lps33hw.cpp 5.33 KB
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#include "lps33hw.hpp"

using namespace ST_LPS33HW;
using namespace time_literals;

namespace lps33hw
{

template<typename T>
static void getTwosComplement(T &raw, uint8_t length)
{
	if (raw & ((T)1 << (length - 1))) {
		raw -= (T)1 << length;
	}
}

LPS33HW::LPS33HW(I2CSPIBusOption bus_option, int bus, device::Device *interface, bool keep_retrying) :
	I2CSPIDriver(MODULE_NAME, px4::device_bus_to_wq(interface->get_device_id()), bus_option, bus,
		     interface->get_device_address()),
	_px4_barometer(interface->get_device_id()),
	_interface(interface),
	_sample_perf(perf_alloc(PC_ELAPSED, MODULE_NAME": read")),
	_comms_errors(perf_alloc(PC_COUNT, MODULE_NAME": comm errors")),
	_keep_retrying(keep_retrying)
{
}

LPS33HW::~LPS33HW()
{
	perf_free(_sample_perf);
	perf_free(_comms_errors);

	delete _interface;
}

int
LPS33HW::init()
{
	uint8_t who_am_i;
	int ret = RegisterRead(Register::WHO_AM_I, who_am_i);

	if (ret != 0) {
		PX4_DEBUG("read failed (%i)", ret);

		if (_keep_retrying) {
			PX4_INFO("no sensor found, but will keep retrying");
			ScheduleNow();
			return 0;
		}

		return ret;
	}

	if (who_am_i != WHO_AM_I_VALUE) {
		PX4_DEBUG("WHO_AM_I mismatch (%i)", who_am_i);
		return PX4_ERROR;
	}

	_state = State::Reset;
	ScheduleNow();
	return PX4_OK;
}

void
LPS33HW::RunImpl()
{
	int ret;

	switch (_state) {
	case State::Detect:
		uint8_t who_am_i;
		ret = RegisterRead(Register::WHO_AM_I, who_am_i);

		if (ret != 0 || who_am_i != WHO_AM_I_VALUE) {
			// periodically retry to detect
			ScheduleDelayed(300_ms);
			return;
		}

		ScheduleDelayed(10_ms);
		_state = State::Reset;
		break;

	case State::Reset:
		// Soft Reset
		ret = RegisterWrite(Register::CTRL_REG2, SWRESET);

		if (ret != OK) {
			PX4_DEBUG("reset failed");
			ScheduleDelayed(100_ms);
			_state = State::Detect;
			return;
		}

		ScheduleDelayed(20_ms);
		_state = State::WaitForReset;
		break;

	case State::WaitForReset:
		uint8_t val;
		ret = RegisterRead(Register::CTRL_REG2, val);

		if (ret != 0 || (val & SWRESET) != 0) {
			ScheduleDelayed(10_ms);
			_state = State::Reset;
			return;
		}

		// Configure sampling rate
		ret = RegisterWrite(Register::CTRL_REG1, ODR_75HZ | BDU);

		if (ret != 0) {
			ScheduleDelayed(10_ms);
			_state = State::Detect;
			return;
		}

		ScheduleDelayed(1000000 / SAMPLE_RATE);
		_state = State::Running;
		break;

	case State::Running:
		perf_begin(_sample_perf);
		uint8_t data[6];

		if (_interface->read((uint8_t)Register::STATUS, data, sizeof(data)) != PX4_OK) {
			perf_count(_comms_errors);
			perf_end(_sample_perf);
			ScheduleDelayed(10_ms);
			_state = State::Reset;
			return;
		}

		uint8_t status = data[0];

		if ((status & P_DA) == 0) { // check if pressure data is available
			perf_end(_sample_perf);
			ScheduleDelayed(1000000 / SAMPLE_RATE);
			return;
		}

		hrt_abstime timestamp_sample = hrt_absolute_time();
		float temp = ((int16_t)data[4] | (data[5] << 8)) / 100.f;

		int32_t Praw = (int32_t)data[1] | (data[2] << 8) | (data[3] << 16);
		getTwosComplement(Praw, 24);
		float pressure_hPa = Praw / 4096.f;

		_px4_barometer.set_error_count(perf_event_count(_comms_errors));
		_px4_barometer.set_temperature(temp);
		_px4_barometer.update(timestamp_sample, pressure_hPa); // hPascals -> Millibar

		perf_end(_sample_perf);
		ScheduleDelayed(1000000 / SAMPLE_RATE);
		break;
	}
}

int
LPS33HW::RegisterRead(Register reg, uint8_t &val)
{
	return _interface->read((uint8_t)reg, &val, 1);
}

int
LPS33HW::RegisterWrite(Register reg, uint8_t value)
{
	return _interface->write((uint8_t)reg, &value, 1);
}

void
LPS33HW::print_status()
{
	I2CSPIDriverBase::print_status();
	perf_print_counter(_sample_perf);
	perf_print_counter(_comms_errors);
}

} // namespace lps33hw