drivers/sensor/bme680/bme680.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /* bme680.c - Driver for Bosch Sensortec's BME680 temperature, pressure,
  * humidity and gas sensor
  *
  * https://www.bosch-sensortec.com/bst/products/all_products/bme680
  */

 /*
  * Copyright (c) 2018 Bosch Sensortec GmbH
  * Copyright (c) 2022, Leonard Pollak
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <zephyr/drivers/gpio.h>
 #include <zephyr/init.h>
 #include <zephyr/kernel.h>
 #include <zephyr/sys/byteorder.h>
 #include <zephyr/sys/__assert.h>
 #include <zephyr/drivers/sensor.h>
 #include <zephyr/logging/log.h>

 #include "bme680.h"

 LOG_MODULE_REGISTER(bme680, CONFIG_SENSOR_LOG_LEVEL);


 #if BME680_BUS_SPI
 static inline bool bme680_is_on_spi(const struct device *dev)
 {
 	const struct bme680_config *config = dev->config;

 	return config->bus_io == &bme680_bus_io_spi;
 }
 #endif

 static inline int bme680_bus_check(const struct device *dev)
 {
 	const struct bme680_config *config = dev->config;

 	return config->bus_io->check(&config->bus);
 }

 static inline int bme680_reg_read(const struct device *dev,
 				  uint8_t start, uint8_t *buf, int size)
 {
 	const struct bme680_config *config = dev->config;

 	return config->bus_io->read(dev, start, buf, size);
 }

 static inline int bme680_reg_write(const struct device *dev, uint8_t reg,
 				   uint8_t val)
 {
 	const struct bme680_config *config = dev->config;

 	return config->bus_io->write(dev, reg, val);
 }

 static void bme680_calc_temp(struct bme680_data *data, uint32_t adc_temp)
 {
 	int64_t var1, var2, var3;

 	var1 = ((int32_t)adc_temp >> 3) - ((int32_t)data->par_t1 << 1);
 	var2 = (var1 * (int32_t)data->par_t2) >> 11;
 	var3 = ((var1 >> 1) * (var1 >> 1)) >> 12;
 	var3 = ((var3) * ((int32_t)data->par_t3 << 4)) >> 14;
 	data->t_fine = var2 + var3;
 	data->calc_temp = ((data->t_fine * 5) + 128) >> 8;
 }

 static void bme680_calc_press(struct bme680_data *data, uint32_t adc_press)
 {
 	int32_t var1, var2, var3, calc_press;

 	var1 = (((int32_t)data->t_fine) >> 1) - 64000;
 	var2 = ((((var1 >> 2) * (var1 >> 2)) >> 11) *
 		(int32_t)data->par_p6) >> 2;
 	var2 = var2 + ((var1 * (int32_t)data->par_p5) << 1);
 	var2 = (var2 >> 2) + ((int32_t)data->par_p4 << 16);
 	var1 = (((((var1 >> 2) * (var1 >> 2)) >> 13) *
 		 ((int32_t)data->par_p3 << 5)) >> 3)
 	       + (((int32_t)data->par_p2 * var1) >> 1);
 	var1 = var1 >> 18;
 	var1 = ((32768 + var1) * (int32_t)data->par_p1) >> 15;
 	calc_press = 1048576 - adc_press;
 	calc_press = (calc_press - (var2 >> 12)) * ((uint32_t)3125);
 	/* This max value is used to provide precedence to multiplication or
 	 * division in the pressure calculation equation to achieve least
 	 * loss of precision and avoiding overflows.
 	 * i.e Comparing value, signed int 32bit (1 << 30)
 	 */
 	if (calc_press >= (int32_t)0x40000000) {
 		calc_press = ((calc_press / var1) << 1);
 	} else {
 		calc_press = ((calc_press << 1) / var1);
 	}
 	var1 = ((int32_t)data->par_p9 *
 		(int32_t)(((calc_press >> 3)
 			 * (calc_press >> 3)) >> 13)) >> 12;
 	var2 = ((int32_t)(calc_press >> 2) * (int32_t)data->par_p8) >> 13;
 	var3 = ((int32_t)(calc_press >> 8) * (int32_t)(calc_press >> 8)
 		* (int32_t)(calc_press >> 8)
 		* (int32_t)data->par_p10) >> 17;

 	data->calc_press = calc_press
 			   + ((var1 + var2 + var3
 			       + ((int32_t)data->par_p7 << 7)) >> 4);
 }

 static void bme680_calc_humidity(struct bme680_data *data, uint16_t adc_humidity)
 {
 	int32_t var1, var2_1, var2_2, var2, var3, var4, var5, var6;
 	int32_t temp_scaled, calc_hum;

