/* * Copyright (c) 2018 Karsten Koenig * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT microchip_mcp2515 #include #include #include #include #define LOG_LEVEL CONFIG_CAN_LOG_LEVEL #include LOG_MODULE_REGISTER(mcp2515_can); #include "can_mcp2515.h" static int mcp2515_cmd_soft_reset(struct device *dev) { uint8_t cmd_buf[] = { MCP2515_OPCODE_RESET }; const struct spi_buf tx_buf = { .buf = cmd_buf, .len = sizeof(cmd_buf), }; const struct spi_buf_set tx = { .buffers = &tx_buf, .count = 1U }; return spi_write(DEV_DATA(dev)->spi, &DEV_DATA(dev)->spi_cfg, &tx); } static int mcp2515_cmd_bit_modify(struct device *dev, uint8_t reg_addr, uint8_t mask, uint8_t data) { uint8_t cmd_buf[] = { MCP2515_OPCODE_BIT_MODIFY, reg_addr, mask, data }; const struct spi_buf tx_buf = { .buf = cmd_buf, .len = sizeof(cmd_buf), }; const struct spi_buf_set tx = { .buffers = &tx_buf, .count = 1U }; return spi_write(DEV_DATA(dev)->spi, &DEV_DATA(dev)->spi_cfg, &tx); } static int mcp2515_cmd_write_reg(struct device *dev, uint8_t reg_addr, uint8_t *buf_data, uint8_t buf_len) { uint8_t cmd_buf[] = { MCP2515_OPCODE_WRITE, reg_addr }; struct spi_buf tx_buf[] = { { .buf = cmd_buf, .len = sizeof(cmd_buf) }, { .buf = buf_data, .len = buf_len } }; const struct spi_buf_set tx = { .buffers = tx_buf, .count = ARRAY_SIZE(tx_buf) }; return spi_write(DEV_DATA(dev)->spi, &DEV_DATA(dev)->spi_cfg, &tx); } /* * Load TX buffer instruction * * When loading a transmit buffer, reduces the overhead of a normal WRITE * command by placing the Address Pointer at one of six locations, as * selected by parameter abc. * * 0: TX Buffer 0, Start at TXB0SIDH (0x31) * 1: TX Buffer 0, Start at TXB0D0 (0x36) * 2: TX Buffer 1, Start at TXB1SIDH (0x41) * 3: TX Buffer 1, Start at TXB1D0 (0x46) * 4: TX Buffer 2, Start at TXB2SIDH (0x51) * 5: TX Buffer 2, Start at TXB2D0 (0x56) */ static int mcp2515_cmd_load_tx_buffer(struct device *dev, uint8_t abc, uint8_t *buf_data, uint8_t buf_len) { __ASSERT(abc <= 5, "abc <= 5"); uint8_t cmd_buf[] = { MCP2515_OPCODE_LOAD_TX_BUFFER | abc }; struct spi_buf tx_buf[] = { { .buf = cmd_buf, .len = sizeof(cmd_buf) }, { .buf = buf_data, .len = buf_len } }; const struct spi_buf_set tx = { .buffers = tx_buf, .count = ARRAY_SIZE(tx_buf) }; return spi_write(DEV_DATA(dev)->spi, &DEV_DATA(dev)->spi_cfg, &tx); } /* * Request-to-Send Instruction * * Parameter nnn is the combination of bits at positions 0, 1 and 2 in the RTS * opcode that respectively initiate transmission for buffers TXB0, TXB1 and * TXB2. */ static int mcp2515_cmd_rts(struct device *dev, uint8_t nnn) { __ASSERT(nnn < BIT(MCP2515_TX_CNT), "nnn < BIT(MCP2515_TX_CNT)"); uint8_t cmd_buf[] = { MCP2515_OPCODE_RTS | nnn }; struct spi_buf tx_buf[] = { { .buf = cmd_buf, .len = sizeof(cmd_buf) } }; const struct spi_buf_set tx = { .buffers = tx_buf, .count = ARRAY_SIZE(tx_buf) }; return spi_write(DEV_DATA(dev)->spi, &DEV_DATA(dev)->spi_cfg, &tx); } static int mcp2515_cmd_read_reg(struct device *dev, uint8_t reg_addr, uint8_t *buf_data, uint8_t buf_len) { uint8_t cmd_buf[] = { MCP2515_OPCODE_READ, reg_addr }; struct spi_buf tx_buf[] = { { .buf = cmd_buf, .len = sizeof(cmd_buf) }, { .buf = NULL, .len = buf_len } }; const struct spi_buf_set tx = { .buffers = tx_buf, .count = ARRAY_SIZE(tx_buf) }; struct spi_buf rx_buf[] = { { .buf = NULL, .len = sizeof(cmd_buf) }, { .buf = buf_data, .len = buf_len } }; const struct spi_buf_set rx = { .buffers = rx_buf, .count = ARRAY_SIZE(rx_buf) }; return spi_transceive(DEV_DATA(dev)->spi, &DEV_DATA(dev)->spi_cfg, &tx, &rx); } /* * Read RX Buffer instruction * * When reading a receive buffer, reduces the overhead of a normal READ * command by placing the Address Pointer at one of four locations selected by * parameter nm: * 0: Receive Buffer 0, Start at RXB0SIDH (0x61) * 1: Receive Buffer 0, Start at RXB0D0 (0x66) * 2: Receive Buffer 1, Start at RXB1SIDH (0x71) * 3: Receive Buffer 1, Start at RXB1D0 (0x76) */ static int mcp2515_cmd_read_rx_buffer(struct device *dev, uint8_t nm, uint8_t *buf_data, uint8_t buf_len) { __ASSERT(nm <= 0x03, "nm <= 0x03"); uint8_t cmd_buf[] = { MCP2515_OPCODE_READ_RX_BUFFER | (nm << 1) }; struct spi_buf tx_buf[] = { { .buf = cmd_buf, .len = sizeof(cmd_buf) }, { .buf = NULL, .len = buf_len } }; const struct spi_buf_set tx = { .buffers = tx_buf, .count = ARRAY_SIZE(tx_buf) }; struct spi_buf rx_buf[] = { { .buf = NULL, .len = sizeof(cmd_buf) }, { .buf = buf_data, .len = buf_len } }; const struct spi_buf_set rx = { .buffers = rx_buf, .count = ARRAY_SIZE(rx_buf) }; return spi_transceive(DEV_DATA(dev)->spi, &DEV_DATA(dev)->spi_cfg, &tx, &rx); } static uint8_t mcp2515_convert_canmode_to_mcp2515mode(enum can_mode mode) { switch (mode) { case CAN_NORMAL_MODE: return MCP2515_MODE_NORMAL; case CAN_SILENT_MODE: return MCP2515_MODE_SILENT; case CAN_LOOPBACK_MODE: return MCP2515_MODE_LOOPBACK; default: LOG_ERR("Unsupported CAN Mode %u", mode); return MCP2515_MODE_SILENT; } } static void mcp2515_convert_zcanframe_to_mcp2515frame(const struct zcan_frame *source, uint8_t *target) { uint8_t rtr; uint8_t dlc; uint8_t data_idx = 0U; if (source->id_type == CAN_STANDARD_IDENTIFIER) { target[MCP2515_FRAME_OFFSET_SIDH] = source->std_id >> 3; target[MCP2515_FRAME_OFFSET_SIDL] = (source->std_id & 0x07) << 5; } else { target[MCP2515_FRAME_OFFSET_SIDH] = source->ext_id >> 21; target[MCP2515_FRAME_OFFSET_SIDL] = (((source->ext_id >> 18) & 0x07) << 5) | (BIT(3)) | ((source->ext_id >> 16) & 0x03); target[MCP2515_FRAME_OFFSET_EID8] = source->ext_id >> 