/* * Copyright (c) 2017, NXP * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT nxp_fxas21002 #include "fxas21002.h" #include #include #include LOG_MODULE_REGISTER(FXAS21002, CONFIG_SENSOR_LOG_LEVEL); /* Sample period in microseconds, indexed by output data rate encoding (DR) */ static const uint32_t sample_period[] = { 1250, 2500, 5000, 10000, 20000, 40000, 80000, 80000 }; static int fxas21002_sample_fetch(const struct device *dev, enum sensor_channel chan) { const struct fxas21002_config *config = dev->config; struct fxas21002_data *data = dev->data; uint8_t buffer[FXAS21002_MAX_NUM_BYTES]; int16_t *raw; int ret = 0; int i; if (chan != SENSOR_CHAN_ALL) { LOG_ERR("Unsupported sensor channel"); return -ENOTSUP; } k_sem_take(&data->sem, K_FOREVER); /* Read all the channels in one I2C transaction. */ if (i2c_burst_read(data->i2c, config->i2c_address, FXAS21002_REG_OUTXMSB, buffer, sizeof(buffer))) { LOG_ERR("Could not fetch sample"); ret = -EIO; goto exit; } /* Parse the buffer into raw channel data (16-bit integers). To save * RAM, store the data in raw format and wait to convert to the * normalized sensor_value type until later. */ raw = &data->raw[0]; for (i = 0; i < sizeof(buffer); i += 2) { *raw++ = (buffer[i] << 8) | (buffer[i+1]); } exit: k_sem_give(&data->sem); return ret; } static void fxas21002_convert(struct sensor_value *val, int16_t raw, enum fxas21002_range range) { int32_t micro_rad; /* Convert units to micro radians per second. * 62500 micro dps * 2*pi/360 = 1091 micro radians per second */ micro_rad = (raw * 1091) >> range; val->val1 = micro_rad / 1000000; val->val2 = micro_rad % 1000000; } static int fxas21002_channel_get(const struct device *dev, enum sensor_channel chan, struct sensor_value *val) { const struct fxas21002_config *config = dev->config; struct fxas21002_data *data = dev->data; int start_channel; int num_channels; int16_t *raw; int ret; int i; k_sem_take(&data->sem, K_FOREVER); /* Start with an error return code by default, then clear it if we find * a supported sensor channel. */ ret = -ENOTSUP; /* Convert raw gyroscope data to the normalized sensor_value type. */ switch (chan) { case SENSOR_CHAN_GYRO_X: start_channel = FXAS21002_CHANNEL_GYRO_X; num_channels = 1; break; case SENSOR_CHAN_GYRO_Y: start_channel = FXAS21002_CHANNEL_GYRO_Y; num_channels = 1; break; case SENSOR_CHAN_GYRO_Z: start_channel = FXAS21002_CHANNEL_GYRO_Z; num_channels = 1; break; case SENSOR_CHAN_GYRO_XYZ: start_channel = FXAS21002_CHANNEL_GYRO_X; num_channels = 3; break; default: start_channel = 0; num_channels = 0; break; } raw = &data->raw[start_channel]; for (i = 0; i < num_channels; i++) { fxas21002_convert(val++, *raw++, config->range); } if (num_channels > 0) { ret = 0; } if (ret != 0) { LOG_ERR("Unsupported sensor channel"); } k_sem_give(&data->sem); return ret; } int fxas21002_get_power(const struct device *dev, enum fxas21002_power *power) { const struct fxas21002_config *config = dev->config; struct fxas21002_data *data = dev->data; uint8_t val = *power; if (i2c_reg_read_byte(data->i2c, config->i2c_address, FXAS21002_REG_CTRLREG1, &val)) { LOG_ERR("Could not get power setting"); return -EIO; } val &= FXAS21002_CTRLREG1_POWER_MASK; *power = val; return 0; } int fxas21002_set_power(const struct device *dev, enum fxas21002_power power) { const struct fxas21002_config *config = dev->config; struct fxas21002_data *data = dev->data; return i2c_reg_update_byte(data->i2c, config->i2c_address, FXAS21002_REG_CTRLREG1, FXAS21002_CTRLREG1_POWER_MASK, power); } uint32_t fxas21002_get_transition_time(enum fxas21002_power start, enum fxas21002_power end, uint8_t dr) { uint32_t transition_time; /* If not transitioning to active mode, then don't need to wait */ if (end != FXAS21002_POWER_ACTIVE) { return 0; } /* Otherwise, the transition time depends on which state we're * transitioning from. These times are defined by the datasheet. */ transition_time = sample_period[dr]; if (start == FXAS21002_POWER_READY) { transition_time += 5000U; } else { transition_time += 60000U; } return transition_time; } static int fxas21002_init(const struct device *dev) { const struct fxas21002_config *config = dev->config; struct fxas21002_data *data = dev->data; uint32_t transition_time; uint8_t whoami; uint8_t ctrlreg1; /* Get the I2C device */ data->i2c = device_get_binding(config->i2c_name); if (data->i2c == NULL) { LOG_ERR("Could not find I2C device"); return -EINVAL; } /* Read the WHOAMI register to make sure we are talking to FXAS21002 * and not some other type of device that happens to have the same I2C * address. */ if (i2c_reg_read_byte(data->i2c, config->i2c_address, FXAS21002_REG_WHOAMI, &whoami)) { LOG_ERR("Could not get WHOAMI value"); return -EIO; } if (whoami != config->whoami) { LOG_ERR("WHOAMI value received 0x%x, expected 0x%x", whoami, config->whoami); return -EIO; } /* Reset the sensor. Upon issuing a software reset command over the I2C * interface, the sensor immediately resets and does not send any * acknowledgment (ACK) of the written byte to the master. Therefore, * do not check the return code of the I2C transaction. */ i2c_reg_write_byte(data->i2c, config->i2c_address, FXAS21002_REG_CTRLREG1, FXAS21002_CTRLREG1_RST_MASK); /* Wait for the reset sequence to complete */ do { if (i2c_reg_read_byte(data->i2c, config->i2c_address, FXAS21002_REG_CTRLREG1, &ctrlreg1)) { LOG_ERR("Could not get ctrlreg1 value"); return -EIO; } } while (ctrlreg1 & FXAS21002_CTRLREG1_RST_MASK); /* Set the full-scale range */ if (i2c_reg_update_byte(data->i2c, config->i2c_address, FXAS21002_REG_CTRLREG0, FXAS21002_CTRLREG0_FS_MASK, config->range)) { LOG_ERR("Could not set range"); return -EIO; } /* Set the output data rate */ if (i2c_reg_update_byte(data->i2c, config->i2c_address, FXAS21002_REG_CTRLREG1, FXAS21002_CTRLREG1_DR_MASK, config->dr << FXAS21002_CTRLREG1_DR_SHIFT)) { LOG_ERR("Could not set output data rate"); return -EIO; } k_sem_init(&data->sem, 0, K_SEM_MAX_LIMIT); #if CONFIG_FXAS21002_TRIGGER if (fxas21002_trigger_init(dev)) { LOG_ERR("Could not initialize interrupts"); return -EIO; } #endif /* Set active */ if (fxas21002_set_power(dev, FXAS21002_POWER_ACTIVE)) { LOG_ERR("Could not set active"); return -EIO; } /* Wait the transition time from standby to active mode */ transition_time = fxas21002_get_transition_time(FXAS21002_POWER_STANDBY, FXAS21002_POWER_ACTIVE, config->dr); k_busy_wait(transition_time); k_sem_give(&data->sem); LOG_DBG("Init complete"); return 0; } static const struct sensor_driver_api fxas21002_driver_api = { .sample_fetch = fxas21002_sample_fetch, .channel_get = fxas21002_channel_get, #if CONFIG_FXAS21002_TRIGGER .trigger_set = fxas21002_trigger_set, #endif }; static const struct fxas21002_config fxas21002_config = { .i2c_name = DT_INST_BUS_LABEL(0), .i2c_address = DT_INST_REG_ADDR(0), .whoami = CONFIG_FXAS21002_WHOAMI, .range = CONFIG_FXAS21002_RANGE, .dr = CONFIG_FXAS21002_DR, #ifdef CONFIG_FXAS21002_TRIGGER #ifdef CONFIG_FXAS21002_DRDY_INT1 .gpio_name = DT_INST_GPIO_LABEL(0, int1_gpios), .gpio_pin = DT_INST_GPIO_PIN(0, int1_gpios), .gpio_flags = DT_INST_GPIO_FLAGS(0, int1_gpios), #else .gpio_name = DT_INST_GPIO_LABEL(0, int2_gpios), .gpio_pin = DT_INST_GPIO_PIN(0, int2_gpios), .gpio_flags = DT_INST_GPIO_FLAGS(0, int2_gpios), #endif #endif }; static struct fxas21002_data fxas21002_data; DEVICE_DT_INST_DEFINE(0, fxas21002_init, NULL, &fxas21002_data, &fxas21002_config, POST_KERNEL, CONFIG_SENSOR_INIT_PRIORITY, &fxas21002_driver_api);