 	temp_scaled = (((int32_t)data->t_fine * 5) + 128) >> 8;
 	var1 = (int32_t)(adc_humidity - ((int32_t)((int32_t)data->par_h1 * 16))) -
 	       (((temp_scaled * (int32_t)data->par_h3)
 		 / ((int32_t)100)) >> 1);
 	var2_1 = (int32_t)data->par_h2;
 	var2_2 = ((temp_scaled * (int32_t)data->par_h4) / (int32_t)100)
 		 + (((temp_scaled * ((temp_scaled * (int32_t)data->par_h5)
 				     / ((int32_t)100))) >> 6) / ((int32_t)100))
 		 +  (int32_t)(1 << 14);
 	var2 = (var2_1 * var2_2) >> 10;
 	var3 = var1 * var2;
 	var4 = (int32_t)data->par_h6 << 7;
 	var4 = ((var4) + ((temp_scaled * (int32_t)data->par_h7) /
 			  ((int32_t)100))) >> 4;
 	var5 = ((var3 >> 14) * (var3 >> 14)) >> 10;
 	var6 = (var4 * var5) >> 1;
 	calc_hum = (((var3 + var6) >> 10) * ((int32_t)1000)) >> 12;

 	if (calc_hum > 100000) { /* Cap at 100%rH */
 		calc_hum = 100000;
 	} else if (calc_hum < 0) {
 		calc_hum = 0;
 	}

 	data->calc_humidity = calc_hum;
 }

 static void bme680_calc_gas_resistance(struct bme680_data *data, uint8_t gas_range,
 				       uint16_t adc_gas_res)
 {
 	int64_t var1, var3;
 	uint64_t var2;

 	static const uint32_t look_up1[16] = { 2147483647, 2147483647, 2147483647,
 			       2147483647, 2147483647, 2126008810, 2147483647,
 			       2130303777, 2147483647, 2147483647, 2143188679,
 			       2136746228, 2147483647, 2126008810, 2147483647,
 			       2147483647 };

 	static const uint32_t look_up2[16] = { 4096000000, 2048000000, 1024000000,
 			       512000000, 255744255, 127110228, 64000000,
 			       32258064, 16016016, 8000000, 4000000, 2000000,
 			       1000000, 500000, 250000, 125000 };

 	var1 = (int64_t)((1340 + (5 * (int64_t)data->range_sw_err)) *
 		       ((int64_t)look_up1[gas_range])) >> 16;
 	var2 = (((int64_t)((int64_t)adc_gas_res << 15) - (int64_t)(16777216)) + var1);
 	var3 = (((int64_t)look_up2[gas_range] * (int64_t)var1) >> 9);
 	data->calc_gas_resistance = (uint32_t)((var3 + ((int64_t)var2 >> 1))
 					    / (int64_t)var2);
 }

 static uint8_t bme680_calc_res_heat(struct bme680_data *data, uint16_t heatr_temp)
 {
 	uint8_t heatr_res;
 	int32_t var1, var2, var3, var4, var5;
 	int32_t heatr_res_x100;
 	int32_t amb_temp = 25;    /* Assume ambient temperature to be 25 deg C */

 	if (heatr_temp > 400) { /* Cap temperature */
 		heatr_temp = 400;
 	}

 	var1 = ((amb_temp * data->par_gh3) / 1000) * 256;
 	var2 = (data->par_gh1 + 784) * (((((data->par_gh2 + 154009)
 					   * heatr_temp * 5) / 100)
 					 + 3276800) / 10);
 	var3 = var1 + (var2 / 2);
 	var4 = (var3 / (data->res_heat_range + 4));
 	var5 = (131 * data->res_heat_val) + 65536;
 	heatr_res_x100 = ((var4 / var5) - 250) * 34;
 	heatr_res = (heatr_res_x100 + 50) / 100;

 	return heatr_res;
 }

 static uint8_t bme680_calc_gas_wait(uint16_t dur)
 {
 	uint8_t factor = 0, durval;

 	if (dur >= 0xfc0) {
 		durval = 0xff; /* Max duration*/
 	} else {
 		while (dur > 0x3F) {
 			dur = dur / 4;
 			factor += 1;
 		}
 		durval = dur + (factor * 64);
 	}

 	return durval;
 }

 static int bme680_sample_fetch(const struct device *dev,
 			       enum sensor_channel chan)
 {
 	struct bme680_data *data = dev->data;
 	uint8_t buff[BME680_LEN_FIELD] = { 0 };
 	uint8_t gas_range;
 	uint32_t adc_temp, adc_press;
 	uint16_t adc_hum, adc_gas_res;
 	int size = BME680_LEN_FIELD;
 	int ret;

