From a5c6adc46d696233bc67e25ac2146173dd6ee8b2 Mon Sep 17 00:00:00 2001 From: Daniel Friesel Date: Mon, 23 Sep 2019 12:53:07 +0200 Subject: Add Bosch SensorTec BME680 driver + utilities --- src/driver/bme680.cc | 1367 +++++++++++++++++++++++++++++++++++++++++++++ src/driver/bme680_util.cc | 27 + 2 files changed, 1394 insertions(+) create mode 100644 src/driver/bme680.cc create mode 100644 src/driver/bme680_util.cc (limited to 'src/driver') diff --git a/src/driver/bme680.cc b/src/driver/bme680.cc new file mode 100644 index 0000000..9469c8f --- /dev/null +++ b/src/driver/bme680.cc @@ -0,0 +1,1367 @@ +/**\mainpage + * Copyright (C) 2017 - 2018 Bosch Sensortec GmbH + * + * Redistribution and use in source and binary forms, with or without + * modification, are permitted provided that the following conditions are met: + * + * Redistributions of source code must retain the above copyright + * notice, this list of conditions and the following disclaimer. + * + * Redistributions in binary form must reproduce the above copyright + * notice, this list of conditions and the following disclaimer in the + * documentation and/or other materials provided with the distribution. + * + * Neither the name of the copyright holder nor the names of the + * contributors may be used to endorse or promote products derived from + * this software without specific prior written permission. + * + * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND + * CONTRIBUTORS "AS IS" AND ANY EXPRESS OR + * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED + * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE + * DISCLAIMED. IN NO EVENT SHALL COPYRIGHT HOLDER + * OR CONTRIBUTORS BE LIABLE FOR ANY + * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, + * OR CONSEQUENTIAL DAMAGES(INCLUDING, BUT NOT LIMITED TO, + * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; + * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) + * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, + * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT + * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN + * ANY WAY OUT OF THE USE OF THIS + * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE + * + * The information provided is believed to be accurate and reliable. + * The copyright holder assumes no responsibility + * for the consequences of use + * of such information nor for any infringement of patents or + * other rights of third parties which may result from its use. + * No license is granted by implication or otherwise under any patent or + * patent rights of the copyright holder. + * + * File bme680.c + * @date 19 Jun 2018 + * @version 3.5.9 + * + */ + +/*! @file bme680.c + @brief Sensor driver for BME680 sensor */ +#include "driver/bme680.h" + +/*! + * @brief This internal API is used to read the calibrated data from the sensor. + * + * This function is used to retrieve the calibration + * data from the image registers of the sensor. + * + * @note Registers 89h to A1h for calibration data 1 to 24 + * from bit 0 to 7 + * @note Registers E1h to F0h for calibration data 25 to 40 + * from bit 0 to 7 + * @param[in] dev :Structure instance of bme680_dev. + * + * @return Result of API execution status. + * @retval zero -> Success / +ve value -> Warning / -ve value -> Error + */ +static int8_t get_calib_data(struct bme680_dev *dev); + +/*! + * @brief This internal API is used to set the gas configuration of the sensor. + * + * @param[in] dev :Structure instance of bme680_dev. + * + * @return Result of API execution status. + * @retval zero -> Success / +ve value -> Warning / -ve value -> Error + */ +static int8_t set_gas_config(struct bme680_dev *dev); + +/*! + * @brief This internal API is used to get the gas configuration of the sensor. + * @note heatr_temp and heatr_dur values are currently register data + * and not the actual values set + * + * @param[in] dev :Structure instance of bme680_dev. + * + * @return Result of API execution status. + * @retval zero -> Success / +ve value -> Warning / -ve value -> Error + */ +static int8_t get_gas_config(struct bme680_dev *dev); + +/*! + * @brief This internal API is used to calculate the Heat duration value. + * + * @param[in] dur :Value of the duration to be shared. + * + * @return uint8_t threshold duration after calculation. + */ +static uint8_t calc_heater_dur(uint16_t dur); + +#ifndef BME680_FLOAT_POINT_COMPENSATION + +/*! + * @brief This internal API is used to calculate the temperature value. + * + * @param[in] dev :Structure instance of bme680_dev. + * @param[in] temp_adc :Contains the temperature ADC value . + * + * @return uint32_t calculated temperature. + */ +static int16_t calc_temperature(uint32_t temp_adc, struct bme680_dev *dev); + +/*! + * @brief This internal API is used to calculate the pressure value. + * + * @param[in] dev :Structure instance of bme680_dev. + * @param[in] pres_adc :Contains the pressure ADC value . + * + * @return uint32_t calculated pressure. + */ +static uint32_t calc_pressure(uint32_t pres_adc, const struct bme680_dev *dev); + +/*! + * @brief This internal API is used to calculate the humidity value. + * + * @param[in] dev :Structure instance of bme680_dev. + * @param[in] hum_adc :Contains the humidity ADC value. + * + * @return uint32_t calculated humidity. + */ +static uint32_t calc_humidity(uint16_t hum_adc, const struct bme680_dev *dev); + +/*! + * @brief This internal API is used to calculate the Gas Resistance value. + * + * @param[in] dev :Structure instance of bme680_dev. + * @param[in] gas_res_adc :Contains the Gas Resistance ADC value. + * @param[in] gas_range :Contains the range of gas values. + * + * @return uint32_t calculated gas resistance. + */ +static uint32_t calc_gas_resistance(uint16_t gas_res_adc, uint8_t gas_range, const struct bme680_dev *dev); + +/*! + * @brief This internal API is used to calculate the Heat Resistance value. + * + * @param[in] dev : Structure instance of bme680_dev + * @param[in] temp : Contains the target temperature value. + * + * @return uint8_t calculated heater resistance. + */ +static uint8_t calc_heater_res(uint16_t temp, const struct bme680_dev *dev); + +#else +/*! + * @brief This internal API is used to calculate the + * temperature value value in float format + * + * @param[in] dev :Structure instance of bme680_dev. + * @param[in] temp_adc :Contains the temperature ADC value . + * + * @return Calculated temperature in float + */ +static float calc_temperature(uint32_t temp_adc, struct bme680_dev *dev); + +/*! + * @brief This internal API is used to calculate the + * pressure value value in float format + * + * @param[in] dev :Structure instance of bme680_dev. + * @param[in] pres_adc :Contains the pressure ADC value . + * + * @return Calculated pressure in float. + */ +static float calc_pressure(uint32_t pres_adc, const struct bme680_dev *dev); + +/*! + * @brief This internal API is used to calculate the + * humidity value value in float format + * + * @param[in] dev :Structure instance of bme680_dev. + * @param[in] hum_adc :Contains the humidity ADC value. + * + * @return Calculated humidity in float. + */ +static float calc_humidity(uint16_t hum_adc, const struct bme680_dev *dev); + +/*! + * @brief This internal API is used to calculate the + * gas resistance value value in float format + * + * @param[in] dev :Structure instance of bme680_dev. + * @param[in] gas_res_adc :Contains the Gas Resistance ADC value. + * @param[in] gas_range :Contains the range of gas values. + * + * @return Calculated gas resistance in float. + */ +static float calc_gas_resistance(uint16_t gas_res_adc, uint8_t gas_range, const struct bme680_dev *dev); + +/*! + * @brief This internal API is used to calculate the + * heater resistance value in float format + * + * @param[in] temp : Contains the target temperature value. + * @param[in] dev : Structure instance of bme680_dev. + * + * @return Calculated heater resistance in float. + */ +static float calc_heater_res(uint16_t temp, const struct bme680_dev *dev); + +#endif + +/*! + * @brief This internal API is used to calculate the field data of sensor. + * + * @param[out] data :Structure instance to hold the data + * @param[in] dev :Structure instance of bme680_dev. + * + * @return int8_t result of the field data from sensor. + */ +static int8_t read_field_data(struct bme680_field_data *data, struct bme680_dev *dev); + +/*! + * @brief This internal API is used to set the memory page + * based on register address. + * + * The value of memory page + * value | Description + * --------|-------------- + * 0 | BME680_PAGE0_SPI + * 1 | BME680_PAGE1_SPI + * + * @param[in] dev :Structure instance of bme680_dev. + * @param[in] reg_addr :Contains the register address array. + * + * @return Result of API execution status + * @retval zero -> Success / +ve value -> Warning / -ve value -> Error + */ +static int8_t set_mem_page(uint8_t reg_addr, struct bme680_dev *dev); + +/*! + * @brief This internal API is used to get the memory page based + * on register address. + * + * The value of memory page + * value | Description + * --------|-------------- + * 0 | BME680_PAGE0_SPI + * 1 | BME680_PAGE1_SPI + * + * @param[in] dev :Structure instance of bme680_dev. + * + * @return Result of API execution status + * @retval zero -> Success / +ve value -> Warning / -ve value -> Error + */ +static int8_t get_mem_page(struct bme680_dev *dev); + +/*! + * @brief This internal API is used to validate the device pointer for + * null conditions. + * + * @param[in] dev :Structure instance of bme680_dev. + * + * @return Result of API execution status + * @retval zero -> Success / +ve value -> Warning / -ve value -> Error + */ +static int8_t null_ptr_check(const struct bme680_dev *dev); + +/*! + * @brief This internal API is used to check the boundary + * conditions. + * + * @param[in] value :pointer to the value. + * @param[in] min :minimum value. + * @param[in] max :maximum value. + * @param[in] dev :Structure instance of bme680_dev. + * + * @return Result of API execution status + * @retval zero -> Success / +ve value -> Warning / -ve value -> Error + */ +static int8_t boundary_check(uint8_t *value, uint8_t min, uint8_t max, struct bme680_dev *dev); + +/****************** Global Function Definitions *******************************/ +/*! + *@brief This API is the entry point. + *It reads the chip-id and calibration data from the sensor. + */ +int8_t bme680_init(struct bme680_dev *dev) +{ + int8_t rslt; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + /* Soft reset to restore it to default values*/ + rslt = bme680_soft_reset(dev); + if (rslt == BME680_OK) { + rslt = bme680_get_regs(BME680_CHIP_ID_ADDR, &dev->chip_id, 1, dev); + if (rslt == BME680_OK) { + if (dev->chip_id == BME680_CHIP_ID) { + /* Get the Calibration data */ + rslt = get_calib_data(dev); + } else { + rslt = BME680_E_DEV_NOT_FOUND; + } + } + } + } + + return rslt; +} + +/*! + * @brief This API reads the data from the given register