// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- /* This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ // // u-blox GPS driver for ArduPilot // Origin code by Michael Smith, Jordi Munoz and Jose Julio, DIYDrones.com // Substantially rewritten for new GPS driver structure by Andrew Tridgell // #include "AP_GPS.h" #include "AP_GPS_UBLOX.h" #include #include #include #if CONFIG_HAL_BOARD_SUBTYPE == HAL_BOARD_SUBTYPE_LINUX_NAVIO || \ CONFIG_HAL_BOARD_SUBTYPE == HAL_BOARD_SUBTYPE_LINUX_BH #define UBLOX_SPEED_CHANGE 1 #else #define UBLOX_SPEED_CHANGE 0 #endif #define UBLOX_DEBUGGING 0 #define UBLOX_FAKE_3DLOCK 0 extern const AP_HAL::HAL& hal; #if UBLOX_DEBUGGING # define Debug(fmt, args ...) do {hal.console->printf("%s:%d: " fmt "\n", __FUNCTION__, __LINE__, ## args); hal.scheduler->delay(1); } while(0) #else # define Debug(fmt, args ...) #endif AP_GPS_UBLOX::AP_GPS_UBLOX(AP_GPS &_gps, AP_GPS::GPS_State &_state, AP_HAL::UARTDriver *_port) : AP_GPS_Backend(_gps, _state, _port), _step(0), _msg_id(0), _payload_length(0), _payload_counter(0), _class(0), _cfg_saved(false), _last_cfg_sent_time(0), _num_cfg_save_tries(0), _last_config_time(0), _delay_time(0), _next_message(STEP_RATE_NAV), _ublox_port(255), _have_version(false), _unconfigured_messages(CONFIG_ALL), _hardware_generation(0), _new_position(0), _new_speed(0), _disable_counter(0), next_fix(AP_GPS::NO_FIX), _last_5hz_time(0), _cfg_needs_save(false), noReceivedHdop(true) { // stop any config strings that are pending gps.send_blob_start(state.instance, NULL, 0); _last_5hz_time = AP_HAL::millis(); // start the process of updating the GPS rates _request_next_config(); } void AP_GPS_UBLOX::_request_next_config(void) { // don't request config if we shouldn't configure the GPS if (gps._auto_config == 0) { return; } // Ensure there is enough space for the largest possible outgoing message if (port->txspace() < (int16_t)(sizeof(struct ubx_header)+sizeof(struct ubx_cfg_nav_rate)+2)) { // not enough space - do it next time return; } Debug("Unconfigured messages: %d Current message: %d\n", _unconfigured_messages, _next_message); switch (_next_message++) { case STEP_RATE_NAV: _configure_rate(); break; case STEP_RATE_POSLLH: if(!_configure_message_rate(CLASS_NAV, MSG_POSLLH, RATE_POSLLH)) { _next_message--; } break; case STEP_RATE_VELNED: if(!_configure_message_rate(CLASS_NAV, MSG_VELNED, RATE_VELNED)) { _next_message--; } break; case STEP_PORT: _request_port(); break; case STEP_POLL_SVINFO: // not required once we know what generation we are on if(_hardware_generation == 0) { _send_message(CLASS_NAV, MSG_NAV_SVINFO, 0, 0); } break; case STEP_POLL_SBAS: _send_message(CLASS_CFG, MSG_CFG_SBAS, NULL, 0); break; case STEP_POLL_NAV: _send_message(CLASS_CFG, MSG_CFG_NAV_SETTINGS, NULL, 0); break; case STEP_POLL_GNSS: _send_message(CLASS_CFG, MSG_CFG_GNSS, NULL, 0); break; case STEP_NAV_RATE: _request_navigation_rate(); break; case STEP_POSLLH: if(!_request_message_rate(CLASS_NAV, MSG_POSLLH)) { _next_message--; } break; case STEP_STATUS: if(!_request_message_rate(CLASS_NAV, MSG_STATUS)) { _next_message--; } break; case STEP_SOL: if(!_request_message_rate(CLASS_NAV, MSG_SOL)) { _next_message--; } break; case STEP_VELNED: if(!_request_message_rate(CLASS_NAV, MSG_VELNED)) { _next_message--; } break; case STEP_DOP: if(! _request_message_rate(CLASS_NAV, MSG_DOP)) { _next_message--; } break; case STEP_MON_HW: if(!_request_message_rate(CLASS_MON, MSG_MON_HW)) { _next_message--; } break; case STEP_MON_HW2: if(!_request_message_rate(CLASS_MON, MSG_MON_HW2)) { _next_message--; } break; case STEP_RAW: #if UBLOX_RXM_RAW_LOGGING if(gps._raw_data == 0) { _unconfigured_messages &= ~CONFIG_RATE_RAW; } else if(!