 	__ASSERT_NO_MSG(chan == SENSOR_CHAN_ALL);

 	ret = bme680_reg_read(dev, BME680_REG_FIELD0, buff, size);
 	if (ret < 0) {
 		return ret;
 	}

 	data->new_data = buff[0] & BME680_MSK_NEW_DATA;
 	data->heatr_stab = buff[14] & BME680_MSK_HEATR_STAB;

 	adc_press = (uint32_t)(((uint32_t)buff[2] << 12) | ((uint32_t)buff[3] << 4)
 			    | ((uint32_t)buff[4] >> 4));
 	adc_temp = (uint32_t)(((uint32_t)buff[5] << 12) | ((uint32_t)buff[6] << 4)
 			   | ((uint32_t)buff[7] >> 4));
 	adc_hum = (uint16_t)(((uint32_t)buff[8] << 8) | (uint32_t)buff[9]);
 	adc_gas_res = (uint16_t)((uint32_t)buff[13] << 2 | (((uint32_t)buff[14]) >> 6));
 	gas_range = buff[14] & BME680_MSK_GAS_RANGE;

 	if (data->new_data) {
 		bme680_calc_temp(data, adc_temp);
 		bme680_calc_press(data, adc_press);
 		bme680_calc_humidity(data, adc_hum);
 		bme680_calc_gas_resistance(data, gas_range, adc_gas_res);
 	}

 	/* Trigger the next measurement */
 	ret = bme680_reg_write(dev, BME680_REG_CTRL_MEAS,
 			       BME680_CTRL_MEAS_VAL);
 	if (ret < 0) {
 		return ret;
 	}

 	return 0;
 }

 static int bme680_channel_get(const struct device *dev,
 			      enum sensor_channel chan,
 			      struct sensor_value *val)
 {
 	struct bme680_data *data = dev->data;

 	switch (chan) {
 	case SENSOR_CHAN_AMBIENT_TEMP:
 		/*
 		 * data->calc_temp has a resolution of 0.01 degC.
 		 * So 5123 equals 51.23 degC.
 		 */
 		val->val1 = data->calc_temp / 100;
 		val->val2 = data->calc_temp % 100 * 10000;
 		break;
 	case SENSOR_CHAN_PRESS:
 		/*
 		 * data->calc_press has a resolution of 1 Pa.
 		 * So 96321 equals 96.321 kPa.
 		 */
 		val->val1 = data->calc_press / 1000;
 		val->val2 = (data->calc_press % 1000) * 1000;
 		break;
 	case SENSOR_CHAN_HUMIDITY:
 		/*
 		 * data->calc_humidity has a resolution of 0.001 %RH.
 		 * So 46333 equals 46.333 %RH.
 		 */
 		val->val1 = data->calc_humidity / 1000;
 		val->val2 = (data->calc_humidity % 1000) * 1000;
 		break;
 	case SENSOR_CHAN_GAS_RES:
 		/*
 		 * data->calc_gas_resistance has a resolution of 1 ohm.
 		 * So 100000 equals 100000 ohms.
 		 */
 		val->val1 = data->calc_gas_resistance;
 		val->val2 = 0;
 		break;
 	default:
 		return -EINVAL;
 	}

 	return 0;
 }

 static int bme680_read_compensation(const struct device *dev)
 {
 	struct bme680_data *data = dev->data;
 	uint8_t buff[BME680_LEN_COEFF_ALL];
 	int err = 0;

 	err = bme680_reg_read(dev, BME680_REG_COEFF1, buff, BME680_LEN_COEFF1);
 	if (err < 0) {
 		return err;
 	}

 	err = bme680_reg_read(dev, BME680_REG_COEFF2, &buff[BME680_LEN_COEFF1],
 			      BME680_LEN_COEFF2);
 	if (err < 0) {
 		return err;
 	}

 	err = bme680_reg_read(dev, BME680_REG_COEFF3,
 			      &buff[BME680_LEN_COEFF1 + BME680_LEN_COEFF2],
 			      BME680_LEN_COEFF3);
 	if (err < 0) {
 		return err;
 	}

 	/* Temperature related coefficients */
 	data->par_t1 = (uint16_t)(BME680_CONCAT_BYTES(buff[32], buff[31]));
 	data->par_t2 = (int16_t)(BME680_CONCAT_BYTES(buff[1], buff[0]));
 	data->par_t3 = (uint8_t)(buff[2]);

 	/* Pressure related coefficients */
 	data->par_p1 = (uint16_t)(BME680_CONCAT_BYTES(buff[5], buff[4]));
 	data->par_p2 = (int16_t)(BME680_CONCAT_BYTES(buff[7], buff[6]));
 	data->par_p3 = (int8_t)buff[8];
 	data->par_p4 = (int16_t)(BME680_CONCAT_BYTES(buff[11], buff[10]));
 	data->par_p5 = (int16_t)(BME680_CONCAT_BYTES(buff[13], buff[12]));
 	data->par_p6 = (int8_t)(buff[15]);
 	data->par_p7 = (int8_t)(buff[14]);
 	data->par_p8 = (int16_t)(BME680_CONCAT_BYTES(buff[19], buff[18]));
 	data->par_p9 = (int16_t)(BME680_CONCAT_BYTES(buff[21], buff[20]));
 	data->par_p10 = (uint8_t)(buff[22]);

