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Merge pull request #4476 from xfwangqiang/sensor_pr

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[components][sensor]Optimize the Sensor Module
This commit is contained in:
Bernard Xiong
2021-03-23 20:09:26 +08:00
committed by GitHub
parent e4b505af23 c72227680d
commit 5ded4a1f52
6 changed files with 338 additions and 282 deletions
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components/drivers/include/drivers/pin.h
-1
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@@ -13,7 +13,6 @@
#define PIN_H__ #define PIN_H__
#include <rtthread.h> #include <rtthread.h>
#include <rtdevice.h>
#ifdef __cplusplus #ifdef __cplusplus
extern "C" { extern "C" {
components/drivers/include/drivers/sensor.h
+238
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@@ -0,0 +1,238 @@
/*
* Copyright (c) 2006-2021, RT-Thread Development Team
*
* SPDX-License-Identifier: Apache-2.0
*
* Change Logs:
* Date Author Notes
* 2019-01-31 flybreak first version
*/
#ifndef __SENSOR_H__
#define __SENSOR_H__
#include <rtthread.h>
#include "pin.h"
#ifdef __cplusplus
extern "C" {
#endif
#ifdef RT_USING_RTC
#define rt_sensor_get_ts() time(RT_NULL) /* API for the sensor to get the timestamp */
#else
#define rt_sensor_get_ts() rt_tick_get() /* API for the sensor to get the timestamp */
#endif
#define RT_PIN_NONE 0xFFFF /* RT PIN NONE */
#define RT_DEVICE_FLAG_FIFO_RX 0x200 /* Flag to use when the sensor is open by fifo mode */
#define RT_SENSOR_MODULE_MAX (3) /* The maximum number of members of a sensor module */
/* Sensor types */
#define RT_SENSOR_CLASS_NONE (0)
#define RT_SENSOR_CLASS_ACCE (1) /* Accelerometer */
#define RT_SENSOR_CLASS_GYRO (2) /* Gyroscope */
#define RT_SENSOR_CLASS_MAG (3) /* Magnetometer */
#define RT_SENSOR_CLASS_TEMP (4) /* Temperature */
#define RT_SENSOR_CLASS_HUMI (5) /* Relative Humidity */
#define RT_SENSOR_CLASS_BARO (6) /* Barometer */
#define RT_SENSOR_CLASS_LIGHT (7) /* Ambient light */
#define RT_SENSOR_CLASS_PROXIMITY (8) /* Proximity */
#define RT_SENSOR_CLASS_HR (9) /* Heart Rate */
#define RT_SENSOR_CLASS_TVOC (10) /* TVOC Level */
#define RT_SENSOR_CLASS_NOISE (11) /* Noise Loudness */
#define RT_SENSOR_CLASS_STEP (12) /* Step sensor */
#define RT_SENSOR_CLASS_FORCE (13) /* Force sensor */
#define RT_SENSOR_CLASS_DUST (14) /* Dust sensor */
#define RT_SENSOR_CLASS_ECO2 (15) /* eCO2 sensor */
#define RT_SENSOR_CLASS_GNSS (16) /* GPS/GNSS sensor */
#define RT_SENSOR_CLASS_TOF (17) /* TOF sensor */
/* Sensor vendor types */
#define RT_SENSOR_VENDOR_UNKNOWN (0)
#define RT_SENSOR_VENDOR_STM (1) /* STMicroelectronics */
#define RT_SENSOR_VENDOR_BOSCH (2) /* Bosch */
#define RT_SENSOR_VENDOR_INVENSENSE (3) /* Invensense */
#define RT_SENSOR_VENDOR_SEMTECH (4) /* Semtech */
#define RT_SENSOR_VENDOR_GOERTEK (5) /* Goertek */
#define RT_SENSOR_VENDOR_MIRAMEMS (6) /* MiraMEMS */
#define RT_SENSOR_VENDOR_DALLAS (7) /* Dallas */
#define RT_SENSOR_VENDOR_ASAIR (8) /* Aosong */
#define RT_SENSOR_VENDOR_SHARP (9) /* Sharp */
#define RT_SENSOR_VENDOR_SENSIRION (10) /* Sensirion */
#define RT_SENSOR_VENDOR_TI (11) /* Texas Instruments */
#define RT_SENSOR_VENDOR_PLANTOWER (12) /* Plantower */
#define RT_SENSOR_VENDOR_AMS (13) /* ams AG */
#define RT_SENSOR_VENDOR_MAXIM (14) /* Maxim Integrated */
/* Sensor unit types */
#define RT_SENSOR_UNIT_NONE (0)
#define RT_SENSOR_UNIT_MG (1) /* Accelerometer unit: mG */
#define RT_SENSOR_UNIT_MDPS (2) /* Gyroscope unit: mdps */
#define RT_SENSOR_UNIT_MGAUSS (3) /* Magnetometer unit: mGauss */
#define RT_SENSOR_UNIT_LUX (4) /* Ambient light unit: lux */
#define RT_SENSOR_UNIT_CM (5) /* Distance unit: cm */