_request_message_rate(CLASS_RXM, MSG_RXM_RAW)) { _next_message--; } #else _unconfigured_messages & = ~CONFIG_RATE_RAW; #endif break; case STEP_RAWX: #if UBLOX_RXM_RAW_LOGGING if(gps._raw_data == 0) { _unconfigured_messages &= ~CONFIG_RATE_RAW; } else if(!_request_message_rate(CLASS_RXM, MSG_RXM_RAWX)) { _next_message--; } #else _unconfigured_messages & = ~CONFIG_RATE_RAW; #endif break; case STEP_VERSION: if(!_have_version && !hal.util->get_soft_armed()) { _request_version(); } else { _unconfigured_messages &= ~CONFIG_VERSION; } // no need to send the initial rates, move to checking only _next_message = STEP_PORT; break; default: // this case should never be reached, do a full reset if it is hit _next_message = STEP_RATE_NAV; break; } } void AP_GPS_UBLOX::_verify_rate(uint8_t msg_class, uint8_t msg_id, uint8_t rate) { switch(msg_class) { case CLASS_NAV: switch(msg_id) { case MSG_POSLLH: if(rate == RATE_POSLLH) { _unconfigured_messages &= ~CONFIG_RATE_POSLLH; } else { _configure_message_rate(msg_class, msg_id, RATE_POSLLH); _unconfigured_messages |= CONFIG_RATE_POSLLH; _cfg_needs_save = true; } break; case MSG_STATUS: if(rate == RATE_STATUS) { _unconfigured_messages &= ~CONFIG_RATE_STATUS; } else { _configure_message_rate(msg_class, msg_id, RATE_STATUS); _unconfigured_messages |= CONFIG_RATE_STATUS; _cfg_needs_save = true; } break; case MSG_SOL: if(rate == RATE_SOL) { _unconfigured_messages &= ~CONFIG_RATE_SOL; } else { _configure_message_rate(msg_class, msg_id, RATE_SOL); _unconfigured_messages |= CONFIG_RATE_SOL; _cfg_needs_save = true; } break; case MSG_VELNED: if(rate == RATE_VELNED) { _unconfigured_messages &= ~CONFIG_RATE_VELNED; } else { _configure_message_rate(msg_class, msg_id, RATE_VELNED); _unconfigured_messages |= CONFIG_RATE_VELNED; _cfg_needs_save = true; } break; case MSG_DOP: if(rate == RATE_DOP) { _unconfigured_messages &= ~CONFIG_RATE_DOP; } else { _configure_message_rate(msg_class, msg_id, RATE_DOP); _unconfigured_messages |= CONFIG_RATE_DOP; _cfg_needs_save = true; } break; } break; case CLASS_MON: switch(msg_id) { case MSG_MON_HW: if(rate == RATE_HW) { _unconfigured_messages &= ~CONFIG_RATE_MON_HW; } else { _configure_message_rate(msg_class, msg_id, RATE_HW); _unconfigured_messages |= CONFIG_RATE_MON_HW; _cfg_needs_save = true; } break; case MSG_MON_HW2: if(rate == RATE_HW2) { _unconfigured_messages &= ~CONFIG_RATE_MON_HW2; } else { _configure_message_rate(msg_class, msg_id, RATE_HW2); _unconfigured_messages |= CONFIG_RATE_MON_HW2; _cfg_needs_save = true; } break; } break; #if UBLOX_RXM_RAW_LOGGING case CLASS_RXM: switch(msg_id) { case MSG_RXM_RAW: if(rate == gps._raw_data) { _unconfigured_messages &= ~CONFIG_RATE_RAW; } else { _configure_message_rate(msg_class, msg_id, gps._raw_data); _unconfigured_messages |= CONFIG_RATE_RAW; _cfg_needs_save = true; } break; case MSG_RXM_RAWX: if(rate == gps._raw_data) { _unconfigured_messages &= ~CONFIG_RATE_RAW; } else { _configure_message_rate(msg_class, msg_id, gps._raw_data); _unconfigured_messages |= CONFIG_RATE_RAW; _cfg_needs_save = true; } break; } break; #endif // UBLOX_RXM_RAW_LOGGING } } // Requests the ublox driver to identify what port we are using to communicate void AP_GPS_UBLOX::_request_port(void) { if (port->txspace() < (int16_t)(sizeof(struct ubx_header)+2)) { // not enough space - do it next time return; } _send_message(CLASS_CFG, MSG_CFG_PRT, NULL, 0); } // Ensure there is enough space for the largest possible outgoing message // Process bytes available from the stream // // The stream is assumed to contain only messages we recognise. If it // contains other messages, and those messages contain the preamble // bytes, it is possible for this code to fail to synchronise to the // stream immediately. Without buffering the entire message and // re-processing it from the top, this is unavoidable. The parser // attempts to avoid this when possible. // bool AP_GPS_UBLOX::read(void) { uint8_t data; int16_t numc; bool parsed = false; uint32_t millis_now = AP_HAL::millis(); // walk through the gps configuration at 1 message per second if (millis_now - _last_config_time >= _delay_time) { _request_next_config(); _last_config_time = millis_now; if (_unconfigured_messages) { // send the updates faster until fully configured if (_next_message < STEP_PORT) { // blast the initial settings out _delay_time = 0; } else { _delay_time = 750; } } else { _delay_time = 2000; } } if(!_unconfigured_messages && gps._save_config && !_cfg_saved && _num_cfg_save_tries < 5 && (millis_now - _last_cfg_sent_time) > 5000 && !hal.util->get_soft_armed()) { //save the configuration sent until now if (gps._save_config == 1 || (gps._save_config == 2 && _cfg_needs_save)) { _save_cfg(); } } numc = port->available(); for (int16_t i = 0; i < numc; i++) { // Process bytes received // read the next byte data = port->read(); reset: switch(_step) { // Message preamble detection // // If we fail to match any of the expected bytes, we reset // the state machine and re-consider the failed byte as // the first byte of the preamble. This improves our // chances of recovering from a mismatch and makes it less // likely that we will be fooled by the preamble appearing // as data in some other message. // case 1: if (PREAMBLE2 == data) { _step++; break; } _step = 0; Debug("reset %u", __LINE__); /* no break */ case 0: if(PREAMBLE1 == data) _step++; break; // Message header processing // // We sniff the class and message ID to decide whether we // are going to gather the message bytes or just discard // them. // // We always collect the length so that we can avoid being // fooled by preamble bytes in messages. // case 2: _step++; _class = data; _ck_b = _ck_a = data; // reset the checksum accumulators break; case 3: _step++; _ck_b += (_ck_a += data); // checksum byte _msg_id = data; break; case 4: _step++; _ck_b += (_ck_a += data); // checksum byte _payload_length = data; // payload length low byte break; case 5: _step++; _ck_b += (_ck_a += data); // checksum byte _payload_length += (uint16_t)(data<<8); if (_payload_length > sizeof(_buffer)) { Debug("large payload %u", (unsigned)_payload_length); // assume any payload bigger then what we know about is noise _payload_length = 0; _step = 0; goto reset; } _payload_counter = 0; // prepare to receive payload break; // Receive message data // case 6: _ck_b += (_ck_a += data); // checksum byte if (_payload_counter < sizeof(_buffer)) { _buffer[_payload_counter] = data; } if (++_payload_counter == _payload_length) _step++; break; // Checksum and message processing // case 7: _step++; if (_ck_a != data) { Debug("bad cka %x should be %x", data, _ck_a); _step = 0; goto reset; } break; case 8: _step = 0; if (_ck_b != data) { Debug("bad ckb %x should be %x", data, _ck_b); break; // bad checksum } if (_parse_gps()) { parsed = true; } break; } } return parsed; } // Private Methods ///////////////////////////////////////////////////////////// void AP_GPS_UBLOX::log_mon_hw(void) { if (gps._DataFlash == NULL || !gps._DataFlash->logging_started()) { return; } struct log_Ubx1 pkt = { LOG_PACKET_HEADER_INIT(_ubx_msg_log_index(LOG_GPS_UBX1_MSG)), time_us : AP_HAL::micros64(), instance : state.instance, noisePerMS : _buffer.mon_hw_60.noisePerMS, jamInd : _buffer.mon_hw_60.jamInd, aPower : _buffer.mon_hw_60.aPower, agcCnt : _buffer.mon_hw_60.agcCnt, }; if (_payload_length == 68) { pkt.noisePerMS = _buffer.mon_hw_68.noisePerMS; pkt.jamInd = _buffer.mon_hw_68.jamInd; pkt.aPower = _buffer.mon_hw_68.aPower; pkt.agcCnt = _buffer.mon_hw_68.agcCnt; } gps._DataFlash->WriteBlock(&pkt, sizeof(pkt)); } void AP_GPS_UBLOX::log_mon_hw2(void) { if (gps._DataFlash == NULL || !gps._DataFlash->logging_started()) { return; } struct log_Ubx2 pkt = { LOG_PACKET_HEADER_INIT(_ubx_msg_log_index(LOG_GPS_UBX2_MSG)), time_us : AP_HAL::micros64(), instance : state.instance, ofsI : _buffer.mon_hw2.ofsI, magI : _buffer.mon_hw2.magI, ofsQ : _buffer.mon_hw2.ofsQ, magQ : _buffer.mon_hw2.magQ, }; gps._DataFlash->WriteBlock(&pkt, sizeof(pkt)); } #if UBLOX_RXM_RAW_LOGGING void AP_GPS_UBLOX::log_rxm_raw(const struct ubx_rxm_raw &raw) { if (gps._DataFlash == NULL || !gps._DataFlash->logging_started()) { return; } uint64_t now = AP_HAL::micros64(); for (uint8_t i=0; iWriteBlock(&pkt, sizeof(pkt)); } } void AP_GPS_UBLOX::log_rxm_rawx(const struct ubx_rxm_rawx &raw) { if (gps._DataFlash == NULL || !gps._DataFlash->logging_started()) { return; } uint64_t now = AP_HAL::micros64(); struct log_GPS_RAWH header = { LOG_PACKET_HEADER_INIT(LOG_GPS_RAWH_MSG), time_us : now, rcvTow : raw.rcvTow, week : raw.week, leapS : raw.leapS, numMeas : raw.numMeas, recStat : raw.recStat }; gps._DataFlash->WriteBlock(&header, sizeof(header)); for (uint8_t i=0; iWriteBlock(&pkt, sizeof(pkt)); } } #endif // UBLOX_RXM_RAW_LOGGING void AP_GPS_UBLOX::unexpected_message(void) { Debug("Unexpected message 0x%02x 0x%02x", (unsigned)_class, (unsigned)_msg_id); if (++_disable_counter == 0) { // disable future sends of this message id, but // only do this every 256 messages, as some // message types can't be disabled and we don't // want to get into an ack war Debug("Disabling message 0x%02x 0x%02x", (unsigned)_class, (unsigned)_msg_id); _configure_message_rate(_class, _msg_id, 0); } } bool AP_GPS_UBLOX::_parse_gps(void) { if (_class == CLASS_ACK) { Debug("ACK %u", (unsigned)_msg_id); if(_msg_id == MSG_ACK_ACK) { switch(_buffer.ack.clsID) { case CLASS_CFG: switch(_buffer.ack.msgID) { case MSG_CFG_CFG: _cfg_saved = true; _cfg_needs_save = false; break; case MSG_CFG_GNSS: _unconfigured_messages &= ~CONFIG_GNSS; break; case MSG_CFG_MSG: // There is no way to know what MSG config was ack'ed, assume it was the last // one requested. To verify it rerequest the last config we sent. If we miss // the actual ack we will catch it next time through the poll loop, but that // will be a good chunk of time later. break; case MSG_CFG_NAV_SETTINGS: _unconfigured_messages &= ~CONFIG_NAV_SETTINGS; break; case MSG_CFG_RATE: _unconfigured_messages &= ~CONFIG_RATE_NAV; break; case MSG_CFG_SBAS: _unconfigured_messages &= ~CONFIG_SBAS; break; } break; case CLASS_MON: switch(_buffer.ack.msgID) { case MSG_MON_HW: _unconfigured_messages &= ~CONFIG_RATE_MON_HW; break; case MSG_MON_HW2: _unconfigured_messages &= ~CONFIG_RATE_MON_HW2; break; } } } return false; } if (_class == CLASS_CFG) { switch(_msg_id) { case MSG_CFG_NAV_SETTINGS: Debug("Got settings %u min_elev %d drLimit %u\n", (unsigned)_buffer.nav_settings.dynModel, (int)_buffer.nav_settings.minElev, (unsigned)_buffer.nav_settings.drLimit); _buffer.nav_settings.mask = 0; if (gps._navfilter != AP_GPS::GPS_ENGINE_NONE && _buffer.nav_settings.dynModel != gps._navfilter) { // we've received the current nav settings, change the engine // settings and send them back Debug("Changing engine setting from %u to %u\n", (unsigned)_buffer.nav_settings.dynModel, (unsigned)gps._navfilter); _buffer.nav_settings.dynModel = gps._navfilter; _buffer.nav_settings.mask |= 1; } if (gps._min_elevation != -100 && _buffer.nav_settings.minElev != gps._min_elevation) { Debug("Changing min elevation to %d\n", (int)gps._min_elevation); _buffer.nav_settings.minElev = gps._min_elevation; _buffer.nav_settings.mask |= 2; } if (_buffer.nav_settings.mask != 0) { _send_message(CLASS_CFG, MSG_CFG_NAV_SETTINGS, &_buffer.nav_settings, sizeof(_buffer.nav_settings)); _unconfigured_messages |= CONFIG_NAV_SETTINGS; _cfg_needs_save = true; } else { _unconfigured_messages &= ~CONFIG_NAV_SETTINGS; } return false; #if UBLOX_GNSS_SETTINGS case MSG_CFG_GNSS: if (gps._gnss_mode[state.instance] != 0) { struct ubx_cfg_gnss start_gnss = _buffer.gnss; uint8_t gnssCount = 0; Debug("Got GNSS Settings %u %u %u %u:\n", (unsigned)_buffer.gnss.msgVer, (unsigned)_buffer.gnss.numTrkChHw, (unsigned)_buffer.gnss.numTrkChUse, (unsigned)_buffer.gnss.numConfigBlocks); #if UBLOX_DEBUGGING for(int i = 0; i < _buffer.gnss.numConfigBlocks; i++) { Debug(" %u %u %u 0x%08x\n", (unsigned)_buffer.gnss.configBlock[i].gnssId, (unsigned)_buffer.gnss.configBlock[i].resTrkCh, (unsigned)_buffer.gnss.configBlock[i].maxTrkCh, (unsigned)_buffer.gnss.configBlock[i].flags); } #endif for(int i = 0; i < UBLOX_MAX_GNSS_CONFIG_BLOCKS; i++) { if((gps._gnss_mode[state.instance] & (1 << i)) && i != GNSS_SBAS) { gnssCount++; } } for(int i = 0; i < _buffer.gnss.numConfigBlocks; i++) { // Reserve an equal portion of channels for all enabled systems if(gps._gnss_mode[state.instance] & (1 << _buffer.gnss.configBlock[i].gnssId)) { if(GNSS_SBAS !=_buffer.gnss.configBlock[i].gnssId) { _buffer.gnss.configBlock[i].resTrkCh = (_buffer.gnss.numTrkChHw - 3) / (gnssCount * 2); _buffer.gnss.configBlock[i].maxTrkCh = _buffer.gnss.numTrkChHw; } else { _buffer.gnss.configBlock[i].resTrkCh = 1; _buffer.gnss.configBlock[i].maxTrkCh = 3; } _buffer.gnss.configBlock[i].flags = _buffer.gnss.configBlock[i].flags | 0x00000001; } else { _buffer.gnss.configBlock[i].resTrkCh = 0; _buffer.gnss.configBlock[i].maxTrkCh = 0; _buffer.gnss.configBlock[i].flags = _buffer.gnss.configBlock[i].flags & 0xFFFFFFFE; } } if (!memcmp(&start_gnss, &_buffer.gnss, sizeof(start_gnss))) { _send_message(CLASS_CFG, MSG_CFG_GNSS, &_buffer.gnss, 4 + (8 * _buffer.gnss.numConfigBlocks)); _unconfigured_messages |= CONFIG_GNSS; _cfg_needs_save = true; } else { _unconfigured_messages &= ~CONFIG_GNSS; } } else { _unconfigured_messages &= ~CONFIG_GNSS; } return false; #endif case MSG_CFG_SBAS: if (gps._sbas_mode != 2) { Debug("Got SBAS settings %u %u %u 0x%x 0x%x\n", (unsigned)_buffer.sbas.mode, (unsigned)_buffer.sbas.usage, (unsigned)_buffer.sbas.maxSBAS, (unsigned)_buffer.sbas.scanmode2, (unsigned)_buffer.sbas.scanmode1); if (_buffer.sbas.mode != gps._sbas_mode) { _buffer.sbas.mode = gps._sbas_mode; _send_message(CLASS_CFG, MSG_CFG_SBAS, &_buffer.sbas, sizeof(_buffer.sbas)); _unconfigured_messages |= CONFIG_SBAS; _cfg_needs_save = true; } else { _unconfigured_messages &= ~CONFIG_SBAS; } } else { _unconfigured_messages &= ~CONFIG_SBAS; } return false; case MSG_CFG_MSG: if(_payload_length == sizeof(ubx_cfg_msg_rate_6)) { // can't verify the setting without knowing the port // request the port again if(_ublox_port >= UBLOX_MAX_PORTS) { _request_port(); return false; } _verify_rate(_buffer.msg_rate_6.msg_class, _buffer.msg_rate_6.msg_id, _buffer.msg_rate_6.rates[_ublox_port]); } else { _verify_rate(_buffer.msg_rate.msg_class, _buffer.msg_rate.msg_id, _buffer.msg_rate.rate); } return false; case MSG_CFG_PRT: _ublox_port = _buffer.prt.portID; return false; case MSG_CFG_RATE: if(_buffer.nav_rate.measure_rate_ms != MEASURE_RATE || _buffer.nav_rate.nav_rate != 1 || _buffer.nav_rate.timeref != 0) { _configure_rate(); _unconfigured_messages |= CONFIG_RATE_NAV; _cfg_needs_save = true; } else { _unconfigured_messages &= ~CONFIG_RATE_NAV; } return false; } } if (_class == CLASS_MON) { switch(_msg_id) { case MSG_MON_HW: if (_payload_length == 60 || _payload_length == 68) { log_mon_hw(); } break; case MSG_MON_HW2: if (_payload_length == 28) { log_mon_hw2(); } break; case MSG_MON_VER: _have_version = true; GCS_MAVLINK::send_statustext_all(MAV_SEVERITY_INFO, "u-blox %d HW: %s SW: %s", state.instance, _buffer.mon_ver.hwVersion, _buffer.mon_ver.swVersion); break; default: unexpected_message(); } return false; } #if UBLOX_RXM_RAW_LOGGING if (_class == CLASS_RXM && _msg_id == MSG_RXM_RAW && gps._raw_data != 0) { log_rxm_raw(_buffer.rxm_raw); return false; } else if (_class == CLASS_RXM && _msg_id == MSG_RXM_RAWX && gps._raw_data != 0) { log_rxm_rawx(_buffer.rxm_rawx); return false; } #endif // UBLOX_RXM_RAW_LOGGING if (_class != CLASS_NAV) { unexpected_message(); return false; } switch (_msg_id) { case MSG_POSLLH: Debug("MSG_POSLLH next_fix=%u", next_fix); _last_pos_time = _buffer.posllh.time; state.location.lng = _buffer.posllh.longitude; state.location.lat = _buffer.posllh.latitude; state.location.alt = _buffer.posllh.altitude_msl / 10; state.status = next_fix; _new_position = true; state.horizontal_accuracy = _buffer.posllh.horizontal_accuracy*1.0e-3f; state.vertical_accuracy = _buffer.posllh.vertical_accuracy*1.0e-3f; state.have_horizontal_accuracy = true; state.have_vertical_accuracy = true; #if UBLOX_FAKE_3DLOCK state.location.lng = 1491652300L; state.location.lat = -353632610L; state.location.alt = 58400; state.vertical_accuracy = 0; state.horizontal_accuracy = 0; #endif break; case MSG_STATUS: Debug("MSG_STATUS fix_status=%u fix_type=%u", _buffer.status.fix_status, _buffer.status.fix_type); if (_buffer.status.fix_status & NAV_STATUS_FIX_VALID) { if( (_buffer.status.fix_type == AP_GPS_UBLOX::FIX_3D) && (_buffer.status.fix_status & AP_GPS_UBLOX::NAV_STATUS_DGPS_USED)) { next_fix = AP_GPS::GPS_OK_FIX_3D_DGPS; }else if( _buffer.status.fix_type == AP_GPS_UBLOX::FIX_3D) { next_fix = AP_GPS::GPS_OK_FIX_3D; }else if (_buffer.status.fix_type == AP_GPS_UBLOX::FIX_2D) { next_fix = AP_GPS::GPS_OK_FIX_2D; }else{ next_fix = AP_GPS::NO_FIX; state.status = AP_GPS::NO_FIX; } }else{ next_fix = AP_GPS::NO_FIX; state.status = AP_GPS::NO_FIX; } #if UBLOX_FAKE_3DLOCK state.status = AP_GPS::GPS_OK_FIX_3D; next_fix = state.status; #endif break; case MSG_DOP: Debug("MSG_DOP"); noReceivedHdop = false; state.hdop = _buffer.dop.hDOP; state.vdop = _buffer.dop.vDOP; #if UBLOX_FAKE_3DLOCK state.hdop = 130; state.hdop = 170; #endif break; case MSG_SOL: Debug("MSG_SOL fix_status=%u fix_type=%u", _buffer.solution.fix_status, _buffer.solution.fix_type); if (_buffer.solution.fix_status & NAV_STATUS_FIX_VALID) { if( (_buffer.solution.fix_type == AP_GPS_UBLOX::FIX_3D) && (_buffer.solution.fix_status & AP_GPS_UBLOX::NAV_STATUS_DGPS_USED)) { next_fix = AP_GPS::GPS_OK_FIX_3D_DGPS; }else if( _buffer.solution.fix_type == AP_GPS_UBLOX::FIX_3D) { next_fix = AP_GPS::GPS_OK_FIX_3D; }else if (_buffer.solution.fix_type == AP_GPS_UBLOX::FIX_2D) { next_fix = AP_GPS::GPS_OK_FIX_2D; }else{ next_fix = AP_GPS::NO_FIX; state.status = AP_GPS::NO_FIX; } }else{ next_fix = AP_GPS::NO_FIX; state.status = AP_GPS::NO_FIX; } if(noReceivedHdop) { state.hdop = _buffer.solution.position_DOP; } state.num_sats = _buffer.solution.satellites; if (next_fix >= AP_GPS::GPS_OK_FIX_2D) { state.last_gps_time_ms = AP_HAL::millis(); if (state.time_week == _buffer.solution.week && state.time_week_ms + 200 == _buffer.solution.time) { // we got a 5Hz update. This relies on the way // that uBlox gives timestamps that are always // multiples of 