 	/* Humidity related coefficients */
 	data->par_h1 = (uint16_t)(((uint16_t)buff[25] << 4) | (buff[24] & 0x0f));
 	data->par_h2 = (uint16_t)(((uint16_t)buff[23] << 4) | ((buff[24]) >> 4));
 	data->par_h3 = (int8_t)buff[26];
 	data->par_h4 = (int8_t)buff[27];
 	data->par_h5 = (int8_t)buff[28];
 	data->par_h6 = (uint8_t)buff[29];
 	data->par_h7 = (int8_t)buff[30];

 	/* Gas heater related coefficients */
 	data->par_gh1 = (int8_t)buff[35];
 	data->par_gh2 = (int16_t)(BME680_CONCAT_BYTES(buff[34], buff[33]));
 	data->par_gh3 = (int8_t)buff[36];

 	data->res_heat_val = (int8_t)buff[37];
 	data->res_heat_range = ((buff[39] & BME680_MSK_RH_RANGE) >> 4);
 	data->range_sw_err = ((int8_t)(buff[41] & BME680_MSK_RANGE_SW_ERR)) / 16;

 	return 0;
 }

 static int bme680_init(const struct device *dev)
 {
 	struct bme680_data *data = dev->data;
 	int err;

 	err = bme680_bus_check(dev);
 	if (err < 0) {
 		LOG_ERR("Bus not ready for '%s'", dev->name);
 		return err;
 	}

 #if BME680_BUS_SPI
 	if (bme680_is_on_spi(dev)) {
 		err = bme680_reg_read(dev, BME680_REG_MEM_PAGE, &data->mem_page, 1);
 		if (err < 0) {
 			return err;
 		}
 	}
 #endif

 	err = bme680_reg_read(dev, BME680_REG_CHIP_ID, &data->chip_id, 1);
 	if (err < 0) {
 		return err;
 	}

 	if (data->chip_id == BME680_CHIP_ID) {
 		LOG_DBG("BME680 chip detected");
 	} else {
 		LOG_ERR("Bad BME680 chip id: 0x%x", data->chip_id);
 		return -ENOTSUP;
 	}

 	err = bme680_read_compensation(dev);
 	if (err < 0) {
 		return err;
 	}

 	err = bme680_reg_write(dev, BME680_REG_CTRL_HUM, BME680_HUMIDITY_OVER);
 	if (err < 0) {
 		return err;
 	}

 	err = bme680_reg_write(dev, BME680_REG_CONFIG, BME680_CONFIG_VAL);
 	if (err < 0) {
 		return err;
 	}

 	err = bme680_reg_write(dev, BME680_REG_CTRL_GAS_1,
 			       BME680_CTRL_GAS_1_VAL);
 	if (err < 0) {
 		return err;
 	}

 	err = bme680_reg_write(dev, BME680_REG_RES_HEAT0,
 			       bme680_calc_res_heat(data, BME680_HEATR_TEMP));
 	if (err < 0) {
 		return err;
 	}

 	err = bme680_reg_write(dev, BME680_REG_GAS_WAIT0,
 			       bme680_calc_gas_wait(BME680_HEATR_DUR_MS));
 	if (err < 0) {
 		return err;
 	}

 	err = bme680_reg_write(dev, BME680_REG_CTRL_MEAS,
 			       BME680_CTRL_MEAS_VAL);

 	return err;
 }

 static const struct sensor_driver_api bme680_api_funcs = {
 	.sample_fetch = bme680_sample_fetch,
 	.channel_get = bme680_channel_get,
 };

 /* Initializes a struct bme680_config for an instance on a SPI bus. */
 #define BME680_CONFIG_SPI(inst)				\
 	{						\
 		.bus.spi = SPI_DT_SPEC_INST_GET(	\
 			inst, BME680_SPI_OPERATION, 0),	\
 		.bus_io = &bme680_bus_io_spi,		\
 	}

 /* Initializes a struct bme680_config for an instance on an I2C bus. */
 #define BME680_CONFIG_I2C(inst)			       \
 	{					       \
 		.bus.i2c = I2C_DT_SPEC_INST_GET(inst), \
 		.bus_io = &bme680_bus_io_i2c,	       \
 	}

 /*
  * Main instantiation macro, which selects the correct bus-specific
  * instantiation macros for the instance.
  */
 #define BME680_DEFINE(inst)						\
 	static struct bme680_data bme680_data_##inst;			\
 	static const struct bme680_config bme680_config_##inst =	\
 		COND_CODE_1(DT_INST_ON_BUS(inst, spi),			\
 			    (BME680_CONFIG_SPI(inst)),			\
 			    (BME680_CONFIG_I2C(inst)));			\
 	DEVICE_DT_INST_DEFINE(inst,					\
 			 bme680_init,					\
 			 NULL,						\
 			 &bme680_data_##inst,				\
 			 &bme680_config_##inst,				\
 			 POST_KERNEL,					\
 			 CONFIG_SENSOR_INIT_PRIORITY,			\
 			 &bme680_api_funcs);