#define RT_SENSOR_UNIT_PA (6) /* Barometer unit: pa */
#define RT_SENSOR_UNIT_PERMILLAGE (7) /* Relative Humidity unit: permillage */
#define RT_SENSOR_UNIT_DCELSIUS (8) /* Temperature unit: dCelsius */
#define RT_SENSOR_UNIT_HZ (9) /* Frequency unit: HZ */
#define RT_SENSOR_UNIT_ONE (10) /* Dimensionless quantity unit: 1 */
#define RT_SENSOR_UNIT_BPM (11) /* Heart rate unit: bpm */
#define RT_SENSOR_UNIT_MM (12) /* Distance unit: mm */
#define RT_SENSOR_UNIT_MN (13) /* Force unit: mN */
#define RT_SENSOR_UNIT_PPM (14) /* Concentration unit: ppm */
#define RT_SENSOR_UNIT_PPB (15) /* Concentration unit: ppb */
#define RT_SENSOR_UNIT_DMS (16) /* Coordinates unit: DMS */
#define RT_SENSOR_UNIT_DD (17) /* Coordinates unit: DD */
/* Sensor communication interface types */
#define RT_SENSOR_INTF_I2C (1 << 0)
#define RT_SENSOR_INTF_SPI (1 << 1)
#define RT_SENSOR_INTF_UART (1 << 2)
#define RT_SENSOR_INTF_ONEWIRE (1 << 3)
/* Sensor power mode types */
#define RT_SENSOR_POWER_NONE (0)
#define RT_SENSOR_POWER_DOWN (1) /* power down mode */
#define RT_SENSOR_POWER_NORMAL (2) /* normal-power mode */
#define RT_SENSOR_POWER_LOW (3) /* low-power mode */
#define RT_SENSOR_POWER_HIGH (4) /* high-power mode */
/* 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 */
/* Sensor control cmd types */
#define RT_SENSOR_CTRL_GET_ID (0) /* Get device id */
#define RT_SENSOR_CTRL_GET_INFO (1) /* Get sensor info */
#define RT_SENSOR_CTRL_SET_RANGE (2) /* Set the measure range of sensor. unit is info of sensor */
#define RT_SENSOR_CTRL_SET_ODR (3) /* Set output date rate. unit is HZ */
#define RT_SENSOR_CTRL_SET_MODE (4) /* Set sensor's work mode. ex. RT_SENSOR_MODE_POLLING,RT_SENSOR_MODE_INT */
#define RT_SENSOR_CTRL_SET_POWER (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 (6) /* Take a self test */
#define RT_SENSOR_CTRL_USER_CMD_START 0x100 /* User commands should be greater than 0x100 */
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 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 fifo_max;
};
struct rt_sensor_intf
{
char *dev_name; /* The name of the communication device */
rt_uint8_t type; /* Communication interface type */
void *user_data; /* Private data for the sensor. ex. i2c addr,spi cs,control I/O */
};
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;
struct rt_sensor_device
{
struct rt_device parent; /* The standard device */
struct rt_sensor_info info; /* The sensor info data */
struct rt_sensor_config config; /* The sensor config data */
void *data_buf; /* The buf of the data received */
rt_size_t data_len; /* The size of the data received */
const struct rt_sensor_ops *ops; /* The sensor ops */
struct rt_sensor_module *module; /* The sensor module */
rt_err_t (*irq_handle)(rt_sensor_t sensor); /* Called when an interrupt is generated, registered by the driver */
};
struct rt_sensor_module
{
rt_mutex_t lock; /* The module lock */
rt_sensor_t sen[RT_SENSOR_MODULE_MAX]; /* The module contains a list of sensors */
rt_uint8_t sen_num; /* Number of sensors contained in the module */
};
/* 3-axis Data Type */
struct sensor_3_axis
{
rt_int32_t x;
rt_int32_t y;
rt_int32_t z;
};
struct coordinates
{
double longitude;
double latitude;
};
struct rt_sensor_data
{
rt_uint32_t timestamp; /* The timestamp when the data was received */
rt_uint8_t type; /* The sensor type of the data */
union
{
struct sensor_3_axis acce; /* Accelerometer. unit: mG */
struct sensor_3_axis gyro; /* Gyroscope. unit: mdps */
struct sensor_3_axis mag; /* Magnetometer. unit: mGauss */
struct coordinates coord; /* Coordinates unit: degrees */
rt_int32_t temp; /* Temperature. unit: dCelsius */
rt_int32_t humi; /* Relative humidity. unit: permillage */
