int _main(void)
{
THROW_BEGIN()
/* init scl and get sockets:: */
THROW_ON_ERR(scl_init("arduino"));
void *rc_socket = scl_get_socket("rc_raw");
THROW_IF(rc_socket == NULL, -ENODEV);
void *power_socket = scl_get_socket("power");
THROW_IF(power_socket == NULL, -ENODEV);
/* allocate msgpack buffers: */
msgpack_sbuffer *msgpack_buf = msgpack_sbuffer_new();
THROW_IF(msgpack_buf == NULL, -ENOMEM);
msgpack_packer *pk = msgpack_packer_new(msgpack_buf, msgpack_sbuffer_write);
THROW_IF(pk == NULL, -ENOMEM);
/* fetch parameters: */
char *dev_path;
tsint_t dev_speed;
opcd_params_init("exynos_quad.arduino_serial.", 0);
opcd_param_t params[] =
{
{"path", &dev_path},
{"speed", &dev_speed},
OPCD_PARAMS_END
};
opcd_params_apply("", params);
/* opern serial port: */
serialport_t port;
THROW_ON_ERR(serial_open(&port, dev_path, tsint_get(&dev_speed), O_RDONLY));
uint16_t channels_raw[PPM_CHAN_MAX];
uint32_t voltage_raw, current_raw;
float channels[PPM_CHAN_MAX];
while (running)
{
int c = serial_read_char(&port);
if (c < 0)
msleep(1);
/* parse channels: */
int status = ppm_parse_frame(channels_raw, (uint8_t)(c));
if (status)
{
int sig_valid = 0;
int invalid_count = 0;
FOR_N(i, PPM_CHAN_MAX)
{
uint16_t chan_in = channels_raw[i];
if (chan_in >= PPM_VALUE_INVALID)
invalid_count++;
if (chan_in > PPM_VALUE_MAX)
chan_in = PPM_VALUE_MAX;
if (chan_in < PPM_VALUE_MIN)
chan_in = PPM_VALUE_MIN;
channels[i] = (float)(chan_in - PPM_VALUE_MIN) / (PPM_VALUE_MAX - PPM_VALUE_MIN) * 2.f - 1.f;
}
sig_valid = (invalid_count < (PPM_CHAN_MAX / 3));
/* send channels: */
msgpack_sbuffer_clear(msgpack_buf);
msgpack_pack_array(pk, 1 + PPM_CHAN_MAX);
PACKI(sig_valid); /* index 0: valid */
PACKFV(channels, PPM_CHAN_MAX); /* index 1, .. : channels */
scl_copy_send_dynamic(rc_socket, msgpack_buf->data, msgpack_buf->size);
}
/* parse adc voltage/current: */
status = power_parse_frame(&voltage_raw, ¤t_raw, (uint8_t)(c));
if (status)
{
float voltage = (float)(voltage_raw) / 1000.0;
float current = (float)(current_raw) / 1000.0;
/* send voltage / current: */
msgpack_sbuffer_clear(msgpack_buf);
msgpack_pack_array(pk, 2);
PACKF(voltage); /* index 0 */
PACKF(current); /* index 1 */
scl_copy_send_dynamic(power_socket, msgpack_buf->data, msgpack_buf->size);
}
}
void _main(int argc, char *argv[])
{
(void)argc;
(void)argv;
if (scl_init("gpsp") != 0)
{
syslog(LOG_CRIT, "could not init scl module");
exit(EXIT_FAILURE);
}
gps_socket = scl_get_socket("data");
if (gps_socket == NULL)
{
syslog(LOG_CRIT, "could not get scl gate");
exit(EXIT_FAILURE);
}
int64_t hwm = 1;
zmq_setsockopt(gps_socket, ZMQ_SNDHWM, &hwm, sizeof(hwm));
opcd_param_t params[] =
{
{"serial_path", &serial_path},
{"serial_speed", &serial_speed},
OPCD_PARAMS_END
};
opcd_params_init("sensors.gps.", 0);
opcd_params_apply("", params);
int status = serial_open(&port, serial_path, tsint_get(&serial_speed), 0, 0, 0);
if (status < 0)
{
syslog(LOG_CRIT, "could not open serial port: %s", serial_path);
exit(EXIT_FAILURE);
}
nmeaPARSER parser;
nmea_parser_init(&parser);
nmeaINFO info;
nmea_zero_INFO(&info);
int time_set = 0;
int smask = 0; /* global smask collects all sentences and is never reset,
in contrast to info.smask */
while (running)
{
int c = serial_read_char(&port);
if (c < 0)
continue;
char b = c;
/* parse NMEA frame: */
if (nmea_parse(&parser, &b, 1, &info) == 1)