 /* Create the struct device for every status "okay" node in the devicetree. */
 DT_INST_FOREACH_STATUS_OKAY(BME680_DEFINE)
	/* bme680.c - Driver for Bosch Sensortec's BME680 temperature, pressure,
	* humidity and gas sensor
	*
	* https://www.bosch-sensortec.com/bst/products/all_products/bme680
	*/

	/*
	* Copyright (c) 2018 Bosch Sensortec GmbH
	* Copyright (c) 2022, Leonard Pollak
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <zephyr/drivers/gpio.h>
	#include <zephyr/init.h>
	#include <zephyr/kernel.h>
	#include <zephyr/sys/byteorder.h>
	#include <zephyr/sys/__assert.h>
	#include <zephyr/drivers/sensor.h>
	#include <zephyr/logging/log.h>

	#include "bme680.h"

	LOG_MODULE_REGISTER(bme680, CONFIG_SENSOR_LOG_LEVEL);


	#if BME680_BUS_SPI
	static inline bool bme680_is_on_spi(const struct device *dev)
	{
	const struct bme680_config *config = dev->config;

	return config->bus_io == &bme680_bus_io_spi;
	}
	#endif

	static inline int bme680_bus_check(const struct device *dev)
	{
	const struct bme680_config *config = dev->config;

	return config->bus_io->check(&config->bus);
	}

	static inline int bme680_reg_read(const struct device *dev,
	uint8_t start, uint8_t *buf, int size)
	{
	const struct bme680_config *config = dev->config;

	return config->bus_io->read(dev, start, buf, size);
	}

	static inline int bme680_reg_write(const struct device *dev, uint8_t reg,
	uint8_t val)
	{
	const struct bme680_config *config = dev->config;

	return config->bus_io->write(dev, reg, val);
	}

	static void bme680_calc_temp(struct bme680_data *data, uint32_t adc_temp)
	{
	int64_t var1, var2, var3;

	var1 = ((int32_t)adc_temp >> 3) - ((int32_t)data->par_t1 << 1);
	var2 = (var1 * (int32_t)data->par_t2) >> 11;
	var3 = ((var1 >> 1) * (var1 >> 1)) >> 12;
	var3 = ((var3) * ((int32_t)data->par_t3 << 4)) >> 14;
	data->t_fine = var2 + var3;
	data->calc_temp = ((data->t_fine * 5) + 128) >> 8;
	}

	static void bme680_calc_press(struct bme680_data *data, uint32_t adc_press)
	{
	int32_t var1, var2, var3, calc_press;

	var1 = (((int32_t)data->t_fine) >> 1) - 64000;
	var2 = ((((var1 >> 2) * (var1 >> 2)) >> 11) *
	(int32_t)data->par_p6) >> 2;
	var2 = var2 + ((var1 * (int32_t)data->par_p5) << 1);
	var2 = (var2 >> 2) + ((int32_t)data->par_p4 << 16);
	var1 = (((((var1 >> 2) * (var1 >> 2)) >> 13) *
	((int32_t)data->par_p3 << 5)) >> 3)
	+ (((int32_t)data->par_p2 * var1) >> 1);
	var1 = var1 >> 18;
	var1 = ((32768 + var1) * (int32_t)data->par_p1) >> 15;
	calc_press = 1048576 - adc_press;
	calc_press = (calc_press - (var2 >> 12)) * ((uint32_t)3125);
	/* This max value is used to provide precedence to multiplication or
	* division in the pressure calculation equation to achieve least
	* loss of precision and avoiding overflows.
	* i.e Comparing value, signed int 32bit (1 << 30)
	*/
	if (calc_press >= (int32_t)0x40000000) {
	calc_press = ((calc_press / var1) << 1);
	} else {
	calc_press = ((calc_press << 1) / var1);
	}
	var1 = ((int32_t)data->par_p9 *
	(int32_t)(((calc_press >> 3)
	* (calc_press >> 3)) >> 13)) >> 12;
	var2 = ((int32_t)(calc_press >> 2) * (int32_t)data->par_p8) >> 13;
	var3 = ((int32_t)(calc_press >> 8) * (int32_t)(calc_press >> 8)
	* (int32_t)(calc_press >> 8)
	* (int32_t)data->par_p10) >> 17;

	data->calc_press = calc_press
	+ ((var1 + var2 + var3
	+ ((int32_t)data->par_p7 << 7)) >> 4);
	}