address of the sensor. + */ +int8_t bme680_get_regs(uint8_t reg_addr, uint8_t *reg_data, uint16_t len, struct bme680_dev *dev) +{ + int8_t rslt; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + if (dev->intf == BME680_SPI_INTF) { + /* Set the memory page */ + rslt = set_mem_page(reg_addr, dev); + if (rslt == BME680_OK) + reg_addr = reg_addr | BME680_SPI_RD_MSK; + } + dev->com_rslt = dev->read(dev->dev_id, reg_addr, reg_data, len); + if (dev->com_rslt != 0) + rslt = BME680_E_COM_FAIL; + } + + return rslt; +} + +/*! + * @brief This API writes the given data to the register address + * of the sensor. + */ +int8_t bme680_set_regs(const uint8_t *reg_addr, const uint8_t *reg_data, uint8_t len, struct bme680_dev *dev) +{ + int8_t rslt; + /* Length of the temporary buffer is 2*(length of register)*/ + uint8_t tmp_buff[BME680_TMP_BUFFER_LENGTH] = { 0 }; + uint16_t index; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + if ((len > 0) && (len < BME680_TMP_BUFFER_LENGTH / 2)) { + /* Interleave the 2 arrays */ + for (index = 0; index < len; index++) { + if (dev->intf == BME680_SPI_INTF) { + /* Set the memory page */ + rslt = set_mem_page(reg_addr[index], dev); + tmp_buff[(2 * index)] = reg_addr[index] & BME680_SPI_WR_MSK; + } else { + tmp_buff[(2 * index)] = reg_addr[index]; + } + tmp_buff[(2 * index) + 1] = reg_data[index]; + } + /* Write the interleaved array */ + if (rslt == BME680_OK) { + dev->com_rslt = dev->write(dev->dev_id, tmp_buff[0], &tmp_buff[1], (2 * len) - 1); + if (dev->com_rslt != 0) + rslt = BME680_E_COM_FAIL; + } + } else { + rslt = BME680_E_INVALID_LENGTH; + } + } + + return rslt; +} + +/*! + * @brief This API performs the soft reset of the sensor. + */ +int8_t bme680_soft_reset(struct bme680_dev *dev) +{ + int8_t rslt; + uint8_t reg_addr = BME680_SOFT_RESET_ADDR; + /* 0xb6 is the soft reset command */ + uint8_t soft_rst_cmd = BME680_SOFT_RESET_CMD; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + if (dev->intf == BME680_SPI_INTF) + rslt = get_mem_page(dev); + + /* Reset the device */ + if (rslt == BME680_OK) { + rslt = bme680_set_regs(®_addr, &soft_rst_cmd, 1, dev); + /* Wait for 5ms */ + dev->delay_ms(BME680_RESET_PERIOD); + + if (rslt == BME680_OK) { + /* After reset get the memory page */ + if (dev->intf == BME680_SPI_INTF) + rslt = get_mem_page(dev); + } + } + } + + return rslt; +} + +/*! + * @brief This API is used to set the oversampling, filter and T,P,H, gas selection + * settings in the sensor. + */ +int8_t bme680_set_sensor_settings(uint16_t desired_settings, struct bme680_dev *dev) +{ + int8_t rslt; + uint8_t reg_addr; + uint8_t data = 0; + uint8_t count = 0; + uint8_t reg_array[BME680_REG_BUFFER_LENGTH] = { 0 }; + uint8_t data_array[BME680_REG_BUFFER_LENGTH] = { 0 }; + uint8_t intended_power_mode = dev->power_mode; /* Save intended power mode */ + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + if (desired_settings & BME680_GAS_MEAS_SEL) + rslt = set_gas_config(dev); + + dev->power_mode = BME680_SLEEP_MODE; + if (rslt == BME680_OK) + rslt = bme680_set_sensor_mode(dev); + + /* Selecting the filter */ + if (desired_settings & BME680_FILTER_SEL) { + rslt = boundary_check(&dev->tph_sett.filter, BME680_FILTER_SIZE_0, BME680_FILTER_SIZE_127, dev); + reg_addr = BME680_CONF_ODR_FILT_ADDR; + + if (rslt == BME680_OK) + rslt = bme680_get_regs(reg_addr, &data, 1, dev); + + if (desired_settings & BME680_FILTER_SEL) + data = BME680_SET_BITS(data, BME680_FILTER, dev->tph_sett.filter); + + reg_array[count] = reg_addr; /* Append configuration */ + data_array[count] = data; + count++; + } + + /* Selecting heater control for the sensor */ + if (desired_settings & BME680_HCNTRL_SEL) { + rslt = boundary_check(&dev->gas_sett.heatr_ctrl, BME680_ENABLE_HEATER, + BME680_DISABLE_HEATER, dev); + reg_addr = BME680_CONF_HEAT_CTRL_ADDR; + + if (rslt == BME680_OK) + rslt = bme680_get_regs(reg_addr, &data, 1, dev); + data = BME680_SET_BITS_POS_0(data, BME680_HCTRL, dev->gas_sett.heatr_ctrl); + + reg_array[count] = reg_addr; /* Append configuration */ + data_array[count] = data; + count++; + } + + /* Selecting heater T,P oversampling for the sensor */ + if (desired_settings & (BME680_OST_SEL | BME680_OSP_SEL)) { + rslt = boundary_check(&dev->tph_sett.os_temp, BME680_OS_NONE, BME680_OS_16X, dev); + reg_addr = BME680_CONF_T_P_MODE_ADDR; + + if (rslt == BME680_OK) + rslt = bme680_get_regs(reg_addr, &data, 1, dev); + + if (desired_settings & BME680_OST_SEL) + data = BME680_SET_BITS(data, BME680_OST, dev->tph_sett.os_temp); + + if (desired_settings & BME680_OSP_SEL) + data = BME680_SET_BITS(data, BME680_OSP, dev->tph_sett.os_pres); + + reg_array[count] = reg_addr; + data_array[count] = data; + count++; + } + + /* Selecting humidity oversampling for the sensor */ + if (desired_settings & BME680_OSH_SEL) { + rslt = boundary_check(&dev->tph_sett.os_hum, BME680_OS_NONE, BME680_OS_16X, dev); + reg_addr = BME680_CONF_OS_H_ADDR; + + if (rslt == BME680_OK) + rslt = bme680_get_regs(reg_addr, &data, 1, dev); + data = BME680_SET_BITS_POS_0(data, BME680_OSH, dev->tph_sett.os_hum); + + reg_array[count] = reg_addr; /* Append configuration */ + data_array[count] = data; + count++; + } + + /* Selecting the runGas and NB conversion settings for the sensor */ + if (desired_settings & (BME680_RUN_GAS_SEL | BME680_NBCONV_SEL)) { + rslt = boundary_check(&dev->gas_sett.run_gas, BME680_RUN_GAS_DISABLE, + BME680_RUN_GAS_ENABLE, dev); + if (rslt == BME680_OK) { + /* Validate boundary conditions */ + rslt = boundary_check(&dev->gas_sett.nb_conv, BME680_NBCONV_MIN, + BME680_NBCONV_MAX, dev); + } + + reg_addr = BME680_CONF_ODR_RUN_GAS_NBC_ADDR; + + if (rslt == BME680_OK) + rslt = bme680_get_regs(reg_addr, &data, 1, dev); + + if (desired_settings & BME680_RUN_GAS_SEL) + data = BME680_SET_BITS(data, BME680_RUN_GAS, dev->gas_sett.run_gas); + + if (desired_settings & BME680_NBCONV_SEL) + data = BME680_SET_BITS_POS_0(data, BME680_NBCONV, dev->gas_sett.nb_conv); + + reg_array[count] = reg_addr; /* Append configuration */ + data_array[count] = data; + count++; + } + + if (rslt == BME680_OK) + rslt = bme680_set_regs(reg_array, data_array, count, dev); + + /* Restore previous intended power mode */ + dev->power_mode = intended_power_mode; + } + + return rslt; +} + +/*! + * @brief This API is used to get the oversampling, filter and T,P,H, gas selection + * settings in the sensor. + */ +int8_t bme680_get_sensor_settings(uint16_t desired_settings, struct bme680_dev *dev) +{ + int8_t rslt; + /* starting address of the register array for burst read*/ + uint8_t reg_addr = BME680_CONF_HEAT_CTRL_ADDR; + uint8_t data_array[BME680_REG_BUFFER_LENGTH] = { 0 }; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + rslt = bme680_get_regs(reg_addr, data_array, BME680_REG_BUFFER_LENGTH, dev); + + if (rslt == BME680_OK) { + if (desired_settings & BME680_GAS_MEAS_SEL) + rslt = get_gas_config(dev); + + /* get the T,P,H ,Filter,ODR settings here */ + if (desired_settings & BME680_FILTER_SEL) + dev->tph_sett.filter = BME680_GET_BITS(data_array[BME680_REG_FILTER_INDEX], + BME680_FILTER); + + if (desired_settings & (BME680_OST_SEL | BME680_OSP_SEL)) { + dev->tph_sett.os_temp = BME680_GET_BITS(data_array[BME680_REG_TEMP_INDEX], BME680_OST); + dev->tph_sett.os_pres = BME680_GET_BITS(data_array[BME680_REG_PRES_INDEX], BME680_OSP); + } + + if (desired_settings & BME680_OSH_SEL) + dev->tph_sett.os_hum = BME680_GET_BITS_POS_0(data_array[BME680_REG_HUM_INDEX], + BME680_OSH); + + /* get the gas related settings */ + if (desired_settings & BME680_HCNTRL_SEL) + dev->gas_sett.heatr_ctrl = BME680_GET_BITS_POS_0(data_array[BME680_REG_HCTRL_INDEX], + BME680_HCTRL); + + if (desired_settings & (BME680_RUN_GAS_SEL | BME680_NBCONV_SEL)) { + dev->gas_sett.nb_conv = BME680_GET_BITS_POS_0(data_array[BME680_REG_NBCONV_INDEX], + BME680_NBCONV); + dev->gas_sett.run_gas = BME680_GET_BITS(data_array[BME680_REG_RUN_GAS_INDEX], + BME680_RUN_GAS); + } + } + } else { + rslt = BME680_E_NULL_PTR; + } + + return rslt; +} + +/*! + * @brief This API is used to set the power mode of the sensor. + */ +int8_t bme680_set_sensor_mode(struct bme680_dev *dev) +{ + int8_t rslt; + uint8_t tmp_pow_mode; + uint8_t pow_mode = 0; + uint8_t reg_addr = BME680_CONF_T_P_MODE_ADDR; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + /* Call repeatedly until in sleep */ + do { + rslt = bme680_get_regs(BME680_CONF_T_P_MODE_ADDR, &tmp_pow_mode, 1, dev); + if (rslt == BME680_OK) { + /* Put to sleep before changing mode */ + pow_mode = (tmp_pow_mode & BME680_MODE_MSK); + + if (pow_mode != BME680_SLEEP_MODE) { + tmp_pow_mode = tmp_pow_mode & (~BME680_MODE_MSK); /* Set to sleep */ + rslt = bme680_set_regs(®_addr, &tmp_pow_mode, 1, dev); + dev->delay_ms(BME680_POLL_PERIOD_MS); + } + } + } while (pow_mode != BME680_SLEEP_MODE); + + /* Already in sleep */ + if (dev->power_mode != BME680_SLEEP_MODE) { + tmp_pow_mode = (tmp_pow_mode & ~BME680_MODE_MSK) | (dev->power_mode & BME680_MODE_MSK); + if (rslt == BME680_OK) + rslt = bme680_set_regs(®_addr, &tmp_pow_mode, 1, dev); + } + } + + return rslt; +} + +/*! + * @brief This API is used to get the power mode of the sensor. + */ +int8_t bme680_get_sensor_mode(struct bme680_dev *dev) +{ + int8_t rslt; + uint8_t mode; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + rslt = bme680_get_regs(BME680_CONF_T_P_MODE_ADDR, &mode, 1, dev); + /* Masking the other register bit info*/ + dev->power_mode = mode & BME680_MODE_MSK; + } + + return rslt; +} + +/*! + * @brief This API is used to set the profile duration of the sensor. + */ +void bme680_set_profile_dur(uint16_t duration, struct bme680_dev *dev) +{ + uint32_t tph_dur; /* Calculate in us */ + uint32_t meas_cycles; + uint8_t os_to_meas_cycles[6] = {0, 1, 2, 4, 8, 16}; + + meas_cycles = os_to_meas_cycles[dev->tph_sett.os_temp]; + meas_cycles += os_to_meas_cycles[dev->tph_sett.os_pres]; + meas_cycles += os_to_meas_cycles[dev->tph_sett.os_hum]; + + /* TPH measurement duration */ + tph_dur = meas_cycles * UINT32_C(1963); + tph_dur += UINT32_C(477 * 4); /* TPH switching duration */ + tph_dur += UINT32_C(477 * 5); /* Gas measurement duration */ + tph_dur += UINT32_C(500); /* Get it to the closest whole number.*/ + tph_dur /= UINT32_C(1000); /* Convert to ms */ + + tph_dur += UINT32_C(1); /* Wake up duration of 1ms */ + /* The remaining time should be used for heating */ + dev->gas_sett.heatr_dur = duration - (uint16_t) tph_dur; +} + +/*! + * @brief This API is used to get the profile duration of the sensor. + */ +void bme680_get_profile_dur(uint16_t *duration, const struct bme680_dev *dev) +{ + uint32_t tph_dur; /* Calculate in us */ + uint32_t meas_cycles; + uint8_t os_to_meas_cycles[6] = {0, 1, 2, 4, 8, 16}; + + meas_cycles = os_to_meas_cycles[dev->tph_sett.os_temp]; + meas_cycles += os_to_meas_cycles[dev->tph_sett.os_pres]; + meas_cycles += os_to_meas_cycles[dev->tph_sett.os_hum]; + + /* TPH measurement duration */ + tph_dur = meas_cycles * UINT32_C(1963); + tph_dur += UINT32_C(477 * 4); /* TPH switching duration */ + tph_dur += UINT32_C(477 * 5); /* Gas measurement duration */ + tph_dur += UINT32_C(500); /* Get it to the closest whole number.