// // Copyright 2010-2011,2014-2016 Ettus Research LLC // Copyright 2018 Ettus Research, a National Instruments Company // // SPDX-License-Identifier: GPL-3.0-or-later // #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace uhd; using namespace boost::posix_time; using namespace boost::algorithm; namespace { constexpr int GPS_COMM_TIMEOUT_MS = 1300; constexpr int GPS_NMEA_NORMAL_FRESHNESS = 1000; constexpr int GPS_SERVO_FRESHNESS = 1000; constexpr int GPS_LOCK_FRESHNESS = 2500; constexpr int GPS_TIMEOUT_DELAY_MS = 200; constexpr int GPSDO_COMMAND_DELAY_MS = 200; } /*! * A NMEA and UBX Parser for the LEA-M8F and other GPSDOs */ class gps_ctrl_parser { private: std::deque gps_data_input; std::string parse_ubx() { // Assumptions: // The deque now contains an UBX message in the format // \xb6\x62 // where // is 1 byte // is 1 byte // is 2 bytes (little-endian), length of // is 2 bytes uint8_t ck_a = 0; uint8_t ck_b = 0; if (gps_data_input.size() >= 8) { uint8_t len_lo = gps_data_input[4]; uint8_t len_hi = gps_data_input[5]; size_t len = len_lo | (len_hi << 8); if (gps_data_input.size() >= len + 8) { /* std::cerr << "DATA: "; for (size_t i=0; i < gps_data_input.size(); i++) { uint8_t dat = gps_data_input[i]; std::cerr << boost::format("%02x ") % (unsigned int)dat; } std::cerr << std::endl; */ uint8_t ck_a_packet = gps_data_input[len+6]; uint8_t ck_b_packet = gps_data_input[len+7]; // Range over which CRC is calculated is for (size_t i = 2; i < len+6; i++) { ck_a += (uint8_t)(gps_data_input[i]); ck_b += ck_a; } std::string msg(gps_data_input.begin(), gps_data_input.begin() + (len + 8)); gps_data_input.erase(gps_data_input.begin(), gps_data_input.begin() + (len + 8)); if (ck_a == ck_a_packet and ck_b == ck_b_packet) { return msg; } } } return std::string(); } std::string parse_nmea() { // Assumptions: // The deque now contains an NMEA message in the format // $G.................*XX // the checksum XX is dropped from the message std::deque::iterator star; star = std::find(gps_data_input.begin() + 2, gps_data_input.end(), '*'); if (star != gps_data_input.end()) { std::string msg(gps_data_input.begin(), star); // The parser will take care of the leftover *XX gps_data_input.erase(gps_data_input.begin(), star); return msg; } return std::string(); } public: template void push_data(InputIterator first, InputIterator last) { gps_data_input.insert(gps_data_input.end(), first, last); } std::string get_next_message() { while (gps_data_input.size() >= 2) { char header1 = gps_data_input[0]; char header2 = gps_data_input[1]; std::string parsed; if (header1 == '$' and header2 == 'G') { parsed = parse_nmea(); } else if (header1 == '\xb5' and header2 == '\x62') { parsed = parse_ubx(); } if (parsed.empty()) { gps_data_input.pop_front(); } else { return parsed; } } return std::string(); } size_t size() { return gps_data_input.size(); } }; /*! * A control for GPSDO devices */ gps_ctrl::~gps_ctrl(void){ /* NOP */ } class gps_ctrl_impl : public gps_ctrl{ private: std::map > sentences; boost::mutex cache_mutex; boost::system_time _last_cache_update; gps_ctrl_parser _gps_parser; std::string get_sentence(const std::string which, const int max_age_ms, const int timeout, const bool wait_for_next = false) { std::string