	static void bme680_calc_humidity(struct bme680_data *data, uint16_t adc_humidity)
	{
	int32_t var1, var2_1, var2_2, var2, var3, var4, var5, var6;
	int32_t temp_scaled, calc_hum;

	temp_scaled = (((int32_t)data->t_fine * 5) + 128) >> 8;
	var1 = (int32_t)(adc_humidity - ((int32_t)((int32_t)data->par_h1 * 16))) -
	(((temp_scaled * (int32_t)data->par_h3)
	/ ((int32_t)100)) >> 1);
	var2_1 = (int32_t)data->par_h2;
	var2_2 = ((temp_scaled * (int32_t)data->par_h4) / (int32_t)100)
	+ (((temp_scaled * ((temp_scaled * (int32_t)data->par_h5)
	/ ((int32_t)100))) >> 6) / ((int32_t)100))
	+ (int32_t)(1 << 14);
	var2 = (var2_1 * var2_2) >> 10;
	var3 = var1 * var2;
	var4 = (int32_t)data->par_h6 << 7;
	var4 = ((var4) + ((temp_scaled * (int32_t)data->par_h7) /
	((int32_t)100))) >> 4;
	var5 = ((var3 >> 14) * (var3 >> 14)) >> 10;
	var6 = (var4 * var5) >> 1;
	calc_hum = (((var3 + var6) >> 10) * ((int32_t)1000)) >> 12;

	if (calc_hum > 100000) { /* Cap at 100%rH */
	calc_hum = 100000;
	} else if (calc_hum < 0) {
	calc_hum = 0;
	}

	data->calc_humidity = calc_hum;
	}

	static void bme680_calc_gas_resistance(struct bme680_data *data, uint8_t gas_range,
	uint16_t adc_gas_res)
	{
	int64_t var1, var3;
	uint64_t var2;

	static const uint32_t look_up1[16] = { 2147483647, 2147483647, 2147483647,
	2147483647, 2147483647, 2126008810, 2147483647,
	2130303777, 2147483647, 2147483647, 2143188679,
	2136746228, 2147483647, 2126008810, 2147483647,
	2147483647 };

	static const uint32_t look_up2[16] = { 4096000000, 2048000000, 1024000000,
	512000000, 255744255, 127110228, 64000000,
	32258064, 16016016, 8000000, 4000000, 2000000,
	1000000, 500000, 250000, 125000 };

	var1 = (int64_t)((1340 + (5 * (int64_t)data->range_sw_err)) *
	((int64_t)look_up1[gas_range])) >> 16;
	var2 = (((int64_t)((int64_t)adc_gas_res << 15) - (int64_t)(16777216)) + var1);
	var3 = (((int64_t)look_up2[gas_range] * (int64_t)var1) >> 9);
	data->calc_gas_resistance = (uint32_t)((var3 + ((int64_t)var2 >> 1))
	/ (int64_t)var2);
	}

	static uint8_t bme680_calc_res_heat(struct bme680_data *data, uint16_t heatr_temp)
	{
	uint8_t heatr_res;
	int32_t var1, var2, var3, var4, var5;
	int32_t heatr_res_x100;
	int32_t amb_temp = 25; /* Assume ambient temperature to be 25 deg C */

	if (heatr_temp > 400) { /* Cap temperature */
	heatr_temp = 400;
	}

	var1 = ((amb_temp * data->par_gh3) / 1000) * 256;
	var2 = (data->par_gh1 + 784) * (((((data->par_gh2 + 154009)
	* heatr_temp * 5) / 100)
	+ 3276800) / 10);
	var3 = var1 + (var2 / 2);
	var4 = (var3 / (data->res_heat_range + 4));
	var5 = (131 * data->res_heat_val) + 65536;
	heatr_res_x100 = ((var4 / var5) - 250) * 34;
	heatr_res = (heatr_res_x100 + 50) / 100;

	return heatr_res;
	}

	static uint8_t bme680_calc_gas_wait(uint16_t dur)
	{
	uint8_t factor = 0, durval;

	if (dur >= 0xfc0) {
	durval = 0xff; /* Max duration*/
	} else {
	while (dur > 0x3F) {
	dur = dur / 4;
	factor += 1;
	}
	durval = dur + (factor * 64);
	}

	return durval;
	}

	static int bme680_sample_fetch(const struct device *dev,
	enum sensor_channel chan)
	{
	struct bme680_data *data = dev->data;
	uint8_t buff[BME680_LEN_FIELD] = { 0 };
	uint8_t gas_range;
	uint32_t adc_temp, adc_press;
	uint16_t adc_hum, adc_gas_res;
	int size = BME680_LEN_FIELD;
	int ret;