8; target[MCP2515_FRAME_OFFSET_EID0] = source->ext_id; } rtr = (source->rtr == CAN_REMOTEREQUEST) ? BIT(6) : 0; dlc = (source->dlc) & 0x0F; target[MCP2515_FRAME_OFFSET_DLC] = rtr | dlc; for (; data_idx < CAN_MAX_DLC; data_idx++) { target[MCP2515_FRAME_OFFSET_D0 + data_idx] = source->data[data_idx]; } } static void mcp2515_convert_mcp2515frame_to_zcanframe(const uint8_t *source, struct zcan_frame *target) { uint8_t data_idx = 0U; if (source[MCP2515_FRAME_OFFSET_SIDL] & BIT(3)) { target->id_type = CAN_EXTENDED_IDENTIFIER; target->ext_id = (source[MCP2515_FRAME_OFFSET_SIDH] << 21) | ((source[MCP2515_FRAME_OFFSET_SIDL] >> 5) << 18) | ((source[MCP2515_FRAME_OFFSET_SIDL] & 0x03) << 16) | (source[MCP2515_FRAME_OFFSET_EID8] << 8) | source[MCP2515_FRAME_OFFSET_EID0]; } else { target->id_type = CAN_STANDARD_IDENTIFIER; target->std_id = (source[MCP2515_FRAME_OFFSET_SIDH] << 3) | (source[MCP2515_FRAME_OFFSET_SIDL] >> 5); } target->dlc = source[MCP2515_FRAME_OFFSET_DLC] & 0x0F; target->rtr = source[MCP2515_FRAME_OFFSET_DLC] & BIT(6) ? CAN_REMOTEREQUEST : CAN_DATAFRAME; for (; data_idx < CAN_MAX_DLC; data_idx++) { target->data[data_idx] = source[MCP2515_FRAME_OFFSET_D0 + data_idx]; } } const int mcp2515_set_mode(struct device *dev, uint8_t mcp2515_mode) { uint8_t canstat; mcp2515_cmd_bit_modify(dev, MCP2515_ADDR_CANCTRL, MCP2515_CANCTRL_MODE_MASK, mcp2515_mode << MCP2515_CANCTRL_MODE_POS); mcp2515_cmd_read_reg(dev, MCP2515_ADDR_CANSTAT, &canstat, 1); if (((canstat & MCP2515_CANSTAT_MODE_MASK) >> MCP2515_CANSTAT_MODE_POS) != mcp2515_mode) { LOG_ERR("Failed to set MCP2515 operation mode"); return -EIO; } return 0; } static int mcp2515_configure(struct device *dev, enum can_mode mode, uint32_t bitrate) { const struct mcp2515_config *dev_cfg = DEV_CFG(dev); struct mcp2515_data *dev_data = DEV_DATA(dev); int ret; /* CNF3, CNF2, CNF1, CANINTE */ uint8_t config_buf[4]; if (bitrate == 0) { bitrate = dev_cfg->bus_speed; } const uint8_t bit_length = 1 + dev_cfg->tq_prop + dev_cfg->tq_bs1 + dev_cfg->tq_bs2; /* CNF1; SJW<7:6> | BRP<5:0> */ uint8_t brp = (dev_cfg->osc_freq / (bit_length * bitrate * 2)) - 1; const uint8_t sjw = (dev_cfg->tq_sjw - 1) << 6; uint8_t cnf1 = sjw | brp; /* CNF2; BTLMODE<7>|SAM<6>|PHSEG1<5:3>|PRSEG<2:0> */ const uint8_t btlmode = 1 << 7; const uint8_t sam = 0 << 6; const uint8_t phseg1 = (dev_cfg->tq_bs1 - 1) << 3; const uint8_t prseg = (dev_cfg->tq_prop - 1); const uint8_t cnf2 = btlmode | sam | phseg1 | prseg; /* CNF3; SOF<7>|WAKFIL<6>|UND<5:3>|PHSEG2<2:0> */ const uint8_t sof = 0 << 7; const uint8_t wakfil = 0 << 6; const uint8_t und = 0 << 3; const uint8_t phseg2 = (dev_cfg->tq_bs2 - 1); const uint8_t cnf3 = sof | wakfil | und | phseg2; const uint8_t caninte = MCP2515_INTE_RX0IE | MCP2515_INTE_RX1IE | MCP2515_INTE_TX0IE | MCP2515_INTE_TX1IE | MCP2515_INTE_TX2IE | MCP2515_INTE_ERRIE; /* Receive everything, filtering done in driver, RXB0 roll over into * RXB1 */ const uint8_t rx0_ctrl = BIT(6) | BIT(5) | BIT(2); const uint8_t rx1_ctrl = BIT(6) | BIT(5); __ASSERT((dev_cfg->tq_sjw >= 1) && (dev_cfg->tq_sjw <= 4), "1 <= SJW <= 4"); __ASSERT((dev_cfg->tq_prop >= 1) && (dev_cfg->tq_prop <= 8), "1 <= PROP <= 8"); __ASSERT((dev_cfg->tq_bs1 >= 1) && (dev_cfg->tq_bs1 <= 8), "1 <= BS1 <= 8"); __ASSERT((dev_cfg->tq_bs2 >= 2) && (dev_cfg->tq_bs2 <= 8), "2 <= BS2 <= 8"); __ASSERT(dev_cfg->tq_prop + dev_cfg->tq_bs1 >= dev_cfg->tq_bs2, "PROP + BS1 >= BS2"); __ASSERT(dev_cfg->tq_bs2 > dev_cfg->tq_sjw, "BS2 > SJW"); if (dev_cfg->osc_freq % (bit_length * bitrate * 2)) { LOG_ERR("Prescaler is not a natural number! " "prescaler = osc_rate / ((PROP + SEG1 + SEG2 + 1) " "* bitrate * 2)\n" "prescaler = %d / ((%d + %d + %d + 1) * %d * 2)", dev_cfg->osc_freq, dev_cfg->tq_prop, dev_cfg->tq_bs1, dev_cfg->tq_bs2, bitrate); } config_buf[0] = cnf3; config_buf[1] = cnf2; config_buf[2] = cnf1; config_buf[3] = caninte; k_mutex_lock(&dev_data->mutex, K_FOREVER); /* will enter configuration mode automatically */ ret = mcp2515_cmd_soft_reset(dev); if (ret < 0) { LOG_ERR("Failed to reset the device [%d]", ret); goto done; } ret = mcp2515_cmd_write_reg(dev, MCP2515_ADDR_CNF3, config_buf, sizeof(config_buf)); if (ret < 0) { LOG_ERR("Failed to write the configuration [%d]", ret); } ret = mcp2515_cmd_bit_modify(dev, MCP2515_ADDR_RXB0CTRL, rx0_ctrl, rx0_ctrl); if (ret < 0) { LOG_ERR("Failed to write RXB0CTRL [%d]", ret); } ret = mcp2515_cmd_bit_modify(dev, MCP2515_ADDR_RXB1CTRL, rx1_ctrl, rx1_ctrl); if (ret < 0) { LOG_ERR("Failed to write RXB1CTRL [%d]", ret); } done: ret = mcp2515_set_mode(dev, mcp2515_convert_canmode_to_mcp2515mode(mode)); if (ret < 0) { LOG_ERR("Failed to set the mode [%d]", ret); } k_mutex_unlock(&dev_data->mutex); return ret; } static int mcp2515_send(struct device *dev, const struct zcan_frame *msg, k_timeout_t timeout, can_tx_callback_t callback, void *callback_arg) { struct mcp2515_data *dev_data = DEV_DATA(dev); uint8_t tx_idx = 0U; uint8_t abc; uint8_t nnn; uint8_t len; uint8_t tx_frame[MCP2515_FRAME_LEN]; if (msg->dlc > CAN_MAX_DLC) { LOG_ERR("DLC of %d exceeds maximum (%d)", msg->dlc, CAN_MAX_DLC); return CAN_TX_EINVAL; } if (k_sem_take(&dev_data->tx_sem, timeout) != 0) { return CAN_TIMEOUT; } k_mutex_lock(&dev_data->mutex, K_FOREVER); /* find a free tx slot */ for (; tx_idx < MCP2515_TX_CNT; tx_idx++) { if ((BIT(tx_idx) & dev_data->tx_busy_map) == 0) { dev_data->tx_busy_map |= BIT(tx_idx); break; } } k_mutex_unlock(&dev_data->mutex); if (tx_idx == MCP2515_TX_CNT) { LOG_WRN("no free tx slot available"); return