rt_int32_t baro; /* Pressure. unit: pascal (Pa) */
rt_int32_t light; /* Light. unit: lux */
rt_int32_t proximity; /* Distance. unit: centimeters */
rt_int32_t hr; /* Heart rate. unit: bpm */
rt_int32_t tvoc; /* TVOC. unit: permillage */
rt_int32_t noise; /* Noise Loudness. unit: HZ */
rt_uint32_t step; /* Step sensor. unit: 1 */
rt_int32_t force; /* Force sensor. unit: mN */
rt_uint32_t dust; /* Dust sensor. unit: ug/m3 */
rt_uint32_t eco2; /* eCO2 sensor. unit: ppm */
} data;
};
struct rt_sensor_ops
{
rt_size_t (*fetch_data)(struct rt_sensor_device *sensor, void *buf, rt_size_t len);
rt_err_t (*control)(struct rt_sensor_device *sensor, int cmd, void *arg);
};
int rt_hw_sensor_register(rt_sensor_t sensor,
const char *name,
rt_uint32_t flag,
void *data);
#ifdef __cplusplus
}
#endif
#endif /* __SENSOR_H__ */
components/drivers/include/rtdevice.h
+23 -17
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@@ -78,70 +78,76 @@ extern "C" {
#include "drivers/mmcsd_core.h" #include "drivers/mmcsd_core.h"
#include "drivers/sd.h" #include "drivers/sd.h"
#include "drivers/sdio.h" #include "drivers/sdio.h"
#endif #endif /* RT_USING_SDIO */
#ifdef RT_USING_WDT #ifdef RT_USING_WDT
#include "drivers/watchdog.h" #include "drivers/watchdog.h"
#endif #endif /* RT_USING_WDT */
#ifdef RT_USING_PIN #ifdef RT_USING_PIN
#include "drivers/pin.h" #include "drivers/pin.h"
#endif #endif /* RT_USING_PIN */
#ifdef RT_USING_SENSOR
#include "drivers/sensor.h"
#endif /* RT_USING_SENSOR */
#ifdef RT_USING_CAN #ifdef RT_USING_CAN
#include "drivers/can.h" #include "drivers/can.h"
#endif #endif /* RT_USING_CAN */
#ifdef RT_USING_HWTIMER #ifdef RT_USING_HWTIMER
#include "drivers/hwtimer.h" #include "drivers/hwtimer.h"
#endif #endif /* RT_USING_HWTIMER */
#ifdef RT_USING_AUDIO #ifdef RT_USING_AUDIO
#include "drivers/audio.h" #include "drivers/audio.h"
#endif #endif /* RT_USING_AUDIO */
#ifdef RT_USING_CPUTIME #ifdef RT_USING_CPUTIME
#include "drivers/cputime.h" #include "drivers/cputime.h"
#endif #endif /* RT_USING_CPUTIME */
#ifdef RT_USING_ADC #ifdef RT_USING_ADC
#include "drivers/adc.h" #include "drivers/adc.h"
#endif #endif /* RT_USING_ADC */
#ifdef RT_USING_DAC #ifdef RT_USING_DAC
#include "drivers/dac.h" #include "drivers/dac.h"
#endif #endif /* RT_USING_DAC */
#ifdef RT_USING_PWM #ifdef RT_USING_PWM
#include "drivers/rt_drv_pwm.h" #include "drivers/rt_drv_pwm.h"
#endif #endif /* RT_USING_PWM */
#ifdef RT_USING_PM #ifdef RT_USING_PM
#include "drivers/pm.h" #include "drivers/pm.h"
#endif #endif /* RT_USING_PM */
#ifdef RT_USING_WIFI #ifdef RT_USING_WIFI
#include "drivers/wlan.h" #include "drivers/wlan.h"
#endif #endif /* RT_USING_WIFI */
#ifdef MTD_USING_NOR #ifdef MTD_USING_NOR
#include "drivers/mtdnor.h" #include "drivers/mtdnor.h"
#endif #endif /* MTD_USING_NOR */
#ifdef MTD_USING_NAND #ifdef MTD_USING_NAND
#include "drivers/mtdnand.h" #include "drivers/mtdnand.h"
#endif #endif /* MTD_USING_NAND */
#ifdef RT_USING_HWCRYPTO #ifdef RT_USING_HWCRYPTO
#include "drivers/crypto.h" #include "drivers/crypto.h"
#endif #endif /* RT_USING_HWCRYPTO */
#ifdef RT_USING_PULSE_ENCODER #ifdef RT_USING_PULSE_ENCODER
#include "drivers/pulse_encoder.h" #include "drivers/pulse_encoder.h"
#endif #endif /* RT_USING_PULSE_ENCODER */
#ifdef RT_USING_INPUT_CAPTURE #ifdef RT_USING_INPUT_CAPTURE
#include "drivers/rt_inputcapture.h" #include "drivers/rt_inputcapture.h"
#endif #endif /* RT_USING_INPUT_CAPTURE */
#ifdef __cplusplus #ifdef __cplusplus
} }
components/drivers/sensors/sensor.c
+72 -37
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@@ -121,12 +121,30 @@ static rt_err_t rt_sensor_irq_init(rt_sensor_t sensor)
