Files
openairinterface5g/radio/LMSSDR/sodera_lib.cpp
Robert Schmidt 8107939f08 Change OAI license to CSSL v1.0 (and others)
- all RAN code, CI code, configuration files, dockerfiles, in CSSL v1.0
- all deployment code (openshift, charts, ancillary files like shell
  scripts), in MIT
- documentation in CC-BY-4.0
- exceptions might apply and are listed in NOTICE
- there is a new LICENSES folder with all licenses
- CONTRIBUTIONS.md has been updated accordingly

For automated changes based on OAI PL v1.1:

    perl -i~ -0pe 's/\/\*.*Licensed to the OpenAirInterface.*openairinterface.org\n#?/\/*\n * SPDX-License-Identifier: LicenseRef-CSSL-1.0\n/s' **/*.{c,h,cpp}
    perl -i~ -0pe 's/\/\*.*Licensed to the OpenAirInterface.*openairinterface.org\n#?/\/*\n * SPDX-License-Identifier: LicenseRef-CSSL-1.0\n/s' **/*.ts
    perl -i~ -0pe 's/<!--.*Licensed to the OpenAirInterface.*openairinterface.org\n.*-->/<!-- SPDX-License-Identifier: LicenseRef-CSSL-1.0 -->/s' **/*.xml

The rest (cmake, files with missing license, cmake) manually.
2026-03-27 16:36:37 +01:00

682 lines
20 KiB
C++

/*
* SPDX-License-Identifier: LicenseRef-CSSL-1.0
*/
#include <vector>
#include <string>
#include <stdio.h>
#include <stdlib.h>
#include <inttypes.h>
#include <string.h>
#include <pthread.h>
#include <unistd.h>
#include <iostream>
#include <complex>
#include <fstream>
#include <cmath>
#include "common_lib.h"
#include "lmsComms.h"
#include "LMS7002M.h"
#include "Si5351C.h"
#include "LMS_StreamBoard.h"
#include "openair1/PHY/sse_intrin.h"
using namespace std;
int num_devices=0;
/*These items configure the underlying asynch stream used by the the sync interface.
*/
#define BUFFERSIZE 4096
#define BUFFERSCOUNT 32
typedef struct
{
// --------------------------------
// variables for SoDeRa configuration
// --------------------------------
LMScomms Port;
Si5351C Si;
LMS7002M lmsControl;
LMS_StreamBoard *lmsStream;
char buffers_rx[BUFFERSIZE*BUFFERSCOUNT];
int handles[BUFFERSCOUNT];
int current_handle;
int samples_left_buffer;
double sample_rate;
// time offset between transmiter timestamp and receiver timestamp;
double tdiff;
int channelscount;
// --------------------------------
// Debug and output control
// --------------------------------
int num_underflows;
int num_overflows;
int num_seq_errors;
int64_t tx_count;
int64_t rx_count;
openair0_timestamp_t rx_timestamp;
} sodera_t;
typedef struct {
uint8_t reserved[8];
uint64_t counter;
char data[4080];
} StreamPacket_t;
sodera_t sodera_state;
enum STATUS {
SUCCESS,
FAILURE
};
STATUS SPI_write(LMScomms* dataPort, uint16_t address, uint16_t data)
{
assert(dataPort != nullptr);
LMScomms::GenericPacket ctrPkt;
ctrPkt.cmd = CMD_BRDSPI_WR;
ctrPkt.outBuffer.push_back((address >> 8) & 0xFF);
ctrPkt.outBuffer.push_back(address & 0xFF);
