camera_capture.cpp 10 KB
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/**
 * @file camera_capture.cpp
 *
 * Online and offline geotagging from camera feedback
 *
 * @author Mohammed Kabir <kabir@uasys.io>
 */

#include "camera_capture.hpp"

#define commandParamToInt(n) static_cast<int>(n >= 0 ? n + 0.5f : n - 0.5f)

namespace camera_capture
{
CameraCapture *g_camera_capture{nullptr};
}

struct work_s CameraCapture::_work_publisher;

CameraCapture::CameraCapture() :
	ScheduledWorkItem(MODULE_NAME, px4::wq_configurations::lp_default)
{
	memset(&_work_publisher, 0, sizeof(_work_publisher));

	// Capture Parameters
	_p_strobe_delay = param_find("CAM_CAP_DELAY");
	param_get(_p_strobe_delay, &_strobe_delay);

	_p_camera_capture_mode = param_find("CAM_CAP_MODE");
	param_get(_p_camera_capture_mode, &_camera_capture_mode);

	_p_camera_capture_edge = param_find("CAM_CAP_EDGE");
	param_get(_p_camera_capture_edge, &_camera_capture_edge);
}

CameraCapture::~CameraCapture()
{
	camera_capture::g_camera_capture = nullptr;
}

void
CameraCapture::capture_callback(uint32_t chan_index, hrt_abstime edge_time, uint32_t edge_state, uint32_t overflow)
{
	_trigger.chan_index = chan_index;
	_trigger.edge_time = edge_time;
	_trigger.edge_state = edge_state;
	_trigger.overflow = overflow;

	work_queue(HPWORK, &_work_publisher, (worker_t)&CameraCapture::publish_trigger_trampoline, this, 0);
}

int
CameraCapture::gpio_interrupt_routine(int irq, void *context, void *arg)
{
	CameraCapture *dev = static_cast<CameraCapture *>(arg);

	dev->_trigger.chan_index = 0;
	dev->_trigger.edge_time = hrt_absolute_time();
	dev->_trigger.edge_state = 0;
	dev->_trigger.overflow = 0;

	work_queue(HPWORK, &_work_publisher, (worker_t)&CameraCapture::publish_trigger_trampoline, dev, 0);

	return PX4_OK;
}

void
CameraCapture::publish_trigger_trampoline(void *arg)
{
	CameraCapture *dev = static_cast<CameraCapture *>(arg);

	dev->publish_trigger();
}

void
CameraCapture::publish_trigger()
{
	bool publish = false;

	camera_trigger_s trigger{};

	// MODES 1 and 2 are not fully tested
	if (_camera_capture_mode == 0 || _gpio_capture) {
		trigger.timestamp = _trigger.edge_time - uint64_t(1000 * _strobe_delay);
		trigger.seq = _capture_seq++;
		_last_trig_time = trigger.timestamp;
		publish = true;

	} else if (_camera_capture_mode == 1) { // Get timestamp of mid-exposure (active high)
		if (_trigger.edge_state == 1) {
			_last_trig_begin_time = _trigger.edge_time - uint64_t(1000 * _strobe_delay);

		} else if (_trigger.edge_state == 0 && _last_trig_begin_time > 0) {
			trigger.timestamp = _trigger.edge_time - ((_trigger.edge_time - _last_trig_begin_time) / 2);
			trigger.seq = _capture_seq++;
			_last_exposure_time = _trigger.edge_time - _last_trig_begin_time;
			_last_trig_time = trigger.timestamp;
			publish = true;
			_capture_seq++;
		}

	} else { // Get timestamp of mid-exposure (active low)
		if (_trigger.edge_state == 0) {
			_last_trig_begin_time = _trigger.edge_time - uint64_t(1000 * _strobe_delay);

		} else if (_trigger.edge_state == 1 && _last_trig_begin_time > 0) {
			trigger.timestamp = _trigger.edge_time - ((_trigger.edge_time - _last_trig_begin_time) / 2);
			trigger.seq = _capture_seq++;
			_last_exposure_time = _trigger.edge_time - _last_trig_begin_time;
			_last_trig_time = trigger.timestamp;
			publish = true;
		}

	}

	trigger.feedback = true;
	_capture_overflows = _trigger.overflow;

	if (!publish) {
		return;
	}

	_trigger_pub.publish(trigger);
}

void
CameraCapture::capture_trampoline(void *context, uint32_t chan_index, hrt_abstime edge_time, uint32_t edge_state,
				  uint32_t overflow)
{
	camera_capture::g_camera_capture->capture_callback(chan_index, edge_time, edge_state, overflow);
}

void
CameraCapture::Run()
{
	// Command handling
	vehicle_command_s cmd{};

	if (_command_sub.update(&cmd)) {

		// TODO : this should eventuallly be a capture control command
		if (cmd.command == vehicle_command_s::VEHICLE_CMD_DO_TRIGGER_CONTROL) {

			// Enable/disable signal capture
			if (commandParamToInt(cmd.param1) == 1) {
				set_capture_control(true);

			} else if (commandParamToInt(cmd.param1) == 0) {
				set_capture_control(false);

			}

			// Reset capture sequence
			if (commandParamToInt(cmd.param2) == 1) {
				reset_statistics(true);