*/ + tph_dur /= UINT32_C(1000); /* Convert to ms */ + + tph_dur += UINT32_C(1); /* Wake up duration of 1ms */ + + *duration = (uint16_t) tph_dur; + + /* Get the gas duration only when the run gas is enabled */ + if (dev->gas_sett.run_gas) { + /* The remaining time should be used for heating */ + *duration += dev->gas_sett.heatr_dur; + } +} + +/*! + * @brief This API reads the pressure, temperature and humidity and gas data + * from the sensor, compensates the data and store it in the bme680_data + * structure instance passed by the user. + */ +int8_t bme680_get_sensor_data(struct bme680_field_data *data, struct bme680_dev *dev) +{ + int8_t rslt; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + /* Reading the sensor data in forced mode only */ + rslt = read_field_data(data, dev); + if (rslt == BME680_OK) { + if (data->status & BME680_NEW_DATA_MSK) + dev->new_fields = 1; + else + dev->new_fields = 0; + } + } + + return rslt; +} + +/*! + * @brief This internal API is used to read the calibrated data from the sensor. + */ +static int8_t get_calib_data(struct bme680_dev *dev) +{ + int8_t rslt; + uint8_t coeff_array[BME680_COEFF_SIZE] = { 0 }; + uint8_t temp_var = 0; /* Temporary variable */ + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + rslt = bme680_get_regs(BME680_COEFF_ADDR1, coeff_array, BME680_COEFF_ADDR1_LEN, dev); + /* Append the second half in the same array */ + if (rslt == BME680_OK) + rslt = bme680_get_regs(BME680_COEFF_ADDR2, &coeff_array[BME680_COEFF_ADDR1_LEN] + , BME680_COEFF_ADDR2_LEN, dev); + + /* Temperature related coefficients */ + dev->calib.par_t1 = (uint16_t) (BME680_CONCAT_BYTES(coeff_array[BME680_T1_MSB_REG], + coeff_array[BME680_T1_LSB_REG])); + dev->calib.par_t2 = (int16_t) (BME680_CONCAT_BYTES(coeff_array[BME680_T2_MSB_REG], + coeff_array[BME680_T2_LSB_REG])); + dev->calib.par_t3 = (int8_t) (coeff_array[BME680_T3_REG]); + + /* Pressure related coefficients */ + dev->calib.par_p1 = (uint16_t) (BME680_CONCAT_BYTES(coeff_array[BME680_P1_MSB_REG], + coeff_array[BME680_P1_LSB_REG])); + dev->calib.par_p2 = (int16_t) (BME680_CONCAT_BYTES(coeff_array[BME680_P2_MSB_REG], + coeff_array[BME680_P2_LSB_REG])); + dev->calib.par_p3 = (int8_t) coeff_array[BME680_P3_REG]; + dev->calib.par_p4 = (int16_t) (BME680_CONCAT_BYTES(coeff_array[BME680_P4_MSB_REG], + coeff_array[BME680_P4_LSB_REG])); + dev->calib.par_p5 = (int16_t) (BME680_CONCAT_BYTES(coeff_array[BME680_P5_MSB_REG], + coeff_array[BME680_P5_LSB_REG])); + dev->calib.par_p6 = (int8_t) (coeff_array[BME680_P6_REG]); + dev->calib.par_p7 = (int8_t) (coeff_array[BME680_P7_REG]); + dev->calib.par_p8 = (int16_t) (BME680_CONCAT_BYTES(coeff_array[BME680_P8_MSB_REG], + coeff_array[BME680_P8_LSB_REG])); + dev->calib.par_p9 = (int16_t) (BME680_CONCAT_BYTES(coeff_array[BME680_P9_MSB_REG], + coeff_array[BME680_P9_LSB_REG])); + dev->calib.par_p10 = (uint8_t) (coeff_array[BME680_P10_REG]); + + /* Humidity related coefficients */ + dev->calib.par_h1 = (uint16_t) (((uint16_t) coeff_array[BME680_H1_MSB_REG] << BME680_HUM_REG_SHIFT_VAL) + | (coeff_array[BME680_H1_LSB_REG] & BME680_BIT_H1_DATA_MSK)); + dev->calib.par_h2 = (uint16_t) (((uint16_t) coeff_array[BME680_H2_MSB_REG] << BME680_HUM_REG_SHIFT_VAL) + | ((coeff_array[BME680_H2_LSB_REG]) >> BME680_HUM_REG_SHIFT_VAL)); + dev->calib.par_h3 = (int8_t) coeff_array[BME680_H3_REG]; + dev->calib.par_h4 = (int8_t) coeff_array[BME680_H4_REG]; + dev->calib.par_h5 = (int8_t) coeff_array[BME680_H5_REG]; + dev->calib.par_h6 = (uint8_t) coeff_array[BME680_H6_REG]; + dev->calib.par_h7 = (int8_t) coeff_array[BME680_H7_REG]; + + /* Gas heater related coefficients */ + dev->calib.par_gh1 = (int8_t) coeff_array[BME680_GH1_REG]; + dev->calib.par_gh2 = (int16_t) (BME680_CONCAT_BYTES(coeff_array[BME680_GH2_MSB_REG], + coeff_array[BME680_GH2_LSB_REG])); + dev->calib.par_gh3 = (int8_t) coeff_array[BME680_GH3_REG]; + + /* Other coefficients */ + if (rslt == BME680_OK) { + rslt = bme680_get_regs(BME680_ADDR_RES_HEAT_RANGE_ADDR, &temp_var, 1, dev); + + dev->calib.res_heat_range = ((temp_var & BME680_RHRANGE_MSK) / 16); + if (rslt == BME680_OK) { + rslt = bme680_get_regs(BME680_ADDR_RES_HEAT_VAL_ADDR, &temp_var, 1, dev); + + dev->calib.res_heat_val = (int8_t) temp_var; + if (rslt == BME680_OK) + rslt = bme680_get_regs(BME680_ADDR_RANGE_SW_ERR_ADDR, &temp_var, 1, dev); + } + } + dev->calib.range_sw_err = ((int8_t) temp_var & (int8_t) BME680_RSERROR_MSK) / 16; + } + + return rslt; +} + +/*! + * @brief This internal API is used to set the gas configuration of the sensor. + */ +static int8_t set_gas_config(struct bme680_dev *dev) +{ + int8_t rslt; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + + uint8_t reg_addr[2] = {0}; + uint8_t reg_data[2] = {0}; + + if (dev->power_mode == BME680_FORCED_MODE) { + reg_addr[0] = BME680_RES_HEAT0_ADDR; + reg_data[0] = calc_heater_res(dev->gas_sett.heatr_temp, dev); + reg_addr[1] = BME680_GAS_WAIT0_ADDR; + reg_data[1] = calc_heater_dur(dev->gas_sett.heatr_dur); + dev->gas_sett.nb_conv = 0; + } else { + rslt = BME680_W_DEFINE_PWR_MODE; + } + if (rslt == BME680_OK) + rslt = bme680_set_regs(reg_addr, reg_data, 2, dev); + } + + return rslt; +} + +/*! + * @brief This internal API is used to get the gas configuration of the sensor. + * @note heatr_temp and heatr_dur values are currently register data + * and not the actual values set + */ +static int8_t