ctrPkt.outBuffer.push_back((data >> 8) & 0xFF);
ctrPkt.outBuffer.push_back(data & 0xFF);
dataPort->TransferPacket(ctrPkt);
return ctrPkt.status == 1 ? SUCCESS : FAILURE;
}
uint16_t SPI_read(LMScomms* dataPort, uint16_t address)
{
assert(dataPort != nullptr);
LMScomms::GenericPacket ctrPkt;
ctrPkt.cmd = CMD_BRDSPI_RD;
ctrPkt.outBuffer.push_back((address >> 8) & 0xFF);
ctrPkt.outBuffer.push_back(address & 0xFF);
dataPort->TransferPacket(ctrPkt);
if (ctrPkt.inBuffer.size() > 4)
return ctrPkt.inBuffer[2] * 256 + ctrPkt.inBuffer[3];
else
return 0;
}
static int trx_sodera_start(openair0_device_t *device)
{
sodera_t *s = (sodera_t*)device->priv;
// init recv and send streaming
printf("Starting LMS Streaming\n");
s->rx_count = 0;
s->tx_count = 0;
s->rx_timestamp = 0;
s->current_handle = 0;
// switch off RX
uint16_t regVal = SPI_read(&s->Port,0x0005);
SPI_write(&s->Port,0x0005,regVal & ~0x6);
// USB FIFO reset
LMScomms::GenericPacket ctrPkt;
ctrPkt.cmd = CMD_USB_FIFO_RST;
ctrPkt.outBuffer.push_back(0x01);
s->Port.TransferPacket(ctrPkt);
ctrPkt.outBuffer[0]=0x00;
s->Port.TransferPacket(ctrPkt);
regVal = SPI_read(&s->Port,0x0005);
// provide timestamp, set streamTXEN, set TX/RX enable
SPI_write(&s->Port,0x0005,(regVal & ~0x20) | 0x6);
if (s->channelscount==2) {
SPI_write(&s->Port,0x0001,0x0003);
SPI_write(&s->Port,0x0007,0x000A);
}
else {
SPI_write(&s->Port,0x0001,0x0001);
SPI_write(&s->Port,0x0007,0x0008);
}
for (int i=0; i< BUFFERSCOUNT ; i++)
s->handles[i] = s->Port.BeginDataReading(&s->buffers_rx[i*BUFFERSIZE],BUFFERSIZE);
printf("Armed %d transfers\n",BUFFERSCOUNT);
return 0;
}
static void trx_sodera_end(openair0_device_t *device)
{
sodera_t *s = (sodera_t*)device->priv;
// stop TX/RX if they were active
uint16_t regVal = SPI_read(&s->Port,0x0005);
SPI_write(&s->Port,0x0005,regVal & ~0x6);
}
static int trx_sodera_write(openair0_device_t *device, openair0_timestamp_t timestamp, void **buff, int nsamps, int cc, int flags)
{
sodera_t *s = (sodera_t*)device->priv;
return 0;
}
#define DEBUG_READ 1
static int trx_sodera_read(openair0_device_t *device, openair0_timestamp_t *ptimestamp, void **buff, int nsamps, int cc)
{
sodera_t *s = (sodera_t*)device->priv;
int samples_received=0,i,j;
int nsamps2; // aligned to upper 32 or 16 byte boundary
StreamPacket_t *p;
int16_t sampleI,sampleQ;
char *pktStart;
int offset = 0;
int num_p;
int ind=0;
int buffsize;
int spp;
int bufindex;
// this assumes that each request is of size 4096 bytes (spp = 4080/4/channelscount)
spp = sizeof(p->data)>>2; // spp = size of payload in samples
spp /= s->channelscount;
#ifdef DEBUG_READ
printf("\nIn trx_read\n");
printf("s->current_handle %d\n", s->current_handle);
printf("s->samples_left_buffer %d\n",s->samples_left_buffer);
#endif
// first get rid of remaining samples
