diff --git a/bsp/stm32/stm32l475-atk-pandora/board/ports/sensor_port.c b/bsp/stm32/stm32l475-atk-pandora/board/ports/sensor_port.c index cc618575b8..d1df91a23a 100644 --- a/bsp/stm32/stm32l475-atk-pandora/board/ports/sensor_port.c +++ b/bsp/stm32/stm32l475-atk-pandora/board/ports/sensor_port.c @@ -11,36 +11,36 @@ #include #ifdef BSP_USING_ICM20608 -#include "sensor_inven_mpu6xxx.h" +#include -int sensor_init(void) +static int rt_hw_icm20608_port(void) { struct rt_sensor_config cfg; - cfg.intf.type = RT_SENSOR_INTF_I2C; cfg.intf.dev_name = "i2c3"; + cfg.intf.type = RT_SENSOR_INTF_I2C; cfg.intf.arg = (void *)MPU6XXX_ADDR_DEFAULT; cfg.irq_pin.pin = RT_PIN_NONE; rt_hw_mpu6xxx_init("icm", &cfg); - return 0; + return RT_EOK; } -INIT_ENV_EXPORT(sensor_init); +INIT_ENV_EXPORT(rt_hw_icm20608_port); #endif #ifdef BSP_USING_AHT10 -#include "sensor_asair_aht10.h" +#include -#define AHT10_I2C_BUS "i2c4" - -int rt_hw_aht10_port(void) +static int rt_hw_aht10_port(void) { struct rt_sensor_config cfg; - cfg.intf.dev_name = AHT10_I2C_BUS; + cfg.intf.dev_name = "i2c4"; + cfg.intf.type = RT_SENSOR_INTF_I2C; cfg.intf.arg = (void *)AHT10_I2C_ADDR; + cfg.irq_pin.pin = RT_PIN_NONE; rt_hw_aht10_init("aht10", &cfg); diff --git a/components/drivers/include/drivers/sensor.h b/components/drivers/include/drivers/sensor.h index 172979d24d..7146e17ca3 100644 --- a/components/drivers/include/drivers/sensor.h +++ b/components/drivers/include/drivers/sensor.h @@ -6,6 +6,7 @@ * Change Logs: * Date Author Notes * 2019-01-31 flybreak first version + * 2022-12-17 Meco Man re-implement sensor framework */ #ifndef __SENSOR_H__ @@ -32,54 +33,54 @@ extern "C" { #define RT_SENSOR_MACRO_GET_NAME(macro) (macro##_STR) /* Sensor types */ -#define RT_SENSOR_CLASS_NONE (0) -#define RT_SENSOR_CLASS_NONE_STR "None" -#define RT_SENSOR_CLASS_ACCE (1) -#define RT_SENSOR_CLASS_ACCE_STR "Accelerometer" -#define RT_SENSOR_CLASS_GYRO (2) -#define RT_SENSOR_CLASS_GYRO_STR "Gyroscope" -#define RT_SENSOR_CLASS_MAG (3) -#define RT_SENSOR_CLASS_MAG_STR "Magnetometer" -#define RT_SENSOR_CLASS_TEMP (4) -#define RT_SENSOR_CLASS_TEMP_STR "Temperature" -#define RT_SENSOR_CLASS_HUMI (5) -#define RT_SENSOR_CLASS_HUMI_STR "Relative Humidity" -#define RT_SENSOR_CLASS_BARO (6) -#define RT_SENSOR_CLASS_BARO_STR "Barometer" -#define RT_SENSOR_CLASS_LIGHT (7) -#define RT_SENSOR_CLASS_LIGHT_STR "Ambient light" -#define RT_SENSOR_CLASS_PROXIMITY (8) -#define RT_SENSOR_CLASS_PROXIMITY_STR "Proximity" -#define RT_SENSOR_CLASS_HR (9) -#define RT_SENSOR_CLASS_HR_STR "Heart Rate" -#define RT_SENSOR_CLASS_TVOC (10) -#define RT_SENSOR_CLASS_TVOC_STR "TVOC Level" -#define RT_SENSOR_CLASS_NOISE (11) -#define RT_SENSOR_CLASS_NOISE_STR "Noise Loudness" -#define RT_SENSOR_CLASS_STEP (12) -#define RT_SENSOR_CLASS_STEP_STR "Step" -#define RT_SENSOR_CLASS_FORCE (13) -#define RT_SENSOR_CLASS_FORCE_STR "Force" -#define RT_SENSOR_CLASS_DUST (14) -#define RT_SENSOR_CLASS_DUST_STR "Dust" -#define RT_SENSOR_CLASS_ECO2 (15) -#define RT_SENSOR_CLASS_ECO2_STR "eCO2" -#define RT_SENSOR_CLASS_GNSS (16) -#define RT_SENSOR_CLASS_GNSS_STR "GNSS" -#define RT_SENSOR_CLASS_TOF (17) -#define RT_SENSOR_CLASS_TOF_STR "ToF" -#define RT_SENSOR_CLASS_SPO2 (18) -#define RT_SENSOR_CLASS_SPO2_STR "SpO2" -#define RT_SENSOR_CLASS_IAQ (19) -#define RT_SENSOR_CLASS_IAQ_STR "IAQ" -#define RT_SENSOR_CLASS_ETOH (20) -#define RT_SENSOR_CLASS_ETOH_STR "EtOH" -#define RT_SENSOR_CLASS_BP (21) -#define RT_SENSOR_CLASS_BP_STR "Blood Pressure" -#define RT_SENSOR_CLASS_VOLTAGE (22) -#define RT_SENSOR_CLASS_VOLTAGE_STR "Voltage" -#define RT_SENSOR_CLASS_CURRENT (23) -#define RT_SENSOR_CLASS_CURRENT_STR "Current" +#define RT_SENSOR_TYPE_NONE (0) +#define RT_SENSOR_TYPE_NONE_STR "None" +#define RT_SENSOR_TYPE_ACCE (1) +#define RT_SENSOR_TYPE_ACCE_STR "Accelerometer" +#define RT_SENSOR_TYPE_GYRO (2) +#define RT_SENSOR_TYPE_GYRO_STR "Gyroscope" +#define RT_SENSOR_TYPE_MAG (3) +#define RT_SENSOR_TYPE_MAG_STR "Magnetometer" +#define RT_SENSOR_TYPE_TEMP (4) +#define RT_SENSOR_TYPE_TEMP_STR "Temperature" +#define RT_SENSOR_TYPE_HUMI (5) +#define RT_SENSOR_TYPE_HUMI_STR "Relative Humidity" +#define RT_SENSOR_TYPE_BARO (6) +#define RT_SENSOR_TYPE_BARO_STR "Barometer" +#define RT_SENSOR_TYPE_LIGHT (7) +#define RT_SENSOR_TYPE_LIGHT_STR "Ambient light" +#define RT_SENSOR_TYPE_PROXIMITY (8) +#define RT_SENSOR_TYPE_PROXIMITY_STR "Proximity" +#define RT_SENSOR_TYPE_HR (9) +#define RT_SENSOR_TYPE_HR_STR "Heart Rate" +#define RT_SENSOR_TYPE_TVOC (10) +#define RT_SENSOR_TYPE_TVOC_STR "TVOC Level" +#define RT_SENSOR_TYPE_NOISE (11) +#define RT_SENSOR_TYPE_NOISE_STR "Noise Loudness" +#define RT_SENSOR_TYPE_STEP (12) +#define RT_SENSOR_TYPE_STEP_STR "Step" +#define