	__ASSERT_NO_MSG(chan == SENSOR_CHAN_ALL);

	ret = bme680_reg_read(dev, BME680_REG_FIELD0, buff, size);
	if (ret < 0) {
	return ret;
	}

	data->new_data = buff[0] & BME680_MSK_NEW_DATA;
	data->heatr_stab = buff[14] & BME680_MSK_HEATR_STAB;

	adc_press = (uint32_t)(((uint32_t)buff[2] << 12) \| ((uint32_t)buff[3] << 4)
	\| ((uint32_t)buff[4] >> 4));
	adc_temp = (uint32_t)(((uint32_t)buff[5] << 12) \| ((uint32_t)buff[6] << 4)
	\| ((uint32_t)buff[7] >> 4));
	adc_hum = (uint16_t)(((uint32_t)buff[8] << 8) \| (uint32_t)buff[9]);
	adc_gas_res = (uint16_t)((uint32_t)buff[13] << 2 \| (((uint32_t)buff[14]) >> 6));
	gas_range = buff[14] & BME680_MSK_GAS_RANGE;

	if (data->new_data) {
	bme680_calc_temp(data, adc_temp);
	bme680_calc_press(data, adc_press);
	bme680_calc_humidity(data, adc_hum);
	bme680_calc_gas_resistance(data, gas_range, adc_gas_res);
	}

	/* Trigger the next measurement */
	ret = bme680_reg_write(dev, BME680_REG_CTRL_MEAS,
	BME680_CTRL_MEAS_VAL);
	if (ret < 0) {
	return ret;
	}

	return 0;
	}

	static int bme680_channel_get(const struct device *dev,
	enum sensor_channel chan,
	struct sensor_value *val)
	{
	struct bme680_data *data = dev->data;

	switch (chan) {
	case SENSOR_CHAN_AMBIENT_TEMP:
	/*
	* data->calc_temp has a resolution of 0.01 degC.
	* So 5123 equals 51.23 degC.
	*/
	val->val1 = data->calc_temp / 100;
	val->val2 = data->calc_temp % 100 * 10000;
	break;
	case SENSOR_CHAN_PRESS:
	/*
	* data->calc_press has a resolution of 1 Pa.
	* So 96321 equals 96.321 kPa.
	*/
	val->val1 = data->calc_press / 1000;
	val->val2 = (data->calc_press % 1000) * 1000;
	break;
	case SENSOR_CHAN_HUMIDITY:
	/*
	* data->calc_humidity has a resolution of 0.001 %RH.
	* So 46333 equals 46.333 %RH.
	*/
	val->val1 = data->calc_humidity / 1000;
	val->val2 = (data->calc_humidity % 1000) * 1000;
	break;
	case SENSOR_CHAN_GAS_RES:
	/*
	* data->calc_gas_resistance has a resolution of 1 ohm.
	* So 100000 equals 100000 ohms.
	*/
	val->val1 = data->calc_gas_resistance;
	val->val2 = 0;
	break;
	default:
	return -EINVAL;
	}

	return 0;
	}

	static int bme680_read_compensation(const struct device *dev)
	{
	struct bme680_data *data = dev->data;
	uint8_t buff[BME680_LEN_COEFF_ALL];
	int err = 0;

	err = bme680_reg_read(dev, BME680_REG_COEFF1, buff, BME680_LEN_COEFF1);
	if (err < 0) {
	return err;
	}

	err = bme680_reg_read(dev, BME680_REG_COEFF2, &buff[BME680_LEN_COEFF1],
	BME680_LEN_COEFF2);
	if (err < 0) {
	return err;
	}

	err = bme680_reg_read(dev, BME680_REG_COEFF3,
	&buff[BME680_LEN_COEFF1 + BME680_LEN_COEFF2],
	BME680_LEN_COEFF3);
	if (err < 0) {
	return err;
	}

	/* Temperature related coefficients */
	data->par_t1 = (uint16_t)(BME680_CONCAT_BYTES(buff[32], buff[31]));
	data->par_t2 = (int16_t)(BME680_CONCAT_BYTES(buff[1], buff[0]));
	data->par_t3 = (uint8_t)(buff[2]);

	/* Pressure related coefficients */
	data->par_p1 = (uint16_t)(BME680_CONCAT_BYTES(buff[5], buff[4]));
	data->par_p2 = (int16_t)(BME680_CONCAT_BYTES(buff[7], buff[6]));
	data->par_p3 = (int8_t)buff[8];
	data->par_p4 = (int16_t)(BME680_CONCAT_BYTES(buff[11], buff[10]));
	data->par_p5 = (int16_t)(BME680_CONCAT_BYTES(buff[13], buff[12]));
	data->par_p6 = (int8_t)(buff[15]);
	data->par_p7 = (int8_t)(buff[14]);
	data->par_p8 = (int16_t)(BME680_CONCAT_BYTES(buff[19], buff[18]));
	data->par_p9 = (int16_t)(BME680_CONCAT_BYTES(buff[21], buff[20]));
	data->par_p10 = (uint8_t)(buff[22]);

