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//
// Copyright 2010-2012,2014 Ettus Research LLC
// Copyright 2018 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: GPL-3.0-or-later
//
#include "wavetable.hpp"
#include <uhd/exception.hpp>
#include <uhd/usrp/multi_usrp.hpp>
#include <uhd/utils/safe_main.hpp>
#include <uhd/utils/static.hpp>
#include <uhd/utils/thread.hpp>
#include <stdint.h>
#include <boost/algorithm/string.hpp>
#include <boost/format.hpp>
#include <boost/program_options.hpp>
#include <chrono>
#include <cmath>
#include <csignal>
#include <iostream>
#include <string>
#include <thread>
namespace po = boost::program_options;
/***********************************************************************
* Signal handlers
**********************************************************************/
static bool stop_signal_called = false;
void sig_int_handler(int)
{
stop_signal_called = true;
}
/***********************************************************************
* Main function
**********************************************************************/
int UHD_SAFE_MAIN(int argc, char* argv[])
{
// variables to be set by po
std::string args, wave_type, ant, subdev, ref, pps, otw, channel_list;
uint64_t total_num_samps;
size_t spb;
double rate, freq, gain, power, wave_freq, bw, lo_offset;
float ampl;
// setup the program options
po::options_description desc("Allowed options");
// clang-format off
desc.add_options()
("help", "help message")
("args", po::value<std::string>(&args)->default_value(""), "single uhd device address args")
("spb", po::value<size_t>(&spb)->default_value(0), "samples per buffer, 0 for default")
("nsamps", po::value<uint64_t>(&total_num_samps)->default_value(0), "total number of samples to transmit")
("rate", po::value<double>(&rate), "rate of outgoing samples")
("freq", po::value<double>(&freq), "RF center frequency in Hz")
("lo-offset", po::value<double>(&lo_offset)->default_value(0.0),
"Offset for frontend LO in Hz (optional)")
("ampl", po::value<float>(&l)->default_value(float(0.3)), "amplitude of the waveform [0 to 0.7]")
("gain", po::value<double>(&gain), "gain for the RF chain")
("power", po::value<double>(&power), "Transmit power (if USRP supports it)")
("ant", po::value<std::string>(&ant), "antenna selection")
("subdev", po::value<std::string>(&subdev), "subdevice specification")
("bw", po::value<double>(&bw), "analog frontend filter bandwidth in Hz")
("wave-type", po::value<std::string>(&wave_type)->default_value("CONST"), "waveform type (CONST, SQUARE, RAMP, SINE)")
("wave-freq", po::value<double>(&wave_freq)->default_value(0), "waveform frequency in Hz")
("ref", po::value<std::string>(&ref)->default_value("internal"), "clock reference (internal, external, mimo, gpsdo)")
("pps", po::value<std::string>(&pps), "PPS source (internal, external, mimo, gpsdo)")
("otw", po::value<std::string>(&otw)->default_value("sc16"), "specify the over-the-wire sample mode")
("channels", po::value<std::string>(&channel_list)->default_value("0"), "which channels to use (specify \"0\", \"1\", \"0,1\", etc)")
("int-n", "tune USRP with integer-N tuning")
;
// clang-format on
po::variables_map vm;
po::store(po::parse_command_line(argc, argv, desc), vm);
po::notify(vm);
// print the help message
if (vm.count("help")) {
std::cout << boost::format("UHD TX Waveforms %s") % desc << std::endl;
return ~0;
}
// create a usrp device
std::cout << std::endl;
std::cout << boost::format("Creating the usrp device with: %s...") % args
<< std::endl;
uhd::usrp::multi_usrp::sptr usrp = uhd::usrp::multi_usrp::make(args);
// always select the subdevice first, the channel mapping affects the other settings
if (vm.count("subdev"))
usrp->set_tx_subdev_spec(subdev);
// detect which channels to use
std::vector<std::string> channel_strings;