RT_SENSOR_TYPE_FORCE (13) +#define RT_SENSOR_TYPE_FORCE_STR "Force" +#define RT_SENSOR_TYPE_DUST (14) +#define RT_SENSOR_TYPE_DUST_STR "Dust" +#define RT_SENSOR_TYPE_ECO2 (15) +#define RT_SENSOR_TYPE_ECO2_STR "eCO2" +#define RT_SENSOR_TYPE_GNSS (16) +#define RT_SENSOR_TYPE_GNSS_STR "GNSS" +#define RT_SENSOR_TYPE_TOF (17) +#define RT_SENSOR_TYPE_TOF_STR "ToF" +#define RT_SENSOR_TYPE_SPO2 (18) +#define RT_SENSOR_TYPE_SPO2_STR "SpO2" +#define RT_SENSOR_TYPE_IAQ (19) +#define RT_SENSOR_TYPE_IAQ_STR "IAQ" +#define RT_SENSOR_TYPE_ETOH (20) +#define RT_SENSOR_TYPE_ETOH_STR "EtOH" +#define RT_SENSOR_TYPE_BP (21) +#define RT_SENSOR_TYPE_BP_STR "Blood Pressure" +#define RT_SENSOR_TYPE_VOLTAGE (22) +#define RT_SENSOR_TYPE_VOLTAGE_STR "Voltage" +#define RT_SENSOR_TYPE_CURRENT (23) +#define RT_SENSOR_TYPE_CURRENT_STR "Current" /* Sensor vendor types */ #define RT_SENSOR_VENDOR_UNKNOWN (0) @@ -186,33 +187,76 @@ extern "C" { #define RT_SENSOR_INTF_UART_STR "UART" #define RT_SENSOR_INTF_ONEWIRE (1 << 3) #define RT_SENSOR_INTF_ONEWIRE_STR "1-Wire" +#define RT_SENSOR_INTF_CAN (1 << 4) +#define RT_SENSOR_INTF_CAN_STR "CAN" +#define RT_SENSOR_INTF_MODBUS (1 << 5) +#define RT_SENSOR_INTF_MODBUS_STR "Modbus" -/* Sensor power mode types */ -#define RT_SENSOR_POWER_NONE (0) -#define RT_SENSOR_POWER_NONE_STR "None" -#define RT_SENSOR_POWER_DOWN (1) /* power down mode */ -#define RT_SENSOR_POWER_DOWN_STR "Down" -#define RT_SENSOR_POWER_NORMAL (2) /* normal-power mode */ -#define RT_SENSOR_POWER_NORMAL_STR "Normal" -#define RT_SENSOR_POWER_LOW (3) /* low-power mode */ -#define RT_SENSOR_POWER_LOW_STR "Low" -#define RT_SENSOR_POWER_HIGH (4) /* high-power mode */ -#define RT_SENSOR_POWER_HIGH_STR "High" +/** + * Sensor mode + * rt_uint16_t mode + * 0000 | 0000 | 0000 | 0000 + * unused accuracy power fetch data + */ +#define RT_SENSOR_MODE_ACCURACY_BIT_OFFSET (8) +#define RT_SENSOR_MODE_POWER_BIT_OFFSET (4) +#define RT_SENSOR_MODE_FETCH_BIT_OFFSET (0) -/* Sensor work mode types */ -#define RT_SENSOR_MODE_NONE (0) -#define RT_SENSOR_MODE_POLLING (1) /* One shot only read a data */ -#define RT_SENSOR_MODE_INT (2) /* TODO: One shot interrupt only read a data */ -#define RT_SENSOR_MODE_FIFO (3) /* TODO: One shot interrupt read all fifo data */ +#define RT_SENSOR_MODE_GET_ACCURACY(mode) (rt_uint8_t)((mode >> RT_SENSOR_MODE_ACCURACY_BIT_OFFSET) & 0x0F) +#define RT_SENSOR_MODE_GET_POWER(mode) (rt_uint8_t)((mode >> RT_SENSOR_MODE_POWER_BIT_OFFSET) & 0x0F) +#define RT_SENSOR_MODE_GET_FETCH(mode) (rt_uint8_t)((mode >> RT_SENSOR_MODE_FETCH_BIT_OFFSET) & 0x0F) + +#define RT_SENSOR_MODE_CLEAR_ACCURACY(mode) (mode &= ((rt_uint16_t)~((rt_uint16_t)0x0F << RT_SENSOR_MODE_ACCURACY_BIT_OFFSET))) +#define RT_SENSOR_MODE_CLEAR_POWER(mode) (mode &= ((rt_uint16_t)~((rt_uint16_t)0x0F << RT_SENSOR_MODE_POWER_BIT_OFFSET))) +#define RT_SENSOR_MODE_CLEAR_FETCH(mode) (mode &= ((rt_uint16_t)~((rt_uint16_t)0x0F << RT_SENSOR_MODE_FETCH_BIT_OFFSET))) + +#define RT_SENSOR_MODE_SET_ACCURACY(mode, accuracy_mode) RT_SENSOR_MODE_CLEAR_ACCURACY(mode); (mode |= (accuracy_mode << RT_SENSOR_MODE_ACCURACY_BIT_OFFSET)) +#define RT_SENSOR_MODE_SET_POWER(mode, power_mode) RT_SENSOR_MODE_CLEAR_POWER(mode); (mode |= (power_mode << RT_SENSOR_MODE_POWER_BIT_OFFSET)) +#define RT_SENSOR_MODE_SET_FETCH(mode, fetch_mode) RT_SENSOR_MODE_CLEAR_FETCH(mode); (mode |= (fetch_mode << RT_SENSOR_MODE_FETCH_BIT_OFFSET)) + +/* Sensor mode: accuracy */ +#define RT_SENSOR_MODE_ACCURACY_HIGHEST (0) +#define RT_SENSOR_MODE_ACCURACY_HIGHEST_STR "Accuracy Highest" +#define RT_SENSOR_MODE_ACCURACY_HIGH (1) +#define RT_SENSOR_MODE_ACCURACY_HIGH_STR "Accuracy High" +#define RT_SENSOR_MODE_ACCURACY_MEDIUM (2) +#define RT_SENSOR_MODE_ACCURACY_MEDIUM_STR "Accuracy Medium" +#define RT_SENSOR_MODE_ACCURACY_LOW (4) +#define RT_SENSOR_MODE_ACCURACY_LOW_STR "Accuracy Low" +#define RT_SENSOR_MODE_ACCURACY_LOWEST (5) +#define RT_SENSOR_MODE_ACCURACY_LOWEST_STR "Accuracy Lowest" +#define RT_SENSOR_MODE_ACCURACY_NOTRUST (6) +#define RT_SENSOR_MODE_ACCURACY_NOTRUST_STR "Accuracy No Trust" + +/* Sensor mode: power */ +#define RT_SENSOR_MODE_POWER_HIGHEST (0) +#define RT_SENSOR_MODE_POWER_HIGHEST_STR "Power Highest" +#define RT_SENSOR_MODE_POWER_HIGH (1) +#define RT_SENSOR_MODE_POWER_HIGH_STR "Power High" +#define RT_SENSOR_MODE_POWER_MEDIUM (2) +#define RT_SENSOR_MODE_POWER_MEDIUM_STR "Power Medium" +#define RT_SENSOR_MODE_POWER_LOW (3) +#define RT_SENSOR_MODE_POWER_LOW_STR "Power Low" +#define RT_SENSOR_MODE_POWER_LOWEST (4) +#define RT_SENSOR_MODE_POWER_LOWEST_STR "Power Lowest" +#define RT_SENSOR_MODE_POWER_DOWN (5) +#define RT_SENSOR_MODE_POWER_DOWN_STR "Power Down" + +/* Sensor mode: fetch data */ +#define