sentence; boost::system_time now = boost::get_system_time(); boost::system_time exit_time = now + milliseconds(timeout); boost::posix_time::time_duration age; if (wait_for_next) { boost::lock_guard lock(cache_mutex); update_cache(); //mark sentence as touched if (sentences.find(which) != sentences.end()) sentences[which].get<2>() = true; } while (1) { try { boost::lock_guard lock(cache_mutex); // update cache if older than a millisecond if (now - _last_cache_update > milliseconds(1)) { update_cache(); } if (sentences.find(which) == sentences.end()) { age = milliseconds(max_age_ms); } else { age = boost::get_system_time() - sentences[which].get<1>(); } if (age < milliseconds(max_age_ms) and (not (wait_for_next and sentences[which].get<2>()))) { sentence = sentences[which].get<0>(); sentences[which].get<2>() = true; } } catch(std::exception &e) { UHD_LOGGER_DEBUG("GPS") << "get_sentence: " << e.what(); } if (not sentence.empty() or now > exit_time) { break; } std::this_thread::sleep_for(std::chrono::milliseconds(1)); now = boost::get_system_time(); } if (sentence.empty()) { throw uhd::value_error("gps ctrl: No " + which + " message found"); } return sentence; } static bool is_nmea_checksum_ok(std::string nmea) { if (nmea.length() < 5 || nmea[0] != '$' || nmea[nmea.length()-3] != '*') return false; std::stringstream ss; uint32_t string_crc; uint32_t calculated_crc = 0; // get crc from string ss << std::hex << nmea.substr(nmea.length()-2, 2); ss >> string_crc; // calculate crc for (size_t i = 1; i < nmea.length()-3; i++) calculated_crc ^= nmea[i]; // return comparison return (string_crc == calculated_crc); } void update_cache() { if(not gps_detected()) { return; } std::list keys; std::map msgs; if (_gps_type == GPS_TYPE_LEA_M8F) { keys = {"GNGGA", "GNRMC", "TIMELOCK", "DISCSRC"}; // Concatenate all incoming data into the deque for (std::string msg = _recv(); msg.length() > 0; msg = _recv()) { _gps_parser.push_data(msg.begin(), msg.end()); } // Get all GPSDO messages available // Creating a map here because we only want the latest of each message type for (std::string msg = _gps_parser.get_next_message(); not msg.empty(); msg = _gps_parser.get_next_message()) { /* if (msg[0] != '$') { std::stringstream ss; ss << "Got message "; for (size_t m = 0; m < msg.size(); m++) { ss << std::hex << (unsigned int)(unsigned char)msg[m] << " " << std::dec; } UHD_LOGGER_WARNING("GPS") << ss.str(); } // */ const uint8_t tim_tos_head[4] = {0xb5, 0x62, 0x0D, 0x12}; const std::string tim_tos_head_str(reinterpret_cast(tim_tos_head), 4); // Try to get NMEA first if (msg[0] == '$') { msgs[msg.substr(1,5)] = msg; } else if (msg.find(tim_tos_head_str) == 0 and msg.length() == 56 + 8) { // header size == 6, field offset == 4, 32-bit field uint8_t flags1 = msg[6 + 4]; uint8_t flags2 = msg[6 + 5]; uint8_t flags3 = msg[6 + 5]; uint8_t flags4 = msg[6 + 5]; uint32_t flags = flags1 | (flags2 << 8) | (flags3 << 16) | (flags4 << 24); /* bits in flags are: leapNow 0 leapSoon 1 leapPositive 2 timeInLimit 3 intOscInLimit 4 extOscInLimit 5 gnssTimeValid 6 UTCTimeValid 7 DiscSrc 10 raim 11 cohPulse 12 lockedPulse 13 */ bool lockedPulse = (flags & (1 << 13)); bool timeInLimit = (flags & (1 << 3)); bool intOscInLimit = (flags & (1 << 