if (s->samples_left_buffer > 0) {
buffsize = min(s->samples_left_buffer,nsamps);
pktStart = ((StreamPacket_t*)&s->buffers_rx[s->current_handle*BUFFERSIZE])->data;
pktStart += (spp-s->samples_left_buffer);
const int stepSize = s->channelscount * 3;
for (int b=0;b<buffsize<<2;b+=stepSize) {
for (int ch=0;ch<s->channelscount;ch++) {
// I sample
sampleI = (pktStart[b + 1 + 3*ch]&0x0F)<<8;
sampleI |= (pktStart[b + 3*ch]&0xFF);
sampleI = (sampleI<<4)>>4;
// Q sample
sampleQ = (pktStart[b + 2 + 3*ch]&0x0F)<<8;
sampleQ |= (pktStart[b + 1 + 3*ch]&0xFF);
sampleQ = (sampleQ<<4)>>4;
((uint32_t*)buff[ch])[ind] = ((uint32_t)sampleI) | (((uint32_t)sampleQ)<<16);
}
ind++;
}
}
if (ind == nsamps) {
s->samples_left_buffer -= nsamps;
s->rx_count += nsamps;
*ptimestamp = s->rx_timestamp;
s->rx_timestamp+=nsamps;
return(nsamps);
}
else {
s->samples_left_buffer = 0;
nsamps -= ind;
samples_received = ind;
}
// This is for the left-over part => READ from USB
num_p = nsamps / spp;
if ((nsamps%spp) > 0)
num_p++;
s->samples_left_buffer = (num_p*spp)-nsamps;
#ifdef DEBUG_READ
printf("num_p %d\n",num_p);
#endif
const int stepSize = s->channelscount * 3;
for (i=0;i<num_p;i++) {
bufindex = (s->current_handle+i)&(BUFFERSCOUNT-1);
if (s->Port.WaitForReading(s->handles[bufindex],1000) == false) {
printf("[recv] Error: request %d samples (%d/%d) WaitForReading timed out\n",nsamps,bufindex,num_p);
*ptimestamp = s->rx_timestamp;
s->rx_timestamp+=samples_received;
return(samples_received);
}
long bytesToRead=BUFFERSIZE;
if (s->Port.FinishDataReading(&s->buffers_rx[bufindex*BUFFERSIZE],bytesToRead,s->handles[bufindex]) != BUFFERSIZE) {
printf("[recv] Error: request %d samples (%d/%d) WaitForReading timed out\n",nsamps,bufindex,num_p);
*ptimestamp = s->rx_timestamp;
s->rx_timestamp+=samples_received;
return(samples_received);
}
p = (StreamPacket_t*)&s->buffers_rx[bufindex*BUFFERSIZE];
// handle timestamp
if ((i==0) & (ind==0)) { // grab the timestamp from HW
*ptimestamp = p->counter;
s->rx_timestamp = p->counter+nsamps; // for next time
#ifdef DEBUG_READ
printf("RX timestamp %d\n",s->rx_timestamp);
#endif
}
else { // check the timestamp
if (i==0) {
if ((s->rx_timestamp + ind) != p->counter) {
printf("Error, RX timestamp error, got %lu, should be %llu\n",p->counter,s->rx_timestamp+ind);
return(ind);
}
}
*ptimestamp = s->rx_timestamp;
s->rx_timestamp+=nsamps;
}
pktStart = p->data;
for (uint16_t b=0;b<sizeof(p->data);b+=stepSize) {
for (int ch=0;ch < s->channelscount;ch++) {
// I sample
sampleI = (pktStart[b + 1 + 3*ch]&0x0F)<<8;
sampleI |= (pktStart[b + 3*ch]&0xFF);
sampleI = (sampleI<<4)>>4;
// Q sample
sampleQ = (pktStart[b + 2 + 3*ch]&0x0F)<<8;
sampleQ |= (pktStart[b + 1 + 3*ch]&0xFF);
sampleQ = (sampleQ<<4)>>4;
((uint32_t*)buff[ch])[ind] = ((uint32_t)sampleI) | (((uint32_t)sampleQ)<<16);
