */ if (mcp251x_is_2510(spi)) clear_intf |= CANINTF_RX1IF; } /* mask out flags we don't care about */ intf &= CANINTF_RX | CANINTF_TX | CANINTF_ERR; /* any error or tx interrupt we need to clear? */ if (intf & (CANINTF_ERR | CANINTF_TX)) clear_intf |= intf & (CANINTF_ERR | CANINTF_TX); if (clear_intf) mcp251x_write_bits(spi, CANINTF, clear_intf, 0x00); if (eflag & (EFLG_RX0OVR | EFLG_RX1OVR)) mcp251x_write_bits(spi, EFLG, eflag, 0x00); /* Update can state */ if (eflag & EFLG_TXBO) { new_state = CAN_STATE_BUS_OFF; can_id |= CAN_ERR_BUSOFF; } else if (eflag & EFLG_TXEP) { new_state = CAN_STATE_ERROR_PASSIVE; can_id |= CAN_ERR_CRTL; data1 |= CAN_ERR_CRTL_TX_PASSIVE; } else if (eflag & EFLG_RXEP) { new_state = CAN_STATE_ERROR_PASSIVE; can_id |= CAN_ERR_CRTL; data1 |= CAN_ERR_CRTL_RX_PASSIVE; } else if (eflag & EFLG_TXWAR) { new_state = CAN_STATE_ERROR_WARNING; can_id |= CAN_ERR_CRTL; data1 |= CAN_ERR_CRTL_TX_WARNING; } else if (eflag & EFLG_RXWAR) { new_state = CAN_STATE_ERROR_WARNING; can_id |= CAN_ERR_CRTL; data1 |= CAN_ERR_CRTL_RX_WARNING; } else { new_state = CAN_STATE_ERROR_ACTIVE; } /* Update can state statistics */ switch (priv->can.state) { case CAN_STATE_ERROR_ACTIVE: if (new_state >= CAN_STATE_ERROR_WARNING && new_state <= CAN_STATE_BUS_OFF) priv->can.can_stats.error_warning++; fallthrough; case CAN_STATE_ERROR_WARNING: if (new_state >= CAN_STATE_ERROR_PASSIVE && new_state <= CAN_STATE_BUS_OFF) priv->can.can_stats.error_passive++; break; default: break; } priv->can.state = new_state; if (intf & CANINTF_ERRIF) { /* Handle overflow counters */ if (eflag & (EFLG_RX0OVR | EFLG_RX1OVR)) { if (eflag & EFLG_RX0OVR) { net->stats.rx_over_errors++; net->stats.rx_errors++; } if (eflag & EFLG_RX1OVR) { net->stats.rx_over_errors++; net->stats.rx_errors++; } can_id |= CAN_ERR_CRTL; data1 |= CAN_ERR_CRTL_RX_OVERFLOW; } mcp251x_error_skb(net, can_id, data1); } if (priv->can.state == CAN_STATE_BUS_OFF) { if (priv->can.restart_ms == 0) { priv->force_quit = 1; priv->can.can_stats.bus_off++; can_bus_off(net); mcp251x_hw_sleep(spi); break; } } if (intf == 0) break; if (intf & CANINTF_TX) { if (priv->tx_busy) { net->stats.tx_packets++; net->stats.tx_bytes += can_get_echo_skb(net, 0, NULL); priv->tx_busy = false; } netif_wake_queue(net); } } mutex_unlock(&priv->mcp_lock); return IRQ_HANDLED; } static int mcp251x_open(struct net_device *net) { struct mcp251x_priv *priv = netdev_priv(net); struct spi_device *spi = priv->spi; unsigned long flags = 0; int ret; ret = open_candev(net); if (ret) { dev_err(&spi->dev, "unable to set initial baudrate!\n"); return ret; } mutex_lock(&priv->mcp_lock); mcp251x_power_enable(priv->transceiver, 1); priv->force_quit = 0; priv->tx_skb = NULL; priv->tx_busy = false; if (!dev_fwnode(&spi->dev)) flags = IRQF_TRIGGER_FALLING; ret = request_threaded_irq(spi->irq, NULL, mcp251x_can_ist, flags | IRQF_ONESHOT, dev_name(&spi->dev), priv); if (ret) { dev_err(&spi->dev, "failed to acquire irq %d\n", spi->irq); goto out_close; } ret = mcp251x_hw_wake(spi); if (ret) goto out_free_irq; ret = mcp251x_setup(net, spi); if (ret) goto