RT_SENSOR_MODE_FETCH_POLLING (0) /* One shot only read a data */ +#define RT_SENSOR_MODE_FETCH_POLLING_STR "Polling Mode" +#define RT_SENSOR_MODE_FETCH_INT (1) /* TODO: One shot interrupt only read a data */ +#define RT_SENSOR_MODE_FETCH_INT_STR "Interrupt Mode" +#define RT_SENSOR_MODE_FETCH_FIFO (2) /* TODO: One shot interrupt read all fifo data */ +#define RT_SENSOR_MODE_FETCH_FIFO_STR "FIFO Mode" /* Sensor control cmd types */ -#define RT_SENSOR_CTRL_GET_ID (RT_DEVICE_CTRL_BASE(Sensor) + 0) /* Get device id */ -#define RT_SENSOR_CTRL_GET_INFO (RT_DEVICE_CTRL_BASE(Sensor) + 1) /* Get sensor info */ -#define RT_SENSOR_CTRL_SET_RANGE (RT_DEVICE_CTRL_BASE(Sensor) + 2) /* Set the measure range of sensor. unit is info of sensor */ -#define RT_SENSOR_CTRL_SET_ODR (RT_DEVICE_CTRL_BASE(Sensor) + 3) /* Set output date rate. unit is HZ */ -#define RT_SENSOR_CTRL_SET_MODE (RT_DEVICE_CTRL_BASE(Sensor) + 4) /* Set sensor's work mode. ex. RT_SENSOR_MODE_POLLING,RT_SENSOR_MODE_INT */ -#define RT_SENSOR_CTRL_SET_POWER (RT_DEVICE_CTRL_BASE(Sensor) + 5) /* Set power mode. args type of sensor power mode. ex. RT_SENSOR_POWER_DOWN,RT_SENSOR_POWER_NORMAL */ -#define RT_SENSOR_CTRL_SELF_TEST (RT_DEVICE_CTRL_BASE(Sensor) + 6) /* Take a self test */ +#define RT_SENSOR_CTRL_GET_ID (RT_DEVICE_CTRL_BASE(Sensor) + 0) /* Get device id */ +#define RT_SENSOR_CTRL_SELF_TEST (RT_DEVICE_CTRL_BASE(Sensor) + 1) /* Take a self test */ +#define RT_SENSOR_CTRL_SOFT_RESET (RT_DEVICE_CTRL_BASE(Sensor) + 2) /* soft reset sensor */ +#define RT_SENSOR_CTRL_SET_FETCH_MODE (RT_DEVICE_CTRL_BASE(Sensor) + 3) /* set fetch data mode */ +#define RT_SENSOR_CTRL_SET_POWER_MODE (RT_DEVICE_CTRL_BASE(Sensor) + 4) /* set power mode */ +#define RT_SENSOR_CTRL_SET_ACCURACY_MODE (RT_DEVICE_CTRL_BASE(Sensor) + 5) /* set accuracy mode */ #define RT_SENSOR_CTRL_USER_CMD_START 0x100 /* User commands should be greater than 0x100 */ @@ -223,17 +267,30 @@ typedef double rt_sensor_float_t; typedef float rt_sensor_float_t; #endif /* RT_USING_SENSOR_DOUBLE_FLOAT */ +struct rt_sensor_accuracy +{ + rt_sensor_float_t resolution; /* resolution of sesnor measurement */ + rt_sensor_float_t error; /* error of sesnor measurement */ +}; + +struct rt_sensor_scale +{ + rt_sensor_float_t range_max; /* maximum range of this sensor's value. unit is 'unit' */ + rt_sensor_float_t range_min; /* minimum range of this sensor's value. unit is 'unit' */ +}; + struct rt_sensor_info { - rt_uint8_t type; /* The sensor type */ - rt_uint8_t vendor; /* Vendor of sensors */ - const char *model; /* model name of sensor */ + rt_uint8_t type; /* sensor type */ + rt_uint8_t vendor; /* sensors vendor */ + const char *name; /* name of sensor */ rt_uint8_t unit; /* unit of measurement */ - rt_uint8_t intf_type; /* Communication interface type */ - rt_int32_t range_max; /* maximum range of this sensor's value. unit is 'unit' */ - rt_int32_t range_min; /* minimum range of this sensor's value. unit is 'unit' */ - rt_uint32_t period_min; /* Minimum measurement period,unit:ms. zero = not a constant rate */ + rt_uint8_t intf_type; /* communication interface type */ + rt_uint16_t mode; /* sensor work mode */ rt_uint8_t fifo_max; + rt_sensor_float_t acquire_min; /* minimum acquirement period, unit:ms. zero = not a constant rate */ + struct rt_sensor_accuracy accuracy; /* sensor current measure accuracy */ + struct rt_sensor_scale scale; /* sensor current scale range */ }; struct rt_sensor_intf @@ -247,15 +304,13 @@ struct rt_sensor_config { struct rt_sensor_intf intf; /* sensor interface config */ struct rt_device_pin_mode irq_pin; /* Interrupt pin, The purpose of this pin is to notification read data */ - rt_uint8_t mode; /* sensor work mode */ - rt_uint8_t power; /* sensor power mode */ - rt_uint16_t odr; /* sensor out data rate */ - rt_int32_t range; /* sensor range of measurement */ }; typedef struct rt_sensor_device *rt_sensor_t; typedef struct rt_sensor_data *rt_sensor_data_t; typedef struct rt_sensor_info *rt_sensor_info_t; +typedef struct rt_sensor_accuracy *rt_sensor_accuracy_t; +typedef struct rt_sensor_scale *rt_sensor_scale_t; struct rt_sensor_device { diff --git a/components/drivers/sensor/sensor.c b/components/drivers/sensor/sensor.c index 3a5a0421df..4966a45405 100644 --- a/components/drivers/sensor/sensor.c +++ b/components/drivers/sensor/sensor.c @@ -7,6 +7,7 @@ * Date Author Notes * 2019-01-31 flybreak first version * 2020-02-22 luhuadong support custom commands + * 2022-12-17 Meco Man re-implement sensor framework */ #include @@ -61,12 +62,12 @@ static void _sensor_cb(rt_sensor_t sen) { sen->parent.rx_indicate(&sen->parent, sen->data_len / sizeof(struct rt_sensor_data)); } - else if (sen->config.mode == RT_SENSOR_MODE_INT) + else if (RT_SENSOR_MODE_GET_FETCH(sen->info.mode) == RT_SENSOR_MODE_FETCH_INT) { /* The interrupt mode only produces one data at a time */ sen->parent.rx_indicate(&sen->parent, 1); } - else if (sen->config.mode == RT_SENSOR_MODE_FIFO) + else if (RT_SENSOR_MODE_GET_FETCH(sen->info.mode) == RT_SENSOR_MODE_FETCH_FIFO) { sen->parent.rx_indicate(&sen->parent, sen->info.fifo_max); } @@ -168,30 +169,32 @@ static rt_err_t _sensor_open(rt_device_t dev, rt_uint16_t oflag) local_ctrl = sensor->ops->control; } - sensor->config.mode = RT_SENSOR_MODE_POLLING; if (oflag & RT_DEVICE_FLAG_RDONLY && dev->flag & RT_DEVICE_FLAG_RDONLY) { /* If polling mode is supported, configure it to polling mode */ - local_ctrl(sensor, RT_SENSOR_CTRL_SET_MODE, (void *)RT_SENSOR_MODE_POLLING); + if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_FETCH_MODE, (void *)RT_SENSOR_MODE_FETCH_POLLING) == RT_EOK) + { + RT_SENSOR_MODE_SET_FETCH(sensor->info.mode, RT_SENSOR_MODE_FETCH_POLLING); + } } else if (oflag & RT_DEVICE_FLAG_INT_RX && dev->flag & RT_DEVICE_FLAG_INT_RX) { /* If interrupt mode is supported, configure it to interrupt mode */ - if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_MODE, (void *)RT_SENSOR_MODE_INT) == RT_EOK) + if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_FETCH_MODE, (void *)RT_SENSOR_MODE_FETCH_INT) == RT_EOK) { /* Initialization sensor interrupt */ _sensor_irq_init(sensor); - sensor->config.mode = RT_SENSOR_MODE_INT; + RT_SENSOR_MODE_SET_FETCH(sensor->info.mode, RT_SENSOR_MODE_FETCH_INT); } } else if (oflag & RT_DEVICE_FLAG_FIFO_RX && dev->flag & RT_DEVICE_FLAG_FIFO_RX) { /* If fifo mode is supported, configure it to fifo mode */ - if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_MODE, (void *)RT_SENSOR_MODE_FIFO) == RT_EOK) + if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_FETCH_MODE, (void *)RT_SENSOR_MODE_FETCH_FIFO) == RT_EOK) { /* Initialization sensor interrupt */ _sensor_irq_init(sensor); - sensor->config.mode = RT_SENSOR_MODE_FIFO; + RT_SENSOR_MODE_SET_FETCH(sensor->info.mode, RT_SENSOR_MODE_FETCH_FIFO); } } else @@ -200,10 +203,16 @@ static rt_err_t _sensor_open(rt_device_t dev, rt_uint16_t oflag) goto __exit; } - /* Configure power mode to normal mode */ - if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_POWER, (void *)RT_SENSOR_POWER_NORMAL) == RT_EOK) + /* Configure power mode to highest mode */ + if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_POWER_MODE, (void *)RT_SENSOR_MODE_POWER_HIGHEST) == RT_EOK) { - sensor->config.power = RT_SENSOR_POWER_NORMAL; + RT_SENSOR_MODE_SET_POWER(sensor->info.mode, RT_SENSOR_MODE_POWER_HIGHEST); + } + + /* Configure accuracy mode to highest mode */ + if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_ACCURACY_MODE, (void *)RT_SENSOR_MODE_ACCURACY_HIGHEST) == RT_EOK) + { + RT_SENSOR_MODE_SET_ACCURACY(sensor->info.mode, RT_SENSOR_MODE_ACCURACY_HIGHEST); } __exit: @@ -234,9 +243,9 @@ static rt_err_t _sensor_close(rt_device_t dev) } /* Configure power mode to power down mode */ - if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_POWER, (void *)RT_SENSOR_POWER_DOWN) == RT_EOK) + if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_POWER_MODE, (void *)RT_SENSOR_MODE_POWER_DOWN) == RT_EOK) { - sensor->config.power = RT_SENSOR_POWER_DOWN; + RT_SENSOR_MODE_SET_POWER(sensor->info.mode, RT_SENSOR_MODE_POWER_DOWN); } if (sensor->module != RT_NULL && sensor->info.fifo_max > 0 && sensor->data_buf != RT_NULL) @@ -257,7 +266,7 @@ static rt_err_t _sensor_close(rt_device_t dev) } } } - if (sensor->config.mode != RT_SENSOR_MODE_POLLING) + if (RT_SENSOR_MODE_GET_FETCH(sensor->info.mode) != RT_SENSOR_MODE_FETCH_POLLING) { /* Sensor disable interrupt */ if (sensor->config.irq_pin.pin != RT_PIN_NONE) @@ -346,45 +355,42 @@ static rt_err_t _sensor_control(rt_device_t dev, int cmd, void *args) result = local_ctrl(sensor, RT_SENSOR_CTRL_GET_ID, args); } break; - case RT_SENSOR_CTRL_GET_INFO: - if (args) - { - rt_memcpy(args, &sensor->info, sizeof(struct rt_sensor_info)); - } - break; - case RT_SENSOR_CTRL_SET_RANGE: - /* Configuration measurement range */ - result = local_ctrl(sensor, RT_SENSOR_CTRL_SET_RANGE, args); - if (result == RT_EOK) - { - sensor->config.range = (rt_int32_t)args; - LOG_D("set range %d", sensor->config.range); - } - break; - case RT_SENSOR_CTRL_SET_ODR: - /* Configuration data output rate */ - result = local_ctrl(sensor, RT_SENSOR_CTRL_SET_ODR, args); - if (result == RT_EOK) - { - sensor->config.odr = (rt_uint32_t)args & 0xFFFF; - LOG_D("set odr %d", sensor->config.odr); - } - break; - case RT_SENSOR_CTRL_SET_POWER: + case RT_SENSOR_CTRL_SET_ACCURACY_MODE: /* Configuration sensor