}
ind++;
}
samples_received+=spp;
// schedule a new transmission for this index
s->handles[bufindex] = s->Port.BeginDataReading(&s->buffers_rx[bufindex*BUFFERSIZE],BUFFERSIZE);
s->current_handle=(s->current_handle+1)&(BUFFERSCOUNT-1);
}
//handle the error code
s->rx_count += samples_received;
// s->rx_timestamp = s->rx_md.time_spec.to_ticks(s->sample_rate);
return samples_received;
}
static bool is_equal(double a, double b)
{
return fabs(a-b) < 1e-6;
}
int trx_sodera_set_freq(openair0_device_t *device, openair0_config_t *openair0_cfg, int dummy)
{
sodera_t *s = (sodera_t*)device->priv;
// s->usrp->set_tx_freq(openair0_cfg[0].tx_freq[0]);
// s->usrp->set_rx_freq(openair0_cfg[0].rx_freq[0]);
return (0);
}
int openair0_set_rx_frequencies(openair0_device_t *device, openair0_config_t *openair0_cfg)
{
sodera_t *s = (sodera_t*)device->priv;
static int first_call=1;
static double rf_freq,diff;
// uhd::tune_request_t rx_tune_req(openair0_cfg[0].rx_freq[0]);
// rx_tune_req.rf_freq_policy = uhd::tune_request_t::POLICY_MANUAL;
// rx_tune_req.rf_freq = openair0_cfg[0].rx_freq[0];
// rf_freq=openair0_cfg[0].rx_freq[0];
// s->usrp->set_rx_freq(rx_tune_req);
return (0);
}
int trx_sodera_set_gains(openair0_device_t *device, openair0_config_t *openair0_cfg)
{
sodera_t *s = (sodera_t*)device->priv;
// s->usrp->set_tx_gain(openair0_cfg[0].tx_gain[0]);
// ::uhd::gain_range_t gain_range = s->usrp->get_rx_gain_range(0);
// limit to maximum gain
/* if (openair0_cfg[0].rx_gain[0]-openair0_cfg[0].rx_gain_offset[0] > gain_range.stop()) {
printf("RX Gain 0 too high, reduce by %f dB\n",
openair0_cfg[0].rx_gain[0]-openair0_cfg[0].rx_gain_offset[0] - gain_range.stop());
exit(-1);
}
s->usrp->set_rx_gain(openair0_cfg[0].rx_gain[0]-openair0_cfg[0].rx_gain_offset[0]);
printf("Setting SODERA RX gain to %f (rx_gain %f,gain_range.stop() %f)\n", openair0_cfg[0].rx_gain[0]-openair0_cfg[0].rx_gain_offset[0],openair0_cfg[0].rx_gain[0],gain_range.stop());
*/
return(0);
}
int trx_sodera_stop(int card) {
return(0);
}
rx_gain_calib_table_t calib_table_sodera[] = {
{3500000000.0,44.0},
{2660000000.0,49.0},
{2300000000.0,50.0},
{1880000000.0,53.0},
{816000000.0,58.0},
{-1,0}};
void set_rx_gain_offset(openair0_config_t *openair0_cfg, int chain_index,int bw_gain_adjust) {
int i=0;
// loop through calibration table to find best adjustment factor for RX frequency
double min_diff = 6e9,diff,gain_adj=0.0;
if (bw_gain_adjust==1) {
switch ((int)openair0_cfg[0].sample_rate) {
case 30720000:
break;
case 23040000:
gain_adj=1.25;
break;
case 15360000:
gain_adj=3.0;
break;
case 7680000:
gain_adj=6.0;
break;
case 3840000:
gain_adj=9.0;
break;
case 1920000:
gain_adj=12.0;
break;
default:
printf("unknown sampling rate %d\n",(int)openair0_cfg[0].sample_rate);
exit(-1);
break;
}
}
