/* ST Microelectronics IIS2ICLX 2-axis accelerometer sensor driver * * Copyright (c) 2020 STMicroelectronics * * SPDX-License-Identifier: Apache-2.0 * * Datasheet: * https://www.st.com/resource/en/datasheet/iis2iclx.pdf */ #define DT_DRV_COMPAT st_iis2iclx #include #include #include #include #include #include #include #include #include "iis2iclx.h" LOG_MODULE_DECLARE(IIS2ICLX, CONFIG_SENSOR_LOG_LEVEL); #define IIS2ICLX_SHUB_DATA_OUT 0x02 #define IIS2ICLX_SHUB_SLV0_ADDR 0x15 #define IIS2ICLX_SHUB_SLV0_SUBADDR 0x16 #define IIS2ICLX_SHUB_SLV0_CONFIG 0x17 #define IIS2ICLX_SHUB_SLV1_ADDR 0x18 #define IIS2ICLX_SHUB_SLV1_SUBADDR 0x19 #define IIS2ICLX_SHUB_SLV1_CONFIG 0x1A #define IIS2ICLX_SHUB_SLV2_ADDR 0x1B #define IIS2ICLX_SHUB_SLV2_SUBADDR 0x1C #define IIS2ICLX_SHUB_SLV2_CONFIG 0x1D #define IIS2ICLX_SHUB_SLV3_ADDR 0x1E #define IIS2ICLX_SHUB_SLV3_SUBADDR 0x1F #define IIS2ICLX_SHUB_SLV3_CONFIG 0x20 #define IIS2ICLX_SHUB_SLV0_DATAWRITE 0x21 #define IIS2ICLX_SHUB_STATUS_MASTER 0x22 #define IIS2ICLX_SHUB_STATUS_SLV0_NACK BIT(3) #define IIS2ICLX_SHUB_STATUS_ENDOP BIT(0) #define IIS2ICLX_SHUB_SLVX_WRITE 0x0 #define IIS2ICLX_SHUB_SLVX_READ 0x1 static uint8_t num_ext_dev; static uint8_t shub_ext[IIS2ICLX_SHUB_MAX_NUM_SLVS]; static int iis2iclx_shub_write_slave_reg(const struct device *dev, uint8_t slv_addr, uint8_t slv_reg, uint8_t *value, uint16_t len); static int iis2iclx_shub_read_slave_reg(const struct device *dev, uint8_t slv_addr, uint8_t slv_reg, uint8_t *value, uint16_t len); static void iis2iclx_shub_enable(const struct device *dev, uint8_t enable); /* * LIS2MDL magn device specific part */ #if defined(CONFIG_IIS2ICLX_EXT_LIS2MDL) || defined(CONFIG_IIS2ICLX_EXT_IIS2MDC) #define LIS2MDL_CFG_REG_A 0x60 #define LIS2MDL_CFG_REG_B 0x61 #define LIS2MDL_CFG_REG_C 0x62 #define LIS2MDL_STATUS_REG 0x67 #define LIS2MDL_SW_RESET 0x20 #define LIS2MDL_ODR_10HZ 0x00 #define LIS2MDL_ODR_100HZ 0x0C #define LIS2MDL_OFF_CANC 0x02 #define LIS2MDL_SENSITIVITY 1500 static int iis2iclx_lis2mdl_init(const struct device *dev, uint8_t i2c_addr) { struct iis2iclx_data *data = dev->data; uint8_t mag_cfg[2]; data->magn_gain = LIS2MDL_SENSITIVITY; /* sw reset device */ mag_cfg[0] = LIS2MDL_SW_RESET; iis2iclx_shub_write_slave_reg(dev, i2c_addr, LIS2MDL_CFG_REG_A, mag_cfg, 1); k_sleep(K_MSEC(10)); /* turn-on time in ms */ /* configure mag */ mag_cfg[0] = LIS2MDL_ODR_10HZ; mag_cfg[1] = LIS2MDL_OFF_CANC; iis2iclx_shub_write_slave_reg(dev, i2c_addr, LIS2MDL_CFG_REG_A, mag_cfg, 2); return 0; } static const uint16_t lis2mdl_map[] = {10, 20, 50, 100}; static int iis2iclx_lis2mdl_odr_set(const struct device *dev, uint8_t