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#include "freesrp_sink_c.h"
using namespace FreeSRP;
using namespace std;
freesrp_sink_c_sptr make_freesrp_sink_c (const string &args)
{
return gnuradio::get_initial_sptr(new freesrp_sink_c (args));
}
/*
* Specify constraints on number of input and output streams.
* This info is used to construct the input and output signatures
* (2nd & 3rd args to gr_block's constructor). The input and
* output signatures are used by the runtime system to
* check that a valid number and type of inputs and outputs
* are connected to this block. In this case, we accept
* only 1 input and 0 output.
*/
static const int MIN_IN = 1; // mininum number of input streams
static const int MAX_IN = 1; // maximum number of input streams
static const int MIN_OUT = 0; // minimum number of output streams
static const int MAX_OUT = 0; // maximum number of output streams
freesrp_sink_c::freesrp_sink_c (const string & args) : gr::sync_block("freesrp_sink_c",
gr::io_signature::make (MIN_IN, MAX_IN, sizeof (gr_complex)),
gr::io_signature::make (MIN_OUT, MAX_OUT, sizeof (gr_complex))),
freesrp_common(args)
{
if(_srp == nullptr)
{
throw runtime_error("FreeSRP not initialized!");
}
}
bool freesrp_sink_c::start()
{
response res = _srp->send_cmd({SET_DATAPATH_EN, 1});
if(res.error != CMD_OK)
{
return false;
}
_srp->start_tx(std::bind(&freesrp_sink_c::freesrp_tx_callback, this, std::placeholders::_1));
return true;
}
bool freesrp_sink_c::stop()
{
_srp->send_cmd({SET_DATAPATH_EN, 0});
_srp->stop_tx();
return true;
}
void freesrp_sink_c::freesrp_tx_callback(vector<sample>& samples)
{
unique_lock<std::mutex> lk(_buf_mut);
for(sample &s : samples)
{
if(!_buf_queue.try_dequeue(s))
{
s.i = 0;
s.q = 0;
}
else
{
_buf_available_space++;
}
}
_buf_cond.notify_one();
}
int freesrp_sink_c::work(int noutput_items, gr_vector_const_void_star& input_items, gr_vector_void_star& output_items)
{
const gr_complex *in = (const gr_complex *) input_items[0];
unique_lock<std::mutex> lk(_buf_mut);
// Wait until enough space is available
while(_buf_available_space < (unsigned int) noutput_items)
{
_buf_cond.wait(lk);
}
for(int i = 0; i < noutput_items; ++i)
{
sample s;
s.i = (int16_t) (real(in[i]) * 2047.0f);
s.q = (int16_t) (imag(in[i]) * 2047.0f);
if(!_buf_queue.try_enqueue(s))
{
throw runtime_error("Failed to add sample to buffer. This should never happen. Available space reported to be " + to_string(_buf_available_space) + " samples, noutput_items=" + to_string(noutput_items) + ", i=" + to_string(i));
}
else
{
_buf_available_space--;
}
}
return noutput_items;
}
double freesrp_sink_c::set_sample_rate( double rate )
{
command cmd = _srp->make_command(SET_TX_SAMP_FREQ, rate);
response r = _srp->send_cmd(cmd);
if(r.error != CMD_OK)
{
cerr << "Could not set TX sample rate, error: " << r.error << endl;
return 0;
}
else
{
return static_cast<double>(r.param);
}
}
double freesrp_sink_c::get_sample_rate( void )
{
response r = _srp->send_cmd({GET_TX_SAMP_FREQ, 0});
if(r.error != CMD_OK)
{
cerr << "Could not get TX sample rate, error: " << r.error << endl;
return 0;
}
else
{
return r.param;
}
}
double freesrp_sink_c::set_center_freq( double freq, size_t chan )
{
command cmd = _srp->make_command(SET_TX_LO_FREQ, freq);
response r = _srp->send_cmd(cmd);
if(r.error != CMD_OK)
{
cerr << "Could not set TX LO frequency, error: " << r.error << endl;
return 0;
}
else
{
return static_cast<double>(r.param);
}
}
double freesrp_sink_c::get_center_freq( size_t chan )
{
response r = _srp->send_cmd({GET_TX_LO_FREQ, 0});
if(r.error != CMD_OK)
{
cerr << "Could not get TX LO frequency, error: " << r.error << endl;
return 0;
}
else
{
return static_cast<double>(r.param);
}
}
vector<string> freesrp_sink_c::get_gain_names( size_t chan )
{
vector<string> names;
names.push_back("TX_RF");
return names;
}
osmosdr::gain_range_t freesrp_sink_c::get_gain_range(size_t chan)
{
osmosdr::meta_range_t gain_ranges;
gain_ranges.push_back(osmosdr::range_t(0, 89.75, 0.25));
return gain_ranges;
}
osmosdr::gain_range_t freesrp_sink_c::get_gain_range(const string& name, size_t chan)
{
return get_gain_range(chan);
}
double freesrp_sink_c::set_gain(double gain, size_t chan)
{
gain = get_gain_range().clip(gain);
double atten = 89.75 - gain;
command cmd = _srp->make_command(SET_TX_ATTENUATION, atten * 1000);
response r = _srp->send_cmd(cmd);
if(r.error != CMD_OK)
{
cerr << "Could not set TX attenuation, error: " << r.error << endl;
return 0;
}
else
{
return 89.75 - (((double) r.param) / 1000.0);
}
}
double freesrp_sink_c::set_gain(double gain, const string& name, size_t chan)
{
return set_gain(gain, chan);
}
double freesrp_sink_c::get_gain(size_t chan)
{
response r = _srp->send_cmd({GET_TX_ATTENUATION, 0});
if(r.error != CMD_OK)
{
cerr << "Could not get TX RF attenuation, error: " << r.error << endl;
return 0;
}
else
{
return 89.75 - (((double) r.param) / 1000.0);
}
}
double freesrp_sink_c::get_gain(const string& name, size_t chan)
{
return get_gain(chan);
}
double freesrp_sink_c::set_bb_gain(double gain, size_t chan)
{
return set_gain(gain, chan);
}
vector<string> freesrp_sink_c::get_antennas(size_t chan)
{
vector<string> antennas;
antennas.push_back(get_antenna(chan));
return antennas;
}
string freesrp_sink_c::set_antenna(const string& antenna, size_t chan)
{
return get_antenna(chan);
}
string freesrp_sink_c::get_antenna(size_t chan)
{
return "TX";
}
double freesrp_sink_c::set_bandwidth(double bandwidth, size_t chan)
{
command cmd = _srp->make_command(SET_TX_RF_BANDWIDTH, bandwidth);
response r = _srp->send_cmd(cmd);
if(r.error != CMD_OK)
{
cerr << "Could not set TX RF bandwidth, error: " << r.error << endl;
return 0;
}
else
{
return static_cast<double>(r.param);
}
}
double freesrp_sink_c::get_bandwidth(size_t chan)
{
response r = _srp->send_cmd({GET_TX_RF_BANDWIDTH, 0});
if(r.error != CMD_OK)
{
cerr << "Could not get TX RF bandwidth, error: " << r.error << endl;
return 0;
}
else
{
return r.param;
}
}
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