return 0; return 0;
} }
// local rt_sensor_ops
static rt_size_t local_fetch_data(struct rt_sensor_device *sensor, void *buf, rt_size_t len)
{
LOG_D("Undefined fetch_data");
return 0;
}
static rt_err_t local_control(struct rt_sensor_device *sensor, int cmd, void *arg)
{
LOG_D("Undefined control");
return RT_ERROR;
}
static struct rt_sensor_ops local_ops = {
.fetch_data = local_fetch_data,
.control = local_control
};
/* RT-Thread Device Interface */ /* RT-Thread Device Interface */
static rt_err_t rt_sensor_open(rt_device_t dev, rt_uint16_t oflag) static rt_err_t rt_sensor_open(rt_device_t dev, rt_uint16_t oflag)
{ {
rt_sensor_t sensor = (rt_sensor_t)dev; rt_sensor_t sensor = (rt_sensor_t)dev;
RT_ASSERT(dev != RT_NULL); RT_ASSERT(dev != RT_NULL);
rt_err_t res = RT_EOK; rt_err_t res = RT_EOK;
rt_err_t (*local_ctrl)(struct rt_sensor_device *sensor, int cmd, void *arg) = local_control;
if (sensor->module) if (sensor->module)
{ {
@@ -144,37 +162,36 @@ static rt_err_t rt_sensor_open(rt_device_t dev, rt_uint16_t oflag)
goto __exit; goto __exit;
} }
} }
if (sensor->ops->control != RT_NULL)
{
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 (oflag & RT_DEVICE_FLAG_RDONLY && dev->flag & RT_DEVICE_FLAG_RDONLY)
{ {
if (sensor->ops->control != RT_NULL) /* If polling mode is supported, configure it to polling mode */
{ local_ctrl(sensor, RT_SENSOR_CTRL_SET_MODE, (void *)RT_SENSOR_MODE_POLLING);
/* If polling mode is supported, configure it to polling mode */
sensor->ops->control(sensor, RT_SENSOR_CTRL_SET_MODE, (void *)RT_SENSOR_MODE_POLLING);
}
sensor->config.mode = RT_SENSOR_MODE_POLLING;
} }
else if (oflag & RT_DEVICE_FLAG_INT_RX && dev->flag & RT_DEVICE_FLAG_INT_RX) else if (oflag & RT_DEVICE_FLAG_INT_RX && dev->flag & RT_DEVICE_FLAG_INT_RX)
{ {
if (sensor->ops->control != RT_NULL) /* 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 interrupt mode is supported, configure it to interrupt mode */ /* Initialization sensor interrupt */
sensor->ops->control(sensor, RT_SENSOR_CTRL_SET_MODE, (void *)RT_SENSOR_MODE_INT); rt_sensor_irq_init(sensor);
sensor->config.mode = RT_SENSOR_MODE_INT;
} }
/* Initialization sensor interrupt */
rt_sensor_irq_init(sensor);
sensor->config.mode = RT_SENSOR_MODE_INT;
} }
else if (oflag & RT_DEVICE_FLAG_FIFO_RX && dev->flag & RT_DEVICE_FLAG_FIFO_RX) else if (oflag & RT_DEVICE_FLAG_FIFO_RX && dev->flag & RT_DEVICE_FLAG_FIFO_RX)
{ {
if (sensor->ops->control != RT_NULL) /* 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 fifo mode is supported, configure it to fifo mode */ /* Initialization sensor interrupt */
sensor->ops->control(sensor, RT_SENSOR_CTRL_SET_MODE, (void *)RT_SENSOR_MODE_FIFO); rt_sensor_irq_init(sensor);
sensor->config.mode = RT_SENSOR_MODE_FIFO;
} }
/* Initialization sensor interrupt */
rt_sensor_irq_init(sensor);
sensor->config.mode = RT_SENSOR_MODE_FIFO;
} }
else else
{ {
@@ -183,7 +200,7 @@ static rt_err_t rt_sensor_open(rt_device_t dev, rt_uint16_t oflag)
} }
/* Configure power mode to normal mode */ /* Configure power mode to normal mode */
if (sensor->ops->control(sensor, RT_SENSOR_CTRL_SET_POWER, (void *)RT_SENSOR_POWER_NORMAL) == RT_EOK) if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_POWER, (void *)RT_SENSOR_POWER_NORMAL) == RT_EOK)
{ {
sensor->config.power = RT_SENSOR_POWER_NORMAL; sensor->config.power = RT_SENSOR_POWER_NORMAL;
} }
@@ -202,6 +219,7 @@ static rt_err_t rt_sensor_close(rt_device_t dev)
{ {
rt_sensor_t sensor = (rt_sensor_t)dev; rt_sensor_t sensor = (rt_sensor_t)dev;
int i; int i;
rt_err_t (*local_ctrl)(struct rt_sensor_device * sensor, int cmd, void *arg) = local_control;
RT_ASSERT(dev != RT_NULL); RT_ASSERT(dev != RT_NULL);