4)); uint8_t discSrc = (flags >> 8) & 0x07; if (lockedPulse and timeInLimit and intOscInLimit) { msgs["TIMELOCK"] = "TIME LOCKED"; } else { std::stringstream ss; ss << (lockedPulse ? "" : "no" ) << "lockedPulse " << (timeInLimit ? "" : "no" ) << "timeInLimit " << (intOscInLimit ? "" : "no" ) << "intOscInLimit "; msgs["TIMELOCK"] = ss.str(); } switch (discSrc) { case 0: msgs["DISCSRC"] = "internal"; break; case 1: msgs["DISCSRC"] = "gnss"; break; default: msgs["DISCSRC"] = "other"; break; } } else if (msg[0] == '\xb5' and msg[1] == '\x62') { /* Ignore unsupported UBX message */ } else { std::stringstream ss; ss << "Unknown message "; for (size_t m = 0; m < msg.size(); m++) { ss << std::hex << (unsigned int)(unsigned char)msg[m] << " " << std::dec; } UHD_LOGGER_WARNING("GPS") << ss.str() << ":" << msg << std::endl; } } } else { keys = {"GPGGA", "GPRMC", "SERVO"}; static const boost::regex servo_regex("^\\d\\d-\\d\\d-\\d\\d.*$"); static const boost::regex gp_msg_regex("^\\$GP.*,\\*[0-9A-F]{2}$"); // Get all GPSDO messages available // Creating a map here because we only want the latest of each message type for (std::string msg = _recv(0); not msg.empty(); msg = _recv(0)) { // Strip any end of line characters erase_all(msg, "\r"); erase_all(msg, "\n"); if (msg.empty()) { // Ignore empty strings continue; } if (msg.length() < 6) { UHD_LOGGER_WARNING("GPS") << __FUNCTION__ << ": Short GPSDO string: " << msg ; continue; } // Look for SERVO message if (boost::regex_search(msg, servo_regex, boost::regex_constants::match_continuous)) { msgs["SERVO"] = msg; } else if (boost::regex_match(msg, gp_msg_regex) and is_nmea_checksum_ok(msg)) { msgs[msg.substr(1,5)] = msg; } else { UHD_LOGGER_WARNING("GPS") << __FUNCTION__ << ": Malformed GPSDO string: " << msg ; } } } boost::system_time time = boost::get_system_time(); // Update sentences with newly read data for(std::string key: keys) { if (not msgs[key].empty()) { sentences[key] = boost::make_tuple(msgs[key], time, false); } } _last_cache_update = time; } public: gps_ctrl_impl(uart_iface::sptr uart) : _uart(uart), _gps_type(GPS_TYPE_NONE) { std::string reply; bool i_heard_some_nmea = false, i_heard_something_weird = false; //first we look for an internal GPSDO _flush(); //get whatever junk is in the rx buffer right now, and throw it away _send("*IDN?\r\n"); //request identity from the GPSDO _send("\xB5\x62\x0A\x04\x00\x00\x0E\x34"); // poll UBX-MON-VER //then we loop until we either timeout, or until we get a response that indicates we're a JL device //maximum response time was measured at ~320ms, so we set the timeout at 650ms // For the LEA-M8F, increase the timeout to over one second to increase detection likelihood. const boost::system_time comm_timeout = boost::get_system_time() + milliseconds(1200); while(boost::get_system_time() < comm_timeout) { reply = _recv(); //known devices are JL "FireFly", "GPSTCXO", and "LC_XO" if(reply.find("FireFly") != std::string::npos or reply.find("LC_XO") != std::string::npos or reply.find("GPSTCXO") != std::string::npos) { _gps_type = GPS_TYPE_INTERNAL_GPSDO; break; } else if(reply.substr(0, 3) == "$GP") { i_heard_some_nmea = true; //but keep looking } else if(reply.substr(0, 3) == "$GN" or reply.substr(0, 2) == "\xB5""\x62") { // The u-blox LEA-M8F outputs UBX protocol messages _gps_type = GPS_TYPE_LEA_M8F; break; } else if(not reply.empty()) { // wrong baud rate or firmware still initializing i_heard_something_weird = true; _send("*IDN?