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sdrangel/plugins/samplesource/bladerf/bladerfinput.cpp

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///////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2015 Edouard Griffiths, F4EXB //
// //
// 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 as version 3 of the License, or //
// //
// 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 V3 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 <string.h>
#include <errno.h>
#include <QDebug>
#include "util/simpleserializer.h"
#include "dsp/dspengine.h"
#include "dsp/dspcommands.h"
#include "bladerfgui.h"
#include "bladerfinput.h"
#include "bladerfthread.h"
MESSAGE_CLASS_DEFINITION(BladerfInput::MsgConfigureBladerf, Message)
MESSAGE_CLASS_DEFINITION(BladerfInput::MsgReportBladerf, Message)
BladerfInput::Settings::Settings() :
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m_centerFrequency(435000*1000),
m_devSampleRate(3072000),
m_lnaGain(0),
m_vga1(20),
m_vga2(9),
m_bandwidth(1500000),
m_log2Decim(0),
m_fcPos(FC_POS_INFRA),
m_xb200(false),
m_xb200Path(BLADERF_XB200_MIX),
m_xb200Filter(BLADERF_XB200_AUTO_1DB)
{
}
void BladerfInput::Settings::resetToDefaults()
{
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m_centerFrequency = 435000*1000;
m_devSampleRate = 3072000;
m_lnaGain = 0;
m_vga1 = 20;
m_vga2 = 9;
m_bandwidth = 1500000;
m_log2Decim = 0;
m_fcPos = FC_POS_INFRA;
m_xb200 = false;
m_xb200Path = BLADERF_XB200_MIX;
m_xb200Filter = BLADERF_XB200_AUTO_1DB;
}
QByteArray BladerfInput::Settings::serialize() const
{
SimpleSerializer s(1);
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s.writeU64(1, m_centerFrequency);
s.writeS32(2, m_devSampleRate);
s.writeS32(3, m_lnaGain);
s.writeS32(4, m_vga1);
s.writeS32(5, m_vga2);
s.writeU32(6, m_log2Decim);
s.writeBool(7, m_xb200);
s.writeS32(8, (int) m_xb200Path);
s.writeS32(9, (int) m_xb200Filter);
s.writeS32(10, m_bandwidth);
s.writeS32(11, (int) m_fcPos);
return s.final();
}
bool BladerfInput::Settings::deserialize(const QByteArray& data)
{
SimpleDeserializer d(data);
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if (!d.isValid())
{
resetToDefaults();
return false;
}
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if (d.getVersion() == 1)
{
int intval;
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d.readU64(1, &m_centerFrequency, 435000*1000);
d.readS32(2, &m_devSampleRate, 3072000);
d.readS32(3, &m_lnaGain, 0);
d.readS32(4, &m_vga1, 20);
d.readS32(5, &m_vga2, 9);
d.readU32(6, &m_log2Decim, 0);
d.readBool(7, &m_xb200);
d.readS32(8, &intval);
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m_xb200Path = (bladerf_xb200_path) intval;
d.readS32(9, &intval);
m_xb200Filter = (bladerf_xb200_filter) intval;
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d.readS32(10, &m_bandwidth, 0);
d.readS32(11, &intval, 0);
m_fcPos = (fcPos_t) intval;
return true;
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}
else
{
resetToDefaults();
return false;
}
}
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BladerfInput::BladerfInput() :
m_settings(),
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m_dev(0),
m_bladerfThread(0),
m_deviceDescription("BladeRF")
{
}
BladerfInput::~BladerfInput()
{
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stop();
}
bool BladerfInput::init(const Message& cmd)
{
return false;
}
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bool BladerfInput::start(int device)
{
QMutexLocker mutexLocker(&m_mutex);
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if (m_dev != 0)
{
stop();
}
int res;
int fpga_loaded;
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if (!m_sampleFifo.setSize(96000 * 4))
{
qCritical("Could not allocate SampleFifo");
return false;
}
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if ((m_dev = open_bladerf_from_serial(0)) == 0) // TODO: fix; Open first available device as there is no proper handling for multiple devices
{
qCritical("could not open BladeRF");
return false;
}
fpga_loaded = bladerf_is_fpga_configured(m_dev);
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if (fpga_loaded < 0)
{
qCritical("Failed to check FPGA state: %s",
bladerf_strerror(fpga_loaded));
return false;
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}
else if (fpga_loaded == 0)
{
qCritical("The device's FPGA is not loaded.");
return false;
}
// TODO: adjust USB transfer data according to sample rate
if ((res = bladerf_sync_config(m_dev, BLADERF_MODULE_RX, BLADERF_FORMAT_SC16_Q11, 64, 8192, 32, 10000)) < 0)
{
qCritical("bladerf_sync_config with return code %d", res);
goto failed;
}
if ((res = bladerf_enable_module(m_dev, BLADERF_MODULE_RX, true)) < 0)
{
qCritical("bladerf_enable_module with return code %d", res);
goto failed;
}
if((m_bladerfThread = new BladerfThread(m_dev, &m_sampleFifo)) == NULL) {
qFatal("out of memory");
goto failed;
}
m_bladerfThread->startWork();
mutexLocker.unlock();
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applySettings(m_settings, true);
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qDebug("BladerfInput::startInput: started");
return true;
failed:
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stop();
