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https://github.com/oliverschmidt/contiki.git
synced 2024-12-23 01:29:33 +00:00
Improve OPT sensor driver and usage
* Query the sensor about its state, rather than using variables in the driver * Correctly put the sensor to deep sleep * Fix doxygen comments * Don't turn off the sensor in examples since it is no longer needed
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@ -251,8 +251,7 @@ get_light_reading()
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printf("OPT: Light Read Error\n");
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}
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SENSORS_DEACTIVATE(opt_3001_sensor);
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/* The OPT will turn itself off, so we don't need to call its DEACTIVATE */
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ctimer_set(&opt_timer, next, init_opt_reading, NULL);
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}
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/*---------------------------------------------------------------------------*/
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@ -574,8 +574,6 @@ get_light_reading()
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value = opt_3001_sensor.value(0);
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SENSORS_DEACTIVATE(opt_3001_sensor);
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if(value != CC26XX_SENSOR_READING_ERROR) {
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opt_reading.raw = value;
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@ -587,6 +585,7 @@ get_light_reading()
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value % 100);
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}
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/* The OPT will turn itself off, so we don't need to call its DEACTIVATE */
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ctimer_set(&opt_timer, next, init_light_reading, NULL);
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}
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/*---------------------------------------------------------------------------*/
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@ -69,16 +69,42 @@
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#define REG_MANUFACTURER_ID 0x7E
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#define REG_DEVICE_ID 0x7F
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/*---------------------------------------------------------------------------*/
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/* Register values */
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#define MANUFACTURER_ID 0x5449 /* TI */
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#define DEVICE_ID 0x3001 /* Opt 3001 */
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#define CONFIG_RESET 0xC810
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#define CONFIG_TEST 0xCC10
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#define CONFIG_ENABLE 0x10CC /* 0xCC10 */
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#define CONFIG_DISABLE 0x108C /* 0xC810 */
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/*---------------------------------------------------------------------------*/
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/* Bit values */
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#define DATA_RDY_BIT 0x0080 /* Data ready */
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/*
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* Configuration Register Bits and Masks.
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* We use uint16_t to read from / write to registers, meaning that the
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* register's MSB is the variable's LSB.
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*/
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#define CONFIG_RN 0x00F0 /* [15..12] Range Number */
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#define CONFIG_CT 0x0008 /* [11] Conversion Time */
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#define CONFIG_M 0x0006 /* [10..9] Mode of Conversion */
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#define CONFIG_OVF 0x0001 /* [8] Overflow */
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#define CONFIG_CRF 0x8000 /* [7] Conversion Ready Field */
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#define CONFIG_FH 0x4000 /* [6] Flag High */
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#define CONFIG_FL 0x2000 /* [5] Flag Low */
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#define CONFIG_L 0x1000 /* [4] Latch */
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#define CONFIG_POL 0x0800 /* [3] Polarity */
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#define CONFIG_ME 0x0400 /* [2] Mask Exponent */
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#define CONFIG_FC 0x0300 /* [1..0] Fault Count */
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/* Possible Values for CT */
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#define CONFIG_CT_100 0x0000
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#define CONFIG_CT_800 CONFIG_CT
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/* Possible Values for M */
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#define CONFIG_M_CONTI 0x0004
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#define CONFIG_M_SINGLE 0x0002
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#define CONFIG_M_SHUTDOWN 0x0000
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/* Reset Value for the register 0xC810. All zeros except: */
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#define CONFIG_RN_RESET 0x00C0
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#define CONFIG_CT_RESET CONFIG_CT_800
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#define CONFIG_L_RESET 0x1000
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#define CONFIG_DEFAULTS (CONFIG_RN_RESET | CONFIG_CT_100 | CONFIG_L_RESET)
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/* Enable / Disable */
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#define CONFIG_ENABLE_CONTINUOUS (CONFIG_M_CONTI | CONFIG_DEFAULTS)
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#define CONFIG_ENABLE_SINGLE_SHOT (CONFIG_M_SINGLE | CONFIG_DEFAULTS)
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#define CONFIG_DISABLE CONFIG_DEFAULTS
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/*---------------------------------------------------------------------------*/
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/* Register length */
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#define REGISTER_LENGTH 2
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@ -86,24 +112,22 @@
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/* Sensor data size */
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#define DATA_LENGTH 2
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/*---------------------------------------------------------------------------*/
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#define SENSOR_STATUS_DISABLED 0
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#define SENSOR_STATUS_NOT_READY 1
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#define SENSOR_STATUS_ENABLED 2
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/*
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* SENSOR_STATE_SLEEPING and SENSOR_STATE_ACTIVE are mutually exclusive.
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* SENSOR_STATE_DATA_READY can be ORd with both of the above. For example the
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* sensor may be sleeping but with a conversion ready to read out.
