// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- /* SITL handling This simulates a GPS on a serial port Andrew Tridgell November 2011 */ #include #if CONFIG_HAL_BOARD == HAL_BOARD_AVR_SITL #include #include #include "AP_HAL_AVR_SITL_Namespace.h" #include "HAL_AVR_SITL_Class.h" #include #include "../SITL/SITL.h" #include "Scheduler.h" #include "UARTDriver.h" #include "../AP_GPS/AP_GPS.h" #include "../AP_GPS/AP_GPS_UBLOX.h" #include #include #include #include #include using namespace AVR_SITL; extern const AP_HAL::HAL& hal; static uint8_t next_gps_index; static uint8_t gps_delay; SITL_State::gps_data SITL_State::_gps_data[MAX_GPS_DELAY]; // state of GPS emulation static struct { /* pipe emulating UBLOX GPS serial stream */ int gps_fd, client_fd; uint32_t last_update; // milliseconds } gps_state; /* hook for reading from the GPS pipe */ ssize_t SITL_State::gps_read(int fd, void *buf, size_t count) { #ifdef FIONREAD // use FIONREAD to get exact value if possible int num_ready; while (ioctl(fd, FIONREAD, &num_ready) == 0 && num_ready > 256) { // the pipe is filling up - drain it uint8_t tmp[128]; if (read(fd, tmp, sizeof(tmp)) != sizeof(tmp)) { break; } } #endif return read(fd, buf, count); } /* setup GPS input pipe */ int SITL_State::gps_pipe(void) { int fd[2]; if (gps_state.client_fd != 0) { return gps_state.client_fd; } pipe(fd); gps_state.gps_fd = fd[1]; gps_state.client_fd = fd[0]; gps_state.last_update = _scheduler->millis(); AVR_SITL::SITLUARTDriver::_set_nonblocking(gps_state.gps_fd); AVR_SITL::SITLUARTDriver::_set_nonblocking(fd[0]); return gps_state.client_fd; } /* write some bytes from the simulated GPS */ void SITL_State::_gps_write(const uint8_t *p, uint16_t size) { while (size--) { if (_sitl->gps_byteloss > 0.0) { float r = ((((unsigned)random()) % 1000000)) / 1.0e4; if (r < _sitl->gps_byteloss) { // lose the byte p++; continue; } } write(gps_state.gps_fd, p++, 1); } } /* send a UBLOX GPS message */ void SITL_State::_gps_send_ubx(uint8_t msgid, uint8_t *buf, uint16_t size) { const uint8_t PREAMBLE1 = 0xb5; const uint8_t PREAMBLE2 = 0x62; const uint8_t CLASS_NAV = 0x1; uint8_t hdr[6], chk[2]; hdr[0] = PREAMBLE1; hdr[1] = PREAMBLE2; hdr[2] = CLASS_NAV; hdr[3] = msgid; hdr[4] = size & 0xFF; hdr[5] = size >> 8; chk[0] = chk[1] = hdr[2]; chk[1] += (chk[0] += hdr[3]); chk[1] += (chk[0] += hdr[4]); chk[1] += (chk[0] += hdr[5]); for (uint8_t i=0; imillis(); // FIX pos.longitude = d->longitude * 1.0e7; pos.latitude = d->latitude * 1.0e7; pos.altitude_ellipsoid = d->altitude*1000.0; pos.altitude_msl = d->altitude*1000.0; pos.horizontal_accuracy = 5; pos.vertical_accuracy = 10; status.time = millis_time_of_week(); status.fix_type = d->have_lock?3:0; status.fix_status = d->have_lock?1:0; status.differential_status = 0; status.res = 0; status.time_to_first_fix = 0; status.uptime = hal.scheduler->millis(); velned.time = status.time; velned.ned_north = 100.0 * d->speedN; velned.ned_east = 100.0 * d->speedE; velned.ned_down = 100.0 * d->speedD; velned.speed_2d = pythagorous2(d->speedN, d->speedE) * 100; velned.speed_3d = pythagorous3(d->speedN, d->speedE, d->speedD) * 100; velned.heading_2d = ToDeg(atan2f(d->speedE, d->speedN)) * 100000.0; if (velned.heading_2d < 0.0) { velned.heading_2d += 360.0 * 100000.0; } velned.speed_accuracy = 2; velned.heading_accuracy = 4; memset(&sol, 0, sizeof(sol)); sol.fix_type = d->have_lock?3:0; sol.fix_status = 221; sol.satellites = d->have_lock?