i2c_addr, uint16_t freq) { uint8_t odr, cfg; for (odr = 0; odr < ARRAY_SIZE(lis2mdl_map); odr++) { if (freq == lis2mdl_map[odr]) { break; } } if (odr == ARRAY_SIZE(lis2mdl_map)) { LOG_ERR("shub: LIS2MDL freq val %d not supported.", freq); return -ENOTSUP; } cfg = (odr << 2); iis2iclx_shub_write_slave_reg(dev, i2c_addr, LIS2MDL_CFG_REG_A, &cfg, 1); iis2iclx_shub_enable(dev, 1); return 0; } static int iis2iclx_lis2mdl_conf(const struct device *dev, uint8_t i2c_addr, enum sensor_channel chan, enum sensor_attribute attr, const struct sensor_value *val) { switch (attr) { case SENSOR_ATTR_SAMPLING_FREQUENCY: return iis2iclx_lis2mdl_odr_set(dev, i2c_addr, val->val1); default: LOG_ERR("shub: LIS2MDL attribute not supported."); return -ENOTSUP; } return 0; } #endif /* CONFIG_IIS2ICLX_EXT_LIS2MDL || CONFIG_IIS2ICLX_EXT_IIS2MDC */ /* * HTS221 humidity device specific part */ #ifdef CONFIG_IIS2ICLX_EXT_HTS221 #define HTS221_AUTOINCREMENT BIT(7) #define HTS221_REG_CTRL1 0x20 #define HTS221_ODR_1HZ 0x01 #define HTS221_BDU 0x04 #define HTS221_PD 0x80 #define HTS221_REG_CONV_START 0x30 static int hts221_read_conv_data(const struct device *dev, uint8_t i2c_addr) { const struct iis2iclx_config *cfg = dev->config; struct iis2iclx_data *data = dev->data; uint8_t buf[16], i; struct hts221_data *ht = &data->hts221; for (i = 0; i < sizeof(buf); i += 7) { unsigned char len = MIN(7, sizeof(buf) - i); if (iis2iclx_shub_read_slave_reg(dev, i2c_addr, (HTS221_REG_CONV_START + i) | HTS221_AUTOINCREMENT, &buf[i], len) < 0) { LOG_ERR("shub: failed to read hts221 conv data"); return -EIO; } } ht->y0 = buf[0] / 2; ht->y1 = buf[1] / 2; ht->x0 = sys_le16_to_cpu(buf[6] | (buf[7] << 8)); ht->x1 = sys_le16_to_cpu(buf[10] | (buf[11] << 8)); return 0; } static int iis2iclx_hts221_init(const struct device *dev, uint8_t i2c_addr) { const struct iis2iclx_config *cfg = dev->config; uint8_t hum_cfg; /* configure ODR and BDU */ hum_cfg = HTS221_ODR_1HZ | HTS221_BDU | HTS221_PD; iis2iclx_shub_write_slave_reg(dev, i2c_addr, HTS221_REG_CTRL1, &hum_cfg, 1); return hts221_read_conv_data(dev, i2c_addr); } static const uint16_t hts221_map[] = {0, 1, 7, 12}; static int iis2iclx_hts221_odr_set(const struct device *dev, uint8_t i2c_addr, uint16_t freq) { uint8_t odr, cfg; for (odr = 0; odr < ARRAY_SIZE(hts221_map); odr++) { if (freq == hts221_map[odr]) { break; } } if (odr == ARRAY_SIZE(hts221_map)) { LOG_ERR("shub: HTS221 freq val %d not supported.", freq); return -ENOTSUP; } cfg = odr | HTS221_BDU | HTS221_PD; iis2iclx_shub_write_slave_reg(dev, i2c_addr, HTS221_REG_CTRL1, &cfg, 1); iis2iclx_shub_enable(dev, 1); return 0; } static int