rt-thread/components/drivers/sensor/sensor_cmd.c

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/*
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* Copyright (c) 2006-2021, RT-Thread Development Team
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*
* SPDX-License-Identifier: Apache-2.0
*
* Change Logs:
* Date Author Notes
* 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
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*/
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#include <drivers/sensor.h>
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#define DBG_TAG "sensor.cmd"
#define DBG_LVL DBG_INFO
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#include <rtdbg.h>
#include <stdlib.h>
#include <string.h>
static rt_sem_t sensor_rx_sem = RT_NULL;
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_NONE:
default:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_CLASS_NONE);
}
}
static const char *sensor_get_vendor_name(rt_sensor_info_t info)
{
switch(info->vendor)
{
case RT_SENSOR_VENDOR_STM:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_STM);
case RT_SENSOR_VENDOR_BOSCH:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_BOSCH);
case RT_SENSOR_VENDOR_INVENSENSE:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_INVENSENSE);
case RT_SENSOR_VENDOR_SEMTECH:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_SEMTECH);
case RT_SENSOR_VENDOR_GOERTEK:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_GOERTEK);
case RT_SENSOR_VENDOR_MIRAMEMS:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_MIRAMEMS);
case RT_SENSOR_VENDOR_DALLAS:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_DALLAS);
case RT_SENSOR_VENDOR_ASAIR:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_ASAIR);
case RT_SENSOR_VENDOR_SHARP:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_SHARP);
case RT_SENSOR_VENDOR_SENSIRION:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_SENSIRION);
case RT_SENSOR_VENDOR_TI:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_TI);
case RT_SENSOR_VENDOR_PLANTOWER:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_PLANTOWER);
case RT_SENSOR_VENDOR_AMS:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_AMS);
case RT_SENSOR_VENDOR_MAXIM:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_MAXIM);
case RT_SENSOR_VENDOR_MELEXIS:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_MELEXIS);
case RT_SENSOR_VENDOR_UNKNOWN:
default:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_VENDOR_UNKNOWN);
}
}
static const char *sensor_get_unit_name(rt_sensor_info_t info)
{
switch(info->unit)
{
case RT_SENSOR_UNIT_MG:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_MG);
case RT_SENSOR_UNIT_MDPS:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_MDPS);
case RT_SENSOR_UNIT_MGAUSS:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_MGAUSS);
case RT_SENSOR_UNIT_LUX:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_LUX);
case RT_SENSOR_UNIT_CM:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_CM);
case RT_SENSOR_UNIT_MM:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_MM);
case RT_SENSOR_UNIT_PA:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_PA);
case RT_SENSOR_UNIT_MMHG:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_MMHG);
case RT_SENSOR_UNIT_PERMILLAGE:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_PERMILLAGE);
case RT_SENSOR_UNIT_PERCENTAGE:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_PERCENTAGE);
case RT_SENSOR_UNIT_CELSIUS:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_CELSIUS);
case RT_SENSOR_UNIT_FAHRENHEIT:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_FAHRENHEIT);
case RT_SENSOR_UNIT_KELVIN:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_KELVIN);
case RT_SENSOR_UNIT_HZ:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_HZ);
case RT_SENSOR_UNIT_BPM:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_BPM);
case RT_SENSOR_UNIT_MN:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_MN);
case RT_SENSOR_UNIT_N:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_N);
case RT_SENSOR_UNIT_PPM:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_PPM);
case RT_SENSOR_UNIT_PPB:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_PPB);
case RT_SENSOR_UNIT_DMS:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_DMS);
case RT_SENSOR_UNIT_DD:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_DD);
case RT_SENSOR_UNIT_MGM3:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_MGM3);
case RT_SENSOR_UNIT_NONE:
default:
return RT_SENSOR_MACRO_GET_NAME(RT_SENSOR_UNIT_NONE);
}
}
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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);
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switch (sensor->info.type)
{
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case RT_SENSOR_CLASS_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);
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break;
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case RT_SENSOR_CLASS_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);
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break;
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case RT_SENSOR_CLASS_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);
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break;
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case RT_SENSOR_CLASS_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);
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break;
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case RT_SENSOR_CLASS_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:
LOG_I("num:%d, humi:%f%s, timestamp:%u", num, sensor_data->data.humi, unit_name, sensor_data->timestamp);
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break;
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case RT_SENSOR_CLASS_BARO:
LOG_I("num:%d, press:%f%s, timestamp:%u", num, sensor_data->data.baro, unit_name, sensor_data->timestamp);
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break;
case RT_SENSOR_CLASS_LIGHT:
LOG_I("num:%d, light:%f%s, timestamp:%u", num, sensor_data->data.light, unit_name, sensor_data->timestamp);
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break;
case RT_SENSOR_CLASS_PROXIMITY:
case RT_SENSOR_CLASS_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:
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:
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:
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:
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:
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:
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:
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:
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:
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:
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:
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default:
LOG_E("Unknown type of sensor!");
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break;
}
}
static rt_err_t rx_callback(rt_device_t dev, rt_size_t size)
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{
rt_sem_release(sensor_rx_sem);
return 0;
}
static void sensor_fifo_rx_entry(void *parameter)
{
rt_device_t dev = (rt_device_t)parameter;
rt_sensor_t sensor = (rt_sensor_t)parameter;
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struct rt_sensor_data *data = RT_NULL;
struct rt_sensor_info info;
rt_size_t res, i;
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rt_device_control(dev, RT_SENSOR_CTRL_GET_INFO, &info);
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data = (struct rt_sensor_data *)rt_malloc(sizeof(struct rt_sensor_data) * info.fifo_max);
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if (data == RT_NULL)
{
LOG_E("Memory allocation failed!");
}
while (1)
{
rt_sem_take(sensor_rx_sem, RT_WAITING_FOREVER);
res = rt_device_read(dev, 0, data, info.fifo_max);
for (i = 0; i < res; i++)
{
sensor_show_data(i, sensor, &data[i]);
}
}
}
static void sensor_fifo(int argc, char **argv)
{
static rt_thread_t tid1 = RT_NULL;
rt_device_t dev = RT_NULL;
rt_sensor_t sensor;
dev = rt_device_find(argv[1]);
if (dev == RT_NULL)
{
LOG_E("Can't find device:%s", argv[1]);
return;
}
sensor = (rt_sensor_t)dev;
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if (rt_device_open(dev, RT_DEVICE_FLAG_FIFO_RX) != RT_EOK)
{
LOG_E("open device failed!");
return;
}
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if (sensor_rx_sem == RT_NULL)
{
sensor_rx_sem = rt_sem_create("sen_rx_sem", 0, RT_IPC_FLAG_FIFO);
}
else
{
LOG_E("The thread is running, please reboot and try again");
return;
}
tid1 = rt_thread_create("sen_rx_thread",
sensor_fifo_rx_entry, sensor,
1024,
15, 5);
if (tid1 != RT_NULL)
rt_thread_startup(tid1);
rt_device_set_rx_indicate(dev, rx_callback);
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rt_device_control(dev, RT_SENSOR_CTRL_SET_ODR, (void *)20);
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}
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#ifdef RT_USING_FINSH
MSH_CMD_EXPORT(sensor_fifo, Sensor fifo mode test function);
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#endif
static void sensor_irq_rx_entry(void *parameter)
{
rt_device_t dev = (rt_device_t)parameter;
rt_sensor_t sensor = (rt_sensor_t)parameter;
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struct rt_sensor_data data;
rt_size_t res, i = 0;
while (1)
{
rt_sem_take(sensor_rx_sem, RT_WAITING_FOREVER);
res = rt_device_read(dev, 0, &data, 1);
if (res == 1)
{
sensor_show_data(i++, sensor, &data);
}
}
}
static void sensor_int(int argc, char **argv)
{
static rt_thread_t tid1 = RT_NULL;
rt_device_t dev = RT_NULL;
rt_sensor_t sensor;
dev = rt_device_find(argv[1]);
if (dev == RT_NULL)
{
LOG_E("Can't find device:%s", argv[1]);
return;
}
sensor = (rt_sensor_t)dev;
if (sensor_rx_sem == RT_NULL)
{
sensor_rx_sem = rt_sem_create("sen_rx_sem", 0, RT_IPC_FLAG_FIFO);
}
else
{
LOG_E("The thread is running, please reboot and try again");
return;
}
tid1 = rt_thread_create("sen_rx_thread",
sensor_irq_rx_entry, sensor,
1024,
15, 5);
if (tid1 != RT_NULL)
rt_thread_startup(tid1);
rt_device_set_rx_indicate(dev, rx_callback);
if (rt_device_open(dev, RT_DEVICE_FLAG_INT_RX) != RT_EOK)
{
LOG_E("open device failed!");
return;
}
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rt_device_control(dev, RT_SENSOR_CTRL_SET_ODR, (void *)20);
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}
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#ifdef RT_USING_FINSH
MSH_CMD_EXPORT(sensor_int, Sensor interrupt mode test function);
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#endif
static void sensor_polling(int argc, char **argv)
{
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rt_uint16_t num = 10;
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rt_device_t dev = RT_NULL;
rt_sensor_t sensor;
struct rt_sensor_data data;
rt_size_t res, i;
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rt_int32_t delay;
rt_err_t result;
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dev = rt_device_find(argv[1]);
if (dev == RT_NULL)
{
LOG_E("Can't find device:%s", argv[1]);
return;
}
if (argc > 2)
num = atoi(argv[2]);
sensor = (rt_sensor_t)dev;