while (openair0_cfg->rx_gain_calib_table[i].freq>0) {
diff = fabs(openair0_cfg->rx_freq[chain_index] - openair0_cfg->rx_gain_calib_table[i].freq);
printf("cal %d: freq %f, offset %f, diff %f\n",
i,
openair0_cfg->rx_gain_calib_table[i].freq,
openair0_cfg->rx_gain_calib_table[i].offset,diff);
if (min_diff > diff) {
min_diff = diff;
openair0_cfg->rx_gain_offset[chain_index] = openair0_cfg->rx_gain_calib_table[i].offset+gain_adj;
}
i++;
}
}
int trx_sodera_get_stats(openair0_device_t *device)
{
return (0);
}
int trx_sodera_reset_stats(openair0_device_t *device)
{
return (0);
}
int openair0_dev_init_sodera(openair0_device_t *device, openair0_config_t *openair0_cfg)
{
sodera_t *s=&sodera_state;
size_t i;
// Initialize SODERA device
s->Port.RefreshDeviceList();
vector<string> deviceNames=s->Port.GetDeviceList();
if (deviceNames.size() == 1) {
if (s->Port.Open(0) != IConnection::SUCCESS) {
printf("Cannot open SoDeRa\n");
exit(-1);
}
LMSinfo devInfo = s->Port.GetInfo();
printf("Device %s, HW: %d, FW: %d, Protocol %d\n",
GetDeviceName(devInfo.device),
(int)devInfo.hardware,
(int)devInfo.firmware,
(int)devInfo.protocol);
printf("Configuring Si5351C\n");
s->Si.Initialize(&s->Port);
s->Si.SetPLL(0, 25000000, 0);
s->Si.SetPLL(1, 25000000, 0);
s->Si.SetClock(0, 27000000, true, false);
s->Si.SetClock(1, 27000000, true, false);
for (int i = 2; i < 8; ++i)
s->Si.SetClock(i, 27000000, false, false);
Si5351C::Status status = s->Si.ConfigureClocks();
if (status != Si5351C::SUCCESS)
{
printf("Failed to configure Si5351C");
exit(-1);
}
status = s->Si.UploadConfiguration();
if (status != Si5351C::SUCCESS)
printf("Failed to upload Si5351C configuration");
printf("Configuring LMS7002\n");
int bw_gain_adjust=0;
openair0_cfg[0].rx_gain_calib_table = calib_table_sodera;
switch ((int)openair0_cfg[0].sample_rate) {
case 30720000:
// from usrp_time_offset
openair0_cfg[0].samples_per_packet = 2048;
openair0_cfg[0].tx_sample_advance = 15;
openair0_cfg[0].tx_bw = 20e6;
openair0_cfg[0].rx_bw = 20e6;
openair0_cfg[0].tx_scheduling_advance = 8*openair0_cfg[0].samples_per_packet;
break;
case 15360000:
openair0_cfg[0].samples_per_packet = 2048;
openair0_cfg[0].tx_sample_advance = 45;
openair0_cfg[0].tx_bw = 10e6;
openair0_cfg[0].rx_bw = 10e6;
openair0_cfg[0].tx_scheduling_advance = 5*openair0_cfg[0].samples_per_packet;
break;
case 7680000:
openair0_cfg[0].samples_per_packet = 1024;
openair0_cfg[0].tx_sample_advance = 50;
openair0_cfg[0].tx_bw = 5e6;
openair0_cfg[0].rx_bw = 5e6;
openair0_cfg[0].tx_scheduling_advance = 5*openair0_cfg[0].samples_per_packet;
break;
case 1920000:
openair0_cfg[0].samples_per_packet = 256;
openair0_cfg[0].tx_sample_advance = 50;
openair0_cfg[0].tx_bw = 1.25e6;
openair0_cfg[0].rx_bw = 1.25e6;
openair0_cfg[0].tx_scheduling_advance = 8*openair0_cfg[0].samples_per_packet;