@@ -209,9 +227,13 @@ static rt_err_t rt_sensor_close(rt_device_t dev)
{ {
rt_mutex_take(sensor->module->lock, RT_WAITING_FOREVER); rt_mutex_take(sensor->module->lock, RT_WAITING_FOREVER);
} }
if (sensor->ops->control != RT_NULL)
{
local_ctrl = sensor->ops->control;
}
/* Configure power mode to power down mode */ /* Configure power mode to power down mode */
if (sensor->ops->control(sensor, RT_SENSOR_CTRL_SET_POWER, (void *)RT_SENSOR_POWER_DOWN) == RT_EOK) if (local_ctrl(sensor, RT_SENSOR_CTRL_SET_POWER, (void *)RT_SENSOR_POWER_DOWN) == RT_EOK)
{ {
sensor->config.power = RT_SENSOR_POWER_DOWN; sensor->config.power = RT_SENSOR_POWER_DOWN;
} }
@@ -234,10 +256,13 @@ static rt_err_t rt_sensor_close(rt_device_t dev)
} }
} }
} }
/* Sensor disable interrupt */ if (sensor->config.mode != RT_SENSOR_MODE_POLLING)
if (sensor->config.irq_pin.pin != RT_PIN_NONE)
{ {
rt_pin_irq_enable(sensor->config.irq_pin.pin, RT_FALSE); /* Sensor disable interrupt */
if (sensor->config.irq_pin.pin != RT_PIN_NONE)
{
rt_pin_irq_enable(sensor->config.irq_pin.pin, RT_FALSE);
}
} }
__exit: __exit:
@@ -282,7 +307,10 @@ static rt_size_t rt_sensor_read(rt_device_t dev, rt_off_t pos, void *buf, rt_siz
else else
{ {
/* If the buffer is empty read the data */ /* If the buffer is empty read the data */
result = sensor->ops->fetch_data(sensor, buf, len); if (sensor->ops->fetch_data != RT_NULL)
{
result = sensor->ops->fetch_data(sensor, buf, len);
}
} }
if (sensor->module) if (sensor->module)
@@ -298,18 +326,23 @@ static rt_err_t rt_sensor_control(rt_device_t dev, int cmd, void *args)
rt_sensor_t sensor = (rt_sensor_t)dev; rt_sensor_t sensor = (rt_sensor_t)dev;
rt_err_t result = RT_EOK; rt_err_t result = RT_EOK;
RT_ASSERT(dev != RT_NULL); RT_ASSERT(dev != RT_NULL);
rt_err_t (*local_ctrl)(struct rt_sensor_device * sensor, int cmd, void *arg) = local_control;
if (sensor->module) if (sensor->module)
{ {
rt_mutex_take(sensor->module->lock, RT_WAITING_FOREVER); rt_mutex_take(sensor->module->lock, RT_WAITING_FOREVER);
} }
if (sensor->ops->control != RT_NULL)
{
local_ctrl = sensor->ops->control;
}
switch (cmd) switch (cmd)
{ {
case RT_SENSOR_CTRL_GET_ID: case RT_SENSOR_CTRL_GET_ID:
if (args) if (args)
{ {
result = sensor->ops->control(sensor, RT_SENSOR_CTRL_GET_ID, args); result = local_ctrl(sensor, RT_SENSOR_CTRL_GET_ID, args);
} }
break; break;
case RT_SENSOR_CTRL_GET_INFO: case RT_SENSOR_CTRL_GET_INFO:
@@ -319,19 +352,17 @@ static rt_err_t rt_sensor_control(rt_device_t dev, int cmd, void *args)
} }
break; break;
case RT_SENSOR_CTRL_SET_RANGE: case RT_SENSOR_CTRL_SET_RANGE:
/* Configuration measurement range */ /* Configuration measurement range */
result = sensor->ops->control(sensor, RT_SENSOR_CTRL_SET_RANGE, args); result = local_ctrl(sensor, RT_SENSOR_CTRL_SET_RANGE, args);
if (result == RT_EOK) if (result == RT_EOK)
{ {
sensor->config.range = (rt_int32_t)args; sensor->config.range = (rt_int32_t)args;
LOG_D("set range %d", sensor->config.range); LOG_D("set range %d", sensor->config.range);
} }
break; break;
case RT_SENSOR_CTRL_SET_ODR: case RT_SENSOR_CTRL_SET_ODR:
/* Configuration data output rate */ /* Configuration data output rate */
result = sensor->ops->control(sensor, RT_SENSOR_CTRL_SET_ODR, args); result = local_ctrl(sensor, RT_SENSOR_CTRL_SET_ODR, args);
if (result == RT_EOK) if (result == RT_EOK)
{ {
sensor->config.odr = (rt_uint32_t)args & 0xFFFF; sensor->config.odr = (rt_uint32_t)args & 0xFFFF;
@@ -339,9 +370,8 @@ static rt_err_t rt_sensor_control(rt_device_t dev, int cmd, void *args)
} }
break; break;
case RT_SENSOR_CTRL_SET_POWER: case RT_SENSOR_CTRL_SET_POWER:
/* Configuration sensor power mode */ /* Configuration sensor power mode */
