// // 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 "wrapper_utils.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace uhd; using namespace uhd::usrp; const std::string multi_usrp::ALL_GAINS = ""; /*********************************************************************** * Simple USRP Implementation **********************************************************************/ class multi_usrp_impl : public multi_usrp{ public: multi_usrp_impl(const device_addr_t &addr){ _dev = device::make(addr); } device::sptr get_device(void){ return _dev; } /******************************************************************* * Mboard methods ******************************************************************/ void set_master_clock_rate(double rate, size_t mboard){ if (mboard != ALL_MBOARDS){ _mboard(mboard)[MBOARD_PROP_CLOCK_RATE] = rate; return; } for (size_t m = 0; m < get_num_mboards(); m++){ set_master_clock_rate(rate, m); } } double get_master_clock_rate(size_t mboard){ return _mboard(mboard)[MBOARD_PROP_CLOCK_RATE].as(); } std::string get_pp_string(void){ std::string buff = str(boost::format( "%s USRP:\n" " Device: %s\n" ) % ((get_num_mboards() > 1)? "Multi" : "Single") % (*_dev)[DEVICE_PROP_NAME].as() ); for (size_t m = 0; m < get_num_mboards(); m++){ buff += str(boost::format( " Mboard %d: %s\n" ) % m % _mboard(m)[MBOARD_PROP_NAME].as() ); } //----------- rx side of life ---------------------------------- for (size_t m = 0, chan = 0; m < get_num_mboards(); m++){ for (; chan < (m + 1)*get_rx_subdev_spec(m).size(); chan++){ buff += str(boost::format( " RX Channel: %u\n" " RX DSP: %s\n" " RX Dboard: %s\n" " RX Subdev: %s\n" ) % chan % _rx_dsp(chan)[DSP_PROP_NAME].as() % _rx_dboard(chan)[DBOARD_PROP_NAME].as() % _rx_subdev(chan)[SUBDEV_PROP_NAME].as() ); } } //----------- tx side of life ---------------------------------- for (size_t m = 0, chan = 0; m < get_num_mboards(); m++){ for (; chan < (m + 1)*get_tx_subdev_spec(m).size(); chan++){ buff += str(boost::format( " TX Channel: %u\n" " TX DSP: %s\n" " TX Dboard: %s\n" " TX Subdev: %s\n" ) % chan % _tx_dsp(chan)[DSP_PROP_NAME].as() % _tx_dboard(chan)[DBOARD_PROP_NAME].as() % _tx_subdev(chan)[SUBDEV_PROP_NAME].as() ); } } return buff; } std::string get_mboard_name(size_t mboard){ return _mboard(mboard)[MBOARD_PROP_NAME].as(); } time_spec_t get_time_now(size_t mboard = 0){ return _mboard(mboard)[MBOARD_PROP_TIME_NOW].as(); } time_spec_t get_time_last_pps(size_t mboard = 0){ return _mboard(mboard)[MBOARD_PROP_TIME_PPS].as(); } void set_time_now(const time_spec_t &time_spec, size_t mboard){ if (mboard != ALL_MBOARDS){ _mboard(mboard)[MBOARD_PROP_TIME_NOW] = time_spec; return; } for (size_t m = 0; m < get_num_mboards(); m++){ set_time_now(time_spec, m); } } void set_time_next_pps(const time_spec_t &time_spec){ for (size_t m = 0; m < get_num_mboards(); m++){ _mboard(m)[MBOARD_PROP_TIME_PPS] = time_spec; } } void set_time_unknown_pps(const time_spec_t &time_spec){ std::cout << " 1) catch time transition at pps edge" << std::endl; time_spec_t time_start = get_time_now(); time_spec_t time_start_last_pps = get_time_last_pps(); while(true){ if (get_time_last_pps() != time_start_last_pps) break; if ((get_time_now() - time_start) > time_spec_t(1.1)){ throw std::runtime_error( "Board 0 may not be getting a PPS signal!\n" "No PPS detected within the time interval.\n" "See the application notes for your device.