200 for 5Hz _last_5hz_time = state.last_gps_time_ms; } state.time_week_ms = _buffer.solution.time; state.time_week = _buffer.solution.week; } #if UBLOX_FAKE_3DLOCK next_fix = state.status; state.num_sats = 10; state.time_week = 1721; state.time_week_ms = AP_HAL::millis() + 3*60*60*1000 + 37000; state.last_gps_time_ms = AP_HAL::millis(); state.hdop = 130; #endif break; case MSG_VELNED: Debug("MSG_VELNED"); _last_vel_time = _buffer.velned.time; state.ground_speed = _buffer.velned.speed_2d*0.01f; // m/s state.ground_course = wrap_360(_buffer.velned.heading_2d * 1.0e-5f); // Heading 2D deg * 100000 state.have_vertical_velocity = true; state.velocity.x = _buffer.velned.ned_north * 0.01f; state.velocity.y = _buffer.velned.ned_east * 0.01f; state.velocity.z = _buffer.velned.ned_down * 0.01f; state.ground_course = wrap_360(degrees(atan2f(state.velocity.y, state.velocity.x))); state.ground_speed = norm(state.velocity.y, state.velocity.x); state.have_speed_accuracy = true; state.speed_accuracy = _buffer.velned.speed_accuracy*0.01f; #if UBLOX_FAKE_3DLOCK state.speed_accuracy = 0; #endif _new_speed = true; break; case MSG_NAV_SVINFO: { Debug("MSG_NAV_SVINFO\n"); static const uint8_t HardwareGenerationMask = 0x07; _hardware_generation = _buffer.svinfo_header.globalFlags & HardwareGenerationMask; switch (_hardware_generation) { case UBLOX_5: case UBLOX_6: // only 7 and newer support CONFIG_GNSS _unconfigured_messages &= ~CONFIG_GNSS; break; case UBLOX_7: case UBLOX_M8: #if UBLOX_SPEED_CHANGE port->begin(4000000U); Debug("Changed speed to 4Mhz for SPI-driven UBlox\n"); #endif break; default: hal.console->printf("Wrong Ublox Hardware Version%u\n", _hardware_generation); break; }; _unconfigured_messages &= ~CONFIG_VERSION; /* We don't need that anymore */ _configure_message_rate(CLASS_NAV, MSG_NAV_SVINFO, 0); break; } default: Debug("Unexpected NAV message 0x%02x", (unsigned)_msg_id); if (++_disable_counter == 0) { Debug("Disabling NAV message 0x%02x", (unsigned)_msg_id); _configure_message_rate(CLASS_NAV, _msg_id, 0); } return false; } // we only return true when we get new position and speed data // this ensures we don't use stale data if (_new_position && _new_speed && _last_vel_time == _last_pos_time) { _new_speed = _new_position = false; // allow the GPS configuration to run through the full loop at least once before throwing this if (state.status != AP_GPS::NO_FIX && AP_HAL::millis() - _last_5hz_time > 20000U) { // the gps seems to be slow, possibly due to a brown out // invalidate the config so it can be reset _last_5hz_time = AP_HAL::millis(); _unconfigured_messages = CONFIG_ALL; _request_next_config(); GCS_MAVLINK::send_statustext_all(MAV_SEVERITY_CRITICAL, "GPS: u-blox %d is not maintaining a 5Hz update", state.instance); } return true; } return false; } // UBlox auto configuration /* * update checksum for a set of bytes */ void AP_GPS_UBLOX::_update_checksum(uint8_t *data, uint16_t len, uint8_t &ck_a, uint8_t &ck_b) { while (len--) { ck_a += *data; ck_b += ck_a; data++; } } /* * send a ublox message */ void AP_GPS_UBLOX::_send_message(uint8_t msg_class, uint8_t msg_id, void *msg, uint16_t size) { struct ubx_header header; uint8_t ck_a=0, ck_b=0; header.preamble1 = PREAMBLE1; header.preamble2 = PREAMBLE2; header.msg_class = msg_class; header.msg_id = msg_id; header.length = size; _update_checksum((uint8_t *)&header.msg_class, sizeof(header)-2, ck_a, ck_b); _update_checksum((uint8_t *)msg, size, ck_a, ck_b); port->write((const uint8_t *)&header, sizeof(header)); port->write((const uint8_t *)msg, size); port->write((const uint8_t *)&ck_a, 1); port->write((const uint8_t *)&ck_b, 1); } /* * requests the given message