power mode */ - result = local_ctrl(sensor, RT_SENSOR_CTRL_SET_POWER, args); + result = local_ctrl(sensor, RT_SENSOR_CTRL_SET_ACCURACY_MODE, args); if (result == RT_EOK) { - sensor->config.power = (rt_uint32_t)args & 0xFF; - LOG_D("set power mode code:", sensor->config.power); + RT_SENSOR_MODE_SET_ACCURACY(sensor->info.mode, (rt_uint32_t)args & 0x0F); + LOG_D("set accuracy mode code: %d", RT_SENSOR_MODE_GET_ACCURACY(sensor->info.mode)); + } + break; + case RT_SENSOR_CTRL_SET_POWER_MODE: + /* Configuration sensor power mode */ + result = local_ctrl(sensor, RT_SENSOR_CTRL_SET_POWER_MODE, args); + if (result == RT_EOK) + { + RT_SENSOR_MODE_SET_POWER(sensor->info.mode, (rt_uint32_t)args & 0x0F); + LOG_D("set power mode code: %d", RT_SENSOR_MODE_GET_POWER(sensor->info.mode)); + } + break; + case RT_SENSOR_CTRL_SET_FETCH_MODE: + /* Configuration sensor power mode */ + result = local_ctrl(sensor, RT_SENSOR_CTRL_SET_FETCH_MODE, args); + if (result == RT_EOK) + { + RT_SENSOR_MODE_SET_FETCH(sensor->info.mode, (rt_uint32_t)args & 0x0F); + LOG_D("set fetch mode code: %d", RT_SENSOR_MODE_GET_FETCH(sensor->info.mode)); } break; case RT_SENSOR_CTRL_SELF_TEST: - /* Device self-test */ + /* device self test */ result = local_ctrl(sensor, RT_SENSOR_CTRL_SELF_TEST, args); break; + case RT_SENSOR_CTRL_SOFT_RESET: + /* device soft reset */ + result = local_ctrl(sensor, RT_SENSOR_CTRL_SOFT_RESET, args); + break; default: - if (cmd > RT_SENSOR_CTRL_USER_CMD_START) { /* Custom commands */ diff --git a/components/drivers/sensor/sensor_cmd.c b/components/drivers/sensor/sensor_cmd.c index e45171a5c7..59aab3e57e 100644 --- a/components/drivers/sensor/sensor_cmd.c +++ b/components/drivers/sensor/sensor_cmd.c @@ -8,6 +8,7 @@ * 2019-01-31 flybreak first version * 2019-07-16 WillianChan Increase the output of sensor information * 2020-02-22 luhuadong Add vendor info and sensor types for cmd + * 2022-12-17 Meco Man re-implement sensor framework */ #include @@ -25,55 +26,55 @@ static const char *sensor_get_type_name(rt_sensor_info_t info) { switch(info->type) { - case RT_SENSOR_CLASS_ACCE: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_ACCE); - case RT_SENSOR_CLASS_GYRO: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_GYRO); - case RT_SENSOR_CLASS_MAG: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_MAG); - case RT_SENSOR_CLASS_TEMP: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_TEMP); - case RT_SENSOR_CLASS_HUMI: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_HUMI); - case RT_SENSOR_CLASS_BARO: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_BARO); - case RT_SENSOR_CLASS_LIGHT: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_LIGHT); - case RT_SENSOR_CLASS_PROXIMITY: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_PROXIMITY); - case RT_SENSOR_CLASS_HR: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_HR); - case RT_SENSOR_CLASS_TVOC: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_TVOC); - case RT_SENSOR_CLASS_NOISE: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_NOISE); - case RT_SENSOR_CLASS_STEP: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_STEP); - case RT_SENSOR_CLASS_FORCE: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_FORCE); - case RT_SENSOR_CLASS_DUST: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_DUST); - case RT_SENSOR_CLASS_ECO2: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_ECO2); - case RT_SENSOR_CLASS_GNSS: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_GNSS); - case RT_SENSOR_CLASS_TOF: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_TOF); - case RT_SENSOR_CLASS_SPO2: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_SPO2); - case RT_SENSOR_CLASS_IAQ: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_IAQ); - case RT_SENSOR_CLASS_ETOH: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_ETOH); - case RT_SENSOR_CLASS_BP: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_BP); - case RT_SENSOR_CLASS_VOLTAGE: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_VOLTAGE); - case RT_SENSOR_CLASS_CURRENT: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_CURRENT); - case RT_SENSOR_CLASS_NONE: + case RT_SENSOR_TYPE_ACCE: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_ACCE); + case RT_SENSOR_TYPE_GYRO: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_GYRO); + case RT_SENSOR_TYPE_MAG: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_MAG); + case RT_SENSOR_TYPE_TEMP: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_TEMP); + case RT_SENSOR_TYPE_HUMI: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_HUMI); + case RT_SENSOR_TYPE_BARO: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_BARO); + case