\n" ); } } std::cout << " 2) set times next pps (synchronously)" << std::endl; set_time_next_pps(time_spec); boost::this_thread::sleep(boost::posix_time::seconds(1)); //verify that the time registers are read to be within a few RTT for (size_t m = 1; m < get_num_mboards(); m++){ time_spec_t time_0 = _mboard(0)[MBOARD_PROP_TIME_NOW].as(); time_spec_t time_i = _mboard(m)[MBOARD_PROP_TIME_NOW].as(); if (time_i < time_0 or (time_i - time_0) > time_spec_t(0.01)){ //10 ms: greater than RTT but not too big uhd::warning::post(str(boost::format( "Detected time deviation between board %d and board 0.\n" "Board 0 time is %f seconds.\n" "Board %d time is %f seconds.\n" ) % m % time_0.get_real_secs() % m % time_i.get_real_secs())); } } } bool get_time_synchronized(void){ for (size_t m = 1; m < get_num_mboards(); m++){ time_spec_t time_0 = _mboard(0)[MBOARD_PROP_TIME_NOW].as(); time_spec_t time_i = _mboard(m)[MBOARD_PROP_TIME_NOW].as(); if (time_i < time_0 or (time_i - time_0) > time_spec_t(0.01)) return false; } return true; } void issue_stream_cmd(const stream_cmd_t &stream_cmd, size_t chan){ if (chan != ALL_CHANS){ _rx_dsp(chan)[DSP_PROP_STREAM_CMD] = stream_cmd; return; } for (size_t c = 0; m < get_rx_num_channels(); m++){ issue_stream_cmd(stream_cmd, c); } } void set_clock_config(const clock_config_t &clock_config, size_t mboard){ if (mboard != ALL_MBOARDS){ _mboard(mboard)[MBOARD_PROP_CLOCK_CONFIG] = clock_config; return; } for (size_t m = 0; m < get_num_mboards(); m++){ set_clock_config(clock_config, m); } } size_t get_num_mboards(void){ return (*_dev)[DEVICE_PROP_MBOARD_NAMES].as().size(); } sensor_value_t get_mboard_sensor(const std::string &name, size_t mboard){ return _mboard(mboard)[named_prop_t(MBOARD_PROP_SENSOR, name)].as(); } std::vector get_mboard_sensor_names(size_t mboard){ return _mboard(mboard)[MBOARD_PROP_SENSOR_NAMES].as(); } /******************************************************************* * RX methods ******************************************************************/ void set_rx_subdev_spec(const subdev_spec_t &spec, size_t mboard){ if (mboard != ALL_MBOARDS){ _mboard(mboard)[MBOARD_PROP_RX_SUBDEV_SPEC] = spec; return; } for (size_t m = 0; m < get_num_mboards(); m++){ set_rx_subdev_spec(spec, m); } } subdev_spec_t get_rx_subdev_spec(size_t mboard){ return _mboard(mboard)[MBOARD_PROP_RX_SUBDEV_SPEC].as(); } size_t get_rx_num_channels(void){ return rx_cpm()*get_num_mboards(); //total num channels } std::string get_rx_subdev_name(size_t chan){ return _rx_subdev(chan)[SUBDEV_PROP_NAME].as(); } void set_rx_rate(double rate){ if (chan != ALL_CHANS){ _rx_dsp(chan)[DSP_PROP_HOST_RATE] = rate; do_samp_rate_warning_message(rate, get_rx_rate(chan), "RX"); return; } for (size_t c = 0; m < get_rx_num_channels(); m++){ set_rx_rate(rate, c); } } double get_rx_rate(size_t chan){ return _rx_dsp(chan)[DSP_PROP_HOST_RATE].as(); } tune_result_t set_rx_freq(const tune_request_t &tune_request, size_t chan){ tune_result_t r = tune_rx_subdev_and_dsp(_rx_subdev(chan), _rx_dsp(chan), chan%rx_cpm(), tune_request); do_tune_freq_warning_message(tune_request.target_freq, get_rx_freq(chan), "RX"); return r; } double get_rx_freq(size_t chan){ return derive_freq_from_rx_subdev_and_dsp(_rx_subdev(chan), _rx_dsp(chan), chan%rx_cpm()); } freq_range_t get_rx_freq_range(size_t chan){ return add_dsp_shift(_rx_subdev(chan)[SUBDEV_PROP_FREQ_RANGE].as(), _rx_dsp(chan)); } void