rate for a specific message class * and msg_id * returns true if it sent the request, false if waiting on knowing the port */ bool AP_GPS_UBLOX::_request_message_rate(uint8_t msg_class, uint8_t msg_id) { // Without knowing what communication port is being used it isn't possible to verify // always ensure we have a port before sending the request if(_ublox_port >= UBLOX_MAX_PORTS) { _request_port(); return false; } else { struct ubx_cfg_msg msg; msg.msg_class = msg_class; msg.msg_id = msg_id; _send_message(CLASS_CFG, MSG_CFG_MSG, &msg, sizeof(msg)); return true; } } /* * configure a UBlox GPS for the given message rate for a specific * message class and msg_id */ bool AP_GPS_UBLOX::_configure_message_rate(uint8_t msg_class, uint8_t msg_id, uint8_t rate) { if (port->txspace() < (int16_t)(sizeof(struct ubx_header)+sizeof(struct ubx_cfg_msg_rate)+2)) { return false; } struct ubx_cfg_msg_rate msg; msg.msg_class = msg_class; msg.msg_id = msg_id; msg.rate = rate; _send_message(CLASS_CFG, MSG_CFG_MSG, &msg, sizeof(msg)); return true; } /* * request the current naviation solution rate */ void AP_GPS_UBLOX::_request_navigation_rate(void) { _send_message(CLASS_CFG, MSG_CFG_RATE, 0, 0); } /* * save gps configurations to non-volatile memory sent until the call of * this message */ void AP_GPS_UBLOX::_save_cfg() { ubx_cfg_cfg save_cfg; save_cfg.clearMask = 0; save_cfg.saveMask = SAVE_CFG_ALL; save_cfg.loadMask = 0; _send_message(CLASS_CFG, MSG_CFG_CFG, &save_cfg, sizeof(save_cfg)); _last_cfg_sent_time = AP_HAL::millis(); _num_cfg_save_tries++; GCS_MAVLINK::send_statustext_all(MAV_SEVERITY_INFO, "GPS: u-blox %d saving config", state.instance); } /* detect a Ublox GPS. Adds one byte, and returns true if the stream matches a UBlox */ bool AP_GPS_UBLOX::_detect(struct UBLOX_detect_state &state, uint8_t data) { reset: switch (state.step) { case 1: if (PREAMBLE2 == data) { state.step++; break; } state.step = 0; /* no break */ case 0: if (PREAMBLE1 == data) state.step++; break; case 2: state.step++; state.ck_b = state.ck_a = data; break; case 3: state.step++; state.ck_b += (state.ck_a += data); break; case 4: state.step++; state.ck_b += (state.ck_a += data); state.payload_length = data; break; case 5: state.step++; state.ck_b += (state.ck_a += data); state.payload_counter = 0; break; case 6: state.ck_b += (state.ck_a += data); if (++state.payload_counter == state.payload_length) state.step++; break; case 7: state.step++; if (state.ck_a != data) { state.step = 0; goto reset; } break; case 8: state.step = 0; if (state.ck_b == data) { // a valid UBlox packet return true; } else { goto reset; } } return false; } void AP_GPS_UBLOX::_request_version(void) { _send_message(CLASS_MON, MSG_MON_VER, NULL, 0); } void AP_GPS_UBLOX::_configure_rate(void) { struct ubx_cfg_nav_rate msg; msg.measure_rate_ms = MEASURE_RATE; msg.nav_rate = 1; msg.timeref = 0; // UTC time _send_message(CLASS_CFG, MSG_CFG_RATE, &msg, sizeof(msg)); } void AP_GPS_UBLOX::inject_data(uint8_t *data, uint8_t len) { if (port->txspace() > len) { port->write(data, len); } else { Debug("UBX: Not enough TXSPACE"); } } static const char *reasons[] = {"navigation rate", "posllh rate", "status rate", "solution rate", "velned rate", "dop rate", "hw monitor rate", "hw2 monitor rate", "raw rate", "version", "navigation settings", "GNSS settings", "SBAS settings"}; void AP_GPS_UBLOX::broadcast_configuration_failure_reason(void) const { for (uint8_t i = 0; i < ARRAY_SIZE(reasons); i++) { if (_unconfigured_messages & (1 << i)) { GCS_MAVLINK::send_statustext_all(MAV_SEVERITY_INFO, "GPS %d: u-blox %s configuration 0x%02x", state.instance +1, reasons[i], _unconfigured_messages); break; } } }