result = sensor->ops->control(sensor, RT_SENSOR_CTRL_SET_POWER, args); result = local_ctrl(sensor, RT_SENSOR_CTRL_SET_POWER, args);
if (result == RT_EOK) if (result == RT_EOK)
{ {
sensor->config.power = (rt_uint32_t)args & 0xFF; sensor->config.power = (rt_uint32_t)args & 0xFF;
@@ -349,16 +379,15 @@ static rt_err_t rt_sensor_control(rt_device_t dev, int cmd, void *args)
} }
break; break;
case RT_SENSOR_CTRL_SELF_TEST: case RT_SENSOR_CTRL_SELF_TEST:
/* Device self-test */ /* Device self-test */
result = sensor->ops->control(sensor, RT_SENSOR_CTRL_SELF_TEST, args); result = local_ctrl(sensor, RT_SENSOR_CTRL_SELF_TEST, args);
break; break;
default: default:
if (cmd > RT_SENSOR_CTRL_USER_CMD_START) if (cmd > RT_SENSOR_CTRL_USER_CMD_START)
{ {
/* Custom commands */ /* Custom commands */
result = sensor->ops->control(sensor, cmd, args); result = local_ctrl(sensor, cmd, args);
} }
else else
{ {
@@ -387,6 +416,7 @@ const static struct rt_device_ops rt_sensor_ops =
}; };
#endif #endif
/* /*
* sensor register * sensor register
*/ */
@@ -401,6 +431,11 @@ int rt_hw_sensor_register(rt_sensor_t sensor,
char *sensor_name = RT_NULL, *device_name = RT_NULL; char *sensor_name = RT_NULL, *device_name = RT_NULL;
if (sensor->ops == RT_NULL)
{
sensor->ops = &local_ops;
}
/* Add a type name for the sensor device */ /* Add a type name for the sensor device */
sensor_name = sensor_name_str[sensor->info.type]; sensor_name = sensor_name_str[sensor->info.type];
device_name = (char *)rt_calloc(1, rt_strlen(sensor_name) + 1 + rt_strlen(name)); device_name = (char *)rt_calloc(1, rt_strlen(sensor_name) + 1 + rt_strlen(name));
@@ -444,12 +479,12 @@ int rt_hw_sensor_register(rt_sensor_t sensor,
result = rt_device_register(device, device_name, flag | RT_DEVICE_FLAG_STANDALONE); result = rt_device_register(device, device_name, flag | RT_DEVICE_FLAG_STANDALONE);
if (result != RT_EOK) if (result != RT_EOK)
{ {
LOG_E("rt_sensor[%s] register err code: %d", device_name, result);
rt_free(device_name); rt_free(device_name);
LOG_E("rt_sensor register err code: %d", result);
return result; return result;
} }
rt_free(device_name); rt_free(device_name);
LOG_I("rt_sensor init success"); LOG_I("rt_sensor[%s] init success", device_name);
return RT_EOK; return RT_EOK;
} }
components/drivers/sensors/sensor.h
-224
View File
@@ -8,231 +8,7 @@
* 2019-01-31 flybreak first version * 2019-01-31 flybreak first version
*/ */
#ifndef __SENSOR_H__
#define __SENSOR_H__
#include <rtthread.h> #include <rtthread.h>
#include <rtdevice.h> #include <rtdevice.h>
#ifdef __cplusplus
extern "C" {
#endif
#ifdef RT_USING_RTC
#define rt_sensor_get_ts() time(RT_NULL) /* API for the sensor to get the timestamp */
#else
#define rt_sensor_get_ts() rt_tick_get() /* API for the sensor to get the timestamp */
#endif
#define RT_PIN_NONE 0xFFFF /* RT PIN NONE */
#define RT_DEVICE_FLAG_FIFO_RX 0x200 /* Flag to use when the sensor is open by fifo mode */
#define RT_SENSOR_MODULE_MAX (3) /* The maximum number of members of a sensor module */
/* Sensor types */
#define RT_SENSOR_CLASS_NONE (0)
#define RT_SENSOR_CLASS_ACCE (1) /* Accelerometer */
#define RT_SENSOR_CLASS_GYRO (2) /* Gyroscope */
#define RT_SENSOR_CLASS_MAG (3) /* Magnetometer */
#define RT_SENSOR_CLASS_TEMP (4) /* Temperature */
#define RT_SENSOR_CLASS_HUMI (5) /* Relative Humidity */
#define RT_SENSOR_CLASS_BARO (6) /* Barometer */
#define RT_SENSOR_CLASS_LIGHT (7) /* Ambient light */
#define RT_SENSOR_CLASS_PROXIMITY (8) /* Proximity */
#define RT_SENSOR_CLASS_HR (9) /* Heart Rate */
#define RT_SENSOR_CLASS_TVOC (10) /* TVOC Level */
#define RT_SENSOR_CLASS_NOISE (11) /* Noise Loudness */
#define RT_SENSOR_CLASS_STEP (12) /* Step sensor */