CAN_TX_ERR; } dev_data->tx_cb[tx_idx].cb = callback; dev_data->tx_cb[tx_idx].cb_arg = callback_arg; mcp2515_convert_zcanframe_to_mcp2515frame(msg, tx_frame); /* Address Pointer selection */ abc = 2 * tx_idx; /* Calculate minimum length to transfer */ len = sizeof(tx_frame) - CAN_MAX_DLC + msg->dlc; mcp2515_cmd_load_tx_buffer(dev, abc, tx_frame, len); /* request tx slot transmission */ nnn = BIT(tx_idx); mcp2515_cmd_rts(dev, nnn); if (callback == NULL) { k_sem_take(&dev_data->tx_cb[tx_idx].sem, K_FOREVER); } return 0; } static int mcp2515_attach_isr(struct device *dev, can_rx_callback_t rx_cb, void *cb_arg, const struct zcan_filter *filter) { struct mcp2515_data *dev_data = DEV_DATA(dev); int filter_idx = 0; __ASSERT(rx_cb != NULL, "response_ptr can not be null"); k_mutex_lock(&dev_data->mutex, K_FOREVER); /* find free filter */ while ((BIT(filter_idx) & dev_data->filter_usage) && (filter_idx < CONFIG_CAN_MCP2515_MAX_FILTER)) { filter_idx++; } /* setup filter */ if (filter_idx < CONFIG_CAN_MCP2515_MAX_FILTER) { dev_data->filter_usage |= BIT(filter_idx); dev_data->filter[filter_idx] = *filter; dev_data->rx_cb[filter_idx] = rx_cb; dev_data->cb_arg[filter_idx] = cb_arg; } else { filter_idx = CAN_NO_FREE_FILTER; } k_mutex_unlock(&dev_data->mutex); return filter_idx; } static void mcp2515_detach(struct device *dev, int filter_nr) { struct mcp2515_data *dev_data = DEV_DATA(dev); k_mutex_lock(&dev_data->mutex, K_FOREVER); dev_data->filter_usage &= ~BIT(filter_nr); k_mutex_unlock(&dev_data->mutex); } static void mcp2515_register_state_change_isr(struct device *dev, can_state_change_isr_t isr) { struct mcp2515_data *dev_data = DEV_DATA(dev); dev_data->state_change_isr = isr; } static uint8_t mcp2515_filter_match(struct zcan_frame *msg, struct zcan_filter *filter) { if (msg->id_type != filter->id_type) { return 0; } if ((msg->rtr ^ filter->rtr) & filter->rtr_mask) { return 0; } if (msg->id_type == CAN_STANDARD_IDENTIFIER) { if ((msg->std_id ^ filter->std_id) & filter->std_id_mask) { return 0; } } else { if ((msg->ext_id ^ filter->ext_id) & filter->ext_id_mask) { return 0; } } return 1; } static void mcp2515_rx_filter(struct device *dev, struct zcan_frame *msg) { struct mcp2515_data *dev_data = DEV_DATA(dev); uint8_t filter_idx = 0U; can_rx_callback_t callback; struct zcan_frame tmp_msg; k_mutex_lock(&dev_data->mutex, K_FOREVER); for (; filter_idx < CONFIG_CAN_MCP2515_MAX_FILTER; filter_idx++) { if (!