// // Copyright 2010-2011 Ettus Research LLC // // 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 . // #include #include #include #include #include #include #include #include #include #include #include #include #include "boost/tuple/tuple.hpp" #include "boost/foreach.hpp" using namespace uhd; using namespace boost::gregorian; using namespace boost::posix_time; using namespace boost::algorithm; using namespace boost::this_thread; /*! * A GPS control for Jackson Labs devices (and other NMEA compatible GPS's) */ class gps_ctrl_impl : public gps_ctrl{ private: std::map > sensors; std::string get_cached_sensor(const std::string sensor, const int freshness, const bool once, const bool touch=true) { boost::system_time time = boost::get_system_time(); try { // this is nasty ... //std::cout << boost::format("Requested %s - seen? ") % sensor << sensors[sensor].get<2>() << " once? " << once << std::endl; if(time - sensors[sensor].get<1>() < milliseconds(freshness) && (!once or !sensors[sensor].get<2>())) { sensors[sensor] = boost::make_tuple(sensors[sensor].get<0>(), sensors[sensor].get<1>(), touch); return sensors[sensor].get<0>(); } else { return update_cached_sensors(sensor); } } catch(std::exception &e) { UHD_MSG(warning) << "get_cached_sensor: " << e.what(); } return std::string(); } std::string update_cached_sensors(const std::string sensor) { if(not gps_detected() || (gps_type != GPS_TYPE_JACKSON_LABS)) { UHD_MSG(error) << "get_stat(): unsupported GPS or no GPS detected"; return std::string(); } std::string msg = _recv(); static const boost::regex status_regex("\\d\\d-\\d\\d-\\d\\d"); boost::system_time time = boost::get_system_time(); if(msg.size() < 6) return std::string(); std::string nmea = msg.substr(1,5); const std::list list = boost::assign::list_of("GPGGA")("GPRMC"); BOOST_FOREACH(std::string key, list) { // beginning matches one of the NMEA keys if(!nmea.compare(key)) { sensors[key] = boost::make_tuple(msg, time, !sensor.compare(key)); // if this was what we're looking for return it return (!sensor.compare(key))? msg : std::string(); } } //We're still here so it's not one of the NMEA strings from above if(boost::regex_search(msg, status_regex, boost::regex_constants::match_continuous)) { trim(msg); sensors["SERVO"] = boost::make_tuple(msg, time, false); if(!sensor.compare("SERVO")) return msg; else return std::string(); } return std::string(); } public: gps_ctrl_impl(uart_iface::sptr uart){ _uart = uart; std::string reply; bool i_heard_some_nmea = false, i_heard_something_weird = false; gps_type = GPS_TYPE_NONE; //first we look for a Jackson Labs Firefly (since that's what we provide...) _flush(); //get whatever junk is in the rx buffer right now, and throw it away _send("HAAAY GUYYYYS\n"); //to elicit a response from the Firefly //wait for _send(...) to return sleep(milliseconds(FIREFLY_STUPID_DELAY_MS)); //then we loop until we either timeout, or until we get a response that indicates we're a JL device const boost::system_time comm_timeout = boost::get_system_time() + milliseconds(GPS_COMM_TIMEOUT_MS); while(boost::get_system_time() < comm_timeout) { reply = _recv(); if(reply.find("Command Error") != std::string::npos) { gps_type = GPS_TYPE_JACKSON_LABS; break; } else if(reply.substr(0, 3) == "$GP") i_heard_some_nmea = true; //but keep looking for that "Command Error" response else if(reply.length() != 0) i_heard_something_weird = true; //probably wrong baud rate sleep(milliseconds(GPS_TIMEOUT_DELAY_MS)); } if((i_heard_some_nmea) && (gps_type != GPS_TYPE_JACKSON_LABS)) gps_type = GPS_TYPE_GENERIC_NMEA; if((gps_type == GPS_TYPE_NONE) && i_heard_something_weird) { UHD_MSG(error) << "GPS invalid reply \"" << reply << "\", assuming none available" << std::endl; } switch(gps_type) { case GPS_TYPE_JACKSON_LABS: UHD_MSG(status) << "Found a Jackson Labs GPS" << std::endl; init_firefly(); break; case GPS_TYPE_GENERIC_NMEA: if(gps_type == GPS_TYPE_GENERIC_NMEA) UHD_MSG(status) << "Found a generic NMEA GPS device" << std::endl; break; case GPS_TYPE_NONE: default: break; } } ~gps_ctrl_impl(void){ /* NOP */ } //return a list of supported sensors std::vector get_sensors(void) { std::vector ret = boost::assign::list_of ("gps_gpgga") ("gps_gprmc") ("gps_time") ("gps_locked") ("gps_servo"); return ret; } uhd::sensor_value_t get_sensor(std::string key) { if(key == "gps_gpgga" or key == "gps_gprmc") { return sensor_value_t( boost::to_upper_copy(key), get_cached_sensor(boost::to_upper_copy(key.substr(4,8)), GPS_NMEA_NORMAL_FRESHNESS, false, false), ""); } 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("GPS servo status", get_servo(), ""); } else { throw uhd::value_error("gps ctrl get_sensor unknown key: " + key); } } private: void init_firefly(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. sleep(milliseconds(FIREFLY_STUPID_DELAY_MS)); _send("SYST:COMM:SER:ECHO OFF\n"); sleep(milliseconds(FIREFLY_STUPID_DELAY_MS)); _send("SYST:COMM:SER:PRO OFF\n"); sleep(milliseconds(FIREFLY_STUPID_DELAY_MS)); _send("GPS:GPGGA 1\n"); sleep(milliseconds(FIREFLY_STUPID_DELAY_MS)); _send("GPS:GGAST 0\n"); sleep(milliseconds(FIREFLY_STUPID_DELAY_MS)); _send("GPS:GPRMC 1\n"); sleep(milliseconds(FIREFLY_STUPID_DELAY_MS)); _send("SERV:TRAC 1\n"); // enable servo trace message sleep(milliseconds(FIREFLY_STUPID_DELAY_MS)); } //retrieve a raw NMEA sentence std::string get_nmea(std::string msgtype) { std::string reply; const boost::system_time comm_timeout = boost::get_system_time() + milliseconds(GPS_COMM_TIMEOUT_MS); while(boost::get_system_time() < comm_timeout) { if(!msgtype.compare("GPRMC")) { reply = get_cached_sensor(msgtype, GPS_NMEA_FRESHNESS, true); } else { reply = get_cached_sensor(msgtype, GPS_NMEA_LOW_FRESHNESS, false); } if(reply.size()) { if(reply.substr(1, 5) == msgtype) return reply; } boost::this_thread::sleep(milliseconds(GPS_TIMEOUT_DELAY_MS)); } throw uhd::value_error(str(boost::format("get_nmea(): no %s message found") % msgtype)); return std::string(); } //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; while(error_cnt < 10) { try { std::string reply = get_nmea("GPRMC"); 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)); } //just trust me on this one gps_time = ptime( date( greg_year(boost::lexical_cast(datestr.substr(4, 2)) + 2000), greg_month(boost::lexical_cast(datestr.substr(2, 2))), greg_day(boost::lexical_cast(datestr.substr(0, 2))) ), hours( boost::lexical_cast(timestr.substr(0, 2))) + minutes(boost::lexical_cast(timestr.substr(2, 2))) + seconds(boost::lexical_cast(timestr.substr(4, 2))) ); return gps_time; } catch(std::exception &e) { UHD_MSG(warning) << "get_time: " << e.what(); _flush(); error_cnt++; } } throw uhd::value_error("Timeout after no valid message found"); return gps_time; //keep gcc from complaining } time_t get_epoch_time(void) { return (get_time() - from_time_t(0)).total_seconds(); } bool gps_detected(void) { return (gps_type != GPS_TYPE_NONE); } bool locked(void) { int error_cnt = 0; while(error_cnt < 3) { try { std::string reply = get_cached_sensor("GPGGA", GPS_LOCK_FRESHNESS, false, false); if(reply.size() <= 1) return false; return (get_token(reply, 6) != "0"); } catch(std::exception &e) { UHD_MSG(warning) << "locked: " << e.what(); error_cnt++; } } throw uhd::value_error("Timeout after no valid message found"); return false; } std::string get_servo(void) { std::string reply; const boost::system_time comm_timeout = boost::get_system_time() + milliseconds(GPS_COMM_TIMEOUT_MS); while(boost::get_system_time() < comm_timeout) { reply = get_cached_sensor("SERVO", GPS_SERVO_FRESHNESS, false); if(reply.size()) return reply; boost::this_thread::sleep(milliseconds(GPS_TIMEOUT_DELAY_MS)); } throw uhd::value_error("get_stat(): no servo message found"); return std::string(); } uart_iface::sptr _uart; void _flush(void){ while (not _uart->read_uart(0.0).empty()){ //NOP } } std::string _recv(void){ return _uart->read_uart(GPS_TIMEOUT_DELAY_MS/1000.); } void _send(const std::string &buf){ return _uart->write_uart(buf); } enum { GPS_TYPE_JACKSON_LABS, GPS_TYPE_GENERIC_NMEA, GPS_TYPE_NONE } gps_type; static const int GPS_COMM_TIMEOUT_MS = 1300; static const int GPS_NMEA_FRESHNESS = 10; static const int GPS_NMEA_LOW_FRESHNESS = 2500; static const int GPS_NMEA_NORMAL_FRESHNESS = 1000; static const int GPS_SERVO_FRESHNESS = 2500; static const int GPS_LOCK_FRESHNESS = 2500; static const int GPS_TIMEOUT_DELAY_MS = 200; static const int FIREFLY_STUPID_DELAY_MS = 200; }; /*********************************************************************** * Public make function for the GPS control **********************************************************************/ gps_ctrl::sptr gps_ctrl::make(uart_iface::sptr uart){ return sptr(new gps_ctrl_impl(uart)); }