\r\n"); //re-send identity request _send("\xB5\x62\x0A\x04\x00\x00\x0E\x34"); // poll UBX-MON-VER } else { // _recv timed out _send("*IDN?\r\n"); //re-send identity request _send("\xB5\x62\x0A\x04\x00\x00\x0E\x34"); // poll UBX-MON-VER } } if (_gps_type == GPS_TYPE_NONE) { if(i_heard_some_nmea) { _gps_type = GPS_TYPE_GENERIC_NMEA; } else if(i_heard_something_weird) { UHD_LOGGER_ERROR("GPS") << "GPS invalid reply \"" << reply << "\", assuming none available"; } } switch(_gps_type) { case GPS_TYPE_INTERNAL_GPSDO: erase_all(reply, "\r"); erase_all(reply, "\n"); UHD_LOGGER_INFO("GPS") << "Found an internal GPSDO: " << reply; init_gpsdo(); break; case GPS_TYPE_GENERIC_NMEA: UHD_LOGGER_INFO("GPS") << "Found a generic NMEA GPS device"; break; case GPS_TYPE_LEA_M8F: UHD_LOGGER_INFO("GPS") << "Found a LEA-M8F GPS device"; init_lea_m8f(); break; case GPS_TYPE_NONE: default: UHD_LOGGER_INFO("GPS") << "No GPSDO found"; break; } // initialize cache update_cache(); } ~gps_ctrl_impl(void){ /* NOP */ } //return a list of supported sensors std::vector get_sensors(void) { std::vector ret{ "gps_gpgga", "gps_gprmc", "gps_gngga", "gps_gnrmc", "gps_time", "gps_locked", "gps_servo", "gps_timelock", "gps_discsrc" }; return ret; } uhd::sensor_value_t get_sensor(std::string key) { if(key == "gps_gpgga" or key == "gps_gprmc" or key == "gps_gngga" or key == "gps_gnrmc" or key == "gps_timelock" or key == "gps_discsrc") { return sensor_value_t( boost::to_upper_copy(key), get_sentence(boost::to_upper_copy(key.substr(4,8)), GPS_NMEA_NORMAL_FRESHNESS, GPS_TIMEOUT_DELAY_MS), ""); } else if(key == "gps_time") { return sensor_value_t("GPS epoch time", int(get_epoch_time()), "seconds"); } else if(key == "gps_locked") { return sensor_value_t("GPS lock status", locked(), "locked", "unlocked"); } else if(key == "gps_servo") { return sensor_value_t( boost::to_upper_copy(key), get_sentence(boost::to_upper_copy(key.substr(4,8)), GPS_SERVO_FRESHNESS, GPS_TIMEOUT_DELAY_MS), ""); } else { throw uhd::value_error("gps ctrl get_sensor unknown key: " + key); } } private: void init_gpsdo(void) { //issue some setup stuff so it spits out the appropriate data //none of these should issue replies so we don't bother looking for them //we have to sleep between commands because the JL device, despite not //acking, takes considerable time to process each command. const std::vector init_cmds = { "SYST:COMM:SER:ECHO OFF\r\n", "SYST:COMM:SER:PRO OFF\r\n", "GPS:GPGGA 1\r\n", "GPS:GGAST 0\r\n", "GPS:GPRMC 1\r\n", "SERV:TRAC 1\r\n" }; for (const auto& cmd : init_cmds) { _send(cmd); std::this_thread::sleep_for( std::chrono::milliseconds(GPSDO_COMMAND_DELAY_MS)); } } void init_lea_m8f(void) { // Enable the UBX-TIM-TOS and the $GNRMC messages const uint8_t en_tim_tos[11] = {0xb5, 0x62, 0x06, 0x01, 0x03, 0x00, 0x0d, 0x12, 0x01, 0x2a, 0x8b}; _send(std::string(reinterpret_cast(en_tim_tos), sizeof(en_tim_tos))); const uint8_t en_gnrmc[11] = {0xb5, 0x62, 0x06, 0x01, 0x03, 0x00, 0xf0, 0x04, 0x01, 0xff, 