(BIT(filter_idx) & dev_data->filter_usage)) { continue; /* filter slot empty */ } if (!mcp2515_filter_match(msg, &dev_data->filter[filter_idx])) { continue; /* filter did not match */ } callback = dev_data->rx_cb[filter_idx]; /*Make a temporary copy in case the user modifies the message*/ tmp_msg = *msg; callback(&tmp_msg, dev_data->cb_arg[filter_idx]); } k_mutex_unlock(&dev_data->mutex); } static void mcp2515_rx(struct device *dev, uint8_t rx_idx) { __ASSERT(rx_idx < MCP2515_RX_CNT, "rx_idx < MCP2515_RX_CNT"); struct zcan_frame msg; uint8_t rx_frame[MCP2515_FRAME_LEN]; uint8_t nm; /* Address Pointer selection */ nm = 2 * rx_idx; /* Fetch rx buffer */ mcp2515_cmd_read_rx_buffer(dev, nm, rx_frame, sizeof(rx_frame)); mcp2515_convert_mcp2515frame_to_zcanframe(rx_frame, &msg); mcp2515_rx_filter(dev, &msg); } static void mcp2515_tx_done(struct device *dev, uint8_t tx_idx) { struct mcp2515_data *dev_data = DEV_DATA(dev); if (dev_data->tx_cb[tx_idx].cb == NULL) { k_sem_give(&dev_data->tx_cb[tx_idx].sem); } else { dev_data->tx_cb[tx_idx].cb(0, dev_data->tx_cb[tx_idx].cb_arg); } k_mutex_lock(&dev_data->mutex, K_FOREVER); dev_data->tx_busy_map &= ~BIT(tx_idx); k_mutex_unlock(&dev_data->mutex); k_sem_give(&dev_data->tx_sem); } static enum can_state mcp2515_get_state(struct device *dev, struct can_bus_err_cnt *err_cnt) { uint8_t eflg; uint8_t err_cnt_buf[2]; int ret; ret = mcp2515_cmd_read_reg(dev, MCP2515_ADDR_EFLG, &eflg, sizeof(eflg)); if (ret < 0) { LOG_ERR("Failed to read error register [%d]", ret); return CAN_BUS_UNKNOWN; } if (err_cnt) { ret = mcp2515_cmd_read_reg(dev, MCP2515_ADDR_TEC, err_cnt_buf, sizeof(err_cnt_buf)); if (ret < 0) { LOG_ERR("Failed to read error counters [%d]", ret); return CAN_BUS_UNKNOWN; } err_cnt->tx_err_cnt = err_cnt_buf[0]; err_cnt->rx_err_cnt = err_cnt_buf[1]; } if (eflg & MCP2515_EFLG_TXBO) { return CAN_BUS_OFF; } if ((eflg & MCP2515_EFLG_RXEP) || (eflg & MCP2515_EFLG_TXEP)) { return CAN_ERROR_PASSIVE; } return CAN_ERROR_ACTIVE; } static void mcp2515_handle_errors(struct device *dev) { struct mcp2515_data *dev_data = DEV_DATA(dev); can_state_change_isr_t state_change_isr = dev_data->state_change_isr; enum can_state state; struct can_bus_err_cnt err_cnt; state = mcp2515_get_state(dev, state_change_isr ? &err_cnt : NULL); if (state_change_isr && dev_data->old_state != state) { dev_data->old_state = state; state_change_isr(state, err_cnt); } } #ifndef CONFIG_CAN_AUTO_BUS_OFF_RECOVERY static void mcp2515_recover(struct device *dev, k_timeout_t timeout) { ARG_UNUSED(dev); ARG_UNUSED(timeout); } #endif static void mcp2515_handle_interrupts(struct device *dev) { const struct mcp2515_config *dev_cfg = DEV_CFG(dev); struct mcp2515_data *dev_data = DEV_DATA(dev); int ret; uint8_t canintf; /* Loop until INT pin is inactive (all interrupt flags handled) */ while (1) { ret = mcp2515_cmd_read_reg(dev, MCP2515_ADDR_CANINTF, &canintf, 1); if (ret != 0) { LOG_ERR("Couldn't read INTF register %d", ret); continue; } if (canintf == 0) { /* No interrupt flags set */ break; } if (canintf & MCP2515_CANINTF_RX0IF) { mcp2515_rx(dev, 