set_rx_gain(double gain, const std::string &name, size_t chan){ return _rx_gain_group(chan)->set_value(gain, name); } double get_rx_gain(const std::string &name, size_t chan){ return _rx_gain_group(chan)->get_value(name); } gain_range_t get_rx_gain_range(const std::string &name, size_t chan){ return _rx_gain_group(chan)->get_range(name); } std::vector get_rx_gain_names(size_t chan){ return _rx_gain_group(chan)->get_names(); } void set_rx_antenna(const std::string &ant, size_t chan){ _rx_subdev(chan)[SUBDEV_PROP_ANTENNA] = ant; } std::string get_rx_antenna(size_t chan){ return _rx_subdev(chan)[SUBDEV_PROP_ANTENNA].as(); } std::vector get_rx_antennas(size_t chan){ return _rx_subdev(chan)[SUBDEV_PROP_ANTENNA_NAMES].as(); } void set_rx_bandwidth(double bandwidth, size_t chan){ _rx_subdev(chan)[SUBDEV_PROP_BANDWIDTH] = bandwidth; } double get_rx_bandwidth(size_t chan){ return _rx_subdev(chan)[SUBDEV_PROP_BANDWIDTH].as(); } dboard_iface::sptr get_rx_dboard_iface(size_t chan){ return _rx_dboard(chan)[DBOARD_PROP_DBOARD_IFACE].as(); } sensor_value_t get_rx_sensor(const std::string &name, size_t chan){ return _rx_subdev(chan)[named_prop_t(SUBDEV_PROP_SENSOR, name)].as(); } std::vector get_rx_sensor_names(size_t chan){ return _rx_subdev(chan)[SUBDEV_PROP_SENSOR_NAMES].as(); } /******************************************************************* * TX methods ******************************************************************/ void set_tx_subdev_spec(const subdev_spec_t &spec, size_t mboard){ if (mboard != ALL_MBOARDS){ _mboard(mboard)[MBOARD_PROP_TX_SUBDEV_SPEC] = spec; return; } for (size_t m = 0; m < get_num_mboards(); m++){ set_tx_subdev_spec(spec, m); } } subdev_spec_t get_tx_subdev_spec(size_t mboard){ return _mboard(mboard)[MBOARD_PROP_TX_SUBDEV_SPEC].as(); } std::string get_tx_subdev_name(size_t chan){ return _tx_subdev(chan)[SUBDEV_PROP_NAME].as(); } size_t get_tx_num_channels(void){ return tx_cpm()*get_num_mboards(); //total num channels } void set_tx_rate(double rate){ if (chan != ALL_CHANS){ _tx_dsp(chan)[DSP_PROP_HOST_RATE] = rate; do_samp_rate_warning_message(rate, get_tx_rate(chan), "TX"); return; } for (size_t c = 0; m < get_tx_num_channels(); m++){ set_tx_rate(rate, c); } } double get_tx_rate(size_t chan){ return _tx_dsp(chan)[DSP_PROP_HOST_RATE].as(); } tune_result_t set_tx_freq(const tune_request_t &tune_request, size_t chan){ tune_result_t r = tune_tx_subdev_and_dsp(_tx_subdev(chan), _tx_dsp(chan), chan%tx_cpm(), tune_request); do_tune_freq_warning_message(tune_request.target_freq, get_tx_freq(chan), "TX"); return r; } double get_tx_freq(size_t chan){ return derive_freq_from_tx_subdev_and_dsp(_tx_subdev(chan), _tx_dsp(chan), chan%tx_cpm()); } freq_range_t get_tx_freq_range(size_t chan){ return add_dsp_shift(_tx_subdev(chan)[SUBDEV_PROP_FREQ_RANGE].as(), _tx_dsp(chan)); } void set_tx_gain(double gain, const std::string &name, size_t chan){ return _tx_gain_group(chan)->set_value(gain, name); } double get_tx_gain(const std::string &name, size_t chan){ return _tx_gain_group(chan)->get_value(name); } gain_range_t get_tx_gain_range(const std::string &name, size_t chan){ return _tx_gain_group(chan)->get_range(name); } std::vector get_tx_gain_names(size_t chan){ return _tx_gain_group(chan)->get_names(); } void set_tx_antenna(const std::string &ant, size_t chan){ _tx_subdev(chan)[SUBDEV_PROP_ANTENNA] = ant; } std::string