break;
default:
printf("Error: unknown sampling rate %f\n",openair0_cfg[0].sample_rate);
exit(-1);
break;
}
s->lmsControl = LMS7002M(&s->Port);
liblms7_status opStatus;
s->lmsControl.ResetChip();
opStatus = s->lmsControl.LoadConfig(openair0_cfg[0].configFilename);
if (opStatus != LIBLMS7_SUCCESS) {
printf("Failed to load configuration file %s\n",openair0_cfg[0].configFilename);
exit(-1);
}
opStatus = s->lmsControl.UploadAll();
if (opStatus != LIBLMS7_SUCCESS) {
printf("Failed to upload configuration file\n");
exit(-1);
}
opStatus = s->lmsControl.SetFrequencySX(LMS7002M::Tx, openair0_cfg[0].tx_freq[0]/1e6,30.72);
if (opStatus != LIBLMS7_SUCCESS) {
printf("Cannot set TX frequency %f MHz\n",openair0_cfg[0].tx_freq[0]/1e6);
exit(-1);
}
opStatus = s->lmsControl.SetFrequencySX(LMS7002M::Rx, openair0_cfg[0].rx_freq[0]/1e6,30.72);
if (opStatus != LIBLMS7_SUCCESS) {
printf("Cannot set RX frequency %f MHz\n",openair0_cfg[0].rx_freq[0]/1e6);
exit(-1);
}
// this makes RX/TX sampling rates equal
opStatus = s->lmsControl.Modify_SPI_Reg_bits(EN_ADCCLKH_CLKGN,0);
if (opStatus != LIBLMS7_SUCCESS) {
printf("Cannot modify SPI (EN_ADCCLKH_CLKGN)\n");
exit(-1);
}
opStatus = s->lmsControl.Modify_SPI_Reg_bits(CLKH_OV_CLKL_CGEN,2);
if (opStatus != LIBLMS7_SUCCESS) {
printf("Cannot modify SPI (CLKH_OV_CLKL_CGEN)\n");
exit(-1);
}
const float cgen_freq_MHz = 245.76;
const int interpolation = 0; // real interpolation = 2
const int decimation = 0; // real decimation = 2
opStatus = s->lmsControl.SetInterfaceFrequency(cgen_freq_MHz,interpolation,decimation);
if (opStatus != LIBLMS7_SUCCESS) {
printf("Cannot SetInterfaceFrequency (%f,%d,%d)\n",cgen_freq_MHz,interpolation,decimation);
exit(-1);
}
/*
// Run calibration procedure
float txrx_calibrationBandwidth_MHz = 5;
opStatus = s->lmsControl.CalibrateTx(txrx_calibrationBandwidth_MHz);
if (opStatus != LIBLMS7_SUCCESS){
printf("TX Calibration failed\n");
exit(-1);
}
opStatus = s->lmsControl.CalibrateRx(txrx_calibrationBandwidth_MHz);
if (opStatus != LIBLMS7_SUCCESS){
printf("RX Calibration failed\n");
exit(-1);
}
*/
s->lmsStream = new LMS_StreamBoard(&s->Port);
LMS_StreamBoard::Status opStreamStatus;
// this will configure that sampling rate at output of FPGA
opStreamStatus = s->lmsStream->ConfigurePLL(&s->Port,openair0_cfg[0].sample_rate,openair0_cfg[0].sample_rate,90);
if (opStatus != LIBLMS7_SUCCESS){
printf("Sample rate programming failed\n");
exit(-1);
}
/*
::uhd::gain_range_t gain_range = s->usrp->get_rx_gain_range(i);
// limit to maximum gain
if (openair0_cfg[0].rx_gain[i]-openair0_cfg[0].rx_gain_offset[i] > gain_range.stop()) {
printf("RX Gain %lu too high, lower by %f dB\n",i,openair0_cfg[0].rx_gain[i]-openair0_cfg[0].rx_gain_offset[i] - gain_range.stop());
exit(-1);
}