return false;
}
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void BladerfInput::stop()
{
QMutexLocker mutexLocker(&m_mutex);
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if(m_bladerfThread != 0)
{
m_bladerfThread->stopWork();
delete m_bladerfThread;
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m_bladerfThread = 0;
}
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if(m_dev != 0)
{
bladerf_close(m_dev);
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m_dev = 0;
}
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m_deviceDescription.clear();
}
const QString& BladerfInput::getDeviceDescription() const
{
return m_deviceDescription;
}
int BladerfInput::getSampleRate() const
{
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int rate = m_settings.m_devSampleRate;
return (rate / (1<<m_settings.m_log2Decim));
}
quint64 BladerfInput::getCenterFrequency() const
{
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return m_settings.m_centerFrequency;
}
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bool BladerfInput::handleMessage(const Message& message)
{
if (MsgConfigureBladerf::match(message))
{
qDebug() << "BladerfInput::handleMessage: MsgConfigureBladerf";
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MsgConfigureBladerf& conf = (MsgConfigureBladerf&) message;
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if (!applySettings(conf.getSettings(), false))
{
qDebug("BladeRF config error");
}
return true;
}
else
{
return false;
}
}
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bool BladerfInput::applySettings(const Settings& settings, bool force)
{
QMutexLocker mutexLocker(&m_mutex);
qDebug() << "BladerfInput::applySettings: m_dev: " << m_dev;
if ((m_settings.m_lnaGain != settings.m_lnaGain) || force)
{
m_settings.m_lnaGain = settings.m_lnaGain;
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if (m_dev != 0)
{
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if(bladerf_set_lna_gain(m_dev, getLnaGain(m_settings.m_lnaGain)) != 0)
{
qDebug("bladerf_set_lna_gain() failed");
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}
else
{
qDebug() << "BladerfInput: LNA gain set to " << getLnaGain(m_settings.m_lnaGain);
}
}
}
if ((m_settings.m_vga1 != settings.m_vga1) || force)
{
m_settings.m_vga1 = settings.m_vga1;
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if (m_dev != 0)
{
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if(bladerf_set_rxvga1(m_dev, m_settings.m_vga1) != 0)
{
qDebug("bladerf_set_rxvga1() failed");
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}
else
{
qDebug() << "BladerfInput: VGA1 gain set to " << m_settings.m_vga1;
}
}
}
if ((m_settings.m_vga2 != settings.m_vga2) || force)
{
m_settings.m_vga2 = settings.m_vga2;
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if(m_dev != 0)
{
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if(bladerf_set_rxvga2(m_dev, m_settings.m_vga2) != 0)
{
qDebug("bladerf_set_rxvga2() failed");
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}
else
{
qDebug() << "BladerfInput: VGA2 gain set to " << m_settings.m_vga2;
}
}
}
if ((m_settings.m_xb200 != settings.m_xb200) || force)
{
m_settings.m_xb200 = settings.m_xb200;
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if (m_dev != 0)
{
if (m_settings.m_xb200)
{
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if (bladerf_expansion_attach(m_dev, BLADERF_XB_200) != 0)
{
qDebug("bladerf_expansion_attach(xb200) failed");
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}
else
{
qDebug() << "BladerfInput: Attach XB200";
}
}
else
{
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if (bladerf_expansion_attach(m_dev, BLADERF_XB_NONE) != 0)
{
qDebug("bladerf_expansion_attach(none) failed");
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}
else
{
qDebug() << "BladerfInput: Detach XB200";
}
}
}
}
if ((m_settings.m_xb200Path != settings.m_xb200Path) || force)
{
m_settings.m_xb200Path = settings.m_xb200Path;
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if (m_dev != 0)
{
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if(bladerf_xb200_set_path(m_dev, BLADERF_MODULE_RX, m_settings.m_xb200Path) != 0)
{
qDebug("bladerf_xb200_set_path(BLADERF_MODULE_RX) failed");
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}
else
{
qDebug() << "BladerfInput: set xb200 path to " << m_settings.m_xb200Path;
}
}
}
if ((m_settings.m_xb200Filter != settings.m_xb200Filter) || force)
{
m_settings.m_xb200Filter = settings.m_xb200Filter;
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if (m_dev != 0)
{
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if(bladerf_xb200_set_filterbank(m_dev, BLADERF_MODULE_RX, m_settings.m_xb200Filter) != 0)
{
qDebug("bladerf_xb200_set_filterbank(BLADERF_MODULE_RX) failed");
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}
else
{
qDebug() << "BladerfInput: set xb200 filter to " << m_settings.m_xb200Filter;
}
}
}
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if ((m_settings.m_devSampleRate != settings.m_devSampleRate) || force)
{
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m_settings.m_devSampleRate = settings.m_devSampleRate;