0); /* RX0IF flag cleared automatically during read */ canintf &= ~MCP2515_CANINTF_RX0IF; } if (canintf & MCP2515_CANINTF_RX1IF) { mcp2515_rx(dev, 1); /* RX1IF flag cleared automatically during read */ canintf &= ~MCP2515_CANINTF_RX1IF; } if (canintf & MCP2515_CANINTF_TX0IF) { mcp2515_tx_done(dev, 0); } if (canintf & MCP2515_CANINTF_TX1IF) { mcp2515_tx_done(dev, 1); } if (canintf & MCP2515_CANINTF_TX2IF) { mcp2515_tx_done(dev, 2); } if (canintf & MCP2515_CANINTF_ERRIF) { mcp2515_handle_errors(dev); } if (canintf != 0) { /* Clear remaining flags */ mcp2515_cmd_bit_modify(dev, MCP2515_ADDR_CANINTF, canintf, ~canintf); } /* Break from loop if INT pin is inactive */ ret = gpio_pin_get(dev_data->int_gpio, dev_cfg->int_pin); if (ret < 0) { LOG_ERR("Couldn't read INT pin"); } else if (ret == 0) { /* All interrupt flags handled */ break; } } } static void mcp2515_int_thread(struct device *dev) { struct mcp2515_data *dev_data = DEV_DATA(dev); while (1) { k_sem_take(&dev_data->int_sem, K_FOREVER); mcp2515_handle_interrupts(dev); } } static void mcp2515_int_gpio_callback(struct device *dev, struct gpio_callback *cb, uint32_t pins) { struct mcp2515_data *dev_data = CONTAINER_OF(cb, struct mcp2515_data, int_gpio_cb); k_sem_give(&dev_data->int_sem); } static const struct can_driver_api can_api_funcs = { .configure = mcp2515_configure, .send = mcp2515_send, .attach_isr = mcp2515_attach_isr, .detach = mcp2515_detach, .get_state = mcp2515_get_state, #ifndef CONFIG_CAN_AUTO_BUS_OFF_RECOVERY .recover = mcp2515_recover, #endif .register_state_change_isr = mcp2515_register_state_change_isr }; static int mcp2515_init(struct device *dev) { const struct mcp2515_config *dev_cfg = DEV_CFG(dev); struct mcp2515_data *dev_data = DEV_DATA(dev); int ret; k_sem_init(&dev_data->int_sem, 0, 1); k_mutex_init(&dev_data->mutex); k_sem_init(&dev_data->tx_sem, MCP2515_TX_CNT, MCP2515_TX_CNT); k_sem_init(&dev_data->tx_cb[0].sem, 0, 1); k_sem_init(&dev_data->tx_cb[1].sem, 0, 1); k_sem_init(&dev_data->tx_cb[2].sem, 0, 1); /* SPI config */ dev_data->spi_cfg.operation = SPI_WORD_SET(8); dev_data->spi_cfg.frequency = dev_cfg->spi_freq; dev_data->spi_cfg.slave = dev_cfg->spi_slave; dev_data->spi = device_get_binding(dev_cfg->spi_port); if (!dev_data->spi) { LOG_ERR("SPI master port %s not found", dev_cfg->spi_port); return -EINVAL; } #if DT_INST_SPI_DEV_HAS_CS_GPIOS(0) dev_data->spi_cs_ctrl.gpio_dev = device_get_binding(dev_cfg->spi_cs_port); if (!dev_data->spi_cs_ctrl.gpio_dev) { LOG_ERR("Unable to get GPIO SPI CS device"); return -ENODEV; } dev_data->spi_cs_ctrl.gpio_pin = dev_cfg->spi_cs_pin; dev_data->spi_cs_ctrl.gpio_dt_flags = dev_cfg->spi_cs_flags; dev_data->spi_cs_ctrl.delay = 0U; dev_data->spi_cfg.cs = &dev_data->spi_cs_ctrl; #else