std::vector<size_t> channel_nums;
boost::split(channel_strings, channel_list, boost::is_any_of("\"',"));
for (size_t ch = 0; ch < channel_strings.size(); ch++) {
size_t chan = std::stoi(channel_strings[ch]);
if (chan >= usrp->get_tx_num_channels())
throw std::runtime_error("Invalid channel(s) specified.");
else
channel_nums.push_back(std::stoi(channel_strings[ch]));
}
// Lock mboard clocks
if (vm.count("ref")) {
usrp->set_clock_source(ref);
}
std::cout << boost::format("Using Device: %s") % usrp->get_pp_string() << std::endl;
// set the sample rate
if (not vm.count("rate")) {
std::cerr << "Please specify the sample rate with --rate" << std::endl;
return ~0;
}
std::cout << boost::format("Setting TX Rate: %f Msps...") % (rate / 1e6) << std::endl;
usrp->set_tx_rate(rate);
std::cout << boost::format("Actual TX Rate: %f Msps...") % (usrp->get_tx_rate() / 1e6)
<< std::endl
<< std::endl;
// set the center frequency
if (not vm.count("freq")) {
std::cerr << "Please specify the center frequency with --freq" << std::endl;
return ~0;
}
// for the const wave, set the wave freq for small samples per period
if (wave_freq == 0) {
if (wave_type == "CONST") {
wave_freq = usrp->get_tx_rate() / 2;
} else {
throw std::runtime_error(
"wave freq cannot be 0 with wave type other than CONST");
}
}
// pre-compute the waveform values
const wave_table_class wave_table(wave_type, ampl);
const size_t step =
std::lround(wave_freq / usrp->get_tx_rate() * wave_table_len);
size_t index = 0;
for (size_t ch = 0; ch < channel_nums.size(); ch++) {
std::cout << boost::format("Setting TX Freq: %f MHz...") % (freq / 1e6)
<< std::endl;
std::cout << boost::format("Setting TX LO Offset: %f MHz...") % (lo_offset / 1e6)
<< std::endl;
uhd::tune_request_t tune_request(freq, lo_offset);
if (vm.count("int-n"))
tune_request.args = uhd::device_addr_t("mode_n=integer");
usrp->set_tx_freq(tune_request, channel_nums[ch]);
std::cout << boost::format("Actual TX Freq: %f MHz...")
% (usrp->get_tx_freq(channel_nums[ch]) / 1e6)
<< std::endl
<< std::endl;
// set the rf gain
if (vm.count("power")) {
if (!usrp->has_tx_power_reference(ch)) {
std::cout << "ERROR: USRP does not have a reference power API on channel "
<< ch << "!" << std::endl;
return EXIT_FAILURE;
}
std::cout << "Setting TX output power: " << power << " dBm..." << std::endl;
usrp->set_tx_power_reference(power - wave_table.get_power(), ch);
std::cout << "Actual TX output power: "
<< usrp->get_tx_power_reference(ch) + wave_table.get_power()
<< " dBm..." << std::endl;
if (vm.count("gain")) {
std::cout << "WARNING: If you specify both --power and --gain, "
" the latter will be ignored."
<< std::endl;
}
} else if (vm.count("gain")) {
std::cout << boost::format("Setting TX Gain: %f dB...") % gain << std::endl;
usrp->set_tx_gain(gain, channel_nums[ch]);
std::cout << boost::format("Actual TX Gain: %f dB...")
% usrp->get_tx_gain(channel_nums[ch])
<< std::endl
<< std::endl;
}
// set the analog frontend filter bandwidth
if (vm.count("bw")) {
std::cout << boost::format("Setting TX Bandwidth: %f MHz...") % bw
<< std::endl;
usrp->set_tx_bandwidth(bw, channel_nums[ch]);
std::cout << boost::format("Actual TX Bandwidth: %f MHz...")
% usrp->get_tx_bandwidth(channel_nums[ch])
<< std::endl
<< std::endl;
}
// set the antenna
if (vm.count("ant"))
usrp->set_tx_antenna(ant, channel_nums[ch]);
}
std::this_thread::sleep_for(std::chrono::seconds(1)); // allow for some setup time
// error when the waveform is not possible to generate
if (std::abs(wave_freq) > usrp->get_tx_rate() / 2) {
throw std::runtime_error("wave freq out of Nyquist zone");
}
if (usrp->get_tx_rate() / std::abs(wave_freq) > wave_table_len / 2) {
throw std::runtime_error("wave freq too small for table");
}
// create a transmit streamer
// linearly map channels (index0 = channel0, index1 = channel1, ...)