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*/
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#define SENSOR_STATE_SLEEPING 0
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#define SENSOR_STATE_ACTIVE 1
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#define SENSOR_STATE_DATA_READY 2
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static int enabled = SENSOR_STATUS_DISABLED;
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static int state = SENSOR_STATE_SLEEPING;
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/*---------------------------------------------------------------------------*/
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/* Wait SENSOR_STARTUP_DELAY for the sensor to be ready - 125ms */
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#define SENSOR_STARTUP_DELAY (CLOCK_SECOND >> 3)
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static struct ctimer startup_timer;
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/*---------------------------------------------------------------------------*/
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static void
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notify_ready(void *not_used)
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{
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enabled = SENSOR_STATUS_ENABLED;
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sensors_changed(&opt_3001_sensor);
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}
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/*---------------------------------------------------------------------------*/
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/**
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* \brief Select the sensor on the I2C bus
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*/
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@ -114,6 +138,28 @@ select(void)
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board_i2c_select(BOARD_I2C_INTERFACE_0, OPT3001_I2C_ADDRESS);
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}
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/*---------------------------------------------------------------------------*/
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static void
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notify_ready(void *not_used)
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{
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/*
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* Depending on the CONFIGURATION.CONVERSION_TIME bits, a conversion will
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* take either 100 or 800 ms. Here we inspect the CONVERSION_READY bit and
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* if the reading is ready we notify, otherwise we just reschedule ourselves
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*/
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uint16_t val;
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select();
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sensor_common_read_reg(REG_CONFIGURATION, (uint8_t *)&val, REGISTER_LENGTH);
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if(val & CONFIG_CRF) {
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sensors_changed(&opt_3001_sensor);
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state = SENSOR_STATE_DATA_READY;
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} else {
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ctimer_set(&startup_timer, SENSOR_STARTUP_DELAY, notify_ready, NULL);
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}
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}
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/*---------------------------------------------------------------------------*/
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/**
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* \brief Turn the sensor on/off
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* \param enable TRUE: on, FALSE: off
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@ -122,13 +168,20 @@ static void
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enable_sensor(bool enable)
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{
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uint16_t val;
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uint16_t had_data_ready = state & SENSOR_STATE_DATA_READY;
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select();
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if(enable) {
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val = CONFIG_ENABLE;
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val = CONFIG_ENABLE_SINGLE_SHOT;
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/* Writing CONFIG_ENABLE_SINGLE_SHOT to M bits will clear CRF bits */
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state = SENSOR_STATE_ACTIVE;
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} else {
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val = CONFIG_DISABLE;
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/* Writing CONFIG_DISABLE to M bits will not clear CRF bits */
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state = SENSOR_STATE_SLEEPING | had_data_ready;
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}
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sensor_common_write_reg(REG_CONFIGURATION, (uint8_t *)&val, REGISTER_LENGTH);
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@ -145,15 +198,15 @@ read_data(uint16_t *raw_data)
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bool success;
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uint16_t val;
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if((state & SENSOR_STATE_DATA_READY) != SENSOR_STATE_DATA_READY) {
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return false;
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}
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select();
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success = sensor_common_read_reg(REG_CONFIGURATION, (uint8_t *)&val,
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REGISTER_LENGTH);
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if(success) {
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success = (val & DATA_RDY_BIT) == DATA_RDY_BIT;
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}
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if(success) {
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success = sensor_common_read_reg(REG_RESULT, (uint8_t *)&val, DATA_LENGTH);
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}
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@ -196,14 +249,9 @@ value(int type)
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uint16_t raw_val;
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float converted_val;
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if(enabled != SENSOR_STATUS_ENABLED) {
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PRINTF("Sensor disabled or starting up (%d)\n", enabled);
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return CC26XX_SENSOR_READING_ERROR;
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}
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rv = read_data(&raw_val);
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if(rv == 0) {
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if(rv == false) {
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return CC26XX_SENSOR_READING_ERROR;
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}
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@ -229,30 +277,38 @@ value(int type)
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static int
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configure(int type, int enable)
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{
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int rv = 0;
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switch(type) {
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case SENSORS_HW_INIT:
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/*
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* Device reset won't reset the sensor, so we put it to sleep here
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* explicitly
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*/
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enable_sensor(0);
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rv = 0;
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break;
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case SENSORS_ACTIVE:
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if(enable) {
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enable_sensor(1);
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ctimer_set(&startup_timer, SENSOR_STARTUP_DELAY, notify_ready, NULL);
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enabled = SENSOR_STATUS_NOT_READY;
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rv = 1;
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} else {
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ctimer_stop(&startup_timer);
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enable_sensor(0);
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enabled = SENSOR_STATUS_DISABLED;
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rv = 0;
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}
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break;
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default:
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break;
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}
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return enabled;
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return rv;
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}
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/*---------------------------------------------------------------------------*/
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/**
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* \brief Returns the status of the sensor
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* \param type SENSORS_ACTIVE or SENSORS_READY
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* \return 1 if the sensor is enabled
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* \param type ignored
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* \return The state of the sensor SENSOR_STATE_xyz
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*/
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static int
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status(int type)
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@ -260,12 +316,10 @@ status(int type)
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switch(type) {
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case SENSORS_ACTIVE:
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case SENSORS_READY:
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return enabled;
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break;
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default:
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break;
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}
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return SENSOR_STATUS_DISABLED;
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return state;
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}
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/*---------------------------------------------------------------------------*/
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SENSORS_SENSOR(opt_3001_sensor, "OPT3001", value, configure, status);
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* sequence, but the call will not wait for it to complete so that the CPU can
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* perform other tasks or drop to a low power mode.
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*
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* Once the sensor is stable, the driver will generate a sensors_changed event.
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* Once the reading and conversion are complete, the driver will generate a
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* sensors_changed event.
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*
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* Once a reading has been taken, the caller has two options:
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* - Turn the sensor off by calling SENSORS_DEACTIVATE, but in order to take
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* subsequent readings SENSORS_ACTIVATE must be called again
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* - Leave the sensor on. In this scenario, the caller can simply keep calling
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* value() for subsequent readings, but having the sensor on will consume
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* energy
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* We use single-shot readings. In this mode, the hardware automatically goes
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* back to its shutdown mode after the conversion is finished. However, it will
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* still respond to I2C operations, so the last conversion can still be read
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* out.
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*
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* In order to take a new reading, the caller has to use SENSORS_ACTIVATE
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* again.
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* @{
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*
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* \file
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