get_tx_antenna(size_t chan){ return _tx_subdev(chan)[SUBDEV_PROP_ANTENNA].as(); } std::vector get_tx_antennas(size_t chan){ return _tx_subdev(chan)[SUBDEV_PROP_ANTENNA_NAMES].as(); } void set_tx_bandwidth(double bandwidth, size_t chan){ _tx_subdev(chan)[SUBDEV_PROP_BANDWIDTH] = bandwidth; } double get_tx_bandwidth(size_t chan){ return _tx_subdev(chan)[SUBDEV_PROP_BANDWIDTH].as(); } dboard_iface::sptr get_tx_dboard_iface(size_t chan){ return _tx_dboard(chan)[DBOARD_PROP_DBOARD_IFACE].as(); } sensor_value_t get_tx_sensor(const std::string &name, size_t chan){ return _tx_subdev(chan)[named_prop_t(SUBDEV_PROP_SENSOR, name)].as(); } std::vector get_tx_sensor_names(size_t chan){ return _tx_subdev(chan)[SUBDEV_PROP_SENSOR_NAMES].as(); } private: device::sptr _dev; size_t rx_cpm(void){ //channels per mboard size_t nchan = get_rx_subdev_spec(0).size(); for (size_t m = 1; m < get_num_mboards(); m++){ if (nchan != get_rx_subdev_spec(m).size()){ throw std::runtime_error("rx subdev spec size inconsistent across all mboards"); } } return nchan; } size_t tx_cpm(void){ //channels per mboard size_t nchan = get_tx_subdev_spec(0).size(); for (size_t m = 1; m < get_num_mboards(); m++){ if (nchan != get_tx_subdev_spec(m).size()){ throw std::runtime_error("tx subdev spec size inconsistent across all mboards"); } } return nchan; } wax::obj _mboard(size_t mboard){ std::string mb_name = (*_dev)[DEVICE_PROP_MBOARD_NAMES].as().at(mboard); return (*_dev)[named_prop_t(DEVICE_PROP_MBOARD, mb_name)]; } wax::obj _rx_dsp(size_t chan){ prop_names_t dsp_names = _mboard(chan/rx_cpm())[MBOARD_PROP_RX_DSP_NAMES].as(); return _mboard(chan/rx_cpm())[named_prop_t(MBOARD_PROP_RX_DSP, dsp_names.at(chan%rx_cpm())]; } wax::obj _tx_dsp(size_t chan){ prop_names_t dsp_names = _mboard(chan/tx_cpm())[MBOARD_PROP_TX_DSP_NAMES].as(); return _mboard(chan/tx_cpm())[named_prop_t(MBOARD_PROP_TX_DSP, dsp_names.at(chan%tx_cpm())]; } wax::obj _rx_dboard(size_t chan){ std::string db_name = get_rx_subdev_spec(chan/rx_cpm()).at(chan%rx_cpm()).db_name; return _mboard(chan/rx_cpm())[named_prop_t(MBOARD_PROP_RX_DBOARD, db_name)]; } wax::obj _tx_dboard(size_t chan){ std::string db_name = get_tx_subdev_spec(chan/tx_cpm()).at(chan%tx_cpm()).db_name; return _mboard(chan/tx_cpm())[named_prop_t(MBOARD_PROP_TX_DBOARD, db_name)]; } wax::obj _rx_subdev(size_t chan){ std::string sd_name = get_rx_subdev_spec(chan/rx_cpm()).at(chan%rx_cpm()).sd_name; return _rx_dboard(chan)[named_prop_t(DBOARD_PROP_SUBDEV, sd_name)]; } wax::obj _tx_subdev(size_t chan){ std::string sd_name = get_tx_subdev_spec(chan/tx_cpm()).at(chan%tx_cpm()).sd_name; return _tx_dboard(chan)[named_prop_t(DBOARD_PROP_SUBDEV, sd_name)]; } gain_group::sptr _rx_gain_group(size_t chan){ std::string sd_name = get_rx_subdev_spec(chan/rx_cpm()).at(chan%rx_cpm()).sd_name; return _rx_dboard(chan)[named_prop_t(DBOARD_PROP_GAIN_GROUP, sd_name)].as(); } gain_group::sptr _tx_gain_group(size_t chan){ std::string sd_name = get_tx_subdev_spec(chan/tx_cpm()).at(chan%tx_cpm()).sd_name; return _tx_dboard(chan)[named_prop_t(DBOARD_PROP_GAIN_GROUP, sd_name)].as(); } }; /*********************************************************************** * The Make Function **********************************************************************/ multi_usrp::sptr multi_usrp::make(const device_addr_t &dev_addr){ return sptr(new multi_usrp_impl(dev_addr)); }