out_free_irq; ret = mcp251x_set_normal_mode(spi); if (ret) goto out_free_irq; netif_wake_queue(net); mutex_unlock(&priv->mcp_lock); return 0; out_free_irq: free_irq(spi->irq, priv); mcp251x_hw_sleep(spi); out_close: mcp251x_power_enable(priv->transceiver, 0); close_candev(net); mutex_unlock(&priv->mcp_lock); return ret; } static const struct net_device_ops mcp251x_netdev_ops = { .ndo_open = mcp251x_open, .ndo_stop = mcp251x_stop, .ndo_start_xmit = mcp251x_hard_start_xmit, .ndo_change_mtu = can_change_mtu, }; static const struct of_device_id mcp251x_of_match[] = { { .compatible = "microchip,mcp2510", .data = (void *)CAN_MCP251X_MCP2510, }, { .compatible = "microchip,mcp2515", .data = (void *)CAN_MCP251X_MCP2515, }, { .compatible = "microchip,mcp25625", .data = (void *)CAN_MCP251X_MCP25625, }, { } }; MODULE_DEVICE_TABLE(of, mcp251x_of_match); static const struct spi_device_id mcp251x_id_table[] = { { .name = "mcp2510", .driver_data = (kernel_ulong_t)CAN_MCP251X_MCP2510, }, { .name = "mcp2515", .driver_data = (kernel_ulong_t)CAN_MCP251X_MCP2515, }, { .name = "mcp25625", .driver_data = (kernel_ulong_t)CAN_MCP251X_MCP25625, }, { } }; MODULE_DEVICE_TABLE(spi, mcp251x_id_table); static int mcp251x_can_probe(struct spi_device *spi) { const void *match = device_get_match_data(&spi->dev); struct net_device *net; struct mcp251x_priv *priv; struct clk *clk; u32 freq; int ret; clk = devm_clk_get_optional(&spi->dev, NULL); if (IS_ERR(clk)) return PTR_ERR(clk); freq = clk_get_rate(clk); if (freq == 0) device_property_read_u32(&spi->dev, "clock-frequency", &freq); /* Sanity check */ if (freq < 1000000 || freq > 25000000) return -ERANGE; /* Allocate can/net device */ net = alloc_candev(sizeof(struct mcp251x_priv), TX_ECHO_SKB_MAX); if (!net) return -ENOMEM; ret = clk_prepare_enable(clk); if (ret) goto out_free; net->netdev_ops = &mcp251x_netdev_ops; net->flags |= IFF_ECHO; priv = netdev_priv(net); priv->can.bittiming_const = &mcp251x_bittiming_const; priv->can.do_set_mode = mcp251x_do_set_mode; priv->can.clock.freq = freq / 2; priv->can.ctrlmode_supported = CAN_CTRLMODE_3_SAMPLES | CAN_CTRLMODE_LOOPBACK | CAN_CTRLMODE_LISTENONLY; if (match) priv->model = (enum mcp251x_model)(uintptr_t)match; else priv->model = spi_get_device_id(spi)->driver_data; priv->net = net; priv->clk = clk; spi_set_drvdata(spi, priv); /* Configure the SPI bus */ spi->bits_per_word = 8; if (mcp251x_is_2510(spi)) spi->max_speed_hz = spi->max_speed_hz ? : 5 * 1000 * 1000; else spi->max_speed_hz = spi->max_speed_hz ? : 10 * 1000 * 1000; ret = spi_setup(spi); if (ret) goto out_clk; priv->power = devm_regulator_get_optional(&spi->dev, "vdd"); priv->transceiver = devm_regulator_get_optional(&spi->dev, "xceiver"); if ((PTR_ERR(priv->power) == -EPROBE_DEFER) || (PTR_ERR(priv->transceiver) == -EPROBE_DEFER)) { ret = -EPROBE_DEFER; goto out_clk; } ret = mcp251x_power_enable(priv->power, 1); if (ret) goto out_clk; priv->wq = alloc_workqueue("mcp251x_wq", WQ_FREEZABLE | WQ_MEM_RECLAIM, 0); if (!priv->wq) { ret = -ENOMEM; goto out_clk; } INIT_WORK(&priv->tx_work, mcp251x_tx_work_handler); INIT_WORK(&priv->restart_work, mcp251x_restart_work_handler); priv->spi = spi; mutex_init(&priv->mcp_lock); priv->spi_tx_buf = devm_kzalloc(&spi->dev, SPI_TRANSFER_BUF_LEN, GFP_KERNEL); if (!priv->spi_tx_buf) { ret = -ENOMEM; goto error_probe; } priv->spi_rx_buf = devm_kzalloc(&spi->dev, SPI_TRANSFER_BUF_LEN, GFP_KERNEL); if (!priv->spi_rx_buf) { ret = -ENOMEM; goto error_probe; } SET_NETDEV_DEV(net, &spi->dev); /* Here is OK to not lock the MCP, no one knows about it yet */ ret = mcp251x_hw_probe(spi); if (ret) { if (ret == -ENODEV) dev_err(&spi->dev, "Cannot initialize MCP%x. Wrong wiring?\n", priv->model); goto error_probe; } mcp251x_hw_sleep(spi); ret = register_candev(net); if (ret) goto error_probe; ret = mcp251x_gpio_setup(priv); if (ret) goto error_probe; netdev_info(net, "MCP%x successfully initialized.\n", priv->model); return 0; error_probe: destroy_workqueue(priv->wq); priv->wq = NULL; mcp251x_power_enable(priv->power, 0); out_clk: clk_disable_unprepare(clk); out_free: free_candev(net); dev_err(&spi->dev, "Probe failed, err=%d\n", -ret); return ret; } static void mcp251x_can_remove(struct spi_device *spi) { struct mcp251x_priv *priv = spi_get_drvdata(spi); struct net_device *net = priv->net; unregister_candev(net); mcp251x_power_enable(priv->power, 0); destroy_workqueue(priv->wq); priv->wq = NULL; clk_disable_unprepare(priv->clk); free_candev(net); } static int __maybe_unused mcp251x_can_suspend(struct device *dev) { struct spi_device *spi = to_spi_device(dev); struct mcp251x_priv *priv = spi_get_drvdata(spi); struct net_device *net = priv->net; priv->force_quit = 1; disable_irq(spi->irq); /* Note: at this point neither IST nor workqueues are running. * open/stop cannot be called anyway so locking is not needed */ if (netif_running(net)) { netif_device_detach(net); mcp251x_hw_sleep(spi); mcp251x_power_enable(priv->transceiver, 0); priv->after_suspend = AFTER_SUSPEND_UP; } else { priv->after_suspend = AFTER_SUSPEND_DOWN; } mcp251x_power_enable(priv->power, 0); priv->after_suspend |= AFTER_SUSPEND_POWER; return 0; } static int __maybe_unused mcp251x_can_resume(struct device *dev) { struct spi_device *spi = to_spi_device(dev); struct mcp251x_priv *priv = spi_get_drvdata(spi); if (priv->after_suspend & AFTER_SUSPEND_POWER) mcp251x_power_enable(priv->power, 1); if (priv->after_suspend & AFTER_SUSPEND_UP) mcp251x_power_enable(priv->transceiver, 1); if (priv->after_suspend & (AFTER_SUSPEND_POWER | AFTER_SUSPEND_UP)) queue_work(priv->wq, &priv->restart_work); else priv->after_suspend = 0; priv->force_quit = 0; enable_irq(spi->irq); return 0; } static SIMPLE_DEV_PM_OPS(mcp251x_can_pm_ops, mcp251x_can_suspend, mcp251x_can_resume); static struct spi_driver mcp251x_can_driver = { .driver = { .name = DEVICE_NAME, .of_match_table = mcp251x_of_match, .pm = &mcp251x_can_pm_ops, }, .id_table = mcp251x_id_table, .probe = mcp251x_can_probe, .remove = mcp251x_can_remove, }; module_spi_driver(mcp251x_can_driver); MODULE_AUTHOR("Chris Elston , " "Christian Pellegrin "); MODULE_DESCRIPTION("Microchip 251x/25625 CAN driver"); MODULE_LICENSE("GPL v2");