#define RT_SENSOR_CLASS_FORCE (13) /* Force sensor */
#define RT_SENSOR_CLASS_DUST (14) /* Dust sensor */
#define RT_SENSOR_CLASS_ECO2 (15) /* eCO2 sensor */
#define RT_SENSOR_CLASS_GNSS (16) /* GPS/GNSS sensor */
#define RT_SENSOR_CLASS_TOF (17) /* TOF sensor */
/* Sensor vendor types */
#define RT_SENSOR_VENDOR_UNKNOWN (0)
#define RT_SENSOR_VENDOR_STM (1) /* STMicroelectronics */
#define RT_SENSOR_VENDOR_BOSCH (2) /* Bosch */
#define RT_SENSOR_VENDOR_INVENSENSE (3) /* Invensense */
#define RT_SENSOR_VENDOR_SEMTECH (4) /* Semtech */
#define RT_SENSOR_VENDOR_GOERTEK (5) /* Goertek */
#define RT_SENSOR_VENDOR_MIRAMEMS (6) /* MiraMEMS */
#define RT_SENSOR_VENDOR_DALLAS (7) /* Dallas */
#define RT_SENSOR_VENDOR_ASAIR (8) /* Aosong */
#define RT_SENSOR_VENDOR_SHARP (9) /* Sharp */
#define RT_SENSOR_VENDOR_SENSIRION (10) /* Sensirion */
#define RT_SENSOR_VENDOR_TI (11) /* Texas Instruments */
#define RT_SENSOR_VENDOR_PLANTOWER (12) /* Plantower */
#define RT_SENSOR_VENDOR_AMS (13) /* ams AG */
#define RT_SENSOR_VENDOR_MAXIM (14) /* Maxim Integrated */
/* Sensor unit types */
#define RT_SENSOR_UNIT_NONE (0)
#define RT_SENSOR_UNIT_MG (1) /* Accelerometer unit: mG */
#define RT_SENSOR_UNIT_MDPS (2) /* Gyroscope unit: mdps */
#define RT_SENSOR_UNIT_MGAUSS (3) /* Magnetometer unit: mGauss */
#define RT_SENSOR_UNIT_LUX (4) /* Ambient light unit: lux */
#define RT_SENSOR_UNIT_CM (5) /* Distance unit: cm */
#define RT_SENSOR_UNIT_PA (6) /* Barometer unit: pa */
#define RT_SENSOR_UNIT_PERMILLAGE (7) /* Relative Humidity unit: permillage */
#define RT_SENSOR_UNIT_DCELSIUS (8) /* Temperature unit: dCelsius */
#define RT_SENSOR_UNIT_HZ (9) /* Frequency unit: HZ */
#define RT_SENSOR_UNIT_ONE (10) /* Dimensionless quantity unit: 1 */
#define RT_SENSOR_UNIT_BPM (11) /* Heart rate unit: bpm */
#define RT_SENSOR_UNIT_MM (12) /* Distance unit: mm */
#define RT_SENSOR_UNIT_MN (13) /* Force unit: mN */
#define RT_SENSOR_UNIT_PPM (14) /* Concentration unit: ppm */
#define RT_SENSOR_UNIT_PPB (15) /* Concentration unit: ppb */
#define RT_SENSOR_UNIT_DMS (16) /* Coordinates unit: DMS */
#define RT_SENSOR_UNIT_DD (17) /* Coordinates unit: DD */
/* Sensor communication interface types */
#define RT_SENSOR_INTF_I2C (1 << 0)
#define RT_SENSOR_INTF_SPI (1 << 1)
#define RT_SENSOR_INTF_UART (1 << 2)
#define RT_SENSOR_INTF_ONEWIRE (1 << 3)
/* Sensor power mode types */
#define RT_SENSOR_POWER_NONE (0)
#define RT_SENSOR_POWER_DOWN (1) /* power down mode */
#define RT_SENSOR_POWER_NORMAL (2) /* normal-power mode */
#define RT_SENSOR_POWER_LOW (3) /* low-power mode */
#define RT_SENSOR_POWER_HIGH (4) /* high-power mode */
/* 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 */
/* Sensor control cmd types */
#define RT_SENSOR_CTRL_GET_ID (0) /* Get device id */
#define RT_SENSOR_CTRL_GET_INFO (1) /* Get sensor info */
#define RT_SENSOR_CTRL_SET_RANGE (2) /* Set the measure range of sensor. unit is info of sensor */
#define RT_SENSOR_CTRL_SET_ODR (3) /* Set output date rate. unit is HZ */
#define RT_SENSOR_CTRL_SET_MODE (4) /* Set sensor's work mode. ex. RT_SENSOR_MODE_POLLING,RT_SENSOR_MODE_INT */
#define RT_SENSOR_CTRL_SET_POWER (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 (6) /* Take a self test */
#define RT_SENSOR_CTRL_USER_CMD_START 0x100 /* User commands should be greater than 0x100 */
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 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 fifo_max;
};
struct rt_sensor_intf
{
char *dev_name; /* The name of the communication device */
rt_uint8_t type; /* Communication interface type */
void *user_data; /* Private data for the sensor. ex. i2c addr,spi cs,control I/O */