uhd::stream_args_t stream_args("fc32", otw);
stream_args.channels = channel_nums;
uhd::tx_streamer::sptr tx_stream = usrp->get_tx_stream(stream_args);
// allocate a buffer which we re-use for each channel
if (spb == 0) {
spb = tx_stream->get_max_num_samps() * 10;
}
std::vector<std::complex<float>> buff(spb);
std::vector<std::complex<float>*> buffs(channel_nums.size(), &buff.front());
// pre-fill the buffer with the waveform
for (size_t n = 0; n < buff.size(); n++) {
buff[n] = wave_table(index += step);
}
std::cout << boost::format("Setting device timestamp to 0...") << std::endl;
if (channel_nums.size() > 1) {
// Sync times
if (pps == "mimo") {
UHD_ASSERT_THROW(usrp->get_num_mboards() == 2);
// make mboard 1 a slave over the MIMO Cable
usrp->set_time_source("mimo", 1);
// set time on the master (mboard 0)
usrp->set_time_now(uhd::time_spec_t(0.0), 0);
// sleep a bit while the slave locks its time to the master
std::this_thread::sleep_for(std::chrono::milliseconds(100));
} else {
if (pps == "internal" or pps == "external" or pps == "gpsdo")
usrp->set_time_source(pps);
usrp->set_time_unknown_pps(uhd::time_spec_t(0.0));
std::this_thread::sleep_for(
std::chrono::seconds(1)); // wait for pps sync pulse
}
} else {
usrp->set_time_now(0.0);
}
// Check Ref and LO Lock detect
std::vector<std::string> sensor_names;
const size_t tx_sensor_chan = channel_nums.empty() ? 0 : channel_nums[0];
sensor_names = usrp->get_tx_sensor_names(tx_sensor_chan);
if (std::find(sensor_names.begin(), sensor_names.end(), "lo_locked")
!= sensor_names.end()) {
uhd::sensor_value_t lo_locked = usrp->get_tx_sensor("lo_locked", tx_sensor_chan);
std::cout << boost::format("Checking TX: %s ...") % lo_locked.to_pp_string()
<< std::endl;
UHD_ASSERT_THROW(lo_locked.to_bool());
}
const size_t mboard_sensor_idx = 0;
sensor_names = usrp->get_mboard_sensor_names(mboard_sensor_idx);
if ((ref == "mimo")
and (std::find(sensor_names.begin(), sensor_names.end(), "mimo_locked")
!= sensor_names.end())) {
uhd::sensor_value_t mimo_locked =
usrp->get_mboard_sensor("mimo_locked", mboard_sensor_idx);
std::cout << boost::format("Checking TX: %s ...") % mimo_locked.to_pp_string()
<< std::endl;
UHD_ASSERT_THROW(mimo_locked.to_bool());
}
if ((ref == "external")
and (std::find(sensor_names.begin(), sensor_names.end(), "ref_locked")
!= sensor_names.end())) {
uhd::sensor_value_t ref_locked =
usrp->get_mboard_sensor("ref_locked", mboard_sensor_idx);
std::cout << boost::format("Checking TX: %s ...") % ref_locked.to_pp_string()
<< std::endl;
UHD_ASSERT_THROW(ref_locked.to_bool());
}
std::signal(SIGINT, &sig_int_handler);
std::cout << "Press Ctrl + C to stop streaming..." << std::endl;
// Set up metadata. We start streaming a bit in the future
// to allow MIMO operation:
uhd::tx_metadata_t md;
md.start_of_burst = true;
md.end_of_burst = false;
md.has_time_spec = true;
md.time_spec = usrp->get_time_now() + uhd::time_spec_t(0.1);
// send data until the signal handler gets called
// or if we accumulate the number of samples specified (unless it's 0)
uint64_t num_acc_samps = 0;
while (true) {
// Break on the end of duration or CTRL-C
if (stop_signal_called) {
break;
}
// Break when we've received nsamps
if (total_num_samps > 0 and num_acc_samps >= total_num_samps) {
break;
}
// send the entire contents of the buffer
num_acc_samps += tx_stream->send(buffs, buff.size(), md);
// fill the buffer with the waveform
for (size_t n = 0; n < buff.size(); n++) {
buff[n] = wave_table(index += step);
}
md.start_of_burst = false;
md.has_time_spec = false;
}
// send a mini EOB packet
md.end_of_burst = true;
tx_stream->send("", 0, md);
// finished
std::cout << std::endl << "Done!" << std::endl << std::endl;
return EXIT_SUCCESS;
}
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