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Diffstat (limited to 'host/lib/simple_device.cpp')
-rw-r--r-- | host/lib/simple_device.cpp | 293 |
1 files changed, 293 insertions, 0 deletions
diff --git a/host/lib/simple_device.cpp b/host/lib/simple_device.cpp new file mode 100644 index 000000000..ba1966e0d --- /dev/null +++ b/host/lib/simple_device.cpp @@ -0,0 +1,293 @@ +// +// Copyright 2010 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 <http://www.gnu.org/licenses/>. +// + +#include <uhd/simple_device.hpp> +#include <uhd/device.hpp> +#include <uhd/utils.hpp> +#include <uhd/props.hpp> +#include <uhd/types.hpp> +#include <boost/algorithm/string.hpp> +#include <boost/foreach.hpp> +#include <boost/format.hpp> +#include <stdexcept> + +using namespace uhd; + +/*********************************************************************** + * Tune Helper Function + **********************************************************************/ +static tune_result_t tune( + double target_freq, + double lo_offset, + wax::obj subdev, + wax::obj dxc, + bool is_tx +){ + wax::obj subdev_freq_proxy = subdev[SUBDEV_PROP_FREQ]; + bool subdev_quadrature = subdev[SUBDEV_PROP_QUADRATURE].as<bool>(); + bool subdev_spectrum_inverted = subdev[SUBDEV_PROP_SPECTRUM_INVERTED].as<bool>(); + wax::obj dxc_freq_proxy = dxc[std::string("freq")]; + double dxc_sample_rate = dxc[std::string("rate")].as<double>(); + + // Ask the d'board to tune as closely as it can to target_freq+lo_offset + double target_inter_freq = target_freq + lo_offset; + subdev_freq_proxy = target_inter_freq; + double actual_inter_freq = subdev_freq_proxy.as<double>(); + + // Calculate the DDC setting that will downconvert the baseband from the + // daughterboard to our target frequency. + double delta_freq = target_freq - actual_inter_freq; + double delta_sign = std::signum(delta_freq); + delta_freq *= delta_sign; + delta_freq = fmod(delta_freq, dxc_sample_rate); + bool inverted = delta_freq > dxc_sample_rate/2.0; + double target_dxc_freq = inverted? (delta_freq - dxc_sample_rate) : (-delta_freq); + target_dxc_freq *= delta_sign; + + // If the spectrum is inverted, and the daughterboard doesn't do + // quadrature downconversion, we can fix the inversion by flipping the + // sign of the dxc_freq... (This only happens using the basic_rx board) + if (subdev_spectrum_inverted){ + inverted = not inverted; + } + if (inverted and not subdev_quadrature){ + target_dxc_freq *= -1.0; + inverted = not inverted; + } + // down conversion versus up conversion, fight! + // your mother is ugly and your going down... + target_dxc_freq *= (is_tx)? -1.0 : +1.0; + + dxc_freq_proxy = target_dxc_freq; + double actual_dxc_freq = dxc_freq_proxy.as<double>(); + + //return some kind of tune result tuple/struct + tune_result_t tune_result; + tune_result.target_inter_freq = target_inter_freq; + tune_result.actual_inter_freq = actual_inter_freq; + tune_result.target_dxc_freq = target_dxc_freq; + tune_result.actual_dxc_freq = actual_dxc_freq; + tune_result.spectrum_inverted = inverted; + return tune_result; +} + +/*********************************************************************** + * Helper Functions + **********************************************************************/ +static std::string trim(const std::string &in){ + return boost::algorithm::trim_copy(in); +} + +device_addr_t args_to_device_addr(const std::string &args){ + device_addr_t addr; + + //split the args at the semi-colons + std::vector<std::string> pairs; + boost::split(pairs, args, boost::is_any_of(";")); + BOOST_FOREACH(std::string pair, pairs){ + if (trim(pair) == "") continue; + + //split the key value pairs at the equals + std::vector<std::string> key_val; + boost::split(key_val, pair, boost::is_any_of("=")); + if (key_val.size() != 2) throw std::runtime_error("invalid args string: "+args); + addr[trim(key_val[0])] = trim(key_val[1]); + } + + return addr; +} + +static std::vector<double> get_xx_rates(wax::obj decerps, wax::obj rate){ + std::vector<double> rates; + BOOST_FOREACH(size_t decerp, decerps.as<std::vector<size_t> >()){ + rates.push_back(rate.as<double>()/decerp); + } + return rates; +} + +/*********************************************************************** + * Simple Device Implementation + **********************************************************************/ +class simple_device_impl : public simple_device{ +public: + simple_device_impl(const device_addr_t &addr){ + _dev = device::make(addr); + _mboard = (*_dev)[DEVICE_PROP_MBOARD]; + _rx_ddc = _mboard[named_prop_t(MBOARD_PROP_RX_DSP, "ddc0")]; + _tx_duc = _mboard[named_prop_t(MBOARD_PROP_TX_DSP, "duc0")]; + + //extract rx subdevice + wax::obj rx_dboard = _mboard[MBOARD_PROP_RX_DBOARD]; + std::string rx_subdev_in_use = rx_dboard[DBOARD_PROP_USED_SUBDEVS].as<prop_names_t>().at(0); + _rx_subdev = rx_dboard[named_prop_t(DBOARD_PROP_SUBDEV, rx_subdev_in_use)]; + + //extract tx subdevice + wax::obj tx_dboard = _mboard[MBOARD_PROP_TX_DBOARD]; + std::string tx_subdev_in_use = tx_dboard[DBOARD_PROP_USED_SUBDEVS].as<prop_names_t>().at(0); + _tx_subdev = tx_dboard[named_prop_t(DBOARD_PROP_SUBDEV, tx_subdev_in_use)]; + } + + ~simple_device_impl(void){ + /* NOP */ + } + + device::sptr get_device(void){ + return _dev; + } + + std::string get_name(void){ + return _mboard[MBOARD_PROP_NAME].as<std::string>(); + } + + /******************************************************************* + * Streaming + ******************************************************************/ + void set_streaming(bool enb){ + _rx_ddc[std::string("enabled")] = enb; + } + + bool get_streaming(void){ + return _rx_ddc[std::string("enabled")].as<bool>(); + } + + /******************************************************************* + * RX methods + ******************************************************************/ + void set_rx_rate(double rate){ + double samp_rate = _rx_ddc[std::string("rate")].as<double>(); + assert_has(get_rx_rates(), rate, "simple device rx rate"); + _rx_ddc[std::string("decim")] = size_t(samp_rate/rate); + } + + double get_rx_rate(void){ + double samp_rate = _rx_ddc[std::string("rate")].as<double>(); + size_t decim = _rx_ddc[std::string("decim")].as<size_t>(); + return samp_rate/decim; + } + + std::vector<double> get_rx_rates(void){ + return get_xx_rates(_rx_ddc[std::string("decims")], _rx_ddc[std::string("rate")]); + } + + tune_result_t set_rx_freq(double target_freq){ + double lo_offset = 0.0; + //if the local oscillator will be in the passband, use an offset + if (_rx_subdev[SUBDEV_PROP_LO_INTERFERES].as<bool>()){ + lo_offset = get_rx_rate()*2.0; + } + return tune(target_freq, lo_offset, _rx_subdev, _rx_ddc, false/* not tx */); + } + + freq_range_t get_rx_freq_range(void){ + return _rx_subdev[SUBDEV_PROP_FREQ_RANGE].as<freq_range_t>(); + } + + void set_rx_gain(float gain){ + _rx_subdev[SUBDEV_PROP_GAIN] = gain; + } + + float get_rx_gain(void){ + return _rx_subdev[SUBDEV_PROP_GAIN].as<gain_t>(); + } + + gain_range_t get_rx_gain_range(void){ + return _rx_subdev[SUBDEV_PROP_GAIN_RANGE].as<gain_range_t>(); + } + + void set_rx_antenna(const std::string &ant){ + _rx_subdev[SUBDEV_PROP_ANTENNA] = ant; + } + + std::string get_rx_antenna(void){ + return _rx_subdev[SUBDEV_PROP_ANTENNA].as<std::string>(); + } + + std::vector<std::string> get_rx_antennas(void){ + return _rx_subdev[SUBDEV_PROP_ANTENNA_NAMES].as<std::vector<std::string> >(); + } + + /******************************************************************* + * TX methods + ******************************************************************/ + void set_tx_rate(double rate){ + double samp_rate = _tx_duc[std::string("rate")].as<double>(); + assert_has(get_tx_rates(), rate, "simple device tx rate"); + _tx_duc[std::string("interp")] = size_t(samp_rate/rate); + } + + double get_tx_rate(void){ + double samp_rate = _tx_duc[std::string("rate")].as<double>(); + size_t interp = _tx_duc[std::string("interp")].as<size_t>(); + return samp_rate/interp; + } + + std::vector<double> get_tx_rates(void){ + return get_xx_rates(_tx_duc[std::string("interps")], _tx_duc[std::string("rate")]); + } + + tune_result_t set_tx_freq(double target_freq){ + double lo_offset = 0.0; + //if the local oscillator will be in the passband, use an offset + if (_tx_subdev[SUBDEV_PROP_LO_INTERFERES].as<bool>()){ + lo_offset = get_tx_rate()*2.0; + } + return tune(target_freq, lo_offset, _tx_subdev, _tx_duc, true/* is tx */); + } + + freq_range_t get_tx_freq_range(void){ + return _tx_subdev[SUBDEV_PROP_FREQ_RANGE].as<freq_range_t>(); + } + + void set_tx_gain(float gain){ + _tx_subdev[SUBDEV_PROP_GAIN] = gain; + } + + float get_tx_gain(void){ + return _tx_subdev[SUBDEV_PROP_GAIN].as<gain_t>(); + } + + gain_range_t get_tx_gain_range(void){ + return _tx_subdev[SUBDEV_PROP_GAIN_RANGE].as<gain_range_t>(); + } + + void set_tx_antenna(const std::string &ant){ + _tx_subdev[SUBDEV_PROP_ANTENNA] = ant; + } + + std::string get_tx_antenna(void){ + return _tx_subdev[SUBDEV_PROP_ANTENNA].as<std::string>(); + } + + std::vector<std::string> get_tx_antennas(void){ + return _tx_subdev[SUBDEV_PROP_ANTENNA_NAMES].as<std::vector<std::string> >(); + } + +private: + device::sptr _dev; + wax::obj _mboard; + wax::obj _rx_ddc; + wax::obj _tx_duc; + wax::obj _rx_subdev; + wax::obj _tx_subdev; +}; + +/*********************************************************************** + * The Make Function + **********************************************************************/ +simple_device::sptr simple_device::make(const std::string &args){ + return sptr(new simple_device_impl(args_to_device_addr(args))); +} |