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delay = sensor->info.period_min > 100 ? sensor->info.period_min : 100;
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result = rt_device_open(dev, RT_DEVICE_FLAG_RDONLY);
if (result != RT_EOK)
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{
LOG_E("open device failed! error code : %d", result);
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return;
}
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rt_device_control(dev, RT_SENSOR_CTRL_SET_ODR, (void *)100);
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for (i = 0; i < num; i++)
{
res = rt_device_read(dev, 0, &data, 1);
if (res != 1)
{
LOG_E("read data failed!size is %d", res);
}
else
{
sensor_show_data(i, sensor, &data);
}
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rt_thread_mdelay(delay);
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}
rt_device_close(dev);
}
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#ifdef RT_USING_FINSH
MSH_CMD_EXPORT(sensor_polling, Sensor polling mode test function);
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#endif
static void sensor(int argc, char **argv)
{
static rt_device_t dev = RT_NULL;
struct rt_sensor_data data;
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rt_sensor_t sensor;
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rt_size_t res, i;
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rt_int32_t delay;
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/* If the number of arguments less than 2 */
if (argc < 2)
{
rt_kprintf("\n");
rt_kprintf("sensor [OPTION] [PARAM]\n");
rt_kprintf(" probe <dev_name> Probe sensor by given name\n");
rt_kprintf(" info Get sensor info\n");
rt_kprintf(" range <var> Set range to var\n");
rt_kprintf(" mode <var> Set work mode to var\n");
rt_kprintf(" power <var> Set power mode to var\n");
rt_kprintf(" rate <var> Set output date rate to var\n");
rt_kprintf(" read [num] Read [num] times sensor (default 5)\n");
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return ;
}
else if (!strcmp(argv[1], "info"))
{
struct rt_sensor_info info;
if (dev == RT_NULL)
{
LOG_W("Please probe sensor device first!");
return ;
}
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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));
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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);
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rt_kprintf("fifo_max :%d\n", info.fifo_max);
}
else if (!strcmp(argv[1], "read"))
{
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rt_uint16_t num = 5;
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if (dev == RT_NULL)
{
LOG_W("Please probe sensor device first!");
return ;
}
if (argc == 3)
{
num = atoi(argv[2]);
}
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sensor = (rt_sensor_t)dev;
delay = sensor->info.period_min > 100 ? sensor->info.period_min : 100;
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for (i = 0; i < num; i++)
{
res = rt_device_read(dev, 0, &data, 1);
if (res != 1)
{
LOG_E("read data failed!size is %d", res);
}
else
{
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sensor_show_data(i, sensor, &data);
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}
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rt_thread_mdelay(delay);
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}
}
else if (argc == 3)
{
if (!strcmp(argv[1], "probe"))
{
rt_uint8_t reg = 0xFF;
rt_device_t new_dev;
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new_dev = rt_device_find(argv[2]);
if (new_dev == RT_NULL)
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{
LOG_E("Can't find device:%s", argv[2]);
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return;
}
if (rt_device_open(new_dev, RT_DEVICE_FLAG_RDWR) != RT_EOK)
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{
LOG_E("open device failed!");
return;
}
rt_device_control(new_dev, RT_SENSOR_CTRL_GET_ID, &reg);
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LOG_I("device id: 0x%x!", reg);
if (dev)
{
rt_device_close(dev);
}
dev = new_dev;
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}
else if (dev == RT_NULL)
{
LOG_W("Please probe sensor first!");
return ;
}
else if (!strcmp(argv[1], "range"))
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{
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rt_device_control(dev, RT_SENSOR_CTRL_SET_RANGE, (void *)atoi(argv[2]));
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}
else if (!strcmp(argv[1], "mode"))
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{
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rt_device_control(dev, RT_SENSOR_CTRL_SET_MODE, (void *)atoi(argv[2]));
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}
else if (!strcmp(argv[1], "power"))
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{
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rt_device_control(dev, RT_SENSOR_CTRL_SET_POWER, (void *)atoi(argv[2]));
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}
else if (!strcmp(argv[1], "rate"))
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{
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rt_device_control(dev, RT_SENSOR_CTRL_SET_ODR, (void *)atoi(argv[2]));
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}
else
{
LOG_W("Unknown command, please enter 'sensor' get help information!");
}
}
else
{
LOG_W("Unknown command, please enter 'sensor' get help information!");
}
}
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#ifdef RT_USING_FINSH
MSH_CMD_EXPORT(sensor, sensor test function);
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#endif