_sitl->gps_numsats:3; _gps_send_ubx(MSG_POSLLH, (uint8_t*)&pos, sizeof(pos)); _gps_send_ubx(MSG_STATUS, (uint8_t*)&status, sizeof(status)); _gps_send_ubx(MSG_VELNED, (uint8_t*)&velned, sizeof(velned)); _gps_send_ubx(MSG_SOL, (uint8_t*)&sol, sizeof(sol)); } static void swap_uint32(uint32_t *v, uint8_t n) { while (n--) { *v = htonl(*v); v++; } } /* MTK type simple checksum */ static void mtk_checksum(const uint8_t *data, uint8_t n, uint8_t *ck_a, uint8_t *ck_b) { *ck_a = *ck_b = 0; while (n--) { *ck_a += *data++; *ck_b += *ck_a; } } /* send a new GPS MTK packet */ void SITL_State::_update_gps_mtk(const struct gps_data *d) { struct PACKED mtk_msg { uint8_t preamble1; uint8_t preamble2; uint8_t msg_class; uint8_t msg_id; int32_t latitude; int32_t longitude; int32_t altitude; int32_t ground_speed; int32_t ground_course; uint8_t satellites; uint8_t fix_type; uint32_t utc_time; uint8_t ck_a; uint8_t ck_b; } p; p.preamble1 = 0xb5; p.preamble2 = 0x62; p.msg_class = 1; p.msg_id = 5; p.latitude = d->latitude * 1.0e6; p.longitude = d->longitude * 1.0e6; p.altitude = d->altitude * 100; p.ground_speed = pythagorous2(d->speedN, d->speedE) * 100; p.ground_course = ToDeg(atan2f(d->speedE, d->speedN)) * 1000000.0; if (p.ground_course < 0.0) { p.ground_course += 360.0 * 1000000.0; } p.satellites = d->have_lock?_sitl->gps_numsats:3; p.fix_type = d->have_lock?3:1; // the spec is not very clear, but the time field seems to be // seconds since the start of the day in UTC time, done in powers // of 100. Quite bizarre. struct tm tm; struct timeval tv; gettimeofday(&tv, NULL); tm = *gmtime(&tv.tv_sec); p.utc_time = tm.tm_sec + tm.tm_min*100 + tm.tm_hour*100*100; swap_uint32((uint32_t *)&p.latitude, 5); swap_uint32((uint32_t *)&p.utc_time, 1); mtk_checksum(&p.msg_class, sizeof(p)-4, &p.ck_a, &p.ck_b); _gps_write((uint8_t*)&p, sizeof(p)); } /* send a new GPS MTK 1.6 packet */ void SITL_State::_update_gps_mtk16(const struct gps_data *d) { struct PACKED mtk_msg { uint8_t preamble1; uint8_t preamble2; uint8_t size; int32_t latitude; int32_t longitude; int32_t altitude; int32_t ground_speed; int32_t ground_course; uint8_t satellites; uint8_t fix_type; uint32_t utc_date; uint32_t utc_time; uint16_t hdop; uint8_t ck_a; uint8_t ck_b; } p; p.preamble1 = 0xd0; p.preamble2 = 0xdd; p.size = sizeof(p) - 5; p.latitude = d->latitude * 1.0e6; p.longitude = d->longitude * 1.0e6; p.altitude = d->altitude * 100; p.ground_speed = pythagorous2(d->speedN, d->speedE) * 100; p.ground_course = ToDeg(atan2f(d->speedE, d->speedN)) * 100.0; if (p.ground_course < 0.0) { p.ground_course += 360.0 * 100.0; } p.satellites = d->have_lock?_sitl->gps_numsats:3; p.fix_type = d->have_lock?3:1; // the spec is not very clear, but the time field seems to be // hundreadths of a second since the start of the day in UTC time, // done in powers of 100. // The data is powers of 100 as well, but in days since 1/1/2000 struct tm tm; struct timeval tv; gettimeofday(&tv, NULL); tm = *gmtime(&tv.tv_sec); p.utc_date = (tm.tm_year-2000) + tm.tm_mon*100 + tm.tm_mday*100*100; p.utc_time = tv.tv_usec/10000 + tm.tm_sec*100 + tm.tm_min*100*100 + tm.tm_hour*100*100*100; p.hdop = 115; mtk_checksum(&p.size, sizeof(p)-4, &p.ck_a, &p.ck_b); _gps_write((uint8_t*)&p, sizeof(p)); } /* send a new GPS MTK 1.9 packet */ void SITL_State::_update_gps_mtk19(const struct gps_data *d) { struct PACKED mtk_msg { uint8_t preamble1; uint8_t preamble2; uint8_t size; int32_t latitude; int32_t longitude; int32_t altitude; int32_t ground_speed; int32_t ground_course; uint8_t satellites; uint8_t fix_type; uint32_t utc_date; uint32_t utc_time; uint16_t hdop; uint8_t ck_a; uint8_t ck_b; } p; p.preamble1 = 0xd1; p.preamble2 = 0xdd; p.size = sizeof(p) - 5; p.latitude = d->latitude * 1.0e7; p.longitude = d->longitude * 1.0e7; p.altitude = d->altitude * 100; p.ground_speed = pythagorous2(d->speedN, d->speedE) * 100; p.ground_course = ToDeg(atan2f(d->speedE, d->speedN)) * 100.0; if (p.ground_course < 0.0) { p.ground_course += 360.0 * 100.0; } p.satellites = d->have_lock?