iis2iclx_hts221_conf(const struct device *dev, uint8_t i2c_addr, enum sensor_channel chan, enum sensor_attribute attr, const struct sensor_value *val) { switch (attr) { case SENSOR_ATTR_SAMPLING_FREQUENCY: return iis2iclx_hts221_odr_set(data, i2c_addr, val->val1); default: LOG_ERR("shub: HTS221 attribute not supported."); return -ENOTSUP; } return 0; } #endif /* CONFIG_IIS2ICLX_EXT_HTS221 */ /* * LPS22HB baro/temp device specific part */ #ifdef CONFIG_IIS2ICLX_EXT_LPS22HB #define LPS22HB_CTRL_REG1 0x10 #define LPS22HB_CTRL_REG2 0x11 #define LPS22HB_SW_RESET 0x04 #define LPS22HB_ODR_10HZ 0x20 #define LPS22HB_LPF_EN 0x08 #define LPS22HB_BDU_EN 0x02 static int iis2iclx_lps22hb_init(const struct device *dev, uint8_t i2c_addr) { uint8_t baro_cfg[2]; /* sw reset device */ baro_cfg[0] = LPS22HB_SW_RESET; iis2iclx_shub_write_slave_reg(dev, i2c_addr, LPS22HB_CTRL_REG2, baro_cfg, 1); k_sleep(K_MSEC(1)); /* turn-on time in ms */ /* configure device */ baro_cfg[0] = LPS22HB_ODR_10HZ | LPS22HB_LPF_EN | LPS22HB_BDU_EN; iis2iclx_shub_write_slave_reg(dev, i2c_addr, LPS22HB_CTRL_REG1, baro_cfg, 1); return 0; } #endif /* CONFIG_IIS2ICLX_EXT_LPS22HB */ /* * LPS22HH baro/temp device specific part */ #ifdef CONFIG_IIS2ICLX_EXT_LPS22HH #define LPS22HH_CTRL_REG1 0x10 #define LPS22HH_CTRL_REG2 0x11 #define LPS22HH_SW_RESET 0x04 #define LPS22HH_IF_ADD_INC 0x10 #define LPS22HH_ODR_10HZ 0x20 #define LPS22HH_LPF_EN 0x08 #define LPS22HH_BDU_EN 0x02 static int iis2iclx_lps22hh_init(const struct device *dev, uint8_t i2c_addr) { uint8_t baro_cfg[2]; /* sw reset device */ baro_cfg[0] = LPS22HH_SW_RESET; iis2iclx_shub_write_slave_reg(dev, i2c_addr, LPS22HH_CTRL_REG2, baro_cfg, 1); k_sleep(K_MSEC(100)); /* turn-on time in ms */ /* configure device */ baro_cfg[0] = LPS22HH_IF_ADD_INC; iis2iclx_shub_write_slave_reg(dev, i2c_addr, LPS22HH_CTRL_REG2, baro_cfg, 1); baro_cfg[0] = LPS22HH_ODR_10HZ | LPS22HH_LPF_EN | LPS22HH_BDU_EN; iis2iclx_shub_write_slave_reg(dev, i2c_addr, LPS22HH_CTRL_REG1, baro_cfg, 1); return 0; } static const uint16_t lps22hh_map[] = {0, 1, 10, 25, 50, 75, 100, 200}; static int iis2iclx_lps22hh_odr_set(const struct device *dev, uint8_t i2c_addr, uint16_t freq) { uint8_t odr, cfg; for (odr = 0; odr < ARRAY_SIZE(lps22hh_map); odr++) { if (freq == lps22hh_map[odr]) { break; } } if (odr == ARRAY_SIZE(lps22hh_map)) { LOG_ERR("shub: LPS22HH freq val %d not supported.", freq); return -ENOTSUP; } cfg = (odr << 4) | LPS22HH_LPF_EN | LPS22HH_BDU_EN; iis2iclx_shub_write_slave_reg(dev, i2c_addr, LPS22HH_CTRL_REG1, &cfg, 1); iis2iclx_shub_enable(dev, 1); return 0; } static int iis2iclx_lps22hh_conf(const struct device *dev, uint8_t i2c_addr, enum sensor_channel chan, enum sensor_attribute attr, const struct sensor_value *val) { switch (attr) { case SENSOR_ATTR_SAMPLING_FREQUENCY: return iis2iclx_lps22hh_odr_set(data, i2c_addr, val->val1); default: LOG_ERR("shub: LPS22HH attribute not supported."); return -ENOTSUP; } return 0; } #endif /* CONFIG_IIS2ICLX_EXT_LPS22HH */ /* List of supported external sensors */ static struct iis2iclx_shub_slist { enum sensor_channel type; uint8_t i2c_addr[2]; uint8_t ext_i2c_addr; uint8_t wai_addr; uint8_t wai_val; uint8_t out_data_addr; uint8_t out_data_len; uint8_t sh_out_reg; int (*dev_init)(const struct device *dev, uint8_t i2c_addr); int (*dev_conf)(const struct device *dev, uint8_t i2c_addr, enum sensor_channel chan, enum sensor_attribute attr, const struct sensor_value *val); } iis2iclx_shub_slist[] = { #if defined(CONFIG_IIS2ICLX_EXT_LIS2MDL) || defined(CONFIG_IIS2ICLX_EXT_IIS2MDC) { /* LIS2MDL */ .type = SENSOR_CHAN_MAGN_XYZ, .i2c_addr = { 0x1E }, .wai_addr = 0x4F, .wai_val = 0x40, .out_data_addr = 0x68, .out_data_len = 0x06, .dev_init = (iis2iclx_lis2mdl_init), .dev_conf = (iis2iclx_lis2mdl_conf), }, #endif /* CONFIG_IIS2ICLX_EXT_LIS2MDL || CONFIG_IIS2ICLX_EXT_IIS2MDC */ #ifdef CONFIG_IIS2ICLX_EXT_HTS221 { /* HTS221 */ .type = SENSOR_CHAN_HUMIDITY, .i2c_addr = { 0x5F }, .wai_addr = 0x0F, .wai_val = 0xBC, .out_data_addr = 0x28 | HTS221_AUTOINCREMENT, .out_data_len = 0x02, .dev_init = (iis2iclx_hts221_init), .dev_conf = (iis2iclx_hts221_conf), }, #endif /* CONFIG_IIS2ICLX_EXT_HTS221 */ #ifdef CONFIG_IIS2ICLX_EXT_LPS22HB { /* LPS22HB */ .type = SENSOR_CHAN_PRESS, .i2c_addr = { 0x5C, 0x5D }, .wai_addr = 0x0F, .wai_val = 0xB1, .out_data_addr = 0x28, .out_data_len = 0x05, .dev_init = (iis2iclx_lps22hb_init), }, #endif /* CONFIG_IIS2ICLX_EXT_LPS22HB */ #ifdef CONFIG_IIS2ICLX_EXT_LPS22HH { /* LPS22HH */ .type = SENSOR_CHAN_PRESS, .i2c_addr = { 0x5C, 0x5D }, .wai_addr = 0x0F, .wai_val = 0xB3, .out_data_addr = 0x28, .out_data_len = 0x05, .dev_init = (iis2iclx_lps22hh_init), .dev_conf = (iis2iclx_lps22hh_conf), }, #endif /* CONFIG_IIS2ICLX_EXT_LPS22HH */ }; static inline void iis2iclx_shub_wait_completed(const struct iis2iclx_config *cfg) { iis2iclx_status_master_t status; do { k_msleep(1); iis2iclx_sh_status_get((stmdev_ctx_t *)&cfg->ctx, &status); } while (status.sens_hub_endop == 0); } static inline void iis2iclx_shub_embedded_en(const struct iis2iclx_config *cfg, bool on) { if (on) { (void) iis2iclx_mem_bank_set((stmdev_ctx_t *)&cfg->ctx, IIS2ICLX_SENSOR_HUB_BANK); } else { (void) iis2iclx_mem_bank_set((stmdev_ctx_t *)&cfg->ctx, IIS2ICLX_USER_BANK); } k_busy_wait(150); } static