get_gas_config(struct bme680_dev *dev) +{ + int8_t rslt; + /* starting address of the register array for burst read*/ + uint8_t reg_addr1 = BME680_ADDR_SENS_CONF_START; + uint8_t reg_addr2 = BME680_ADDR_GAS_CONF_START; + uint8_t reg_data = 0; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + if (BME680_SPI_INTF == dev->intf) { + /* Memory page switch the SPI address*/ + rslt = set_mem_page(reg_addr1, dev); + } + + if (rslt == BME680_OK) { + rslt = bme680_get_regs(reg_addr1, ®_data, 1, dev); + if (rslt == BME680_OK) { + dev->gas_sett.heatr_temp = reg_data; + rslt = bme680_get_regs(reg_addr2, ®_data, 1, dev); + if (rslt == BME680_OK) { + /* Heating duration register value */ + dev->gas_sett.heatr_dur = reg_data; + } + } + } + } + + return rslt; +} + +#ifndef BME680_FLOAT_POINT_COMPENSATION + +/*! + * @brief This internal API is used to calculate the temperature value. + */ +static int16_t calc_temperature(uint32_t temp_adc, struct bme680_dev *dev) +{ + int64_t var1; + int64_t var2; + int64_t var3; + int16_t calc_temp; + + var1 = ((int32_t) temp_adc >> 3) - ((int32_t) dev->calib.par_t1 << 1); + var2 = (var1 * (int32_t) dev->calib.par_t2) >> 11; + var3 = ((var1 >> 1) * (var1 >> 1)) >> 12; + var3 = ((var3) * ((int32_t) dev->calib.par_t3 << 4)) >> 14; + dev->calib.t_fine = (int32_t) (var2 + var3); + calc_temp = (int16_t) (((dev->calib.t_fine * 5) + 128) >> 8); + + return calc_temp; +} + +/*! + * @brief This internal API is used to calculate the pressure value. + */ +static uint32_t calc_pressure(uint32_t pres_adc, const struct bme680_dev *dev) +{ + int32_t var1; + int32_t var2; + int32_t var3; + int32_t pressure_comp; + + var1 = (((int32_t)dev->calib.t_fine) >> 1) - 64000; + var2 = ((((var1 >> 2) * (var1 >> 2)) >> 11) * + (int32_t)dev->calib.par_p6) >> 2; + var2 = var2 + ((var1 * (int32_t)dev->calib.par_p5) << 1); + var2 = (var2 >> 2) + ((int32_t)dev->calib.par_p4 << 16); + var1 = (((((var1 >> 2) * (var1 >> 2)) >> 13) * + ((int32_t)dev->calib.par_p3 << 5)) >> 3) + + (((int32_t)dev->calib.par_p2 * var1) >> 1); + var1 = var1 >> 18; + var1 = ((32768 + var1) * (int32_t)dev->calib.par_p1) >> 15; + pressure_comp = 1048576 - pres_adc; + pressure_comp = (int32_t)((pressure_comp - (var2 >> 12)) * ((uint32_t)3125)); + if (pressure_comp >= BME680_MAX_OVERFLOW_VAL) + pressure_comp = ((pressure_comp / var1) << 1); + else + pressure_comp = ((pressure_comp << 1) / var1); + var1 = ((int32_t)dev->calib.par_p9 * (int32_t)(((pressure_comp >> 3) * + (pressure_comp >> 3)) >> 13)) >> 12; + var2 = ((int32_t)(pressure_comp >> 2) * + (int32_t)dev->calib.par_p8) >> 13; + var3 = ((int32_t)(pressure_comp >> 8) * (int32_t)(pressure_comp >> 8) * + (int32_t)(pressure_comp >> 8) * + (int32_t)dev->calib.par_p10) >> 17; + + pressure_comp = (int32_t)(pressure_comp) + ((var1 + var2 + var3 + + ((int32_t)dev->calib.par_p7 << 7)) >> 4); + + return (uint32_t)pressure_comp; + +} + +/*! + * @brief This internal API is used to calculate the humidity value. + */ +static uint32_t calc_humidity(uint16_t hum_adc, const struct bme680_dev *dev) +{ + int32_t var1; + int32_t var2; + int32_t var3; + int32_t var4; + int32_t var5; + int32_t var6; + int32_t temp_scaled; + int32_t calc_hum; + + temp_scaled = (((int32_t) dev->calib.t_fine * 5) + 128) >> 8; + var1 = (int32_t) (hum_adc - ((int32_t) ((int32_t) dev->calib.par_h1 * 16))) + - (((temp_scaled * (int32_t) dev->calib.par_h3) / ((int32_t) 100)) >> 1); + var2 = ((int32_t) dev->calib.par_h2 + * (((temp_scaled * (int32_t) dev->calib.par_h4) / ((int32_t) 100)) + + (((temp_scaled * ((temp_scaled * (int32_t) dev->calib.par_h5) / ((int32_t) 100))) >> 6) + / ((int32_t) 100)) + (int32_t) (1 << 14))) >> 10; + var3 = var1 * var2; + var4 = (int32_t) dev->calib.par_h6 << 7; + var4 = ((var4) + ((temp_scaled * (int32_t) dev->calib.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; + + return (uint32_t) calc_hum; +} + +/*! + * @brief This internal API is used to calculate the Gas Resistance value. + */ +static uint32_t calc_gas_resistance(uint16_t gas_res_adc, uint8_t gas_range, const struct bme680_dev *dev) +{ + int64_t var1; + uint64_t var2; + int64_t var3; + uint32_t calc_gas_res; + /**Look up table 1 for the possible gas range values */ + uint32_t lookupTable1[16] = { UINT32_C(2147483647), UINT32_C(2147483647), UINT32_C(2147483647), UINT32_C(2147483647), + UINT32_C(2147483647), UINT32_C(2126008810), UINT32_C(2147483647), UINT32_C(2130303777), + UINT32_C(2147483647), UINT32_C(2147483647), UINT32_C(2143188679), UINT32_C(2136746228), + UINT32_C(2147483647), UINT32_C(2126008810), UINT32_C(2147483647), UINT32_C(2147483647) }; + /**Look up table 2 for the possible gas range values */ + uint32_t lookupTable2[16] = { UINT32_C(4096000000), UINT32_C(2048000000), UINT32_C(1024000000), UINT32_C(512000000), + UINT32_C(255744255), UINT32_C(127110228), UINT32_C(64000000), UINT32_C(32258064), UINT32_C(16016016), + UINT32_C(8000000), UINT32_C(4000000), UINT32_C(2000000), UINT32_C(1000000), UINT32_C(500000), + UINT32_C(250000), UINT32_C(125000) }; + + var1 = (int64_t) ((1340 + (5 * (int64_t) dev->calib.range_sw_err)) * + ((int64_t) lookupTable1[gas_range])) >> 16; + var2 = (((int64_t) ((int64_t) gas_res_adc << 15) - (int64_t) (16777216)) + var1); + var3 = (((int64_t) lookupTable2[gas_range] * (int64_t) var1) >> 9); + calc_gas_res = (uint32_t) ((var3 + ((int64_t) var2 >> 1)) / (int64_t) var2); + + return calc_gas_res; +} + +/*! + * @brief This internal API is used to calculate the Heat Resistance value. + */ +static uint8_t