RT_SENSOR_TYPE_LIGHT: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_LIGHT); + case RT_SENSOR_TYPE_PROXIMITY: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_PROXIMITY); + case RT_SENSOR_TYPE_HR: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_HR); + case RT_SENSOR_TYPE_TVOC: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_TVOC); + case RT_SENSOR_TYPE_NOISE: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_NOISE); + case RT_SENSOR_TYPE_STEP: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_STEP); + case RT_SENSOR_TYPE_FORCE: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_FORCE); + case RT_SENSOR_TYPE_DUST: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_DUST); + case RT_SENSOR_TYPE_ECO2: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_ECO2); + case RT_SENSOR_TYPE_GNSS: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_GNSS); + case RT_SENSOR_TYPE_TOF: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_TOF); + case RT_SENSOR_TYPE_SPO2: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_SPO2); + case RT_SENSOR_TYPE_IAQ: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_IAQ); + case RT_SENSOR_TYPE_ETOH: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_ETOH); + case RT_SENSOR_TYPE_BP: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_BP); + case RT_SENSOR_TYPE_VOLTAGE: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_VOLTAGE); + case RT_SENSOR_TYPE_CURRENT: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_CURRENT); + case RT_SENSOR_TYPE_NONE: default: - return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_NONE); + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_TYPE_NONE); } } @@ -185,76 +186,170 @@ static const char *sensor_get_unit_name(rt_sensor_info_t info) } } +static const char* sensor_get_accuracy_mode_name(rt_sensor_info_t info) +{ + switch(RT_SENSOR_MODE_GET_ACCURACY(info->mode)) + { + case RT_SENSOR_MODE_ACCURACY_HIGHEST: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_ACCURACY_HIGHEST); + case RT_SENSOR_MODE_ACCURACY_HIGH: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_ACCURACY_HIGH); + case RT_SENSOR_MODE_ACCURACY_MEDIUM: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_ACCURACY_MEDIUM); + case RT_SENSOR_MODE_ACCURACY_LOW: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_ACCURACY_LOW); + case RT_SENSOR_MODE_ACCURACY_LOWEST: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_ACCURACY_LOWEST); + case RT_SENSOR_MODE_ACCURACY_NOTRUST: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_ACCURACY_NOTRUST); + default: + LOG_E("accuracy mode illegal!"); + return ""; + } +} + +static const char* sensor_get_power_mode_name(rt_sensor_info_t info) +{ + switch(RT_SENSOR_MODE_GET_POWER(info->mode)) + { + case RT_SENSOR_MODE_POWER_HIGHEST: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_POWER_HIGHEST); + case RT_SENSOR_MODE_POWER_HIGH: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_POWER_HIGH); + case RT_SENSOR_MODE_POWER_MEDIUM: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_POWER_MEDIUM); + case RT_SENSOR_MODE_POWER_LOW: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_POWER_LOW); + case RT_SENSOR_MODE_POWER_LOWEST: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_POWER_LOWEST); + case RT_SENSOR_MODE_POWER_DOWN: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_POWER_DOWN); + default: + LOG_E("power mode illegal!"); + return ""; + } +} + +static const char* sensor_get_fetch_mode_name(rt_sensor_info_t info) +{ + switch(RT_SENSOR_MODE_GET_FETCH(info->mode)) + { + case RT_SENSOR_MODE_FETCH_POLLING: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_FETCH_POLLING); + case RT_SENSOR_MODE_FETCH_INT: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_FETCH_INT); + case RT_SENSOR_MODE_FETCH_FIFO: + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_MODE_FETCH_FIFO); + default: + LOG_E("fetch data mode illegal!"); + return ""; + } +} + static void sensor_show_data(rt_size_t num, rt_sensor_t sensor, struct rt_sensor_data *sensor_data) { const char *unit_name = sensor_get_unit_name(&sensor->info); switch (sensor->info.type) { - case RT_SENSOR_CLASS_ACCE: + case RT_SENSOR_TYPE_ACCE: LOG_I("num:%d, x:%f, y:%f, z:%f %s, timestamp:%u", num, sensor_data->data.acce.x, sensor_data->data.acce.y, sensor_data->data.acce.z, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_GYRO: + case RT_SENSOR_TYPE_GYRO: LOG_I("num:%d, x:%f, y:%f, z:%f %s, timestamp:%u", num, sensor_data->data.gyro.x, sensor_data->data.gyro.y, sensor_data->data.gyro.z, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_MAG: + case RT_SENSOR_TYPE_MAG: LOG_I("num:%d, x:%f, y:%f, z:%f %s, timestamp:%u", num, sensor_data->data.mag.x, sensor_data->data.mag.y, sensor_data->data.mag.z, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_GNSS: + case RT_SENSOR_TYPE_GNSS: LOG_I("num:%d, lon:%f, lat:%f %s, timestamp:%u", num, sensor_data->data.coord.longitude, sensor_data->data.coord.latitude, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_TEMP: + case RT_SENSOR_TYPE_TEMP: LOG_I("num:%d, temp:%f%s, timestamp:%u", num, sensor_data->data.temp, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_HUMI: + case RT_SENSOR_TYPE_HUMI: LOG_I("num:%d, humi:%f%s, timestamp:%u", num, sensor_data->data.humi, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_BARO: + case RT_SENSOR_TYPE_BARO: LOG_I("num:%d, press:%f%s, timestamp:%u", num, sensor_data->data.baro, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_LIGHT: + case RT_SENSOR_TYPE_LIGHT: LOG_I("num:%d, light:%f%s, timestamp:%u", num, sensor_data->data.light, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_PROXIMITY: - case RT_SENSOR_CLASS_TOF: + case RT_SENSOR_TYPE_PROXIMITY: + case RT_SENSOR_TYPE_TOF: LOG_I("num:%d, distance:%f%s, timestamp:%u", num, sensor_data->data.proximity, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_HR: + case RT_SENSOR_TYPE_HR: LOG_I("num:%d, heart rate:%f%s, timestamp:%u", num, sensor_data->data.hr, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_TVOC: + case RT_SENSOR_TYPE_TVOC: LOG_I("num:%d, tvoc:%f%s, timestamp:%u", num, sensor_data->data.tvoc, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_NOISE: + case RT_SENSOR_TYPE_NOISE: LOG_I("num:%d, noise:%f%s, timestamp:%u", num, sensor_data->data.noise, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_STEP: + case RT_SENSOR_TYPE_STEP: LOG_I("num:%d, step:%f%s, timestamp:%u", num, sensor_data->data.step, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_FORCE: + case RT_SENSOR_TYPE_FORCE: LOG_I("num:%d, force:%f%s, timestamp:%u", num, sensor_data->data.force, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_DUST: + case RT_SENSOR_TYPE_DUST: LOG_I("num:%d, dust:%f%s, timestamp:%u", num, sensor_data->data.dust, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_ECO2: + case RT_SENSOR_TYPE_ECO2: LOG_I("num:%d, eco2:%f%s, timestamp:%u", num, sensor_data->data.eco2, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_IAQ: + case RT_SENSOR_TYPE_IAQ: LOG_I("num:%d, IAQ:%f%s, timestamp:%u", num, sensor_data->data.iaq, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_ETOH: + case RT_SENSOR_TYPE_ETOH: LOG_I("num:%d, EtOH:%f%s, timestamp:%u", num, sensor_data->data.etoh, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_BP: + case RT_SENSOR_TYPE_BP: LOG_I("num:%d, bp.sbp:%f, bp.dbp:%f %s, timestamp:%u", num, sensor_data->data.bp.sbp, sensor_data->data.bp.dbp, unit_name, sensor_data->timestamp); break; - case RT_SENSOR_CLASS_NONE: + case RT_SENSOR_TYPE_NONE: default: LOG_E("Unknown type of sensor!"); break; } } +static const char* sensor_get_intf_name(rt_sensor_t sensor) +{ + rt_uint8_t type = sensor->config.intf.type; + + if (type | RT_SENSOR_INTF_I2C) + { + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_INTF_I2C); + } + else if (type | RT_SENSOR_INTF_SPI) + { + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_INTF_SPI); + } + else if (type | RT_SENSOR_INTF_UART) + { + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_INTF_UART); + } + else if (type | RT_SENSOR_INTF_ONEWIRE) + { + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_INTF_ONEWIRE); + } + else if (type | RT_SENSOR_INTF_CAN) + { + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_INTF_CAN); + } + else if (type | RT_SENSOR_INTF_MODBUS) + { + return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_INTF_MODBUS); + } + else + { + return ""; + } +} + static rt_err_t rx_callback(rt_device_t dev, rt_size_t size) { rt_sem_release(sensor_rx_sem); @@ -263,15 +358,11 @@ static rt_err_t rx_callback(rt_device_t dev, rt_size_t size) static void sensor_fifo_rx_entry(void *parameter) { - rt_device_t dev = (rt_device_t)parameter; rt_sensor_t sensor = (rt_sensor_t)parameter; struct rt_sensor_data *data = RT_NULL; - struct rt_sensor_info info; rt_size_t res, i; - rt_device_control(dev, RT_SENSOR_CTRL_GET_INFO, &info); - - data = (struct rt_sensor_data *)rt_malloc(sizeof(struct rt_sensor_data) * info.fifo_max); + data = (struct rt_sensor_data *)rt_malloc(sizeof(struct rt_sensor_data) * sensor->info.fifo_max); if (data == RT_NULL) { LOG_E("Memory allocation failed!"); @@ -281,7 +372,7 @@ static void sensor_fifo_rx_entry(void *parameter) { rt_sem_take(sensor_rx_sem, RT_WAITING_FOREVER); - res = rt_device_read(dev, 0, data, info.fifo_max); + res = rt_device_read((rt_device_t)sensor, 0, data, sensor->info.fifo_max); for (i = 0; i < res; i++) { sensor_show_data(i, sensor, &data[i]); @@ -328,8 +419,6 @@ static void sensor_fifo(int argc, char **argv) rt_thread_startup(tid1); rt_device_set_rx_indicate(dev, rx_callback); - - rt_device_control(dev, RT_SENSOR_CTRL_SET_ODR, (void *)20); } #ifdef RT_USING_FINSH MSH_CMD_EXPORT(sensor_fifo, Sensor fifo mode test function); @@ -393,7 +482,6 @@ static void sensor_int(int argc, char **argv) LOG_E("open device failed!"); return; } - rt_device_control(dev, RT_SENSOR_CTRL_SET_ODR, (void *)20); } #ifdef RT_USING_FINSH MSH_CMD_EXPORT(sensor_int, Sensor interrupt mode test function); @@ -419,7 +507,7 @@ static void sensor_polling(int argc, char **argv) num = atoi(argv[2]); sensor = (rt_sensor_t)dev; - delay = sensor->info.period_min > 100 ? sensor->info.period_min : 100; + delay = sensor->info.acquire_min > 100 ? sensor->info.acquire_min : 100; result = rt_device_open(dev, RT_DEVICE_FLAG_RDONLY); if (result != RT_EOK) @@ -427,7 +515,6 @@ static void sensor_polling(int argc, char **argv) LOG_E("open device failed! error code : %d", result); return; } - rt_device_control(dev, RT_SENSOR_CTRL_SET_ODR, (void *)100); for (i = 0; i < num; i++) { @@ -461,32 +548,33 @@ static void sensor(int argc, char **argv) { rt_kprintf("\n"); rt_kprintf("sensor [OPTION] [PARAM]\n"); - rt_kprintf(" probe Probe sensor by given name\n"); - rt_kprintf(" info Get sensor info\n"); - rt_kprintf(" range Set range to var\n"); - rt_kprintf(" mode Set work mode to var\n"); - rt_kprintf(" power Set power mode to var\n"); - rt_kprintf(" rate Set output date rate to var\n"); - rt_kprintf(" read [num] Read [num] times sensor (default 5)\n"); + rt_kprintf(" probe probe sensor by given name\n"); + rt_kprintf(" info get sensor information\n"); + rt_kprintf(" read [num] read [num] times sensor (default 5)\n"); return ; } else if (!strcmp(argv[1], "info")) { - struct rt_sensor_info info; if (dev == RT_NULL) { LOG_W("Please probe sensor device first!"); return ; } - rt_device_control(dev, RT_SENSOR_CTRL_GET_INFO, &info); - rt_kprintf("model :%s\n", info.model); - rt_kprintf("type: :%s\n", sensor_get_type_name(&info)); - rt_kprintf("vendor :%s\n", sensor_get_vendor_name(&info)); - rt_kprintf("unit :%s\n", sensor_get_unit_name(&info)); - rt_kprintf("range_max :%d\n", info.range_max); - rt_kprintf("range_min :%d\n", info.range_min); - rt_kprintf("period_min:%dms\n", info.period_min); - rt_kprintf("fifo_max :%d\n", info.fifo_max); + sensor = (rt_sensor_t)dev; + rt_kprintf("name :%s\n", sensor->info.name); + rt_kprintf("type: :%s\n", sensor_get_type_name(&sensor->info)); + rt_kprintf("vendor :%s\n", sensor_get_vendor_name(&sensor->info)); + rt_kprintf("interface :%s\n", sensor_get_intf_name(sensor)); + rt_kprintf("unit :%s\n", sensor_get_unit_name(&sensor->info)); + rt_kprintf("fetch data:%s\n", sensor_get_fetch_mode_name(&sensor->info)); + rt_kprintf("power :%s\n", sensor_get_power_mode_name(&sensor->info)); + rt_kprintf("accuracy :%s\n", sensor_get_accuracy_mode_name(&sensor->info)); + rt_kprintf("range max :%f\n", sensor->info.scale.range_max); + rt_kprintf("range min :%f\n", sensor->info.scale.range_min); + rt_kprintf("resolution:%f\n", sensor->info.accuracy.resolution); + rt_kprintf("error :%f\n", sensor->info.accuracy.error); + rt_kprintf("acquire min:%fms\n", sensor->info.acquire_min); + rt_kprintf("fifo max :%d\n", sensor->info.fifo_max); } else if (!strcmp(argv[1], "read")) { @@ -503,7 +591,7 @@ static void sensor(int argc, char **argv) } sensor = (rt_sensor_t)dev; - delay = sensor->info.period_min > 100 ? sensor->info.period_min : 100; + delay = sensor->info.acquire_min > 100 ? sensor->info.acquire_min : 100; for (i = 0; i < num; i++) { @@ -537,8 +625,10 @@ static void sensor(int argc, char **argv) LOG_E("open device failed!"); return; } - rt_device_control(new_dev, RT_SENSOR_CTRL_GET_ID, ®); - LOG_I("device id: 0x%x!", reg); + if (rt_device_control(new_dev, RT_SENSOR_CTRL_GET_ID, ®) == RT_EOK) + { + LOG_I("Sensor Chip ID: %#x", reg); + } if (dev) { rt_device_close(dev); @@ -550,22 +640,6 @@ static void sensor(int argc, char **argv) LOG_W("Please probe sensor first!"); return ; } - else if (!strcmp(argv[1], "range")) - { - rt_device_control(dev, RT_SENSOR_CTRL_SET_RANGE, (void *)atoi(argv[2])); - } - else if (!strcmp(argv[1], "mode")) - { - rt_device_control(dev, RT_SENSOR_CTRL_SET_MODE, (void *)atoi(argv[2])); - } - else if (!strcmp(argv[1], "power")) - { - rt_device_control(dev, RT_SENSOR_CTRL_SET_POWER, (void *)atoi(argv[2])); - } - else if (!strcmp(argv[1], "rate")) - { - rt_device_control(dev, RT_SENSOR_CTRL_SET_ODR, (void *)atoi(argv[2])); - } else { LOG_W("Unknown command, please enter 'sensor' get help information!");