	/* Humidity related coefficients */
	data->par_h1 = (uint16_t)(((uint16_t)buff[25] << 4) \| (buff[24] & 0x0f));
	data->par_h2 = (uint16_t)(((uint16_t)buff[23] << 4) \| ((buff[24]) >> 4));
	data->par_h3 = (int8_t)buff[26];
	data->par_h4 = (int8_t)buff[27];
	data->par_h5 = (int8_t)buff[28];
	data->par_h6 = (uint8_t)buff[29];
	data->par_h7 = (int8_t)buff[30];

	/* Gas heater related coefficients */
	data->par_gh1 = (int8_t)buff[35];
	data->par_gh2 = (int16_t)(BME680_CONCAT_BYTES(buff[34], buff[33]));
	data->par_gh3 = (int8_t)buff[36];

	data->res_heat_val = (int8_t)buff[37];
	data->res_heat_range = ((buff[39] & BME680_MSK_RH_RANGE) >> 4);
	data->range_sw_err = ((int8_t)(buff[41] & BME680_MSK_RANGE_SW_ERR)) / 16;

	return 0;
	}

	static int bme680_init(const struct device *dev)
	{
	struct bme680_data *data = dev->data;
	int err;

	err = bme680_bus_check(dev);
	if (err < 0) {
	LOG_ERR("Bus not ready for '%s'", dev->name);
	return err;
	}

	#if BME680_BUS_SPI
	if (bme680_is_on_spi(dev)) {
	err = bme680_reg_read(dev, BME680_REG_MEM_PAGE, &data->mem_page, 1);
	if (err < 0) {
	return err;
	}
	}
	#endif

	err = bme680_reg_read(dev, BME680_REG_CHIP_ID, &data->chip_id, 1);
	if (err < 0) {
	return err;
	}

	if (data->chip_id == BME680_CHIP_ID) {
	LOG_DBG("BME680 chip detected");
	} else {
	LOG_ERR("Bad BME680 chip id: 0x%x", data->chip_id);
	return -ENOTSUP;
	}

	err = bme680_read_compensation(dev);
	if (err < 0) {
	return err;
	}

	err = bme680_reg_write(dev, BME680_REG_CTRL_HUM, BME680_HUMIDITY_OVER);
	if (err < 0) {
	return err;
	}

	err = bme680_reg_write(dev, BME680_REG_CONFIG, BME680_CONFIG_VAL);
	if (err < 0) {
	return err;
	}

	err = bme680_reg_write(dev, BME680_REG_CTRL_GAS_1,
	BME680_CTRL_GAS_1_VAL);
	if (err < 0) {
	return err;
	}

	err = bme680_reg_write(dev, BME680_REG_RES_HEAT0,
	bme680_calc_res_heat(data, BME680_HEATR_TEMP));
	if (err < 0) {
	return err;
	}

	err = bme680_reg_write(dev, BME680_REG_GAS_WAIT0,
	bme680_calc_gas_wait(BME680_HEATR_DUR_MS));
	if (err < 0) {
	return err;
	}

	err = bme680_reg_write(dev, BME680_REG_CTRL_MEAS,
	BME680_CTRL_MEAS_VAL);

	return err;
	}

	static const struct sensor_driver_api bme680_api_funcs = {
	.sample_fetch = bme680_sample_fetch,
	.channel_get = bme680_channel_get,
	};

	/* Initializes a struct bme680_config for an instance on a SPI bus. */
	#define BME680_CONFIG_SPI(inst) \
	{ \
	.bus.spi = SPI_DT_SPEC_INST_GET( \
	inst, BME680_SPI_OPERATION, 0), \
	.bus_io = &bme680_bus_io_spi, \
	}

	/* Initializes a struct bme680_config for an instance on an I2C bus. */
	#define BME680_CONFIG_I2C(inst) \
	{ \
	.bus.i2c = I2C_DT_SPEC_INST_GET(inst), \
	.bus_io = &bme680_bus_io_i2c, \
	}

	/*
	* Main instantiation macro, which selects the correct bus-specific
	* instantiation macros for the instance.
	*/
	#define BME680_DEFINE(inst) \
	static struct bme680_data bme680_data_##inst; \
	static const struct bme680_config bme680_config_##inst = \
	COND_CODE_1(DT_INST_ON_BUS(inst, spi), \
	(BME680_CONFIG_SPI(inst)), \
	(BME680_CONFIG_I2C(inst))); \
	DEVICE_DT_INST_DEFINE(inst, \
	bme680_init, \
	NULL, \
	&bme680_data_##inst, \
	&bme680_config_##inst, \
	POST_KERNEL, \
	CONFIG_SENSOR_INIT_PRIORITY, \
	&bme680_api_funcs);

	/* Create the struct device for every status "okay" node in the devicetree. */
	DT_INST_FOREACH_STATUS_OKAY(BME680_DEFINE)