dev_data->spi_cfg.cs = NULL; #endif /* DT_INST_SPI_DEV_HAS_CS_GPIOS(0) */ /* Reset MCP2515 */ if (mcp2515_cmd_soft_reset(dev)) { LOG_ERR("Soft-reset failed"); return -EIO; } /* Initialize interrupt handling */ dev_data->int_gpio = device_get_binding(dev_cfg->int_port); if (dev_data->int_gpio == NULL) { LOG_ERR("GPIO port %s not found", dev_cfg->int_port); return -EINVAL; } if (gpio_pin_configure(dev_data->int_gpio, dev_cfg->int_pin, (GPIO_INPUT | DT_INST_GPIO_FLAGS(0, int_gpios)))) { LOG_ERR("Unable to configure GPIO pin %u", dev_cfg->int_pin); return -EINVAL; } gpio_init_callback(&(dev_data->int_gpio_cb), mcp2515_int_gpio_callback, BIT(dev_cfg->int_pin)); if (gpio_add_callback(dev_data->int_gpio, &(dev_data->int_gpio_cb))) { return -EINVAL; } if (gpio_pin_interrupt_configure(dev_data->int_gpio, dev_cfg->int_pin, GPIO_INT_EDGE_TO_ACTIVE)) { return -EINVAL; } k_thread_create(&dev_data->int_thread, dev_data->int_thread_stack, dev_cfg->int_thread_stack_size, (k_thread_entry_t) mcp2515_int_thread, (void *)dev, NULL, NULL, K_PRIO_COOP(dev_cfg->int_thread_priority), 0, K_NO_WAIT); (void)memset(dev_data->rx_cb, 0, sizeof(dev_data->rx_cb)); (void)memset(dev_data->filter, 0, sizeof(dev_data->filter)); dev_data->old_state = CAN_ERROR_ACTIVE; ret = mcp2515_configure(dev, CAN_NORMAL_MODE, dev_cfg->bus_speed); return ret; } #if DT_NODE_HAS_STATUS(DT_DRV_INST(0), okay) static K_THREAD_STACK_DEFINE(mcp2515_int_thread_stack, CONFIG_CAN_MCP2515_INT_THREAD_STACK_SIZE); static struct mcp2515_data mcp2515_data_1 = { .int_thread_stack = mcp2515_int_thread_stack, .tx_cb[0].cb = NULL, .tx_cb[1].cb = NULL, .tx_cb[2].cb = NULL, .tx_busy_map = 0U, .filter_usage = 0U, }; static const struct mcp2515_config mcp2515_config_1 = { .spi_port = DT_INST_BUS_LABEL(0), .spi_freq = DT_INST_PROP(0, spi_max_frequency), .spi_slave = DT_INST_REG_ADDR(0), .int_pin = DT_INST_GPIO_PIN(0, int_gpios), .int_port = DT_INST_GPIO_LABEL(0, int_gpios), .int_thread_stack_size = CONFIG_CAN_MCP2515_INT_THREAD_STACK_SIZE, .int_thread_priority = CONFIG_CAN_MCP2515_INT_THREAD_PRIO, #if DT_INST_SPI_DEV_HAS_CS_GPIOS(0) .spi_cs_pin = DT_INST_SPI_DEV_CS_GPIOS_PIN(0), .spi_cs_port = DT_INST_SPI_DEV_CS_GPIOS_LABEL(0), .spi_cs_flags = DT_INST_SPI_DEV_CS_GPIOS_FLAGS(0), #endif /* DT_INST_SPI_DEV_HAS_CS_GPIOS(0) */ .tq_sjw = DT_INST_PROP(0, sjw), .tq_prop = DT_INST_PROP(0, prop_seg), .tq_bs1 = DT_INST_PROP(0, phase_seg1), .tq_bs2 = DT_INST_PROP(0, phase_seg2), .bus_speed = DT_INST_PROP(0, bus_speed), .osc_freq = DT_INST_PROP(0, osc_freq) }; DEVICE_AND_API_INIT(can_mcp2515_1, DT_INST_LABEL(0), &mcp2515_init, &mcp2515_data_1, &mcp2515_config_1, POST_KERNEL, CONFIG_CAN_MCP2515_INIT_PRIORITY, &can_api_funcs); #endif /* DT_NODE_HAS_STATUS(DT_DRV_INST(0), okay) */