_sitl->gps_numsats:3; p.fix_type = d->have_lock?3:1; // the spec is not very clear, but the time field seems to be // hundreadths of a second since the start of the day in UTC time, // done in powers of 100. // The data is powers of 100 as well, but in days since 1/1/2000 struct tm tm; struct timeval tv; gettimeofday(&tv, NULL); tm = *gmtime(&tv.tv_sec); p.utc_date = (tm.tm_year-2000) + tm.tm_mon*100 + tm.tm_mday*100*100; p.utc_time = tv.tv_usec/10000 + tm.tm_sec*100 + tm.tm_min*100*100 + tm.tm_hour*100*100*100; p.hdop = 115; mtk_checksum(&p.size, sizeof(p)-4, &p.ck_a, &p.ck_b); _gps_write((uint8_t*)&p, sizeof(p)); } /* NMEA checksum */ uint16_t SITL_State::_gps_nmea_checksum(const char *s) { uint16_t cs = 0; const uint8_t *b = (const uint8_t *)s; for (uint16_t i=1; s[i]; i++) { cs ^= b[i]; } return cs; } /* formated print of NMEA message, with checksum appended */ void SITL_State::_gps_nmea_printf(const char *fmt, ...) { char *s = NULL; uint16_t csum; char trailer[6]; va_list ap; va_start(ap, fmt); vasprintf(&s, fmt, ap); va_end(ap); csum = _gps_nmea_checksum(s); snprintf(trailer, sizeof(trailer), "*%02X\r\n", (unsigned)csum); _gps_write((const uint8_t*)s, strlen(s)); _gps_write((const uint8_t*)trailer, 5); free(s); } /* send a new GPS NMEA packet */ void SITL_State::_update_gps_nmea(const struct gps_data *d) { struct timeval tv; struct tm *tm; char tstring[20]; char dstring[20]; char lat_string[20]; char lng_string[20]; gettimeofday(&tv, NULL); tm = gmtime(&tv.tv_sec); // format time string snprintf(tstring, sizeof(tstring), "%02d%02d%05.3f", tm->tm_hour, tm->tm_min, tm->tm_sec + tv.tv_usec*1.0e-6); // format date string snprintf(dstring, sizeof(dstring), "%02d%02d%02d", tm->tm_mday, tm->tm_mon, tm->tm_year % 100); // format latitude double deg = fabs(d->latitude); snprintf(lat_string, sizeof(lat_string), "%02u%08.5f,%c", (unsigned)deg, (deg - int(deg))*60, d->latitude<0?'S':'N'); // format longitude deg = fabs(d->longitude); snprintf(lng_string, sizeof(lng_string), "%03u%08.5f,%c", (unsigned)deg, (deg - int(deg))*60, d->longitude<0?'W':'E'); _gps_nmea_printf("$GPGGA,%s,%s,%s,%01d,%02d,%04.1f,%07.2f,M,0.0,M,,", tstring, lat_string, lng_string, d->have_lock?1:0, d->have_lock?_sitl->gps_numsats:3, 2.0, d->altitude); float speed_knots = pythagorous2(d->speedN, d->speedE)*1.94384449f; float heading = ToDeg(atan2f(d->speedE, d->speedN)); if (heading < 0) { heading += 360.0f; } _gps_nmea_printf("$GPRMC,%s,%c,%s,%s,%.2f,%.2f,%s,,", tstring, d->have_lock?'A':'V', lat_string, lng_string, speed_knots, heading, dstring); } /* possibly send a new GPS packet */ void SITL_State::_update_gps(double latitude, double longitude, float altitude, double speedN, double speedE, double speedD, bool have_lock) { struct gps_data d; char c; Vector3f glitch_offsets = _sitl->gps_glitch; // 5Hz, to match the real config in APM if (hal.scheduler->millis() - gps_state.last_update < 200) { return; } // swallow any config bytes if (gps_state.gps_fd != 0) { read(gps_state.gps_fd, &c, 1); } gps_state.last_update = hal.scheduler->millis(); d.latitude = latitude + glitch_offsets.x; d.longitude = longitude + glitch_offsets.y; d.altitude = altitude + glitch_offsets.z; d.speedN = speedN; d.speedE = speedE; d.speedD = speedD; d.have_lock = have_lock; // add in some GPS lag _gps_data[next_gps_index++] = d; if (next_gps_index >= gps_delay) { next_gps_index = 0; } d = _gps_data[next_gps_index]; if (_sitl->gps_delay != gps_delay) { // cope with updates to the delay control gps_delay = _sitl->gps_delay; for (uint8_t i=0; igps_type.get()) { case SITL::GPS_TYPE_NONE: // no GPS attached break; case SITL::GPS_TYPE_UBLOX: _update_gps_ubx(&d); break; case SITL::GPS_TYPE_MTK: _update_gps_mtk(&d); break; case SITL::GPS_TYPE_MTK16: _update_gps_mtk16(&d); break; case SITL::GPS_TYPE_MTK19: _update_gps_mtk19(&d); break; case SITL::GPS_TYPE_NMEA: _update_gps_nmea(&d); break; } } #endif