calc_heater_res(uint16_t temp, const struct bme680_dev *dev) +{ + uint8_t heatr_res; + int32_t var1; + int32_t var2; + int32_t var3; + int32_t var4; + int32_t var5; + int32_t heatr_res_x100; + + if (temp > 400) /* Cap temperature */ + temp = 400; + + var1 = (((int32_t) dev->amb_temp * dev->calib.par_gh3) / 1000) * 256; + var2 = (dev->calib.par_gh1 + 784) * (((((dev->calib.par_gh2 + 154009) * temp * 5) / 100) + 3276800) / 10); + var3 = var1 + (var2 / 2); + var4 = (var3 / (dev->calib.res_heat_range + 4)); + var5 = (131 * dev->calib.res_heat_val) + 65536; + heatr_res_x100 = (int32_t) (((var4 / var5) - 250) * 34); + heatr_res = (uint8_t) ((heatr_res_x100 + 50) / 100); + + return heatr_res; +} + +#else + + +/*! + * @brief This internal API is used to calculate the + * temperature value in float format + */ +static float calc_temperature(uint32_t temp_adc, struct bme680_dev *dev) +{ + float var1 = 0; + float var2 = 0; + float calc_temp = 0; + + /* calculate var1 data */ + var1 = ((((float)temp_adc / 16384.0f) - ((float)dev->calib.par_t1 / 1024.0f)) + * ((float)dev->calib.par_t2)); + + /* calculate var2 data */ + var2 = (((((float)temp_adc / 131072.0f) - ((float)dev->calib.par_t1 / 8192.0f)) * + (((float)temp_adc / 131072.0f) - ((float)dev->calib.par_t1 / 8192.0f))) * + ((float)dev->calib.par_t3 * 16.0f)); + + /* t_fine value*/ + dev->calib.t_fine = (var1 + var2); + + /* compensated temperature data*/ + calc_temp = ((dev->calib.t_fine) / 5120.0f); + + return calc_temp; +} + +/*! + * @brief This internal API is used to calculate the + * pressure value in float format + */ +static float calc_pressure(uint32_t pres_adc, const struct bme680_dev *dev) +{ + float var1 = 0; + float var2 = 0; + float var3 = 0; + float calc_pres = 0; + + var1 = (((float)dev->calib.t_fine / 2.0f) - 64000.0f); + var2 = var1 * var1 * (((float)dev->calib.par_p6) / (131072.0f)); + var2 = var2 + (var1 * ((float)dev->calib.par_p5) * 2.0f); + var2 = (var2 / 4.0f) + (((float)dev->calib.par_p4) * 65536.0f); + var1 = (((((float)dev->calib.par_p3 * var1 * var1) / 16384.0f) + + ((float)dev->calib.par_p2 * var1)) / 524288.0f); + var1 = ((1.0f + (var1 / 32768.0f)) * ((float)dev->calib.par_p1)); + calc_pres = (1048576.0f - ((float)pres_adc)); + + /* Avoid exception caused by division by zero */ + if ((int)var1 != 0) { + calc_pres = (((calc_pres - (var2 / 4096.0f)) * 6250.0f) / var1); + var1 = (((float)dev->calib.par_p9) * calc_pres * calc_pres) / 2147483648.0f; + var2 = calc_pres * (((float)dev->calib.par_p8) / 32768.0f); + var3 = ((calc_pres / 256.0f) * (calc_pres / 256.0f) * (calc_pres / 256.0f) + * (dev->calib.par_p10 / 131072.0f)); + calc_pres = (calc_pres + (var1 + var2 + var3 + ((float)dev->calib.par_p7 * 128.0f)) / 16.0f); + } else { + calc_pres = 0; + } + + return calc_pres; +} + +/*! + * @brief This internal API is used to calculate the + * humidity value in float format + */ +static float calc_humidity(uint16_t hum_adc, const struct bme680_dev *dev) +{ + float calc_hum = 0; + float var1 = 0; + float var2 = 0; + float var3 = 0; + float var4 = 0; + float temp_comp; + + /* compensated temperature data*/ + temp_comp = ((dev->calib.t_fine) / 5120.0f); + + var1 = (float)((float)hum_adc) - (((float)dev->calib.par_h1 * 16.0f) + (((float)dev->calib.par_h3 / 2.0f) + * temp_comp)); + + var2 = var1 * ((float)(((float) dev->calib.par_h2 / 262144.0f) * (1.0f + (((float)dev->calib.par_h4 / 16384.0f) + * temp_comp) + (((float)dev->calib.par_h5 / 1048576.0f) * temp_comp * temp_comp)))); + + var3 = (float) dev->calib.par_h6 / 16384.0f; + + var4 = (float) dev->calib.par_h7 / 2097152.0f; + + calc_hum = var2 + ((var3 + (var4 * temp_comp)) * var2 * var2); + + if (calc_hum > 100.0f) + calc_hum = 100.0f; + else if (calc_hum < 0.0f) + calc_hum = 0.0f; + + return calc_hum; +} + +/*! + * @brief This internal API is used to calculate the + * gas resistance value in float format + */ +static float calc_gas_resistance(uint16_t gas_res_adc, uint8_t gas_range, const struct bme680_dev *dev) +{ + float calc_gas_res; + float var1 = 0; + float var2 = 0; + float var3 = 0; + + const float lookup_k1_range[16] = { + 0.0, 0.0, 0.0, 0.0, 0.0, -1.0, 0.0, -0.8, + 0.0, 0.0, -0.2, -0.5, 0.0, -1.0, 0.0, 0.0}; + const float lookup_k2_range[16] = { + 0.0, 0.0, 0.0, 0.0, 0.1, 0.7, 0.0, -0.8, + -0.1, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0}; + + var1 = (1340.0f + (5.0f * dev->calib.range_sw_err)); + var2 = (var1) * (1.0f + lookup_k1_range[gas_range]/100.0f); + var3 = 1.0f + (lookup_k2_range[gas_range]/100.0f); + + calc_gas_res = 1.0f / (float)(var3 * (0.000000125f) * (float)(1 << gas_range) * (((((float)gas_res_adc) + - 512.0f)/var2) + 1.0f)); + + return calc_gas_res; +} + +/*! + * @brief This internal API is used to calculate the + * heater resistance value in float format + */ +static float calc_heater_res(uint16_t temp, const struct bme680_dev *dev) +{ + float var1 = 0; + float var2 = 0; + float var3 = 0; + float var4 = 0; + float var5 = 0; + float res_heat = 0; + + if (temp > 400) /* Cap temperature */ + temp = 400; + + var1 = (((float)dev->calib.par_gh1 / (16.0f)) + 49.0f); + var2 = ((((float)dev->calib.par_gh2 / (32768.0f)) * (0.0005f)) + 0.00235f); + var3 = ((float)dev->calib.par_gh3 / (1024.0f)); + var4 = (var1 * (1.0f + (var2 * (float)temp))); + var5 = (var4 + (var3 * (float)dev->amb_temp)); + res_heat = (uint8_t)(3.4f * ((var5 * (4 / (4 + (float)dev->calib.res_heat_range)) * + (1/(1 + ((float) dev->calib.res_heat_val * 0.002f)))) - 25)); + + return res_heat; +} + +#endif + +/*! + * @brief This internal API is used to calculate the Heat duration value. + */ +static uint8_t calc_heater_dur(uint16_t dur) +{ + uint8_t factor = 0; + uint8_t durval; + + if (dur >= 0xfc0) { + durval = 0xff; /* Max duration*/ + } else { + while (dur > 0x3F) { + dur = dur / 4; + factor += 1; + } + durval = (uint8_t) (dur + (factor * 64)); + } + + return durval; +} + +/*! + * @brief This internal API is used to calculate the field data of sensor. + */ +static int8_t read_field_data(struct bme680_field_data *data, struct bme680_dev *dev) +{ + int8_t rslt; + uint8_t buff[BME680_FIELD_LENGTH] = { 0 }; + uint8_t gas_range; + uint32_t adc_temp; + uint32_t adc_pres; + uint16_t adc_hum; + uint16_t adc_gas_res; + uint8_t tries = 10; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + do { + if (rslt == BME680_OK) { + rslt = bme680_get_regs(((uint8_t) (BME680_FIELD0_ADDR)), buff, (uint16_t) BME680_FIELD_LENGTH, + dev); + + data->status = buff[0] & BME680_NEW_DATA_MSK; + data->gas_index = buff[0] & BME680_GAS_INDEX_MSK; + data->meas_index = buff[1]; + + /* read the raw data from the sensor */ + adc_pres = (uint32_t) (((uint32_t) buff[2] * 4096) | ((uint32_t) buff[3] * 16) + | ((uint32_t) buff[4] / 16)); + adc_temp = (uint32_t) (((uint32_t) buff[5] * 4096) | ((uint32_t) buff[6] * 16) + | ((uint32_t) buff[7] / 16)); + adc_hum = (uint16_t) (((uint32_t) buff[8] * 256) | (uint32_t) buff[9]); + adc_gas_res = (uint16_t) ((uint32_t) buff[13] * 4 | (((uint32_t) buff[14]) / 64)); + gas_range = buff[14] & BME680_GAS_RANGE_MSK; + + data->status |= buff[14] & BME680_GASM_VALID_MSK; + data->status |= buff[14] & BME680_HEAT_STAB_MSK; + + if (data->status & BME680_NEW_DATA_MSK) { + data->temperature = calc_temperature(adc_temp, dev); + data->pressure = calc_pressure(adc_pres, dev); + data->humidity = calc_humidity(adc_hum, dev); + data->gas_resistance = calc_gas_resistance(adc_gas_res, gas_range, dev); + break; + } + /* Delay to poll the data */ + dev->delay_ms(BME680_POLL_PERIOD_MS); + } + tries--; + } while (tries); + + if (!tries) + rslt = BME680_W_NO_NEW_DATA; + + return rslt; +} + +/*! + * @brief This internal API is used to set the memory page based on register address. + */ +static int8_t set_mem_page(uint8_t reg_addr, struct bme680_dev *dev) +{ + int8_t rslt; + uint8_t reg; + uint8_t mem_page; + + /* Check for null pointers in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + if (reg_addr > 0x7f) + mem_page = BME680_MEM_PAGE1; + else + mem_page = BME680_MEM_PAGE0; + + if (mem_page != dev->mem_page) { + dev->mem_page = mem_page; + + dev->com_rslt = dev->read(dev->dev_id, BME680_MEM_PAGE_ADDR | BME680_SPI_RD_MSK, ®, 1); + if (dev->com_rslt != 0) + rslt = BME680_E_COM_FAIL; + + if (rslt == BME680_OK) { + reg = reg & (~BME680_MEM_PAGE_MSK); + reg = reg | (dev->mem_page & BME680_MEM_PAGE_MSK); + + dev->com_rslt = dev->write(dev->dev_id, BME680_MEM_PAGE_ADDR & BME680_SPI_WR_MSK, + ®, 1); + if (dev->com_rslt != 0) + rslt = BME680_E_COM_FAIL; + } + } + } + + return rslt; +} + +/*! + * @brief This internal API is used to get the memory page based on register address. + */ +static int8_t get_mem_page(struct bme680_dev *dev) +{ + int8_t rslt; + uint8_t reg; + + /* Check for null pointer in the device structure*/ + rslt = null_ptr_check(dev); + if (rslt == BME680_OK) { + dev->com_rslt = dev->read(dev->dev_id, BME680_MEM_PAGE_ADDR | BME680_SPI_RD_MSK, ®, 1); + if (dev->com_rslt != 0) + rslt = BME680_E_COM_FAIL; + else + dev->mem_page = reg & BME680_MEM_PAGE_MSK; + } + + return rslt; +} + +/*! + * @brief This internal API is used to validate the boundary + * conditions. + */ +static int8_t boundary_check(uint8_t *value, uint8_t min, uint8_t max, struct bme680_dev *dev) +{ + int8_t rslt = BME680_OK; + + if (value != NULL) { + /* Check if value is below minimum value */ + if (*value < min) { + /* Auto correct the invalid value to minimum value */ + *value = min; + dev->info_msg |= BME680_I_MIN_CORRECTION; + } + /* Check if value is above maximum value */ + if (*value > max) { + /* Auto correct the invalid value to maximum value */ + *value = max; + dev->info_msg |= BME680_I_MAX_CORRECTION; + } + } else { + rslt = BME680_E_NULL_PTR; + } + + return rslt; +} + +/*! + * @brief This internal API is used to validate the device structure pointer for + * null conditions. + */ +static int8_t null_ptr_check(const struct bme680_dev *dev) +{ + int8_t rslt; + + if ((dev == NULL) || (dev->read == NULL) || (dev->write == NULL) || (dev->delay_ms == NULL)) { + /* Device structure pointer is not valid */ + rslt = BME680_E_NULL_PTR; + } else { + /* Device structure is fine */ + rslt = BME680_OK; + } + + return rslt; +} diff --git a/src/driver/bme680_util.cc b/src/driver/bme680_util.cc new file mode 100644 index 0000000..cb9b529 --- /dev/null +++ b/src/driver/bme680_util.cc @@ -0,0 +1,27 @@ +#include "arch.h" +#include "driver/i2c.h" +#include + +void bme680_delay_ms(uint32_t const period) +{ + arch.delay_ms(period); +} + +int8_t bme680_i2c_read(uint8_t dev_id, uint8_t reg_addr, uint8_t *reg_data, uint16_t len) +{ + int8_t ret = i2c.xmit(dev_id, 1, ®_addr, 0, 0); + if (ret) { + return ret; + } + return i2c.xmit(dev_id, 0, 0, len, reg_data); +} + +int8_t bme680_i2c_write(uint8_t dev_id, uint8_t reg_addr, uint8_t *reg_data, uint16_t len) +{ + unsigned char txbuf[len+1]; + txbuf[0] = reg_addr; + for (uint16_t i = 0; i < len; i++) { + txbuf[i+1] = reg_data[i]; + } + return i2c.xmit(dev_id, len + 1, txbuf, 0, 0); +} -- cgit v1.2.3