#include "bme68x.hpp" #include "pico/stdlib.h" namespace pimoroni { bool BME68X::init() { int8_t result = 0; if(interrupt != PIN_UNUSED) { gpio_set_function(interrupt, GPIO_FUNC_SIO); gpio_set_dir(interrupt, GPIO_IN); gpio_pull_up(interrupt); } i2c_interface.i2c = i2c; i2c_interface.address = address; device.intf_ptr = &i2c_interface; device.intf = bme68x_intf::BME68X_I2C_INTF; device.read = (bme68x_read_fptr_t)&read_bytes; device.write = (bme68x_write_fptr_t)&write_bytes; device.delay_us = (bme68x_delay_us_fptr_t)&delay_us; device.amb_temp = 20; result = bme68x_init(&device); bme68x_check_rslt("bme68x_init", result); if(result != BME68X_OK) return false; result = bme68x_get_conf(&conf, &device); bme68x_check_rslt("bme68x_get_conf", result); if(result != BME68X_OK) return false; configure(BME68X_FILTER_OFF, BME68X_ODR_NONE, BME68X_OS_16X, BME68X_OS_1X, BME68X_OS_2X); return true; } bool BME68X::configure(uint8_t filter, uint8_t odr, uint8_t os_humidity, uint8_t os_pressure, uint8_t os_temp) { int8_t result = 0; conf.filter = filter; conf.odr = odr; conf.os_hum = os_humidity; conf.os_pres = os_pressure; conf.os_temp = os_temp; bme68x_set_conf(&conf, &device); bme68x_check_rslt("bme68x_set_conf", result); if(result != BME68X_OK) return false; return true; } bool BME68X::read_forced(bme68x_data *data, uint16_t heater_temp, uint16_t heater_duration) { int8_t result = 0; uint8_t n_fields; uint32_t delay_period; heatr_conf.enable = BME68X_ENABLE; heatr_conf.heatr_temp = heater_temp; heatr_conf.heatr_dur = heater_duration; result = bme68x_set_heatr_conf(BME68X_FORCED_MODE, &heatr_conf, &device); bme68x_check_rslt("bme68x_set_heatr_conf", result); if(result != BME68X_OK) return false; result = bme68x_set_op_mode(BME68X_FORCED_MODE, &device); bme68x_check_rslt("bme68x_set_op_mode", result); if(result != BME68X_OK) return false; delay_period = bme68x_get_meas_dur(BME68X_FORCED_MODE, &conf, &device) + (heatr_conf.heatr_dur * 1000); // Could probably just call sleep_us here directly, I guess the API uses this internally device.delay_us(delay_period, device.intf_ptr); result = bme68x_get_data(BME68X_FORCED_MODE, data, &n_fields, &device); bme68x_check_rslt("bme68x_get_data", result); if(result != BME68X_OK) return false; return true; } /* Will read profile_length results with the given temperatures and duration multipliers into the results array. Blocks until it has a valid result for each temp/duration, and returns the entire set in the given order. */ bool BME68X::read_parallel(bme68x_data *results, uint16_t *profile_temps, uint16_t *profile_durations, size_t profile_length) { int8_t result; bme68x_data data[3]; // Parallel & Sequential mode read 3 simultaneous fields uint8_t n_fields; uint32_t delay_period; heatr_conf.enable = BME68X_ENABLE; heatr_conf.heatr_temp_prof = profile_temps; heatr_conf.heatr_dur_prof = profile_durations; heatr_conf.profile_len = profile_length; heatr_conf.shared_heatr_dur = 140 - (bme68x_get_meas_dur(BME68X_PARALLEL_MODE, &conf, &device) / 1000); result = bme68x_set_heatr_conf(BME68X_PARALLEL_MODE, &heatr_conf, &device); bme68x_check_rslt("bme68x_set_heatr_conf", result); if(result != BME68X_OK) return false; result = bme68x_set_op_mode(BME68X_PARALLEL_MODE, &device); bme68x_check_rslt("bme68x_set_op_mode", result); if(result != BME68X_OK) return false; while (1) { delay_period = bme68x_get_meas_dur(BME68X_PARALLEL_MODE, &conf, &device) + (heatr_conf.shared_heatr_dur * 1000); device.delay_us(delay_period, device.intf_ptr); result = bme68x_get_data(BME68X_PARALLEL_MODE, data, &n_fields, &device); if(result == BME68X_W_NO_NEW_DATA) continue; bme68x_check_rslt("bme68x_get_data", result); if(result != BME68X_OK) return false; for(auto i = 0u; i < n_fields; i++) { results[data[i].gas_index] = data[i]; if(data[i].gas_index == profile_length - 1) return true; } } return true; } }