{
smask |= info.smask;
if ( (info.smask & GPGGA) /* check for new position update */
&& (smask & (GPGSA | GPRMC))) /* go sure that we collect all sentences for first output*/
{
GpsData gps_data = GPS_DATA__INIT;
/* set general data: */
char time_str[TIME_STR_LEN];
generate_time_str(time_str, &info.utc);
gps_data.fix = 0;
gps_data.time = time_str;
/* set system time to gps time once: */
if (!time_set && info.fix >= 2)
{
char shell_date_cmd[TIME_STR_LEN + 8];
linux_sys_set_timezone(convert(info.lat), convert(info.lon));
sprintf(shell_date_cmd, "date -s \"%s\"", time_str);
time_set = system(shell_date_cmd) == 0;
}
/* set position data if a minimum of satellites is seen: */
if (info.fix >= 2)
{
gps_data.fix = 2;
PB_SET(gps_data, hdop, info.HDOP);
PB_SET(gps_data, lat, convert(info.lat));
PB_SET(gps_data, lon, convert(info.lon));
PB_SET(gps_data, sats, info.satinfo.inuse);
PB_SET(gps_data, course, info.track);
PB_SET(gps_data, speed, info.speed);
}
/* set data for 3d fix: */
if (info.fix == 3)
{
gps_data.fix = 3;
PB_SET(gps_data, vdop, info.VDOP);
PB_SET(gps_data, alt, info.elv);
}
/* add satellit info: */
unsigned int i;
gps_data.n_satinfo = info.satinfo.inview;
SatInfo **satinfo = malloc(gps_data.n_satinfo * sizeof(SatInfo *));
for (i = 0; i < gps_data.n_satinfo; i++)
{
/* fill SatInfo structure: */
nmeaSATELLITE *nmea_satinfo = &info.satinfo.sat[i];
satinfo[i] = malloc(gps_data.n_satinfo * sizeof(SatInfo));
sat_info__init(satinfo[i]);
satinfo[i]->id = nmea_satinfo->id;
satinfo[i]->in_use = info.satinfo.in_use[i] ? 1 : 0;
satinfo[i]->elv = nmea_satinfo->elv;
satinfo[i]->azimuth = nmea_satinfo->azimuth;
satinfo[i]->sig = nmea_satinfo->sig;
}
gps_data.satinfo = satinfo;
/* send the data: */
SCL_PACK_AND_SEND_DYNAMIC(gps_socket, gps_data, gps_data);
/* free allocated memory: */
for (i = 0; i < gps_data.n_satinfo; i++)
{
free(satinfo[i]);
}
free(satinfo);
}
nmea_zero_INFO(&info);
}
}
}
void _main(int argc, char *argv[])
{
(void)argc;
(void)argv;
syslog(LOG_INFO, "initializing core");
/* init SCL subsystem: */
syslog(LOG_INFO, "initializing signaling and communication link (SCL)");
if (scl_init("core") != 0)
{
syslog(LOG_CRIT, "could not init scl module");
exit(EXIT_FAILURE);
}
/* init params subsystem: */
syslog(LOG_INFO, "initializing opcd interface");
opcd_params_init("core.", 1);
/* initialize logger: */
syslog(LOG_INFO, "opening logger");
if (logger_open() != 0)
{
syslog(LOG_CRIT, "could not open logger");
exit(EXIT_FAILURE);
}
syslog(LOG_CRIT, "logger opened");
sleep(1); /* give scl some time to establish
a link between publisher and subscriber */
LOG(LL_INFO, "+------------------+");
LOG(LL_INFO, "| core startup |");
LOG(LL_INFO, "+------------------+");
LOG(LL_INFO, "initializing system");
/* set-up real-time scheduling: */
struct sched_param sp;
sp.sched_priority = sched_get_priority_max(SCHED_FIFO);
sched_setscheduler(getpid(), SCHED_FIFO, &sp);
if (mlockall(MCL_CURRENT | MCL_FUTURE))
{
LOG(LL_ERROR, "mlockall() failed");
exit(EXIT_FAILURE);
}
/* initialize hardware/drivers: */
omap_i2c_bus_init();
baro_altimeter_init();
ultra_altimeter_init();
ahrs_init();
motors_init();
voltage_reader_start();
//gps_init();
LOG(LL_INFO, "initializing model/controller");
model_init();
ctrl_init();
/* initialize command interface */
LOG(LL_INFO, "initializing cmd interface");