s->usrp->set_rx_gain(openair0_cfg[0].rx_gain[i]-openair0_cfg[0].rx_gain_offset[i],i);
printf("RX Gain %lu %f (%f) => %f (max %f)\n",i,
openair0_cfg[0].rx_gain[i],openair0_cfg[0].rx_gain_offset[i],
openair0_cfg[0].rx_gain[i]-openair0_cfg[0].rx_gain_offset[i],gain_range.stop());
}
}
for(i=0;i<s->usrp->get_tx_num_channels();i++) {
if (i<openair0_cfg[0].tx_num_channels) {
s->usrp->set_tx_rate(openair0_cfg[0].sample_rate,i);
s->usrp->set_tx_bandwidth(openair0_cfg[0].tx_bw,i);
printf("Setting tx freq/gain on channel %lu/%lu: BW %f (readback %f)\n",i,s->usrp->get_tx_num_channels(),openair0_cfg[0].tx_bw/1e6,s->usrp->get_tx_bandwidth(i)/1e6);
s->usrp->set_tx_freq(openair0_cfg[0].tx_freq[i],i);
s->usrp->set_tx_gain(openair0_cfg[0].tx_gain[i],i);
}
}
*/
// create tx & rx streamer
//stream_args_rx.args["spp"] = str(boost::format("%d") % 2048);//(openair0_cfg[0].rx_num_channels*openair0_cfg[0].samples_per_packet));
/*
for (i=0;i<openair0_cfg[0].rx_num_channels;i++) {
if (i<openair0_cfg[0].rx_num_channels) {
printf("RX Channel %lu\n",i);
std::cout << boost::format("Actual RX sample rate: %fMSps...") % (s->usrp->get_rx_rate(i)/1e6) << std::endl;
std::cout << boost::format("Actual RX frequency: %fGHz...") % (s->usrp->get_rx_freq(i)/1e9) << std::endl;
std::cout << boost::format("Actual RX gain: %f...") % (s->usrp->get_rx_gain(i)) << std::endl;
std::cout << boost::format("Actual RX bandwidth: %fM...") % (s->usrp->get_rx_bandwidth(i)/1e6) << std::endl;
std::cout << boost::format("Actual RX antenna: %s...") % (s->usrp->get_rx_antenna(i)) << std::endl;
}
}
for (i=0;i<openair0_cfg[0].tx_num_channels;i++) {
if (i<openair0_cfg[0].tx_num_channels) {
printf("TX Channel %lu\n",i);
std::cout << std::endl<<boost::format("Actual TX sample rate: %fMSps...") % (s->usrp->get_tx_rate(i)/1e6) << std::endl;
std::cout << boost::format("Actual TX frequency: %fGHz...") % (s->usrp->get_tx_freq(i)/1e9) << std::endl;
std::cout << boost::format("Actual TX gain: %f...") % (s->usrp->get_tx_gain(i)) << std::endl;
std::cout << boost::format("Actual TX bandwidth: %fM...") % (s->usrp->get_tx_bandwidth(i)/1e6) << std::endl;
std::cout << boost::format("Actual TX antenna: %s...") % (s->usrp->get_tx_antenna(i)) << std::endl;
}
*/
}
else {
printf("Please connect SoDeRa\n");
exit(-1);
}
device->priv = s;
device->trx_start_func = trx_sodera_start;
device->trx_write_func = trx_sodera_write;
device->trx_read_func = trx_sodera_read;
device->trx_get_stats_func = trx_sodera_get_stats;
device->trx_reset_stats_func = trx_sodera_reset_stats;
device->trx_end_func = trx_sodera_end;
device->trx_stop_func = trx_sodera_stop;
device->trx_set_freq_func = trx_sodera_set_freq;
device->trx_set_gains_func = trx_sodera_set_gains;
s->sample_rate = openair0_cfg[0].sample_rate;
s->channelscount = openair0_cfg[0].rx_num_channels;
// TODO:
return 0;
}