			}

			// Acknowledge the command
			vehicle_command_ack_s command_ack{};

			command_ack.timestamp = hrt_absolute_time();
			command_ack.command = cmd.command;
			command_ack.result = (uint8_t)vehicle_command_s::VEHICLE_CMD_RESULT_ACCEPTED;
			command_ack.target_system = cmd.source_system;
			command_ack.target_component = cmd.source_component;

			_command_ack_pub.publish(command_ack);
		}
	}
}

void
CameraCapture::set_capture_control(bool enabled)
{
// a board can define BOARD_CAPTURE_GPIO to use a separate capture pin
#if defined(BOARD_CAPTURE_GPIO)

	px4_arch_gpiosetevent(BOARD_CAPTURE_GPIO, true, false, true, &CameraCapture::gpio_interrupt_routine, this);
	_capture_enabled = enabled;
	_gpio_capture = true;
	reset_statistics(false);

#else

	int fd = ::open(PX4FMU_DEVICE_PATH, O_RDWR);

	if (fd < 0) {
		PX4_ERR("open fail");
		return;
	}

	input_capture_config_t conf;
	conf.channel = 5; // FMU chan 6
	conf.filter = 0;

	if (_camera_capture_mode == 0) {
		conf.edge = _camera_capture_edge ? Rising : Falling;

	} else {
		conf.edge = Both;
	}

	conf.callback = nullptr;
	conf.context = nullptr;

	if (enabled) {

		conf.callback = &CameraCapture::capture_trampoline;
		conf.context = this;

		unsigned int capture_count = 0;

		if (::ioctl(fd, INPUT_CAP_GET_COUNT, (unsigned long)&capture_count) != 0) {
			PX4_INFO("Not in a capture mode");

			unsigned long mode = PWM_SERVO_MODE_4PWM2CAP;

			if (::ioctl(fd, PWM_SERVO_SET_MODE, mode) == 0) {
				PX4_INFO("Mode changed to 4PWM2CAP");

			} else {
				PX4_ERR("Mode NOT changed to 4PWM2CAP!");
				goto err_out;
			}
		}
	}

	if (::ioctl(fd, INPUT_CAP_SET_CALLBACK, (unsigned long)&conf) == 0) {
		_capture_enabled = enabled;
		_gpio_capture = false;

	} else {
		PX4_ERR("Unable to set capture callback for chan %u\n", conf.channel);
		_capture_enabled = false;
		goto err_out;
	}

	reset_statistics(false);

err_out:
	::close(fd);
#endif
}

void
CameraCapture::reset_statistics(bool reset_seq)
{
	if (reset_seq) {
		_capture_seq = 0;
	}

	_last_trig_begin_time = 0;
	_last_exposure_time = 0;
	_last_trig_time = 0;
	_capture_overflows = 0;
}

int
CameraCapture::start()
{
	// run every 100 ms (10 Hz)
	ScheduleOnInterval(100000, 10000);

	return PX4_OK;
}

void
CameraCapture::stop()
{
	ScheduleClear();

	work_cancel(HPWORK, &_work_publisher);

	if (camera_capture::g_camera_capture != nullptr) {
		delete (camera_capture::g_camera_capture);
	}
}

void
CameraCapture::status()
{
	PX4_INFO("Capture enabled : %s", _capture_enabled ? "YES" : "NO");
	PX4_INFO("Frame sequence : %u", _capture_seq);

	if (_last_trig_time != 0) {
		PX4_INFO("Last trigger timestamp : %" PRIu64 " (%i ms ago)", _last_trig_time,
			 (int)(hrt_elapsed_time(&_last_trig_time) / 1000));

	} else {
		PX4_INFO("No trigger yet");
	}

	if (_camera_capture_mode != 0) {
		PX4_INFO("Last exposure time : %0.2f ms", double(_last_exposure_time) / 1000.0);
	}

	PX4_INFO("Number of overflows : %u", _capture_overflows);
}

static int usage()
{
	PX4_INFO("usage: camera_capture {start|stop|on|off|reset|status}\n");
	return 1;
}

extern "C" __EXPORT int camera_capture_main(int argc, char *argv[]);

int camera_capture_main(int argc, char *argv[])
{
	if (argc < 2) {
		return usage();
	}

	if (!strcmp(argv[1], "start")) {

		if (camera_capture::g_camera_capture != nullptr) {
			PX4_WARN("already running");
			return 0;
		}

		camera_capture::g_camera_capture = new CameraCapture();

		if (camera_capture::g_camera_capture == nullptr) {
			PX4_WARN("alloc failed");
			return 1;
		}

		if (!camera_capture::g_camera_capture->start()) {
			return 0;

		} else {
			return 1;
		}

	}

	if (camera_capture::g_camera_capture == nullptr) {
		PX4_WARN("not running");
		return 1;

	} else if (!strcmp(argv[1], "stop")) {
		camera_capture::g_camera_capture->stop();

	} else if (!strcmp(argv[1], "status")) {
		camera_capture::g_camera_capture->status();

	} else if (!strcmp(argv[1], "on")) {
		camera_capture::g_camera_capture->set_capture_control(true);

	} else if (!strcmp(argv[1], "off")) {
		camera_capture::g_camera_capture->set_capture_control(false);

	} else if (!strcmp(argv[1], "reset")) {
		camera_capture::g_camera_capture->set_capture_control(false);
		camera_capture::g_camera_capture->reset_statistics(true);

	} else {
		return usage();
	}

	return 0;
}