int iis2iclx_shub_read_embedded_regs(const struct iis2iclx_config *cfg, uint8_t reg_addr, uint8_t *value, int len) { iis2iclx_shub_embedded_en(cfg, true); if (iis2iclx_read_reg((stmdev_ctx_t *)&cfg->ctx, reg_addr, value, len) < 0) { LOG_ERR("shub: failed to read external reg: %02x", reg_addr); iis2iclx_shub_embedded_en(cfg, false); return -EIO; } iis2iclx_shub_embedded_en(cfg, false); return 0; } static int iis2iclx_shub_write_embedded_regs(const struct iis2iclx_config *cfg, uint8_t reg_addr, uint8_t *value, uint8_t len) { iis2iclx_shub_embedded_en(cfg, true); if (iis2iclx_write_reg((stmdev_ctx_t *)&cfg->ctx, reg_addr, value, len) < 0) { LOG_ERR("shub: failed to write external reg: %02x", reg_addr); iis2iclx_shub_embedded_en(cfg, false); return -EIO; } iis2iclx_shub_embedded_en(cfg, false); return 0; } static void iis2iclx_shub_enable(const struct device *dev, uint8_t enable) { const struct iis2iclx_config *cfg = dev->config; struct iis2iclx_data *data = dev->data; /* Enable Accel @26hz */ if (!data->accel_freq) { uint8_t odr = (enable) ? 2 : 0; if (iis2iclx_xl_data_rate_set((stmdev_ctx_t *)&cfg->ctx, odr) < 0) { LOG_DBG("shub: failed to set XL sampling rate"); return; } } iis2iclx_shub_embedded_en(cfg, true); if (iis2iclx_sh_master_set((stmdev_ctx_t *)&cfg->ctx, enable) < 0) { LOG_DBG("shub: failed to set master on"); iis2iclx_shub_embedded_en(cfg, false); return; } iis2iclx_shub_embedded_en(cfg, false); } /* must be called with master on */ static int iis2iclx_shub_check_slv0_nack(const struct iis2iclx_config *cfg) { uint8_t status; if (iis2iclx_shub_read_embedded_regs(cfg, IIS2ICLX_SHUB_STATUS_MASTER, &status, 1) < 0) { LOG_ERR("shub: error reading embedded reg"); return -EIO; } if (status & (IIS2ICLX_SHUB_STATUS_SLV0_NACK)) { LOG_ERR("shub: SLV0 nacked"); return -EIO; } return 0; } /* * use SLV0 for generic read to slave device */ static int iis2iclx_shub_read_slave_reg(const struct device *dev, uint8_t slv_addr, uint8_t slv_reg, uint8_t *value, uint16_t len) { const struct iis2iclx_config *cfg = dev->config; uint8_t slave[3]; slave[0] = (slv_addr << 1) | IIS2ICLX_SHUB_SLVX_READ; slave[1] = slv_reg; slave[2] = (len & 0x7); if (iis2iclx_shub_write_embedded_regs(cfg, IIS2ICLX_SHUB_SLV0_ADDR, slave, 3) < 0) { LOG_ERR("shub: error writing embedded reg"); return -EIO; } /* turn SH on */ iis2iclx_shub_enable(dev, 1); iis2iclx_shub_wait_completed(cfg); if (iis2iclx_shub_check_slv0_nack(cfg) < 0) { iis2iclx_shub_enable(dev, 0); return -EIO; } /* read data from external slave */ iis2iclx_shub_embedded_en(cfg, true); if (iis2iclx_read_reg((stmdev_ctx_t *)&cfg->ctx, IIS2ICLX_SHUB_DATA_OUT, value, len) < 0) { LOG_ERR("shub: error reading sensor data"); iis2iclx_shub_embedded_en(cfg, false); return -EIO; } iis2iclx_shub_embedded_en(cfg, false); iis2iclx_shub_enable(dev, 0); return 0; } /* * use SLV0 to configure slave device */ static int iis2iclx_shub_write_slave_reg(const struct device *dev, uint8_t slv_addr, uint8_t slv_reg, uint8_t *value, uint16_t len) { const struct iis2iclx_config *cfg = dev->config; uint8_t slv_cfg[3]; uint8_t cnt = 0U; while (cnt < len) { slv_cfg[0] = (slv_addr << 1) & ~IIS2ICLX_SHUB_SLVX_READ; slv_cfg[1] = slv_reg + cnt; if (iis2iclx_shub_write_embedded_regs(cfg, IIS2ICLX_SHUB_SLV0_ADDR, slv_cfg, 2) < 0) { LOG_ERR("shub: error writing embedded reg"); return -EIO; } slv_cfg[0] = value[cnt]; if (iis2iclx_shub_write_embedded_regs(cfg, IIS2ICLX_SHUB_SLV0_DATAWRITE, slv_cfg, 1) < 0) { LOG_ERR("shub: error writing embedded reg"); return -EIO; } /* turn SH on */ iis2iclx_shub_enable(dev, 1); iis2iclx_shub_wait_completed(cfg); if (iis2iclx_shub_check_slv0_nack(cfg) < 0) { iis2iclx_shub_enable(dev, 0); return -EIO; } iis2iclx_shub_enable(dev, 0); cnt++; } /* Put SLV0 in IDLE mode */ slv_cfg[0] = 0x7; slv_cfg[1] = 0x0; slv_cfg[2] = 0x0; if (iis2iclx_shub_write_embedded_regs(cfg, IIS2ICLX_SHUB_SLV0_ADDR, slv_cfg, 3) < 0) { LOG_ERR("shub: error writing embedded reg"); return -EIO; } return 0; } /* * SLAVEs configurations: * * - SLAVE 0: used for configuring all slave devices * - SLAVE 1: used as data read channel for external slave device #1 * - SLAVE 2: used as data read channel for external slave device #2 * - SLAVE 3: used for generic reads while data channel is enabled */ static int iis2iclx_shub_set_data_channel(const struct device *dev) { const struct iis2iclx_config *cfg = dev->config; uint8_t n, i, slv_cfg[6]; struct iis2iclx_shub_slist *sp; /* Set data channel for slave devices */ for (n = 0; n < num_ext_dev; n++) { sp = &iis2iclx_shub_slist[shub_ext[n]]; i = n * 3; slv_cfg[i] = (sp->ext_i2c_addr << 1) | IIS2ICLX_SHUB_SLVX_READ; slv_cfg[i + 1] = sp->out_data_addr; slv_cfg[i + 2] = sp->out_data_len; } if (iis2iclx_shub_write_embedded_regs(cfg, IIS2ICLX_SHUB_SLV1_ADDR, slv_cfg, n*3) < 0) { LOG_ERR("shub: error writing embedded reg"); return -EIO; } /* Configure the master */ iis2iclx_aux_sens_on_t aux = IIS2ICLX_SLV_0_1_2; if (iis2iclx_sh_slave_connected_set((stmdev_ctx_t *)&cfg->ctx, aux) < 0) { LOG_ERR("shub: error setting aux sensors"); return -EIO; } iis2iclx_write_once_t wo = IIS2ICLX_ONLY_FIRST_CYCLE; if (iis2iclx_sh_write_mode_set((stmdev_ctx_t *)&cfg->ctx, wo) < 0) { LOG_ERR("shub: error setting write once"); return -EIO; } /* turn