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if (m_dev != 0)
{
unsigned int actualSamplerate;
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if (bladerf_set_sample_rate(m_dev, BLADERF_MODULE_RX, m_settings.m_devSampleRate, &actualSamplerate) < 0)
{
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qCritical("could not set sample rate: %d", m_settings.m_devSampleRate);
}
else
{
qDebug() << "bladerf_set_sample_rate(BLADERF_MODULE_RX) actual sample rate is " << actualSamplerate;
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m_bladerfThread->setSamplerate(m_settings.m_devSampleRate);
}
}
}
if ((m_settings.m_bandwidth != settings.m_bandwidth) || force)
{
m_settings.m_bandwidth = settings.m_bandwidth;
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if(m_dev != 0)
{
unsigned int actualBandwidth;
if( bladerf_set_bandwidth(m_dev, BLADERF_MODULE_RX, m_settings.m_bandwidth, &actualBandwidth) < 0)
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{
qCritical("could not set bandwidth: %d", m_settings.m_bandwidth);
}
else
{
qDebug() << "bladerf_set_bandwidth(BLADERF_MODULE_RX) actual bandwidth is " << actualBandwidth;
}
}
}
if ((m_settings.m_log2Decim != settings.m_log2Decim) || force)
{
m_settings.m_log2Decim = settings.m_log2Decim;
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if(m_dev != 0)
{
m_bladerfThread->setLog2Decimation(m_settings.m_log2Decim);
qDebug() << "BladerfInput: set decimation to " << (1<<m_settings.m_log2Decim);
}
}
if ((m_settings.m_fcPos != settings.m_fcPos) || force)
{
m_settings.m_fcPos = settings.m_fcPos;
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if(m_dev != 0)
{
m_bladerfThread->setFcPos((int) m_settings.m_fcPos);
qDebug() << "BladerfInput: set fc pos (enum) to " << (int) m_settings.m_fcPos;
}
}
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m_settings.m_centerFrequency = settings.m_centerFrequency;
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qint64 centerFrequency = m_settings.m_centerFrequency;
qint64 f_img = centerFrequency;
qint64 f_cut = centerFrequency + m_settings.m_bandwidth/2;
if ((m_settings.m_log2Decim == 0) || (m_settings.m_fcPos == FC_POS_CENTER))
{
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centerFrequency = m_settings.m_centerFrequency;
f_img = centerFrequency;
f_cut = centerFrequency + m_settings.m_bandwidth/2;
}
else
{
if (m_settings.m_fcPos == FC_POS_INFRA)
{
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centerFrequency = m_settings.m_centerFrequency + (m_settings.m_devSampleRate / 4);
f_img = centerFrequency + m_settings.m_devSampleRate/2;
f_cut = centerFrequency + m_settings.m_bandwidth/2;
}
else if (m_settings.m_fcPos == FC_POS_SUPRA)
{
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centerFrequency = m_settings.m_centerFrequency - (m_settings.m_devSampleRate / 4);
f_img = centerFrequency - m_settings.m_devSampleRate/2;
f_cut = centerFrequency - m_settings.m_bandwidth/2;
}
}
if (m_dev != NULL)
{
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if (bladerf_set_frequency( m_dev, BLADERF_MODULE_RX, centerFrequency ) != 0)
{
qDebug("bladerf_set_frequency(%lld) failed", m_settings.m_centerFrequency);
}
}
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qDebug() << " - center freq: " << m_settings.m_centerFrequency << " Hz"
<< " RF center freq: " << centerFrequency << " Hz"
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<< " RF sample rate: " << m_settings.m_devSampleRate << "Hz"
<< " Actual sample rate: " << m_settings.m_devSampleRate/(1<<m_settings.m_log2Decim) << "Hz"
<< " BW: " << m_settings.m_bandwidth << "Hz"
<< " img: " << f_img << "Hz"
<< " cut: " << f_cut << "Hz"
<< " img - cut: " << f_img - f_cut;
return true;
}
bladerf_lna_gain BladerfInput::getLnaGain(int lnaGain)
{
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if (lnaGain == 2)
{
return BLADERF_LNA_GAIN_MAX;
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}
else if (lnaGain == 1)
{
return BLADERF_LNA_GAIN_MID;
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}
else
{
return BLADERF_LNA_GAIN_BYPASS;
}
}
struct bladerf *BladerfInput::open_bladerf_from_serial(const char *serial)
{
int status;
struct bladerf *dev;
struct bladerf_devinfo info;
/* Initialize all fields to "don't care" wildcard values.
*
* Immediately passing this to bladerf_open_with_devinfo() would cause
* libbladeRF to open any device on any available backend. */
bladerf_init_devinfo(&info);
/* Specify the desired device's serial number, while leaving all other
* fields in the info structure wildcard values */
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if (serial != NULL)
{
strncpy(info.serial, serial, BLADERF_SERIAL_LENGTH - 1);
info.serial[BLADERF_SERIAL_LENGTH - 1] = '\0';
}
status = bladerf_open_with_devinfo(&dev, &info);
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if (status == BLADERF_ERR_NODEV)
{
fprintf(stderr, "No devices available with serial=%s\n", serial);
return NULL;
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}
else if (status != 0)
{
fprintf(stderr, "Failed to open device with serial=%s (%s)\n",
serial, bladerf_strerror(status));
return NULL;
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}
else
{
return dev;
}
}