cmd_init();
/* prepare main loop: */
for (int i = 0; i < NUM_AVG; i++)
{
output_avg[i] = sliding_avg_create(OUTPUT_RATIO, 0.0f);
}
LOG(LL_INFO, "system up and running");
struct timespec ts_curr;
struct timespec ts_prev;
struct timespec ts_diff;
clock_gettime(CLOCK_REALTIME, &ts_curr);
/* run model and controller: */
while (1)
{
/* calculate dt: */
ts_prev = ts_curr;
clock_gettime(CLOCK_REALTIME, &ts_curr);
TIMESPEC_SUB(ts_diff, ts_curr, ts_prev);
float dt = (float)ts_diff.tv_sec + (float)ts_diff.tv_nsec / (float)NSEC_PER_SEC;
/* read sensor values into model input structure: */
model_input_t model_input;
model_input.dt = dt;
ahrs_read(&model_input.ahrs_data);
gps_read(&model_input.gps_data);
model_input.ultra_z = ultra_altimeter_read();
model_input.baro_z = baro_altimeter_read();
/* execute model step: */
model_state_t model_state;
model_step(&model_state, &model_input);
/* execute controller step: */
mixer_in_t mixer_in;
ctrl_step(&mixer_in, dt, &model_state);
/* set up mixer input: */
mixer_in.pitch = sliding_avg_calc(output_avg[AVG_PITCH], mixer_in.pitch);
mixer_in.roll = sliding_avg_calc(output_avg[AVG_ROLL], mixer_in.roll);
mixer_in.yaw = sliding_avg_calc(output_avg[AVG_YAW], mixer_in.yaw);
mixer_in.gas = sliding_avg_calc(output_avg[AVG_GAS], mixer_in.gas);
/* write data to motor mixer: */
EVERY_N_TIMES(OUTPUT_RATIO, motors_write(&mixer_in));
}
}
void main_init(int argc, char *argv[])
{
bool override_hw = false;
if (argc > 1)
{
if (strcmp(argv[1], "calibrate") == 0)
calibrate = true;
else
override_hw = true;
}
/* init data structures: */
memset(&pos_in, 0, sizeof(pos_in_t));
vec3_init(&pos_in.acc);
/* init SCL subsystem: */
syslog(LOG_INFO, "initializing signaling and communication link (SCL)");
if (scl_init("pilot") != 0)
{
syslog(LOG_CRIT, "could not init scl module");
die();
}
/* init params subsystem: */
syslog(LOG_INFO, "initializing opcd interface");
opcd_params_init("pilot.", 1);
/* initialize logger: */
syslog(LOG_INFO, "opening logger");
if (logger_open() != 0)
{
syslog(LOG_CRIT, "could not open logger");
die();
}
syslog(LOG_CRIT, "logger opened");
LOG(LL_INFO, "initializing platform");
if (arcade_quad_init(&platform, override_hw) < 0)
{
LOG(LL_ERROR, "could not initialize platform");
die();
}
acc_mag_cal_init();
cmc_init();
const size_t array_len = sizeof(float) * platform.n_motors;
setpoints = malloc(array_len);
ASSERT_NOT_NULL(setpoints);
memset(setpoints, 0, array_len);
rpm_square = malloc(array_len);
ASSERT_NOT_NULL(rpm_square);
memset(rpm_square, 0, array_len);
LOG(LL_INFO, "initializing model/controller");
pos_init();
ne_speed_ctrl_init(REALTIME_PERIOD);
att_ctrl_init();
yaw_ctrl_init();
u_ctrl_init();
u_speed_init();
navi_init();
LOG(LL_INFO, "initializing command interface");
cmd_init();
motors_state_init();
blackbox_init();
/* init flight logic: */
flight_logic_init();
/* init calibration data: */
cal_init(&gyro_cal, 3, 1000);
cal_ahrs_init();
flight_state_init(50, 150, 4.0);
piid_init(REALTIME_PERIOD);
interval_init(&gyro_move_interval);
gps_data_init(&gps_data);
mag_decl_init();
cal_init(&rc_cal, 3, 500);
tsfloat_t acc_fg;
opcd_param_t params[] =
{
{"acc_fg", &acc_fg},
OPCD_PARAMS_END
};
opcd_params_apply("main.", params);
filter1_lp_init(&lp_filter, tsfloat_get(&acc_fg), 0.06, 3);
cm_init();
mon_init();
LOG(LL_INFO, "entering main loop");
}