SH on */ iis2iclx_shub_enable(dev, 1); iis2iclx_shub_wait_completed(cfg); return 0; } int iis2iclx_shub_get_idx(enum sensor_channel type) { uint8_t n; struct iis2iclx_shub_slist *sp; for (n = 0; n < num_ext_dev; n++) { sp = &iis2iclx_shub_slist[shub_ext[n]]; if (sp->type == type) return n; } return -ENOTSUP; } int iis2iclx_shub_fetch_external_devs(const struct device *dev) { uint8_t n; const struct iis2iclx_config *cfg = dev->config; struct iis2iclx_data *data = dev->data; struct iis2iclx_shub_slist *sp; /* read data from external slave */ iis2iclx_shub_embedded_en(cfg, true); for (n = 0; n < num_ext_dev; n++) { sp = &iis2iclx_shub_slist[shub_ext[n]]; if (iis2iclx_read_reg((stmdev_ctx_t *)&cfg->ctx, sp->sh_out_reg, data->ext_data[n], sp->out_data_len) < 0) { LOG_ERR("shub: failed to read sample"); iis2iclx_shub_embedded_en(cfg, false); return -EIO; } } iis2iclx_shub_embedded_en(cfg, false); return 0; } int iis2iclx_shub_config(const struct device *dev, enum sensor_channel chan, enum sensor_attribute attr, const struct sensor_value *val) { struct iis2iclx_shub_slist *sp = NULL; uint8_t n; for (n = 0; n < num_ext_dev; n++) { sp = &iis2iclx_shub_slist[shub_ext[n]]; if (sp->type == chan) break; } if (n == num_ext_dev) { LOG_ERR("shub: chan not supported"); return -ENOTSUP; } if (sp == NULL || sp->dev_conf == NULL) { LOG_ERR("shub: chan not configurable"); return -ENOTSUP; } return sp->dev_conf(dev, sp->ext_i2c_addr, chan, attr, val); } int iis2iclx_shub_init(const struct device *dev) { uint8_t i, n = 0, regn; uint8_t chip_id; struct iis2iclx_shub_slist *sp; for (n = 0; n < ARRAY_SIZE(iis2iclx_shub_slist); n++) { if (num_ext_dev >= IIS2ICLX_SHUB_MAX_NUM_SLVS) break; chip_id = 0; sp = &iis2iclx_shub_slist[n]; /* * The external sensor may have different I2C address. * So, try them one by one until we read the correct * chip ID. */ for (i = 0U; i < ARRAY_SIZE(sp->i2c_addr); i++) { if (iis2iclx_shub_read_slave_reg(dev, sp->i2c_addr[i], sp->wai_addr, &chip_id, 1) < 0) { continue; } if (chip_id == sp->wai_val) { break; } } if (i >= ARRAY_SIZE(sp->i2c_addr)) { LOG_DBG("shub: invalid chip id 0x%x", chip_id); continue; } LOG_INF("shub: Ext Device Chip Id: 0x%02x", chip_id); sp->ext_i2c_addr = sp->i2c_addr[i]; shub_ext[num_ext_dev++] = n; } if (num_ext_dev == 0) { LOG_WRN("shub: no slave devices found"); return -ENOTSUP; } /* init external devices */ for (n = 0, regn = 0; n < num_ext_dev; n++) { sp = &iis2iclx_shub_slist[shub_ext[n]]; sp->sh_out_reg = IIS2ICLX_SHUB_DATA_OUT + regn; regn += sp->out_data_len; sp->dev_init(dev, sp->ext_i2c_addr); } iis2iclx_shub_set_data_channel(dev); return 0; }