};
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;
struct rt_sensor_device
{
struct rt_device parent; /* The standard device */
struct rt_sensor_info info; /* The sensor info data */
struct rt_sensor_config config; /* The sensor config data */
void *data_buf; /* The buf of the data received */
rt_size_t data_len; /* The size of the data received */
const struct rt_sensor_ops *ops; /* The sensor ops */
struct rt_sensor_module *module; /* The sensor module */
rt_err_t (*irq_handle)(rt_sensor_t sensor); /* Called when an interrupt is generated, registered by the driver */
};
struct rt_sensor_module
{
rt_mutex_t lock; /* The module lock */
rt_sensor_t sen[RT_SENSOR_MODULE_MAX]; /* The module contains a list of sensors */
rt_uint8_t sen_num; /* Number of sensors contained in the module */
};
/* 3-axis Data Type */
struct sensor_3_axis
{
rt_int32_t x;
rt_int32_t y;
rt_int32_t z;
};
struct coordinates
{
double longitude;
double latitude;
};
struct rt_sensor_data
{
rt_uint32_t timestamp; /* The timestamp when the data was received */
rt_uint8_t type; /* The sensor type of the data */
union
{
struct sensor_3_axis acce; /* Accelerometer. unit: mG */
struct sensor_3_axis gyro; /* Gyroscope. unit: mdps */
struct sensor_3_axis mag; /* Magnetometer. unit: mGauss */
struct coordinates coord; /* Coordinates unit: degrees */
rt_int32_t temp; /* Temperature. unit: dCelsius */
rt_int32_t humi; /* Relative humidity. unit: permillage */
rt_int32_t baro; /* Pressure. unit: pascal (Pa) */
rt_int32_t light; /* Light. unit: lux */
rt_int32_t proximity; /* Distance. unit: centimeters */
rt_int32_t hr; /* Heart rate. unit: bpm */
rt_int32_t tvoc; /* TVOC. unit: permillage */
rt_int32_t noise; /* Noise Loudness. unit: HZ */
rt_uint32_t step; /* Step sensor. unit: 1 */
rt_int32_t force; /* Force sensor. unit: mN */
rt_uint32_t dust; /* Dust sensor. unit: ug/m3 */
rt_uint32_t eco2; /* eCO2 sensor. unit: ppm */
} data;
};
struct rt_sensor_ops
{
rt_size_t (*fetch_data)(struct rt_sensor_device *sensor, void *buf, rt_size_t len);
rt_err_t (*control)(struct rt_sensor_device *sensor, int cmd, void *arg);
};
int rt_hw_sensor_register(rt_sensor_t sensor,
const char *name,
rt_uint32_t flag,
void *data);
#ifdef __cplusplus
}
#endif
#endif /* __SENSOR_H__ */
components/drivers/sensors/sensor_cmd.c
+5 -3
View File
@@ -231,6 +231,7 @@ static void sensor_polling(int argc, char **argv)
struct rt_sensor_data data; struct rt_sensor_data data;
rt_size_t res, i; rt_size_t res, i;
rt_int32_t delay; rt_int32_t delay;
rt_err_t result;
dev = rt_device_find(argv[1]); dev = rt_device_find(argv[1]);
if (dev == RT_NULL) if (dev == RT_NULL)
@@ -244,9 +245,10 @@ static void sensor_polling(int argc, char **argv)
sensor = (rt_sensor_t)dev; sensor = (rt_sensor_t)dev;
delay = sensor->info.period_min > 100 ? sensor->info.period_min : 100; delay = sensor->info.period_min > 100 ? sensor->info.period_min : 100;
if (rt_device_open(dev, RT_DEVICE_FLAG_RDWR) != RT_EOK) result = rt_device_open(dev, RT_DEVICE_FLAG_RDONLY);
if (result != RT_EOK)
{ {
LOG_E("open device failed!"); LOG_E("open device failed! error code : %d", result);
return; return;
} }
rt_device_control(dev, RT_SENSOR_CTRL_SET_ODR, (void *)100); rt_device_control(dev, RT_SENSOR_CTRL_SET_ODR, (void *)100);
@@ -451,7 +453,7 @@ static void sensor(int argc, char **argv)
dev = rt_device_find(argv[2]); dev = rt_device_find(argv[2]);
if (dev == RT_NULL) if (dev == RT_NULL)
{ {
LOG_E("Can't find device:%s", argv[1]); LOG_E("Can't find device:%s", argv[2]);
return; return;
} }
if (rt_device_open(dev, RT_DEVICE_FLAG_RDWR) != RT_EOK) if (rt_device_open(dev, RT_DEVICE_FLAG_RDWR) != RT_EOK)