0x18}; _send(std::string(reinterpret_cast(en_gnrmc), sizeof(en_gnrmc))); } //helper function to retrieve a field from an NMEA sentence std::string get_token(std::string sentence, size_t offset) { boost::tokenizer > tok(sentence); std::vector toked; tok.assign(sentence); //this can throw toked.assign(tok.begin(), tok.end()); if(toked.size() <= offset) { throw uhd::value_error(str(boost::format("Invalid response \"%s\"") % sentence)); } return toked[offset]; } ptime get_time(void) { int error_cnt = 0; ptime gps_time; const std::string rmc = (_gps_type == GPS_TYPE_LEA_M8F) ? "GNRMC" : "GPRMC"; while(error_cnt < 2) { try { // wait for next GPRMC string std::string reply = get_sentence(rmc, GPS_NMEA_NORMAL_FRESHNESS, GPS_COMM_TIMEOUT_MS, true); std::string datestr = get_token(reply, 9); std::string timestr = get_token(reply, 1); if(datestr.size() == 0 or timestr.size() == 0) { throw uhd::value_error(str(boost::format("Invalid response \"%s\"") % reply)); } struct tm raw_date; raw_date.tm_year = std::stoi(datestr.substr(4, 2)) + 2000 - 1900; // years since 1900 raw_date.tm_mon = std::stoi(datestr.substr(2, 2)) - 1; // months since january (0-11) raw_date.tm_mday = std::stoi(datestr.substr(0, 2)); // dom (1-31) raw_date.tm_hour = std::stoi(timestr.substr(0, 2)); raw_date.tm_min = std::stoi(timestr.substr(2, 2)); raw_date.tm_sec = std::stoi(timestr.substr(4,2)); gps_time = boost::posix_time::ptime_from_tm(raw_date); UHD_LOG_TRACE("GPS", "GPS time: " + boost::posix_time::to_simple_string(gps_time)); return gps_time; } catch(std::exception &e) { UHD_LOGGER_DEBUG("GPS") << "get_time: " << e.what(); error_cnt++; } } throw uhd::value_error("get_time: Timeout after no valid message found"); return gps_time; //keep gcc from complaining } int64_t get_epoch_time(void) { return (get_time() - from_time_t(0)).total_seconds(); } bool gps_detected(void) { return (_gps_type != GPS_TYPE_NONE); } int gps_refclock_frequency(void) { if (_gps_type == GPS_TYPE_LEA_M8F) { return 30720; } else if (_gps_type != GPS_TYPE_NONE) { return 10000; } return 0; } bool locked(void) { int error_cnt = 0; const std::string locksentence = (_gps_type == GPS_TYPE_LEA_M8F) ? "TIMELOCK" : "GPGGA"; while(error_cnt < 3) { try { std::string reply = get_sentence(locksentence, GPS_LOCK_FRESHNESS, GPS_COMM_TIMEOUT_MS); if(reply.empty()) error_cnt++; else { if (_gps_type == GPS_TYPE_LEA_M8F) { return reply == "TIME LOCKED"; } else { return (get_token(reply, 6) != "0"); } } } catch(std::exception &e) { UHD_LOGGER_DEBUG("GPS") << "locked: " << e.what(); error_cnt++; } } throw uhd::value_error("locked(): unable to determine GPS lock status"); } uart_iface::sptr _uart; void _flush(void){ while (not _uart->read_uart(0.0).empty()){ //NOP } } std::string _recv(double timeout = GPS_TIMEOUT_DELAY_MS/1000.){ return _uart->read_uart(timeout); } void _send(const std::string &buf){ return _uart->write_uart(buf); } enum { GPS_TYPE_INTERNAL_GPSDO, GPS_TYPE_GENERIC_NMEA, GPS_TYPE_LEA_M8F, GPS_TYPE_NONE } _gps_type; }; /*********************************************************************** * Public make function for the GPS control **********************************************************************/ gps_ctrl::sptr gps_ctrl::make(uart_iface::sptr uart){ return sptr(new gps_ctrl_impl(uart)); }